Transaction Hash:
Block:
22025569 at Mar-11-2025 06:59:11 PM +UTC
Transaction Fee:
0.000408560118825594 ETH
$0.76
Gas Used:
122,478 Gas / 3.335783723 Gwei
Emitted Events:
| 202 |
Seaport.OrderFulfilled( orderHash=3C2D02B41C8E6EB93DCB3422F7670A0AE45489854CD7C8E00A6E7A880B79890E, offerer=0x926c510c49e4b4d9a4624cdeacf0f2b097d7c2c5, zone=0x00000000...000000000, recipient=[Sender] 0x52f3d5973af83a31f9f334e06898604aec898d21, offer=, consideration= )
|
| 203 |
TheModZ.Approval( owner=0x926c510c49e4b4d9a4624cdeacf0f2b097d7c2c5, approved=0x00000000...000000000, tokenId=3258 )
|
| 204 |
TheModZ.Transfer( from=0x926c510c49e4b4d9a4624cdeacf0f2b097d7c2c5, to=[Sender] 0x52f3d5973af83a31f9f334e06898604aec898d21, tokenId=3258 )
|
Account State Difference:
| Address | Before | After | State Difference | ||
|---|---|---|---|---|---|
| 0x00000000...1123eB395 | (Seaport 1.6) | ||||
| 0x0000a26b...000fAa719 | 3.879616931462555941 Eth | 3.879637426462555941 Eth | 0.000020495 | ||
|
0x4838B106...B0BAD5f97
Miner
| (Titan Builder) | 7.370615057713424917 Eth | 7.370733861373424917 Eth | 0.00011880366 | |
| 0x50e712b3...461418F23 | |||||
| 0x52f3D597...AeC898d21 |
0.017041470060692157 Eth
Nonce: 25
|
0.012533909941866563 Eth
Nonce: 26
| 0.004507560118825594 | ||
| 0x926c510c...097D7c2C5 | 0.045498477872852688 Eth | 0.049576982872852688 Eth | 0.004078505 |
Execution Trace
ETH 0.004099
Seaport.fulfillBasicOrder_efficient_6GL6yc( [{name:considerationToken, type:address, order:1, indexed:false, value:0x0000000000000000000000000000000000000000, valueString:0x0000000000000000000000000000000000000000}, {name:considerationIdentifier, type:uint256, order:2, indexed:false, value:0, valueString:0}, {name:considerationAmount, type:uint256, order:3, indexed:false, value:4078505000000000, valueString:4078505000000000}, {name:offerer, type:address, order:4, indexed:false, value:0x926c510c49E4B4D9a4624cDEacF0F2b097D7c2C5, valueString:0x926c510c49E4B4D9a4624cDEacF0F2b097D7c2C5}, {name:zone, type:address, order:5, indexed:false, value:0x0000000000000000000000000000000000000000, valueString:0x0000000000000000000000000000000000000000}, {name:offerToken, type:address, order:6, indexed:false, value:0x50e712b3A260D7639179e8277836253461418F23, valueString:0x50e712b3A260D7639179e8277836253461418F23}, {name:offerIdentifier, type:uint256, order:7, indexed:false, value:3258, valueString:3258}, {name:offerAmount, type:uint256, order:8, indexed:false, value:1, valueString:1}, {name:basicOrderType, type:uint8, order:9, indexed:false, value:0, valueString:0}, {name:startTime, type:uint256, order:10, indexed:false, value:1740663518, valueString:1740663518}, {name:endTime, type:uint256, order:11, indexed:false, value:1745847518, valueString:1745847518}, {name:zoneHash, type:bytes32, order:12, indexed:false, value:0000000000000000000000000000000000000000000000000000000000000000, valueString:0000000000000000000000000000000000000000000000000000000000000000}, {name:salt, type:uint256, order:13, indexed:false, value:27855337018906766782546881864045825683096516384821792734252194436456322294944, valueString:27855337018906766782546881864045825683096516384821792734252194436456322294944}, {name:offererConduitKey, type:bytes32, order:14, indexed:false, value:0000007B02230091A7ED01230072F7006A004D60A8D4E71D599B8104250F0000, valueString:0000007B02230091A7ED01230072F7006A004D60A8D4E71D599B8104250F0000}, {name:fulfillerConduitKey, type:bytes32, order:15, indexed:false, value:0000007B02230091A7ED01230072F7006A004D60A8D4E71D599B8104250F0000, valueString:0000007B02230091A7ED01230072F7006A004D60A8D4E71D599B8104250F0000}, {name:totalOriginalAdditionalRecipients, type:uint256, order:16, indexed:false, value:1, valueString:1}, {name:additionalRecipients, type:tuple[], order:17, indexed:false}, {name:signature, type:bytes, order:18, indexed:false, value:0xAE639EDF01732F7DB4CAA7DE194DD9B926E2BBF28661F412E02C468E3AE483C296D02DBDD0514445ED4E93CC71F4EF500BDBE97D752DA9CA10E351C03736E2760000008FE9879453D01990E6F0EACC27F783BE3BE37319284772ABD82D7CBC0B0313D9E83B835B5FCFCCB06CA81A5BC2EF2C9DE6AAAD86801EB6F21BFEB51E1C8B17B4806FE5DB8A05D4690B9BD6FAA68E125CB71175B0EF609C11703851C7C127D86FD4DE4E6A07D983F39B013349D03591150658AC4FD45D17658A513F964C583378, valueString:0xAE639EDF01732F7DB4CAA7DE194DD9B926E2BBF28661F412E02C468E3AE483C296D02DBDD0514445ED4E93CC71F4EF500BDBE97D752DA9CA10E351C03736E2760000008FE9879453D01990E6F0EACC27F783BE3BE37319284772ABD82D7CBC0B0313D9E83B835B5FCFCCB06CA81A5BC2EF2C9DE6AAAD86801EB6F21BFEB51E1C8B17B4806FE5DB8A05D4690B9BD6FAA68E125CB71175B0EF609C11703851C7C127D86FD4DE4E6A07D983F39B013349D03591150658AC4FD45D17658A513F964C583378}] )
Seaport.fulfillBasicOrder_efficient_6GL6yc( [{name:considerationToken, type:address, order:1, indexed:false, value:0x0000000000000000000000000000000000000000, valueString:0x0000000000000000000000000000000000000000}, {name:considerationIdentifier, type:uint256, order:2, indexed:false, value:0, valueString:0}, {name:considerationAmount, type:uint256, order:3, indexed:false, value:4078505000000000, valueString:4078505000000000}, {name:offerer, type:address, order:4, indexed:false, value:0x926c510c49E4B4D9a4624cDEacF0F2b097D7c2C5, valueString:0x926c510c49E4B4D9a4624cDEacF0F2b097D7c2C5}, {name:zone, type:address, order:5, indexed:false, value:0x0000000000000000000000000000000000000000, valueString:0x0000000000000000000000000000000000000000}, {name:offerToken, type:address, order:6, indexed:false, value:0x50e712b3A260D7639179e8277836253461418F23, valueString:0x50e712b3A260D7639179e8277836253461418F23}, {name:offerIdentifier, type:uint256, order:7, indexed:false, value:3258, valueString:3258}, {name:offerAmount, type:uint256, order:8, indexed:false, value:1, valueString:1}, {name:basicOrderType, type:uint8, order:9, indexed:false, value:0, valueString:0}, {name:startTime, type:uint256, order:10, indexed:false, value:1740663518, valueString:1740663518}, {name:endTime, type:uint256, order:11, indexed:false, value:1745847518, valueString:1745847518}, {name:zoneHash, type:bytes32, order:12, indexed:false, value:0000000000000000000000000000000000000000000000000000000000000000, valueString:0000000000000000000000000000000000000000000000000000000000000000}, {name:salt, type:uint256, order:13, indexed:false, value:27855337018906766782546881864045825683096516384821792734252194436456322294944, valueString:27855337018906766782546881864045825683096516384821792734252194436456322294944}, {name:offererConduitKey, type:bytes32, order:14, indexed:false, value:0000007B02230091A7ED01230072F7006A004D60A8D4E71D599B8104250F0000, valueString:0000007B02230091A7ED01230072F7006A004D60A8D4E71D599B8104250F0000}, {name:fulfillerConduitKey, type:bytes32, order:15, indexed:false, value:0000007B02230091A7ED01230072F7006A004D60A8D4E71D599B8104250F0000, valueString:0000007B02230091A7ED01230072F7006A004D60A8D4E71D599B8104250F0000}, {name:totalOriginalAdditionalRecipients, type:uint256, order:16, indexed:false, value:1, valueString:1}, {name:additionalRecipients, type:tuple[], order:17, indexed:false}, {name:signature, type:bytes, order:18, indexed:false, value:0xAE639EDF01732F7DB4CAA7DE194DD9B926E2BBF28661F412E02C468E3AE483C296D02DBDD0514445ED4E93CC71F4EF500BDBE97D752DA9CA10E351C03736E2760000008FE9879453D01990E6F0EACC27F783BE3BE37319284772ABD82D7CBC0B0313D9E83B835B5FCFCCB06CA81A5BC2EF2C9DE6AAAD86801EB6F21BFEB51E1C8B17B4806FE5DB8A05D4690B9BD6FAA68E125CB71175B0EF609C11703851C7C127D86FD4DE4E6A07D983F39B013349D03591150658AC4FD45D17658A513F964C583378, valueString:0xAE639EDF01732F7DB4CAA7DE194DD9B926E2BBF28661F412E02C468E3AE483C296D02DBDD0514445ED4E93CC71F4EF500BDBE97D752DA9CA10E351C03736E2760000008FE9879453D01990E6F0EACC27F783BE3BE37319284772ABD82D7CBC0B0313D9E83B835B5FCFCCB06CA81A5BC2EF2C9DE6AAAD86801EB6F21BFEB51E1C8B17B4806FE5DB8A05D4690B9BD6FAA68E125CB71175B0EF609C11703851C7C127D86FD4DE4E6A07D983F39B013349D03591150658AC4FD45D17658A513F964C583378}] )
-
Null: 0x000...001.33a1c097( ) Conduit.execute( transfers= ) => ( transfers= )-
TheModZ.transferFrom( from=0x926c510c49E4B4D9a4624cDEacF0F2b097D7c2C5, to=0x52f3D5973af83A31F9F334e06898604AeC898d21, tokenId=3258 )
-
- ETH 0.000020495
PayableProxy.CALL( )
- ETH 0.004078505
0x926c510c49e4b4d9a4624cdeacf0f2b097d7c2c5.CALL( )
File 1 of 4: Seaport
File 2 of 4: TheModZ
File 3 of 4: Conduit
File 4 of 4: PayableProxy
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import { Consideration } from "./lib/Consideration.sol";
/**
* @title Seaport
* @custom:version 1.6
* @author 0age (0age.eth)
* @custom:coauthor d1ll0n (d1ll0n.eth)
* @custom:coauthor transmissions11 (t11s.eth)
* @custom:coauthor James Wenzel (emo.eth)
* @custom:coauthor Daniel Viau (snotrocket.eth)
* @custom:contributor Kartik (slokh.eth)
* @custom:contributor LeFevre (lefevre.eth)
* @custom:contributor Joseph Schiarizzi (CupOJoseph.eth)
* @custom:contributor Aspyn Palatnick (stuckinaboot.eth)
* @custom:contributor Stephan Min (stephanm.eth)
* @custom:contributor Ryan Ghods (ralxz.eth)
* @custom:contributor hack3r-0m (hack3r-0m.eth)
* @custom:contributor Diego Estevez (antidiego.eth)
* @custom:contributor Chomtana (chomtana.eth)
* @custom:contributor Saw-mon and Natalie (sawmonandnatalie.eth)
* @custom:contributor 0xBeans (0xBeans.eth)
* @custom:contributor 0x4non (punkdev.eth)
* @custom:contributor Laurence E. Day (norsefire.eth)
* @custom:contributor vectorized.eth (vectorized.eth)
* @custom:contributor karmacoma (karmacoma.eth)
* @custom:contributor horsefacts (horsefacts.eth)
* @custom:contributor UncarvedBlock (uncarvedblock.eth)
* @custom:contributor Zoraiz Mahmood (zorz.eth)
* @custom:contributor William Poulin (wpoulin.eth)
* @custom:contributor Rajiv Patel-O'Connor (rajivpoc.eth)
* @custom:contributor tserg (tserg.eth)
* @custom:contributor cygaar (cygaar.eth)
* @custom:contributor Meta0xNull (meta0xnull.eth)
* @custom:contributor gpersoon (gpersoon.eth)
* @custom:contributor Matt Solomon (msolomon.eth)
* @custom:contributor Weikang Song (weikangs.eth)
* @custom:contributor zer0dot (zer0dot.eth)
* @custom:contributor Mudit Gupta (mudit.eth)
* @custom:contributor leonardoalt (leoalt.eth)
* @custom:contributor cmichel (cmichel.eth)
* @custom:contributor PraneshASP (pranesh.eth)
* @custom:contributor JasperAlexander (jasperalexander.eth)
* @custom:contributor Ellahi (ellahi.eth)
* @custom:contributor zaz (1zaz1.eth)
* @custom:contributor berndartmueller (berndartmueller.eth)
* @custom:contributor dmfxyz (dmfxyz.eth)
* @custom:contributor daltoncoder (dontkillrobots.eth)
* @custom:contributor 0xf4ce (0xf4ce.eth)
* @custom:contributor phaze (phaze.eth)
* @custom:contributor hrkrshnn (hrkrshnn.eth)
* @custom:contributor axic (axic.eth)
* @custom:contributor leastwood (leastwood.eth)
* @custom:contributor 0xsanson (sanson.eth)
* @custom:contributor blockdev (blockd3v.eth)
* @custom:contributor fiveoutofnine (fiveoutofnine.eth)
* @custom:contributor shuklaayush (shuklaayush.eth)
* @custom:contributor dravee (dravee.eth)
* @custom:contributor 0xPatissier
* @custom:contributor pcaversaccio
* @custom:contributor David Eiber
* @custom:contributor csanuragjain
* @custom:contributor sach1r0
* @custom:contributor twojoy0
* @custom:contributor ori_dabush
* @custom:contributor Daniel Gelfand
* @custom:contributor okkothejawa
* @custom:contributor FlameHorizon
* @custom:contributor vdrg
* @custom:contributor dmitriia
* @custom:contributor bokeh-eth
* @custom:contributor asutorufos
* @custom:contributor rfart(rfa)
* @custom:contributor Riley Holterhus
* @custom:contributor big-tech-sux
* @notice Seaport is a generalized native token/ERC20/ERC721/ERC1155
* marketplace with lightweight methods for common routes as well as
* more flexible methods for composing advanced orders or groups of
* orders. Each order contains an arbitrary number of items that may be
* spent (the "offer") along with an arbitrary number of items that must
* be received back by the indicated recipients (the "consideration").
*/
contract Seaport is Consideration {
/**
* @notice Derive and set hashes, reference chainId, and associated domain
* separator during deployment.
*
* @param conduitController A contract that deploys conduits, or proxies
* that may optionally be used to transfer approved
* ERC20/721/1155 tokens.
*/
constructor(address conduitController) Consideration(conduitController) {}
/**
* @dev Internal pure function to retrieve and return the name of this
* contract.
*
* @return The name of this contract.
*/
function _name() internal pure override returns (string memory) {
// Return the name of the contract.
assembly {
mstore(0x20, 0x20)
mstore(0x47, 0x07536561706f7274)
return(0x20, 0x60)
}
}
/**
* @dev Internal pure function to retrieve the name of this contract as a
* string that will be used to derive the name hash in the constructor.
*
* @return The name of this contract as a string.
*/
function _nameString() internal pure override returns (string memory) {
// Return the name of the contract.
return "Seaport";
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
ConsiderationInterface
} from "seaport-types/src/interfaces/ConsiderationInterface.sol";
import {
AdvancedOrder,
BasicOrderParameters,
CriteriaResolver,
Execution,
Fulfillment,
FulfillmentComponent,
Order,
OrderComponents
} from "seaport-types/src/lib/ConsiderationStructs.sol";
import { OrderCombiner } from "./OrderCombiner.sol";
import {
CalldataStart,
CalldataPointer
} from "seaport-types/src/helpers/PointerLibraries.sol";
import {
Offset_fulfillAdvancedOrder_criteriaResolvers,
Offset_fulfillAvailableAdvancedOrders_cnsdrationFlflmnts,
Offset_fulfillAvailableAdvancedOrders_criteriaResolvers,
Offset_fulfillAvailableAdvancedOrders_offerFulfillments,
Offset_fulfillAvailableOrders_considerationFulfillments,
Offset_fulfillAvailableOrders_offerFulfillments,
Offset_matchAdvancedOrders_criteriaResolvers,
Offset_matchAdvancedOrders_fulfillments,
Offset_matchOrders_fulfillments,
OrderParameters_counter_offset
} from "seaport-types/src/lib/ConsiderationConstants.sol";
/**
* @title Consideration
* @author 0age (0age.eth)
* @custom:coauthor d1ll0n (d1ll0n.eth)
* @custom:coauthor transmissions11 (t11s.eth)
* @custom:coauthor James Wenzel (emo.eth)
* @custom:coauthor Daniel Viau (snotrocket.eth)
* @custom:version 1.6
* @notice Consideration is a generalized native token/ERC20/ERC721/ERC1155
* marketplace that provides lightweight methods for common routes as
* well as more flexible methods for composing advanced orders or groups
* of orders. Each order contains an arbitrary number of items that may
* be spent (the "offer") along with an arbitrary number of items that
* must be received back by the indicated recipients (the
* "consideration").
*/
contract Consideration is ConsiderationInterface, OrderCombiner {
/**
* @notice Derive and set hashes, reference chainId, and associated domain
* separator during deployment.
*
* @param conduitController A contract that deploys conduits, or proxies
* that may optionally be used to transfer approved
* ERC20/721/1155 tokens.
*/
constructor(address conduitController) OrderCombiner(conduitController) {}
/**
* @notice Accept native token transfers during execution that may then be
* used to facilitate native token transfers, where any tokens that
* remain will be transferred to the caller. Native tokens are only
* acceptable mid-fulfillment (and not during basic fulfillment).
*/
receive() external payable {
// Ensure the reentrancy guard is currently set to accept native tokens.
_assertAcceptingNativeTokens();
}
/**
* @notice Fulfill an order offering an ERC20, ERC721, or ERC1155 item by
* supplying Ether (or other native tokens), ERC20 tokens, an ERC721
* item, or an ERC1155 item as consideration. Six permutations are
* supported: Native token to ERC721, Native token to ERC1155, ERC20
* to ERC721, ERC20 to ERC1155, ERC721 to ERC20, and ERC1155 to
* ERC20 (with native tokens supplied as msg.value). For an order to
* be eligible for fulfillment via this method, it must contain a
* single offer item (though that item may have a greater amount if
* the item is not an ERC721). An arbitrary number of "additional
* recipients" may also be supplied which will each receive native
* tokens or ERC20 items from the fulfiller as consideration. Refer
* to the documentation for a more comprehensive summary of how to
* utilize this method and what orders are compatible with it.
*
* @custom:param parameters Additional information on the fulfilled order.
* Note that the offerer and the fulfiller must
* first approve this contract (or their chosen
* conduit if indicated) before any tokens can be
* transferred. Also note that contract recipients
* of ERC1155 consideration items must implement
* `onERC1155Received` to receive those items.
*
* @return fulfilled A boolean indicating whether the order has been
* successfully fulfilled.
*/
function fulfillBasicOrder(
/**
* @custom:name parameters
*/
BasicOrderParameters calldata
) external payable override returns (bool fulfilled) {
// Validate and fulfill the basic order.
fulfilled = _validateAndFulfillBasicOrder();
}
/**
* @notice Fulfill an order offering an ERC20, ERC721, or ERC1155 item by
* supplying Ether (or other native tokens), ERC20 tokens, an ERC721
* item, or an ERC1155 item as consideration. Six permutations are
* supported: Native token to ERC721, Native token to ERC1155, ERC20
* to ERC721, ERC20 to ERC1155, ERC721 to ERC20, and ERC1155 to
* ERC20 (with native tokens supplied as msg.value). For an order to
* be eligible for fulfillment via this method, it must contain a
* single offer item (though that item may have a greater amount if
* the item is not an ERC721). An arbitrary number of "additional
* recipients" may also be supplied which will each receive native
* tokens or ERC20 items from the fulfiller as consideration. Refer
* to the documentation for a more comprehensive summary of how to
* utilize this method and what orders are compatible with it. Note
* that this function costs less gas than `fulfillBasicOrder` due to
* the zero bytes in the function selector (0x00000000) which also
* results in earlier function dispatch.
*
* @custom:param parameters Additional information on the fulfilled order.
* Note that the offerer and the fulfiller must
* first approve this contract (or their chosen
* conduit if indicated) before any tokens can be
* transferred. Also note that contract recipients
* of ERC1155 consideration items must implement
* `onERC1155Received` to receive those items.
*
* @return fulfilled A boolean indicating whether the order has been
* successfully fulfilled.
*/
function fulfillBasicOrder_efficient_6GL6yc(
/**
* @custom:name parameters
*/
BasicOrderParameters calldata
) external payable override returns (bool fulfilled) {
// Validate and fulfill the basic order.
fulfilled = _validateAndFulfillBasicOrder();
}
/**
* @notice Fulfill an order with an arbitrary number of items for offer and
* consideration. Note that this function does not support
* criteria-based orders or partial filling of orders (though
* filling the remainder of a partially-filled order is supported).
*
* @custom:param order The order to fulfill. Note that both the
* offerer and the fulfiller must first approve
* this contract (or the corresponding conduit if
* indicated) to transfer any relevant tokens on
* their behalf and that contracts must implement
* `onERC1155Received` to receive ERC1155 tokens
* as consideration.
* @param fulfillerConduitKey A bytes32 value indicating what conduit, if
* any, to source the fulfiller's token approvals
* from. The zero hash signifies that no conduit
* should be used (and direct approvals set on
* this contract).
*
* @return fulfilled A boolean indicating whether the order has been
* successfully fulfilled.
*/
function fulfillOrder(
/**
* @custom:name order
*/
Order calldata,
bytes32 fulfillerConduitKey
) external payable override returns (bool fulfilled) {
// Convert order to "advanced" order, then validate and fulfill it.
fulfilled = _validateAndFulfillAdvancedOrder(
_toAdvancedOrderReturnType(_decodeOrderAsAdvancedOrder)(
CalldataStart.pptr()
),
new CriteriaResolver[](0), // No criteria resolvers supplied.
fulfillerConduitKey,
msg.sender
);
}
/**
* @notice Fill an order, fully or partially, with an arbitrary number of
* items for offer and consideration alongside criteria resolvers
* containing specific token identifiers and associated proofs.
*
* @custom:param advancedOrder The order to fulfill along with the
* fraction of the order to attempt to fill.
* Note that both the offerer and the
* fulfiller must first approve this
* contract (or their conduit if indicated
* by the order) to transfer any relevant
* tokens on their behalf and that contracts
* must implement `onERC1155Received` to
* receive ERC1155 tokens as consideration.
* Also note that all offer and
* consideration components must have no
* remainder after multiplication of the
* respective amount with the supplied
* fraction for the partial fill to be
* considered valid.
* @custom:param criteriaResolvers An array where each element contains a
* reference to a specific offer or
* consideration, a token identifier, and a
* proof that the supplied token identifier
* is contained in the merkle root held by
* the item in question's criteria element.
* Note that an empty criteria indicates
* that any (transferable) token identifier
* on the token in question is valid and
* that no associated proof needs to be
* supplied.
* @param fulfillerConduitKey A bytes32 value indicating what conduit,
* if any, to source the fulfiller's token
* approvals from. The zero hash signifies
* that no conduit should be used (and
* direct approvals set on this contract).
* @param recipient The intended recipient for all received
* items, with `address(0)` indicating that
* the caller should receive the items.
*
* @return fulfilled A boolean indicating whether the order has been
* successfully fulfilled.
*/
function fulfillAdvancedOrder(
/**
* @custom:name advancedOrder
*/
AdvancedOrder calldata,
/**
* @custom:name criteriaResolvers
*/
CriteriaResolver[] calldata,
bytes32 fulfillerConduitKey,
address recipient
) external payable override returns (bool fulfilled) {
// Validate and fulfill the order.
fulfilled = _validateAndFulfillAdvancedOrder(
_toAdvancedOrderReturnType(_decodeAdvancedOrder)(
CalldataStart.pptr()
),
_toCriteriaResolversReturnType(_decodeCriteriaResolvers)(
CalldataStart.pptrOffset(
Offset_fulfillAdvancedOrder_criteriaResolvers
)
),
fulfillerConduitKey,
_substituteCallerForEmptyRecipient(recipient)
);
}
/**
* @notice Attempt to fill a group of orders, each with an arbitrary number
* of items for offer and consideration. Any order that is not
* currently active, has already been fully filled, or has been
* cancelled will be omitted. Remaining offer and consideration
* items will then be aggregated where possible as indicated by the
* supplied offer and consideration component arrays and aggregated
* items will be transferred to the fulfiller or to each intended
* recipient, respectively. Note that a failing item transfer or an
* issue with order formatting will cause the entire batch to fail.
* Note that this function does not support criteria-based orders or
* partial filling of orders (though filling the remainder of a
* partially-filled order is supported).
*
* @custom:param orders The orders to fulfill. Note that
* both the offerer and the
* fulfiller must first approve this
* contract (or the corresponding
* conduit if indicated) to transfer
* any relevant tokens on their
* behalf and that contracts must
* implement `onERC1155Received` to
* receive ERC1155 tokens as
* consideration.
* @custom:param offerFulfillments An array of FulfillmentComponent
* arrays indicating which offer
* items to attempt to aggregate
* when preparing executions. Note
* that any offer items not included
* as part of a fulfillment will be
* sent unaggregated to the caller.
* @custom:param considerationFulfillments An array of FulfillmentComponent
* arrays indicating which
* consideration items to attempt to
* aggregate when preparing
* executions.
* @param fulfillerConduitKey A bytes32 value indicating what
* conduit, if any, to source the
* fulfiller's token approvals from.
* The zero hash signifies that no
* conduit should be used (and
* direct approvals set on this
* contract).
* @param maximumFulfilled The maximum number of orders to
* fulfill.
*
* @return availableOrders An array of booleans indicating if each order
* with an index corresponding to the index of the
* returned boolean was fulfillable or not.
* @return executions An array of elements indicating the sequence of
* transfers performed as part of matching the given
* orders.
*/
function fulfillAvailableOrders(
/**
* @custom:name orders
*/
Order[] calldata,
/**
* @custom:name offerFulfillments
*/
FulfillmentComponent[][] calldata,
/**
* @custom:name considerationFulfillments
*/
FulfillmentComponent[][] calldata,
bytes32 fulfillerConduitKey,
uint256 maximumFulfilled
)
external
payable
override
returns (
bool[] memory /* availableOrders */,
Execution[] memory /* executions */
)
{
// Convert orders to "advanced" orders and fulfill all available orders.
return
_fulfillAvailableAdvancedOrders(
_toAdvancedOrdersReturnType(_decodeOrdersAsAdvancedOrders)(
CalldataStart.pptr()
), // Convert to advanced orders.
new CriteriaResolver[](0), // No criteria resolvers supplied.
_toNestedFulfillmentComponentsReturnType(
_decodeNestedFulfillmentComponents
)(
CalldataStart.pptrOffset(
Offset_fulfillAvailableOrders_offerFulfillments
)
),
_toNestedFulfillmentComponentsReturnType(
_decodeNestedFulfillmentComponents
)(
CalldataStart.pptrOffset(
Offset_fulfillAvailableOrders_considerationFulfillments
)
),
fulfillerConduitKey,
msg.sender,
maximumFulfilled
);
}
/**
* @notice Attempt to fill a group of orders, fully or partially, with an
* arbitrary number of items for offer and consideration per order
* alongside criteria resolvers containing specific token
* identifiers and associated proofs. Any order that is not
* currently active, has already been fully filled, or has been
* cancelled will be omitted. Remaining offer and consideration
* items will then be aggregated where possible as indicated by the
* supplied offer and consideration component arrays and aggregated
* items will be transferred to the fulfiller or to each intended
* recipient, respectively. Note that a failing item transfer or an
* issue with order formatting will cause the entire batch to fail.
*
* @custom:param advancedOrders The orders to fulfill along with
* the fraction of those orders to
* attempt to fill. Note that both
* the offerer and the fulfiller
* must first approve this contract
* (or their conduit if indicated by
* the order) to transfer any
* relevant tokens on their behalf
* and that contracts must implement
* `onERC1155Received` to receive
* ERC1155 tokens as consideration.
* Also note that all offer and
* consideration components must
* have no remainder after
* multiplication of the respective
* amount with the supplied fraction
* for an order's partial fill
* amount to be considered valid.
* @custom:param criteriaResolvers An array where each element
* contains a reference to a
* specific offer or consideration,
* a token identifier, and a proof
* that the supplied token
* identifier is contained in the
* merkle root held by the item in
* question's criteria element. Note
* that an empty criteria indicates
* that any (transferable) token
* identifier on the token in
* question is valid and that no
* associated proof needs to be
* supplied.
* @custom:param offerFulfillments An array of FulfillmentComponent
* arrays indicating which offer
* items to attempt to aggregate
* when preparing executions. Note
* that any offer items not included
* as part of a fulfillment will be
* sent unaggregated to the caller.
* @custom:param considerationFulfillments An array of FulfillmentComponent
* arrays indicating which
* consideration items to attempt to
* aggregate when preparing
* executions.
* @param fulfillerConduitKey A bytes32 value indicating what
* conduit, if any, to source the
* fulfiller's token approvals from.
* The zero hash signifies that no
* conduit should be used (and
* direct approvals set on this
* contract).
* @param recipient The intended recipient for all
* received items, with `address(0)`
* indicating that the caller should
* receive the offer items.
* @param maximumFulfilled The maximum number of orders to
* fulfill.
*
* @return availableOrders An array of booleans indicating if each order
* with an index corresponding to the index of the
* returned boolean was fulfillable or not.
* @return executions An array of elements indicating the sequence of
* transfers performed as part of matching the given
* orders.
*/
function fulfillAvailableAdvancedOrders(
/**
* @custom:name advancedOrders
*/
AdvancedOrder[] calldata,
/**
* @custom:name criteriaResolvers
*/
CriteriaResolver[] calldata,
/**
* @custom:name offerFulfillments
*/
FulfillmentComponent[][] calldata,
/**
* @custom:name considerationFulfillments
*/
FulfillmentComponent[][] calldata,
bytes32 fulfillerConduitKey,
address recipient,
uint256 maximumFulfilled
)
external
payable
override
returns (
bool[] memory /* availableOrders */,
Execution[] memory /* executions */
)
{
// Fulfill all available orders.
return
_fulfillAvailableAdvancedOrders(
_toAdvancedOrdersReturnType(_decodeAdvancedOrders)(
CalldataStart.pptr()
),
_toCriteriaResolversReturnType(_decodeCriteriaResolvers)(
CalldataStart.pptrOffset(
Offset_fulfillAvailableAdvancedOrders_criteriaResolvers
)
),
_toNestedFulfillmentComponentsReturnType(
_decodeNestedFulfillmentComponents
)(
CalldataStart.pptrOffset(
Offset_fulfillAvailableAdvancedOrders_offerFulfillments
)
),
_toNestedFulfillmentComponentsReturnType(
_decodeNestedFulfillmentComponents
)(
CalldataStart.pptrOffset(
Offset_fulfillAvailableAdvancedOrders_cnsdrationFlflmnts
)
),
fulfillerConduitKey,
_substituteCallerForEmptyRecipient(recipient),
maximumFulfilled
);
}
/**
* @notice Match an arbitrary number of orders, each with an arbitrary
* number of items for offer and consideration along with a set of
* fulfillments allocating offer components to consideration
* components. Note that this function does not support
* criteria-based or partial filling of orders (though filling the
* remainder of a partially-filled order is supported). Any unspent
* offer item amounts or native tokens will be transferred to the
* caller.
*
* @custom:param orders The orders to match. Note that both the
* offerer and fulfiller on each order must first
* approve this contract (or their conduit if
* indicated by the order) to transfer any
* relevant tokens on their behalf and each
* consideration recipient must implement
* `onERC1155Received` to receive ERC1155 tokens.
* @custom:param fulfillments An array of elements allocating offer
* components to consideration components. Note
* that each consideration component must be
* fully met for the match operation to be valid,
* and that any unspent offer items will be sent
* unaggregated to the caller.
*
* @return executions An array of elements indicating the sequence of
* transfers performed as part of matching the given
* orders. Note that unspent offer item amounts or native
* tokens will not be reflected as part of this array.
*/
function matchOrders(
/**
* @custom:name orders
*/
Order[] calldata,
/**
* @custom:name fulfillments
*/
Fulfillment[] calldata
) external payable override returns (Execution[] memory /* executions */) {
// Convert to advanced, validate, and match orders using fulfillments.
return
_matchAdvancedOrders(
_toAdvancedOrdersReturnType(_decodeOrdersAsAdvancedOrders)(
CalldataStart.pptr()
),
new CriteriaResolver[](0), // No criteria resolvers supplied.
_toFulfillmentsReturnType(_decodeFulfillments)(
CalldataStart.pptrOffset(Offset_matchOrders_fulfillments)
),
msg.sender
);
}
/**
* @notice Match an arbitrary number of full, partial, or contract orders,
* each with an arbitrary number of items for offer and
* consideration, supplying criteria resolvers containing specific
* token identifiers and associated proofs as well as fulfillments
* allocating offer components to consideration components. Any
* unspent offer item amounts will be transferred to the designated
* recipient (with the null address signifying to use the caller)
* and any unspent native tokens will be returned to the caller.
*
* @custom:param advancedOrders The advanced orders to match. Note that
* both the offerer and fulfiller on each
* order must first approve this contract
* (or their conduit if indicated by the
* order) to transfer any relevant tokens on
* their behalf and each consideration
* recipient must implement
* `onERC1155Received` to receive ERC1155
* tokens. Also note that the offer and
* consideration components for each order
* must have no remainder after multiplying
* the respective amount with the supplied
* fraction for the group of partial fills
* to be considered valid.
* @custom:param criteriaResolvers An array where each element contains a
* reference to a specific offer or
* consideration, a token identifier, and a
* proof that the supplied token identifier
* is contained in the merkle root held by
* the item in question's criteria element.
* Note that an empty criteria indicates
* that any (transferable) token identifier
* on the token in question is valid and
* that no associated proof needs to be
* supplied.
* @custom:param fulfillments An array of elements allocating offer
* components to consideration components.
* Note that each consideration component
* must be fully met for the match operation
* to be valid, and that any unspent offer
* items will be sent unaggregated to the
* designated recipient.
* @param recipient The intended recipient for all unspent
* offer item amounts, or the caller if the
* null address is supplied.
*
* @return executions An array of elements indicating the sequence of
* transfers performed as part of matching the given
* orders. Note that unspent offer item amounts or
* native tokens will not be reflected as part of this
* array.
*/
function matchAdvancedOrders(
/**
* @custom:name advancedOrders
*/
AdvancedOrder[] calldata,
/**
* @custom:name criteriaResolvers
*/
CriteriaResolver[] calldata,
/**
* @custom:name fulfillments
*/
Fulfillment[] calldata,
address recipient
) external payable override returns (Execution[] memory /* executions */) {
// Validate and match the advanced orders using supplied fulfillments.
return
_matchAdvancedOrders(
_toAdvancedOrdersReturnType(_decodeAdvancedOrders)(
CalldataStart.pptr()
),
_toCriteriaResolversReturnType(_decodeCriteriaResolvers)(
CalldataStart.pptrOffset(
Offset_matchAdvancedOrders_criteriaResolvers
)
),
_toFulfillmentsReturnType(_decodeFulfillments)(
CalldataStart.pptrOffset(
Offset_matchAdvancedOrders_fulfillments
)
),
_substituteCallerForEmptyRecipient(recipient)
);
}
/**
* @notice Cancel an arbitrary number of orders. Note that only the offerer
* or the zone of a given order may cancel it. Callers should ensure
* that the intended order was cancelled by calling `getOrderStatus`
* and confirming that `isCancelled` returns `true`.
*
* @param orders The orders to cancel.
*
* @return cancelled A boolean indicating whether the supplied orders have
* been successfully cancelled.
*/
function cancel(
OrderComponents[] calldata orders
) external override returns (bool cancelled) {
// Cancel the orders.
cancelled = _cancel(orders);
}
/**
* @notice Validate an arbitrary number of orders, thereby registering their
* signatures as valid and allowing the fulfiller to skip signature
* verification on fulfillment. Note that validated orders may still
* be unfulfillable due to invalid item amounts or other factors;
* callers should determine whether validated orders are fulfillable
* by simulating the fulfillment call prior to execution. Also note
* that anyone can validate a signed order, but only the offerer can
* validate an order without supplying a signature.
*
* @custom:param orders The orders to validate.
*
* @return validated A boolean indicating whether the supplied orders have
* been successfully validated.
*/
function validate(
/**
* @custom:name orders
*/
Order[] calldata
) external override returns (bool /* validated */) {
return
_validate(_toOrdersReturnType(_decodeOrders)(CalldataStart.pptr()));
}
/**
* @notice Cancel all orders from a given offerer with a given zone in bulk
* by incrementing a counter. Note that only the offerer may
* increment the counter.
*
* @return newCounter The new counter.
*/
function incrementCounter() external override returns (uint256 newCounter) {
// Increment current counter for the supplied offerer. Note that the
// counter is incremented by a large, quasi-random interval.
newCounter = _incrementCounter();
}
/**
* @notice Retrieve the order hash for a given order.
*
* @custom:param order The components of the order.
*
* @return orderHash The order hash.
*/
function getOrderHash(
/**
* @custom:name order
*/
OrderComponents calldata
) external view override returns (bytes32 orderHash) {
CalldataPointer orderPointer = CalldataStart.pptr();
// Derive order hash by supplying order parameters along with counter.
orderHash = _deriveOrderHash(
_toOrderParametersReturnType(
_decodeOrderComponentsAsOrderParameters
)(orderPointer),
// Read order counter
orderPointer.offset(OrderParameters_counter_offset).readUint256()
);
}
/**
* @notice Retrieve the status of a given order by hash, including whether
* the order has been cancelled or validated and the fraction of the
* order that has been filled. Since the _orderStatus[orderHash]
* does not get set for contract orders, getOrderStatus will always
* return (false, false, 0, 0) for those hashes. Note that this
* function is susceptible to view reentrancy and so should be used
* with care when calling from other contracts.
*
* @param orderHash The order hash in question.
*
* @return isValidated A boolean indicating whether the order in question
* has been validated (i.e. previously approved or
* partially filled).
* @return isCancelled A boolean indicating whether the order in question
* has been cancelled.
* @return totalFilled The total portion of the order that has been filled
* (i.e. the "numerator").
* @return totalSize The total size of the order that is either filled or
* unfilled (i.e. the "denominator").
*/
function getOrderStatus(
bytes32 orderHash
)
external
view
override
returns (
bool isValidated,
bool isCancelled,
uint256 totalFilled,
uint256 totalSize
)
{
// Retrieve the order status using the order hash.
return _getOrderStatus(orderHash);
}
/**
* @notice Retrieve the current counter for a given offerer.
*
* @param offerer The offerer in question.
*
* @return counter The current counter.
*/
function getCounter(
address offerer
) external view override returns (uint256 counter) {
// Return the counter for the supplied offerer.
counter = _getCounter(offerer);
}
/**
* @notice Retrieve configuration information for this contract.
*
* @return version The contract version.
* @return domainSeparator The domain separator for this contract.
* @return conduitController The conduit Controller set for this contract.
*/
function information()
external
view
override
returns (
string memory version,
bytes32 domainSeparator,
address conduitController
)
{
// Return the information for this contract.
return _information();
}
/**
* @dev Gets the contract offerer nonce for the specified contract offerer.
* Note that this function is susceptible to view reentrancy and so
* should be used with care when calling from other contracts.
*
* @param contractOfferer The contract offerer for which to get the nonce.
*
* @return nonce The contract offerer nonce.
*/
function getContractOffererNonce(
address contractOfferer
) external view override returns (uint256 nonce) {
nonce = _contractNonces[contractOfferer];
}
/**
* @notice Retrieve the name of this contract.
*
* @return contractName The name of this contract.
*/
function name()
external
pure
override
returns (string memory /* contractName */)
{
// Return the name of the contract.
return _name();
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
import {
AdvancedOrder,
BasicOrderParameters,
CriteriaResolver,
Execution,
Fulfillment,
FulfillmentComponent,
Order,
OrderComponents
} from "../lib/ConsiderationStructs.sol";
/**
* @title ConsiderationInterface
* @author 0age
* @custom:version 1.6
* @notice Consideration is a generalized native token/ERC20/ERC721/ERC1155
* marketplace. It minimizes external calls to the greatest extent
* possible and provides lightweight methods for common routes as well
* as more flexible methods for composing advanced orders.
*
* @dev ConsiderationInterface contains all external function interfaces for
* Consideration.
*/
interface ConsiderationInterface {
/**
* @notice Fulfill an order offering an ERC721 token by supplying Ether (or
* the native token for the given chain) as consideration for the
* order. An arbitrary number of "additional recipients" may also be
* supplied which will each receive native tokens from the fulfiller
* as consideration.
*
* @param parameters Additional information on the fulfilled order. Note
* that the offerer must first approve this contract (or
* their preferred conduit if indicated by the order) for
* their offered ERC721 token to be transferred.
*
* @return fulfilled A boolean indicating whether the order has been
* successfully fulfilled.
*/
function fulfillBasicOrder(
BasicOrderParameters calldata parameters
) external payable returns (bool fulfilled);
/**
* @notice Fulfill an order with an arbitrary number of items for offer and
* consideration. Note that this function does not support
* criteria-based orders or partial filling of orders (though
* filling the remainder of a partially-filled order is supported).
*
* @param order The order to fulfill. Note that both the
* offerer and the fulfiller must first approve
* this contract (or the corresponding conduit if
* indicated) to transfer any relevant tokens on
* their behalf and that contracts must implement
* `onERC1155Received` to receive ERC1155 tokens
* as consideration.
* @param fulfillerConduitKey A bytes32 value indicating what conduit, if
* any, to source the fulfiller's token approvals
* from. The zero hash signifies that no conduit
* should be used, with direct approvals set on
* Consideration.
*
* @return fulfilled A boolean indicating whether the order has been
* successfully fulfilled.
*/
function fulfillOrder(
Order calldata order,
bytes32 fulfillerConduitKey
) external payable returns (bool fulfilled);
/**
* @notice Fill an order, fully or partially, with an arbitrary number of
* items for offer and consideration alongside criteria resolvers
* containing specific token identifiers and associated proofs.
*
* @param advancedOrder The order to fulfill along with the fraction
* of the order to attempt to fill. Note that
* both the offerer and the fulfiller must first
* approve this contract (or their preferred
* conduit if indicated by the order) to transfer
* any relevant tokens on their behalf and that
* contracts must implement `onERC1155Received`
* to receive ERC1155 tokens as consideration.
* Also note that all offer and consideration
* components must have no remainder after
* multiplication of the respective amount with
* the supplied fraction for the partial fill to
* be considered valid.
* @param criteriaResolvers An array where each element contains a
* reference to a specific offer or
* consideration, a token identifier, and a proof
* that the supplied token identifier is
* contained in the merkle root held by the item
* in question's criteria element. Note that an
* empty criteria indicates that any
* (transferable) token identifier on the token
* in question is valid and that no associated
* proof needs to be supplied.
* @param fulfillerConduitKey A bytes32 value indicating what conduit, if
* any, to source the fulfiller's token approvals
* from. The zero hash signifies that no conduit
* should be used, with direct approvals set on
* Consideration.
* @param recipient The intended recipient for all received items,
* with `address(0)` indicating that the caller
* should receive the items.
*
* @return fulfilled A boolean indicating whether the order has been
* successfully fulfilled.
*/
function fulfillAdvancedOrder(
AdvancedOrder calldata advancedOrder,
CriteriaResolver[] calldata criteriaResolvers,
bytes32 fulfillerConduitKey,
address recipient
) external payable returns (bool fulfilled);
/**
* @notice Attempt to fill a group of orders, each with an arbitrary number
* of items for offer and consideration. Any order that is not
* currently active, has already been fully filled, or has been
* cancelled will be omitted. Remaining offer and consideration
* items will then be aggregated where possible as indicated by the
* supplied offer and consideration component arrays and aggregated
* items will be transferred to the fulfiller or to each intended
* recipient, respectively. Note that a failing item transfer or an
* issue with order formatting will cause the entire batch to fail.
* Note that this function does not support criteria-based orders or
* partial filling of orders (though filling the remainder of a
* partially-filled order is supported).
*
* @param orders The orders to fulfill. Note that both
* the offerer and the fulfiller must first
* approve this contract (or the
* corresponding conduit if indicated) to
* transfer any relevant tokens on their
* behalf and that contracts must implement
* `onERC1155Received` to receive ERC1155
* tokens as consideration.
* @param offerFulfillments An array of FulfillmentComponent arrays
* indicating which offer items to attempt
* to aggregate when preparing executions.
* @param considerationFulfillments An array of FulfillmentComponent arrays
* indicating which consideration items to
* attempt to aggregate when preparing
* executions.
* @param fulfillerConduitKey A bytes32 value indicating what conduit,
* if any, to source the fulfiller's token
* approvals from. The zero hash signifies
* that no conduit should be used, with
* direct approvals set on this contract.
* @param maximumFulfilled The maximum number of orders to fulfill.
*
* @return availableOrders An array of booleans indicating if each order
* with an index corresponding to the index of the
* returned boolean was fulfillable or not.
* @return executions An array of elements indicating the sequence of
* transfers performed as part of matching the given
* orders. Note that unspent offer item amounts or
* native tokens will not be reflected as part of
* this array.
*/
function fulfillAvailableOrders(
Order[] calldata orders,
FulfillmentComponent[][] calldata offerFulfillments,
FulfillmentComponent[][] calldata considerationFulfillments,
bytes32 fulfillerConduitKey,
uint256 maximumFulfilled
)
external
payable
returns (bool[] memory availableOrders, Execution[] memory executions);
/**
* @notice Attempt to fill a group of orders, fully or partially, with an
* arbitrary number of items for offer and consideration per order
* alongside criteria resolvers containing specific token
* identifiers and associated proofs. Any order that is not
* currently active, has already been fully filled, or has been
* cancelled will be omitted. Remaining offer and consideration
* items will then be aggregated where possible as indicated by the
* supplied offer and consideration component arrays and aggregated
* items will be transferred to the fulfiller or to each intended
* recipient, respectively. Note that a failing item transfer or an
* issue with order formatting will cause the entire batch to fail.
*
* @param advancedOrders The orders to fulfill along with the
* fraction of those orders to attempt to
* fill. Note that both the offerer and the
* fulfiller must first approve this
* contract (or their preferred conduit if
* indicated by the order) to transfer any
* relevant tokens on their behalf and that
* contracts must implement
* `onERC1155Received` to enable receipt of
* ERC1155 tokens as consideration. Also
* note that all offer and consideration
* components must have no remainder after
* multiplication of the respective amount
* with the supplied fraction for an
* order's partial fill amount to be
* considered valid.
* @param criteriaResolvers An array where each element contains a
* reference to a specific offer or
* consideration, a token identifier, and a
* proof that the supplied token identifier
* is contained in the merkle root held by
* the item in question's criteria element.
* Note that an empty criteria indicates
* that any (transferable) token
* identifier on the token in question is
* valid and that no associated proof needs
* to be supplied.
* @param offerFulfillments An array of FulfillmentComponent arrays
* indicating which offer items to attempt
* to aggregate when preparing executions.
* @param considerationFulfillments An array of FulfillmentComponent arrays
* indicating which consideration items to
* attempt to aggregate when preparing
* executions.
* @param fulfillerConduitKey A bytes32 value indicating what conduit,
* if any, to source the fulfiller's token
* approvals from. The zero hash signifies
* that no conduit should be used, with
* direct approvals set on this contract.
* @param recipient The intended recipient for all received
* items, with `address(0)` indicating that
* the caller should receive the items.
* @param maximumFulfilled The maximum number of orders to fulfill.
*
* @return availableOrders An array of booleans indicating if each order
* with an index corresponding to the index of the
* returned boolean was fulfillable or not.
* @return executions An array of elements indicating the sequence of
* transfers performed as part of matching the given
* orders. Note that unspent offer item amounts or
* native tokens will not be reflected as part of
* this array.
*/
function fulfillAvailableAdvancedOrders(
AdvancedOrder[] calldata advancedOrders,
CriteriaResolver[] calldata criteriaResolvers,
FulfillmentComponent[][] calldata offerFulfillments,
FulfillmentComponent[][] calldata considerationFulfillments,
bytes32 fulfillerConduitKey,
address recipient,
uint256 maximumFulfilled
)
external
payable
returns (bool[] memory availableOrders, Execution[] memory executions);
/**
* @notice Match an arbitrary number of orders, each with an arbitrary
* number of items for offer and consideration along with a set of
* fulfillments allocating offer components to consideration
* components. Note that this function does not support
* criteria-based or partial filling of orders (though filling the
* remainder of a partially-filled order is supported). Any unspent
* offer item amounts or native tokens will be transferred to the
* caller.
*
* @param orders The orders to match. Note that both the offerer and
* fulfiller on each order must first approve this
* contract (or their conduit if indicated by the order)
* to transfer any relevant tokens on their behalf and
* each consideration recipient must implement
* `onERC1155Received` to enable ERC1155 token receipt.
* @param fulfillments An array of elements allocating offer components to
* consideration components. Note that each
* consideration component must be fully met for the
* match operation to be valid.
*
* @return executions An array of elements indicating the sequence of
* transfers performed as part of matching the given
* orders. Note that unspent offer item amounts or
* native tokens will not be reflected as part of this
* array.
*/
function matchOrders(
Order[] calldata orders,
Fulfillment[] calldata fulfillments
) external payable returns (Execution[] memory executions);
/**
* @notice Match an arbitrary number of full or partial orders, each with an
* arbitrary number of items for offer and consideration, supplying
* criteria resolvers containing specific token identifiers and
* associated proofs as well as fulfillments allocating offer
* components to consideration components. Any unspent offer item
* amounts will be transferred to the designated recipient (with the
* null address signifying to use the caller) and any unspent native
* tokens will be returned to the caller.
*
* @param orders The advanced orders to match. Note that both the
* offerer and fulfiller on each order must first
* approve this contract (or a preferred conduit if
* indicated by the order) to transfer any relevant
* tokens on their behalf and each consideration
* recipient must implement `onERC1155Received` in
* order to receive ERC1155 tokens. Also note that
* the offer and consideration components for each
* order must have no remainder after multiplying
* the respective amount with the supplied fraction
* in order for the group of partial fills to be
* considered valid.
* @param criteriaResolvers An array where each element contains a reference
* to a specific order as well as that order's
* offer or consideration, a token identifier, and
* a proof that the supplied token identifier is
* contained in the order's merkle root. Note that
* an empty root indicates that any (transferable)
* token identifier is valid and that no associated
* proof needs to be supplied.
* @param fulfillments An array of elements allocating offer components
* to consideration components. Note that each
* consideration component must be fully met in
* order for the match operation to be valid.
* @param recipient The intended recipient for all unspent offer
* item amounts, or the caller if the null address
* is supplied.
*
* @return executions An array of elements indicating the sequence of
* transfers performed as part of matching the given
* orders. Note that unspent offer item amounts or native
* tokens will not be reflected as part of this array.
*/
function matchAdvancedOrders(
AdvancedOrder[] calldata orders,
CriteriaResolver[] calldata criteriaResolvers,
Fulfillment[] calldata fulfillments,
address recipient
) external payable returns (Execution[] memory executions);
/**
* @notice Cancel an arbitrary number of orders. Note that only the offerer
* or the zone of a given order may cancel it. Callers should ensure
* that the intended order was cancelled by calling `getOrderStatus`
* and confirming that `isCancelled` returns `true`.
*
* @param orders The orders to cancel.
*
* @return cancelled A boolean indicating whether the supplied orders have
* been successfully cancelled.
*/
function cancel(
OrderComponents[] calldata orders
) external returns (bool cancelled);
/**
* @notice Validate an arbitrary number of orders, thereby registering their
* signatures as valid and allowing the fulfiller to skip signature
* verification on fulfillment. Note that validated orders may still
* be unfulfillable due to invalid item amounts or other factors;
* callers should determine whether validated orders are fulfillable
* by simulating the fulfillment call prior to execution. Also note
* that anyone can validate a signed order, but only the offerer can
* validate an order without supplying a signature.
*
* @param orders The orders to validate.
*
* @return validated A boolean indicating whether the supplied orders have
* been successfully validated.
*/
function validate(
Order[] calldata orders
) external returns (bool validated);
/**
* @notice Cancel all orders from a given offerer with a given zone in bulk
* by incrementing a counter. Note that only the offerer may
* increment the counter.
*
* @return newCounter The new counter.
*/
function incrementCounter() external returns (uint256 newCounter);
/**
* @notice Fulfill an order offering an ERC721 token by supplying Ether (or
* the native token for the given chain) as consideration for the
* order. An arbitrary number of "additional recipients" may also be
* supplied which will each receive native tokens from the fulfiller
* as consideration. Note that this function costs less gas than
* `fulfillBasicOrder` due to the zero bytes in the function
* selector (0x00000000) which also results in earlier function
* dispatch.
*
* @param parameters Additional information on the fulfilled order. Note
* that the offerer must first approve this contract (or
* their preferred conduit if indicated by the order) for
* their offered ERC721 token to be transferred.
*
* @return fulfilled A boolean indicating whether the order has been
* successfully fulfilled.
*/
function fulfillBasicOrder_efficient_6GL6yc(
BasicOrderParameters calldata parameters
) external payable returns (bool fulfilled);
/**
* @notice Retrieve the order hash for a given order.
*
* @param order The components of the order.
*
* @return orderHash The order hash.
*/
function getOrderHash(
OrderComponents calldata order
) external view returns (bytes32 orderHash);
/**
* @notice Retrieve the status of a given order by hash, including whether
* the order has been cancelled or validated and the fraction of the
* order that has been filled.
*
* @param orderHash The order hash in question.
*
* @return isValidated A boolean indicating whether the order in question
* has been validated (i.e. previously approved or
* partially filled).
* @return isCancelled A boolean indicating whether the order in question
* has been cancelled.
* @return totalFilled The total portion of the order that has been filled
* (i.e. the "numerator").
* @return totalSize The total size of the order that is either filled or
* unfilled (i.e. the "denominator").
*/
function getOrderStatus(
bytes32 orderHash
)
external
view
returns (
bool isValidated,
bool isCancelled,
uint256 totalFilled,
uint256 totalSize
);
/**
* @notice Retrieve the current counter for a given offerer.
*
* @param offerer The offerer in question.
*
* @return counter The current counter.
*/
function getCounter(
address offerer
) external view returns (uint256 counter);
/**
* @notice Retrieve configuration information for this contract.
*
* @return version The contract version.
* @return domainSeparator The domain separator for this contract.
* @return conduitController The conduit Controller set for this contract.
*/
function information()
external
view
returns (
string memory version,
bytes32 domainSeparator,
address conduitController
);
function getContractOffererNonce(
address contractOfferer
) external view returns (uint256 nonce);
/**
* @notice Retrieve the name of this contract.
*
* @return contractName The name of this contract.
*/
function name() external view returns (string memory contractName);
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
import {
BasicOrderType,
ItemType,
OrderType,
Side
} from "./ConsiderationEnums.sol";
import {
CalldataPointer,
MemoryPointer
} from "../helpers/PointerLibraries.sol";
/**
* @dev An order contains eleven components: an offerer, a zone (or account that
* can cancel the order or restrict who can fulfill the order depending on
* the type), the order type (specifying partial fill support as well as
* restricted order status), the start and end time, a hash that will be
* provided to the zone when validating restricted orders, a salt, a key
* corresponding to a given conduit, a counter, and an arbitrary number of
* offer items that can be spent along with consideration items that must
* be received by their respective recipient.
*/
struct OrderComponents {
address offerer;
address zone;
OfferItem[] offer;
ConsiderationItem[] consideration;
OrderType orderType;
uint256 startTime;
uint256 endTime;
bytes32 zoneHash;
uint256 salt;
bytes32 conduitKey;
uint256 counter;
}
/**
* @dev An offer item has five components: an item type (ETH or other native
* tokens, ERC20, ERC721, and ERC1155, as well as criteria-based ERC721 and
* ERC1155), a token address, a dual-purpose "identifierOrCriteria"
* component that will either represent a tokenId or a merkle root
* depending on the item type, and a start and end amount that support
* increasing or decreasing amounts over the duration of the respective
* order.
*/
struct OfferItem {
ItemType itemType;
address token;
uint256 identifierOrCriteria;
uint256 startAmount;
uint256 endAmount;
}
/**
* @dev A consideration item has the same five components as an offer item and
* an additional sixth component designating the required recipient of the
* item.
*/
struct ConsiderationItem {
ItemType itemType;
address token;
uint256 identifierOrCriteria;
uint256 startAmount;
uint256 endAmount;
address payable recipient;
}
/**
* @dev A spent item is translated from a utilized offer item and has four
* components: an item type (ETH or other native tokens, ERC20, ERC721, and
* ERC1155), a token address, a tokenId, and an amount.
*/
struct SpentItem {
ItemType itemType;
address token;
uint256 identifier;
uint256 amount;
}
/**
* @dev A received item is translated from a utilized consideration item and has
* the same four components as a spent item, as well as an additional fifth
* component designating the required recipient of the item.
*/
struct ReceivedItem {
ItemType itemType;
address token;
uint256 identifier;
uint256 amount;
address payable recipient;
}
/**
* @dev For basic orders involving ETH / native / ERC20 <=> ERC721 / ERC1155
* matching, a group of six functions may be called that only requires a
* subset of the usual order arguments. Note the use of a "basicOrderType"
* enum; this represents both the usual order type as well as the "route"
* of the basic order (a simple derivation function for the basic order
* type is `basicOrderType = orderType + (4 * basicOrderRoute)`.)
*/
struct BasicOrderParameters {
// calldata offset
address considerationToken; // 0x24
uint256 considerationIdentifier; // 0x44
uint256 considerationAmount; // 0x64
address payable offerer; // 0x84
address zone; // 0xa4
address offerToken; // 0xc4
uint256 offerIdentifier; // 0xe4
uint256 offerAmount; // 0x104
BasicOrderType basicOrderType; // 0x124
uint256 startTime; // 0x144
uint256 endTime; // 0x164
bytes32 zoneHash; // 0x184
uint256 salt; // 0x1a4
bytes32 offererConduitKey; // 0x1c4
bytes32 fulfillerConduitKey; // 0x1e4
uint256 totalOriginalAdditionalRecipients; // 0x204
AdditionalRecipient[] additionalRecipients; // 0x224
bytes signature; // 0x244
// Total length, excluding dynamic array data: 0x264 (580)
}
/**
* @dev Basic orders can supply any number of additional recipients, with the
* implied assumption that they are supplied from the offered ETH (or other
* native token) or ERC20 token for the order.
*/
struct AdditionalRecipient {
uint256 amount;
address payable recipient;
}
/**
* @dev The full set of order components, with the exception of the counter,
* must be supplied when fulfilling more sophisticated orders or groups of
* orders. The total number of original consideration items must also be
* supplied, as the caller may specify additional consideration items.
*/
struct OrderParameters {
address offerer; // 0x00
address zone; // 0x20
OfferItem[] offer; // 0x40
ConsiderationItem[] consideration; // 0x60
OrderType orderType; // 0x80
uint256 startTime; // 0xa0
uint256 endTime; // 0xc0
bytes32 zoneHash; // 0xe0
uint256 salt; // 0x100
bytes32 conduitKey; // 0x120
uint256 totalOriginalConsiderationItems; // 0x140
// offer.length // 0x160
}
/**
* @dev Orders require a signature in addition to the other order parameters.
*/
struct Order {
OrderParameters parameters;
bytes signature;
}
/**
* @dev Advanced orders include a numerator (i.e. a fraction to attempt to fill)
* and a denominator (the total size of the order) in addition to the
* signature and other order parameters. It also supports an optional field
* for supplying extra data; this data will be provided to the zone if the
* order type is restricted and the zone is not the caller, or will be
* provided to the offerer as context for contract order types.
*/
struct AdvancedOrder {
OrderParameters parameters;
uint120 numerator;
uint120 denominator;
bytes signature;
bytes extraData;
}
/**
* @dev Orders can be validated (either explicitly via `validate`, or as a
* consequence of a full or partial fill), specifically cancelled (they can
* also be cancelled in bulk via incrementing a per-zone counter), and
* partially or fully filled (with the fraction filled represented by a
* numerator and denominator).
*/
struct OrderStatus {
bool isValidated;
bool isCancelled;
uint120 numerator;
uint120 denominator;
}
/**
* @dev A criteria resolver specifies an order, side (offer vs. consideration),
* and item index. It then provides a chosen identifier (i.e. tokenId)
* alongside a merkle proof demonstrating the identifier meets the required
* criteria.
*/
struct CriteriaResolver {
uint256 orderIndex;
Side side;
uint256 index;
uint256 identifier;
bytes32[] criteriaProof;
}
/**
* @dev A fulfillment is applied to a group of orders. It decrements a series of
* offer and consideration items, then generates a single execution
* element. A given fulfillment can be applied to as many offer and
* consideration items as desired, but must contain at least one offer and
* at least one consideration that match. The fulfillment must also remain
* consistent on all key parameters across all offer items (same offerer,
* token, type, tokenId, and conduit preference) as well as across all
* consideration items (token, type, tokenId, and recipient).
*/
struct Fulfillment {
FulfillmentComponent[] offerComponents;
FulfillmentComponent[] considerationComponents;
}
/**
* @dev Each fulfillment component contains one index referencing a specific
* order and another referencing a specific offer or consideration item.
*/
struct FulfillmentComponent {
uint256 orderIndex;
uint256 itemIndex;
}
/**
* @dev An execution is triggered once all consideration items have been zeroed
* out. It sends the item in question from the offerer to the item's
* recipient, optionally sourcing approvals from either this contract
* directly or from the offerer's chosen conduit if one is specified. An
* execution is not provided as an argument, but rather is derived via
* orders, criteria resolvers, and fulfillments (where the total number of
* executions will be less than or equal to the total number of indicated
* fulfillments) and returned as part of `matchOrders`.
*/
struct Execution {
ReceivedItem item;
address offerer;
bytes32 conduitKey;
}
/**
* @dev Restricted orders are validated post-execution by calling validateOrder
* on the zone. This struct provides context about the order fulfillment
* and any supplied extraData, as well as all order hashes fulfilled in a
* call to a match or fulfillAvailable method.
*/
struct ZoneParameters {
bytes32 orderHash;
address fulfiller;
address offerer;
SpentItem[] offer;
ReceivedItem[] consideration;
bytes extraData;
bytes32[] orderHashes;
uint256 startTime;
uint256 endTime;
bytes32 zoneHash;
}
/**
* @dev Zones and contract offerers can communicate which schemas they implement
* along with any associated metadata related to each schema.
*/
struct Schema {
uint256 id;
bytes metadata;
}
using StructPointers for OrderComponents global;
using StructPointers for OfferItem global;
using StructPointers for ConsiderationItem global;
using StructPointers for SpentItem global;
using StructPointers for ReceivedItem global;
using StructPointers for BasicOrderParameters global;
using StructPointers for AdditionalRecipient global;
using StructPointers for OrderParameters global;
using StructPointers for Order global;
using StructPointers for AdvancedOrder global;
using StructPointers for OrderStatus global;
using StructPointers for CriteriaResolver global;
using StructPointers for Fulfillment global;
using StructPointers for FulfillmentComponent global;
using StructPointers for Execution global;
using StructPointers for ZoneParameters global;
/**
* @dev This library provides a set of functions for converting structs to
* pointers.
*/
library StructPointers {
/**
* @dev Get a MemoryPointer from OrderComponents.
*
* @param obj The OrderComponents object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
OrderComponents memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from OrderComponents.
*
* @param obj The OrderComponents object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
OrderComponents calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from OfferItem.
*
* @param obj The OfferItem object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
OfferItem memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from OfferItem.
*
* @param obj The OfferItem object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
OfferItem calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from ConsiderationItem.
*
* @param obj The ConsiderationItem object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
ConsiderationItem memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from ConsiderationItem.
*
* @param obj The ConsiderationItem object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
ConsiderationItem calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from SpentItem.
*
* @param obj The SpentItem object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
SpentItem memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from SpentItem.
*
* @param obj The SpentItem object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
SpentItem calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from ReceivedItem.
*
* @param obj The ReceivedItem object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
ReceivedItem memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from ReceivedItem.
*
* @param obj The ReceivedItem object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
ReceivedItem calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from BasicOrderParameters.
*
* @param obj The BasicOrderParameters object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
BasicOrderParameters memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from BasicOrderParameters.
*
* @param obj The BasicOrderParameters object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
BasicOrderParameters calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from AdditionalRecipient.
*
* @param obj The AdditionalRecipient object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
AdditionalRecipient memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from AdditionalRecipient.
*
* @param obj The AdditionalRecipient object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
AdditionalRecipient calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from OrderParameters.
*
* @param obj The OrderParameters object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
OrderParameters memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from OrderParameters.
*
* @param obj The OrderParameters object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
OrderParameters calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from Order.
*
* @param obj The Order object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
Order memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from Order.
*
* @param obj The Order object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
Order calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from AdvancedOrder.
*
* @param obj The AdvancedOrder object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
AdvancedOrder memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from AdvancedOrder.
*
* @param obj The AdvancedOrder object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
AdvancedOrder calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from OrderStatus.
*
* @param obj The OrderStatus object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
OrderStatus memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from OrderStatus.
*
* @param obj The OrderStatus object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
OrderStatus calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from CriteriaResolver.
*
* @param obj The CriteriaResolver object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
CriteriaResolver memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from CriteriaResolver.
*
* @param obj The CriteriaResolver object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
CriteriaResolver calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from Fulfillment.
*
* @param obj The Fulfillment object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
Fulfillment memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from Fulfillment.
*
* @param obj The Fulfillment object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
Fulfillment calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from FulfillmentComponent.
*
* @param obj The FulfillmentComponent object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
FulfillmentComponent memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from FulfillmentComponent.
*
* @param obj The FulfillmentComponent object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
FulfillmentComponent calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from Execution.
*
* @param obj The Execution object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
Execution memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from Execution.
*
* @param obj The Execution object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
Execution calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a MemoryPointer from ZoneParameters.
*
* @param obj The ZoneParameters object.
*
* @return ptr The MemoryPointer.
*/
function toMemoryPointer(
ZoneParameters memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Get a CalldataPointer from ZoneParameters.
*
* @param obj The ZoneParameters object.
*
* @return ptr The CalldataPointer.
*/
function toCalldataPointer(
ZoneParameters calldata obj
) internal pure returns (CalldataPointer ptr) {
assembly {
ptr := obj
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
Side,
ItemType,
OrderType
} from "seaport-types/src/lib/ConsiderationEnums.sol";
import {
AdvancedOrder,
ConsiderationItem,
CriteriaResolver,
Execution,
Fulfillment,
FulfillmentComponent,
OfferItem,
OrderParameters,
ReceivedItem
} from "seaport-types/src/lib/ConsiderationStructs.sol";
import { OrderFulfiller } from "./OrderFulfiller.sol";
import { FulfillmentApplier } from "./FulfillmentApplier.sol";
import {
_revertConsiderationNotMet,
_revertInvalidNativeOfferItem,
_revertNoSpecifiedOrdersAvailable
} from "seaport-types/src/lib/ConsiderationErrors.sol";
import {
Error_selector_offset,
InsufficientNativeTokensSupplied_error_selector,
InsufficientNativeTokensSupplied_error_length
} from "seaport-types/src/lib/ConsiderationErrorConstants.sol";
import {
AccumulatorDisarmed,
ConsiderationItem_recipient_offset,
Execution_offerer_offset,
NonMatchSelector_InvalidErrorValue,
NonMatchSelector_MagicMask,
OneWord,
OneWordShift,
OrdersMatchedTopic0,
ReceivedItem_amount_offset,
ReceivedItem_recipient_offset,
TwoWords
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
MemoryPointer,
MemoryPointerLib,
ZeroSlotPtr
} from "seaport-types/src/helpers/PointerLibraries.sol";
/**
* @title OrderCombiner
* @author 0age
* @notice OrderCombiner contains logic for fulfilling combinations of orders,
* either by matching offer items to consideration items or by
* fulfilling orders where available.
*/
contract OrderCombiner is OrderFulfiller, FulfillmentApplier {
/**
* @dev Derive and set hashes, reference chainId, and associated domain
* separator during deployment.
*
* @param conduitController A contract that deploys conduits, or proxies
* that may optionally be used to transfer approved
* ERC20/721/1155 tokens.
*/
constructor(address conduitController) OrderFulfiller(conduitController) {}
/**
* @notice Internal function to attempt to fill a group of orders, fully or
* partially, with an arbitrary number of items for offer and
* consideration per order alongside criteria resolvers containing
* specific token identifiers and associated proofs. Any order that
* is not currently active, has already been fully filled, or has
* been cancelled will be omitted. Remaining offer and consideration
* items will then be aggregated where possible as indicated by the
* supplied offer and consideration component arrays and aggregated
* items will be transferred to the fulfiller or to each intended
* recipient, respectively. Note that a failing item transfer or an
* issue with order formatting will cause the entire batch to fail.
*
* @param advancedOrders The orders to fulfill along with the
* fraction of those orders to attempt to
* fill. Note that both the offerer and the
* fulfiller must first approve this
* contract (or a conduit if indicated by
* the order) to transfer any relevant
* tokens on their behalf and that
* contracts must implement
* `onERC1155Received` in order to receive
* ERC1155 tokens as consideration. Also
* note that all offer and consideration
* components must have no remainder after
* multiplication of the respective amount
* with the supplied fraction for an
* order's partial fill amount to be
* considered valid.
* @param criteriaResolvers An array where each element contains a
* reference to a specific offer or
* consideration, a token identifier, and a
* proof that the supplied token identifier
* is contained in the merkle root held by
* the item in question's criteria element.
* Note that an empty criteria indicates
* that any (transferable) token
* identifier on the token in question is
* valid and that no associated proof needs
* to be supplied.
* @param offerFulfillments An array of FulfillmentComponent arrays
* indicating which offer items to attempt
* to aggregate when preparing executions.
* @param considerationFulfillments An array of FulfillmentComponent arrays
* indicating which consideration items to
* attempt to aggregate when preparing
* executions.
* @param fulfillerConduitKey A bytes32 value indicating what conduit,
* if any, to source the fulfiller's token
* approvals from. The zero hash signifies
* that no conduit should be used (and
* direct approvals set on Consideration).
* @param recipient The intended recipient for all received
* items.
* @param maximumFulfilled The maximum number of orders to fulfill.
*
* @return availableOrders An array of booleans indicating if each order
* with an index corresponding to the index of the
* returned boolean was fulfillable or not.
* @return executions An array of elements indicating the sequence of
* transfers performed as part of matching the given
* orders.
*/
function _fulfillAvailableAdvancedOrders(
AdvancedOrder[] memory advancedOrders,
CriteriaResolver[] memory criteriaResolvers,
FulfillmentComponent[][] memory offerFulfillments,
FulfillmentComponent[][] memory considerationFulfillments,
bytes32 fulfillerConduitKey,
address recipient,
uint256 maximumFulfilled
)
internal
returns (
bool[] memory /* availableOrders */,
Execution[] memory /* executions */
)
{
// Create a `false` boolean variable to indicate that invalid orders
// should NOT revert. Does not use a constant to avoid function
// specialization in solc that would increase contract size.
bool revertOnInvalid = _runTimeConstantFalse();
// Validate orders, apply amounts, & determine if they use conduits.
(
bytes32[] memory orderHashes,
bool containsNonOpen
) = _validateOrdersAndPrepareToFulfill(
advancedOrders,
criteriaResolvers,
revertOnInvalid,
maximumFulfilled,
recipient
);
// Aggregate used offer and consideration items and execute transfers.
return
_executeAvailableFulfillments(
advancedOrders,
offerFulfillments,
considerationFulfillments,
fulfillerConduitKey,
recipient,
orderHashes,
containsNonOpen
);
}
/**
* @dev Internal function to validate a group of orders, update their
* statuses, reduce amounts by their previously filled fractions, apply
* criteria resolvers, and emit OrderFulfilled events. Note that this
* function needs to be called before
* _aggregateValidFulfillmentConsiderationItems to set the memory
* layout that _aggregateValidFulfillmentConsiderationItems depends on.
*
* @param advancedOrders The advanced orders to validate and reduce by
* their previously filled amounts.
* @param criteriaResolvers An array where each element contains a reference
* to a specific order as well as that order's
* offer or consideration, a token identifier, and
* a proof that the supplied token identifier is
* contained in the order's merkle root. Note that
* a root of zero indicates that any transferable
* token identifier is valid and that no proof
* needs to be supplied.
* @param revertOnInvalid A boolean indicating whether to revert on any
* order being invalid; setting this to false will
* instead cause the invalid order to be skipped.
* @param maximumFulfilled The maximum number of orders to fulfill.
* @param recipient The intended recipient for all items that do not
* already have a designated recipient and are not
* already used as part of a provided fulfillment.
*
* @return orderHashes The hashes of the orders being fulfilled.
* @return containsNonOpen A boolean indicating whether any restricted or
* contract orders are present within the provided
* array of advanced orders.
*/
function _validateOrdersAndPrepareToFulfill(
AdvancedOrder[] memory advancedOrders,
CriteriaResolver[] memory criteriaResolvers,
bool revertOnInvalid,
uint256 maximumFulfilled,
address recipient
) internal returns (bytes32[] memory orderHashes, bool containsNonOpen) {
// Ensure this function cannot be triggered during a reentrant call.
_setReentrancyGuard(true); // Native tokens accepted during execution.
// Declare "terminal memory offset" variable for use in efficient loops.
uint256 terminalMemoryOffset;
{
// Declare an error buffer indicating status of any native offer
// items. Native tokens may only be provided as part of contract
// orders or when fulfilling via matchOrders or matchAdvancedOrders;
// throw if bits indicating the conditions aren't met have been set.
uint256 invalidNativeOfferItemErrorBuffer;
// Use assembly to set the value for the second bit of error buffer.
assembly {
/**
* Use the 231st bit of the error buffer to indicate whether the
* current function is not matchAdvancedOrders or matchOrders.
*
* sig func
* -------------------------------------------------------------
* 1010100000010111010001000 0 000100 matchOrders
* 1111001011010001001010110 0 010010 matchAdvancedOrders
* 1110110110011000101001010 1 110100 fulfillAvailableOrders
* 1000011100100000000110110 1 000001 fulfillAvailableAdvanced
* ^ 7th bit
*/
invalidNativeOfferItemErrorBuffer := and(
NonMatchSelector_MagicMask,
calldataload(0)
)
}
unchecked {
// Read length of orders array and place on the stack.
uint256 totalOrders = advancedOrders.length;
// Track the order hash for each order being fulfilled.
orderHashes = new bytes32[](totalOrders);
// Determine the memory offset to terminate on during loops.
terminalMemoryOffset = (totalOrders + 1) << OneWordShift;
}
// Skip overflow checks as for loops are indexed starting at zero.
unchecked {
// Declare variable to track if order is not a contract order.
bool isNonContract;
// Iterate over each order.
for (
uint256 i = OneWord;
i < terminalMemoryOffset;
i += OneWord
) {
// Retrieve order via pointer to bypass out-of-range check &
// cast function to avoid additional memory allocation.
AdvancedOrder memory advancedOrder = (
_getReadAdvancedOrderByOffset()(advancedOrders, i)
);
// Validate it, update status, & determine fraction to fill.
(
bytes32 orderHash,
uint256 numerator,
uint256 denominator
) = _validateOrder(advancedOrder, revertOnInvalid);
// Update the numerator on the order in question.
advancedOrder.numerator = uint120(numerator);
// Do not track hash or adjust prices if order is skipped.
if (numerator == 0) {
// Continue iterating through the remaining orders.
continue;
}
// Update the denominator on the order in question.
advancedOrder.denominator = uint120(denominator);
// Otherwise, track the order hash in question.
assembly {
mstore(add(orderHashes, i), orderHash)
}
// Place the start time for the order on the stack.
uint256 startTime = advancedOrder.parameters.startTime;
// Place the end time for the order on the stack.
uint256 endTime = advancedOrder.parameters.endTime;
{
// Determine order type, used to check for eligibility
// for native token offer items as well as for presence
// of restricted and contract orders or non-open orders.
OrderType orderType = (
advancedOrder.parameters.orderType
);
// Utilize assembly to efficiently check order types.
// Note these checks expect that there are no order
// types beyond current set (0-4) and will need to be
// modified if more order types are added.
assembly {
// Assign the variable indicating if the order is
// not a contract order.
isNonContract := lt(orderType, 4)
// Update the variable indicating if order is not an
// open order & keep set if it has been set already.
containsNonOpen := or(
containsNonOpen,
gt(orderType, 1)
)
}
}
// Retrieve array of offer items for the order in question.
OfferItem[] memory offer = advancedOrder.parameters.offer;
// Read length of offer array and place on the stack.
uint256 totalOfferItems = offer.length;
// Iterate over each offer item on the order.
for (uint256 j = 0; j < totalOfferItems; ++j) {
// Retrieve the offer item.
OfferItem memory offerItem = offer[j];
// If the offer item is for the native token and the
// order type is not a contract order type, set the
// first bit of the error buffer to true.
assembly {
invalidNativeOfferItemErrorBuffer := or(
invalidNativeOfferItemErrorBuffer,
lt(mload(offerItem), isNonContract)
)
}
// Apply order fill fraction to offer item end amount.
uint256 endAmount = _getFraction(
numerator,
denominator,
offerItem.endAmount
);
// Reuse same fraction if start & end amounts are equal.
if (offerItem.startAmount == offerItem.endAmount) {
// Apply derived amount to both start & end amount.
offerItem.startAmount = endAmount;
} else {
// Apply order fill fraction to item start amount.
offerItem.startAmount = _getFraction(
numerator,
denominator,
offerItem.startAmount
);
}
// Adjust offer amount using current time; round down.
uint256 currentAmount = _locateCurrentAmount(
offerItem.startAmount,
endAmount,
startTime,
endTime,
_runTimeConstantFalse() // round down
);
// Update amounts in memory to match the current amount.
// Note the end amount is used to track spent amounts.
offerItem.startAmount = currentAmount;
offerItem.endAmount = currentAmount;
}
// Retrieve consideration item array for order in question.
ConsiderationItem[] memory consideration = (
advancedOrder.parameters.consideration
);
// Read length of consideration array and place on stack.
uint256 totalConsiderationItems = consideration.length;
// Iterate over each consideration item on the order.
for (uint256 j = 0; j < totalConsiderationItems; ++j) {
// Retrieve the consideration item.
ConsiderationItem memory considerationItem = (
consideration[j]
);
// Apply fraction to consideration item end amount.
uint256 endAmount = _getFraction(
numerator,
denominator,
considerationItem.endAmount
);
// Reuse same fraction if start & end amounts are equal.
if (
considerationItem.startAmount ==
considerationItem.endAmount
) {
// Apply derived amount to both start & end amount.
considerationItem.startAmount = endAmount;
} else {
// Apply fraction to item start amount.
considerationItem.startAmount = _getFraction(
numerator,
denominator,
considerationItem.startAmount
);
}
// Adjust amount using current time; round up.
uint256 currentAmount = (
_locateCurrentAmount(
considerationItem.startAmount,
endAmount,
startTime,
endTime,
_runTimeConstantTrue() // round up
)
);
// Set the start amount as equal to the current amount.
considerationItem.startAmount = currentAmount;
// Utilize assembly to manually "shift" the recipient
// value, then copy the start amount to the recipient.
// Note that this sets up the memory layout that is
// subsequently relied upon by
// _aggregateValidFulfillmentConsiderationItems as well
// as during comparison to generated contract orders.
assembly {
// Derive pointer to the recipient using the item
// pointer along with the offset to the recipient.
let considerationItemRecipientPtr := add(
considerationItem,
ConsiderationItem_recipient_offset
)
// Write recipient to endAmount, as endAmount is not
// used from this point on and can be repurposed to
// fit the layout of a ReceivedItem.
mstore(
add(
considerationItem,
// Note that this value used to be endAmount
ReceivedItem_recipient_offset
),
mload(considerationItemRecipientPtr)
)
// Write startAmount to recipient, as recipient is
// not used from this point on and can be repurposed
// to track received amounts.
mstore(considerationItemRecipientPtr, currentAmount)
}
}
}
}
// If the first bit is set, a native offer item was encountered on
// an order that is not a contract order. If the 231st bit is set in
// the error buffer, the current function is not matchOrders or
// matchAdvancedOrders. If the value is 1 + (1 << 230), then both
// 1st and 231st bits were set; in that case, revert with an error.
if (
invalidNativeOfferItemErrorBuffer ==
NonMatchSelector_InvalidErrorValue
) {
_revertInvalidNativeOfferItem();
}
}
// Apply criteria resolvers to each order as applicable.
_applyCriteriaResolvers(advancedOrders, criteriaResolvers);
// Iterate over each order to check authorization status (for restricted
// orders), generate orders (for contract orders), and emit events (for
// all available orders) signifying that they have been fulfilled.
// Skip overflow checks as all for loops are indexed starting at zero.
unchecked {
// Declare stack variable outside of the loop to track order hash.
bytes32 orderHash;
// Track whether any orders are still available for fulfillment.
bool someOrderAvailable = false;
// Iterate over each order.
for (uint256 i = OneWord; i < terminalMemoryOffset; i += OneWord) {
// Retrieve order hash, bypassing out-of-range check.
assembly {
orderHash := mload(add(orderHashes, i))
}
// Do not emit an event if no order hash is present.
if (orderHash == bytes32(0)) {
continue;
}
// Retrieve order using pointer libraries to bypass out-of-range
// check & cast function to avoid additional memory allocation.
AdvancedOrder memory advancedOrder = (
_getReadAdvancedOrderByOffset()(advancedOrders, i)
);
// Determine if max number orders have already been fulfilled.
if (maximumFulfilled == 0) {
// If so, set the order hash to zero.
assembly {
mstore(add(orderHashes, i), 0)
}
// Set the numerator to zero to signal to skip the order.
advancedOrder.numerator = 0;
// Continue iterating through the remaining orders.
continue;
}
// Handle final checks and status updates based on order type.
if (advancedOrder.parameters.orderType != OrderType.CONTRACT) {
// Check authorization for restricted orders.
if (
!_checkRestrictedAdvancedOrderAuthorization(
advancedOrder,
orderHashes,
orderHash,
(i >> OneWordShift) - 1,
revertOnInvalid
)
) {
// If authorization check fails, set order hash to zero.
assembly {
mstore(add(orderHashes, i), 0)
}
// Set numerator to zero to signal to skip the order.
advancedOrder.numerator = 0;
// Continue iterating through the remaining orders.
continue;
}
// Update status as long as some fraction is available.
if (
!_updateStatus(
orderHash,
advancedOrder.numerator,
advancedOrder.denominator,
_revertOnFailedUpdate(
advancedOrder.parameters,
revertOnInvalid
)
)
) {
// If status update fails, set the order hash to zero.
assembly {
mstore(add(orderHashes, i), 0)
}
// Set numerator to zero to signal to skip the order.
advancedOrder.numerator = 0;
// Continue iterating through the remaining orders.
continue;
}
} else {
// Return the generated order based on the order params and
// the provided extra data. If revertOnInvalid is true, the
// function will revert if the input is invalid.
orderHash = _getGeneratedOrder(
advancedOrder.parameters,
advancedOrder.extraData,
revertOnInvalid
);
// Write the derived order hash to the order hashes array.
assembly {
mstore(add(orderHashes, i), orderHash)
}
// Handle invalid orders, indicated by a zero order hash.
if (orderHash == bytes32(0)) {
// Set numerator to zero to signal to skip the order.
advancedOrder.numerator = 0;
// Continue iterating through the remaining orders.
continue;
}
}
// Decrement the number of fulfilled orders.
// Skip underflow check as the condition before
// implies that maximumFulfilled > 0.
--maximumFulfilled;
// Retrieve parameters for the order in question.
OrderParameters memory orderParameters = (
advancedOrder.parameters
);
// Emit an OrderFulfilled event.
_emitOrderFulfilledEvent(
orderHash,
orderParameters.offerer,
orderParameters.zone,
recipient,
orderParameters.offer,
orderParameters.consideration
);
// Set the flag indicating that some order is available.
someOrderAvailable = true;
}
// Revert if no orders are available.
if (!someOrderAvailable) {
_revertNoSpecifiedOrdersAvailable();
}
}
}
/**
* @dev Internal function to fulfill a group of validated orders, fully or
* partially, with an arbitrary number of items for offer and
* consideration per order and to execute transfers. Any order that is
* not currently active, has already been fully filled, or has been
* cancelled will be omitted. Remaining offer and consideration items
* will then be aggregated where possible as indicated by the supplied
* offer and consideration component arrays and aggregated items will
* be transferred to the fulfiller or to each intended recipient,
* respectively. Note that a failing item transfer or an issue with
* order formatting will cause the entire batch to fail.
*
* @param advancedOrders The orders to fulfill along with the
* fraction of those orders to attempt to
* fill. Note that both the offerer and the
* fulfiller must first approve this
* contract (or the conduit if indicated by
* the order) to transfer any relevant
* tokens on their behalf and that
* contracts must implement
* `onERC1155Received` in order to receive
* ERC1155 tokens as consideration. Also
* note that all offer and consideration
* components must have no remainder after
* multiplication of the respective amount
* with the supplied fraction for an
* order's partial fill amount to be
* considered valid.
* @param offerFulfillments An array of FulfillmentComponent arrays
* indicating which offer items to attempt
* to aggregate when preparing executions.
* @param considerationFulfillments An array of FulfillmentComponent arrays
* indicating which consideration items to
* attempt to aggregate when preparing
* executions.
* @param fulfillerConduitKey A bytes32 value indicating what conduit,
* if any, to source the fulfiller's token
* approvals from. The zero hash signifies
* that no conduit should be used, with
* direct approvals set on Consideration.
* @param recipient The intended recipient for all items
* that do not already have a designated
* recipient and are not already used as
* part of a provided fulfillment.
* @param orderHashes An array of order hashes for each order.
* @param containsNonOpen A boolean indicating whether any
* restricted or contract orders are
* present within the provided array of
* advanced orders.
*
* @return availableOrders An array of booleans indicating if each order
* with an index corresponding to the index of the
* returned boolean was fulfillable or not.
* @return executions An array of elements indicating the sequence of
* transfers performed as part of matching the given
* orders.
*/
function _executeAvailableFulfillments(
AdvancedOrder[] memory advancedOrders,
FulfillmentComponent[][] memory offerFulfillments,
FulfillmentComponent[][] memory considerationFulfillments,
bytes32 fulfillerConduitKey,
address recipient,
bytes32[] memory orderHashes,
bool containsNonOpen
)
internal
returns (bool[] memory availableOrders, Execution[] memory executions)
{
// Retrieve length of offer fulfillments array and place on the stack.
uint256 totalOfferFulfillments = offerFulfillments.length;
// Retrieve length of consideration fulfillments array & place on stack.
uint256 totalConsiderationFulfillments = (
considerationFulfillments.length
);
// Allocate an execution for each offer and consideration fulfillment.
executions = new Execution[](
totalOfferFulfillments + totalConsiderationFulfillments
);
// Skip overflow checks as all for loops are indexed starting at zero.
unchecked {
// Iterate over each offer fulfillment.
for (uint256 i = 0; i < totalOfferFulfillments; ++i) {
// Derive aggregated execution corresponding with fulfillment
// and assign it to the executions array.
executions[i] = _aggregateAvailable(
advancedOrders,
Side.OFFER,
offerFulfillments[i],
fulfillerConduitKey,
recipient
);
}
// Iterate over each consideration fulfillment.
for (uint256 i = 0; i < totalConsiderationFulfillments; ++i) {
// Derive aggregated execution corresponding with fulfillment
// and assign it to the executions array.
executions[i + totalOfferFulfillments] = _aggregateAvailable(
advancedOrders,
Side.CONSIDERATION,
considerationFulfillments[i],
fulfillerConduitKey,
address(0) // unused
);
}
}
// Perform final checks and return.
availableOrders = _performFinalChecksAndExecuteOrders(
advancedOrders,
executions,
orderHashes,
recipient,
containsNonOpen
);
return (availableOrders, executions);
}
/**
* @dev Internal function to perform a final check that each consideration
* item for an arbitrary number of fulfilled orders has been met and to
* trigger associated executions, transferring the respective items.
*
* @param advancedOrders The orders to check and perform executions for.
* @param executions An array of elements indicating the sequence of
* transfers to perform when fulfilling the given
* orders.
* @param orderHashes An array of order hashes for each order.
* @param recipient The intended recipient for all items that do not
* already have a designated recipient and are not
* used as part of a provided fulfillment.
* @param containsNonOpen A boolean indicating whether any restricted or
* contract orders are present within the provided
* array of advanced orders.
*
* @return availableOrders An array of booleans indicating if each order
* with an index corresponding to the index of the
* returned boolean was fulfillable or not.
*/
function _performFinalChecksAndExecuteOrders(
AdvancedOrder[] memory advancedOrders,
Execution[] memory executions,
bytes32[] memory orderHashes,
address recipient,
bool containsNonOpen
) internal returns (bool[] memory /* availableOrders */) {
// Retrieve the length of the advanced orders array and place on stack.
uint256 totalOrders = advancedOrders.length;
// Initialize array for tracking available orders.
bool[] memory availableOrders = new bool[](totalOrders);
// Initialize an accumulator array. From this point forward, no new
// memory regions can be safely allocated until the accumulator is no
// longer being utilized, as the accumulator operates in an open-ended
// fashion from this memory pointer; existing memory may still be
// accessed and modified, however.
bytes memory accumulator = new bytes(AccumulatorDisarmed);
// Skip overflow check: loop index & executions length are both bounded.
unchecked {
// Determine the memory offset to terminate on during loops.
uint256 terminalMemoryOffset = ((executions.length + 1) <<
OneWordShift);
// Iterate over each execution.
for (uint256 i = OneWord; i < terminalMemoryOffset; i += OneWord) {
// Get execution using pointer libraries to bypass out-of-range
// check & cast function to avoid additional memory allocation.
Execution memory execution = (
_getReadExecutionByOffset()(executions, i)
);
// Retrieve the associated received item and amount.
ReceivedItem memory item = execution.item;
uint256 amount = item.amount;
// Transfer the item specified by the execution as long as the
// execution is not a zero-amount execution (which can occur if
// the corresponding fulfillment contained only items on orders
// that are unavailable or are out of range of the respective
// item array).
if (amount != 0) {
// Utilize assembly to check for native token balance.
assembly {
// Ensure a sufficient native balance if relevant.
if and(
iszero(mload(item)), // itemType == ItemType.NATIVE
// item.amount > address(this).balance
gt(amount, selfbalance())
) {
// Store left-padded selector with push4,
// mem[28:32] = selector
mstore(
0,
InsufficientNativeTokensSupplied_error_selector
)
// revert(abi.encodeWithSignature(
// "InsufficientNativeTokensSupplied()"
// ))
revert(
Error_selector_offset,
InsufficientNativeTokensSupplied_error_length
)
}
}
// Transfer the item specified by the execution.
_transfer(
item,
execution.offerer,
execution.conduitKey,
accumulator
);
}
}
}
// Skip overflow checks as all for loops are indexed starting at zero.
unchecked {
// Iterate over each order.
for (uint256 i = 0; i < totalOrders; ++i) {
// Retrieve the order in question.
AdvancedOrder memory advancedOrder = advancedOrders[i];
// Skip the order in question if not being not fulfilled.
if (advancedOrder.numerator == 0) {
// Explicitly set availableOrders at the given index to
// guard against the possibility of dirtied memory.
availableOrders[i] = false;
continue;
}
// Mark the order as available.
availableOrders[i] = true;
// Retrieve the order parameters.
OrderParameters memory parameters = advancedOrder.parameters;
{
// Retrieve offer items.
OfferItem[] memory offer = parameters.offer;
// Read length of offer array & place on the stack.
uint256 totalOfferItems = offer.length;
// Iterate over each offer item to restore it.
for (uint256 j = 0; j < totalOfferItems; ++j) {
// Retrieve the offer item in question.
OfferItem memory offerItem = offer[j];
// Transfer to recipient if unspent amount is not zero.
// Note that the transfer will not be reflected in the
// executions array.
if (offerItem.startAmount != 0) {
// Replace endAmount parameter with the recipient to
// make offerItem compatible with the ReceivedItem
// input to _transfer & cache the original endAmount
// so it can be restored after the transfer.
uint256 originalEndAmount = (
_replaceEndAmountWithRecipient(
offerItem,
recipient
)
);
// Transfer excess offer item amount to recipient.
_toOfferItemInput(_transfer)(
offerItem,
parameters.offerer,
parameters.conduitKey,
accumulator
);
// Restore the original endAmount in offerItem.
assembly {
mstore(
add(
offerItem,
ReceivedItem_recipient_offset
),
originalEndAmount
)
}
}
// Restore original amount on the offer item.
offerItem.startAmount = offerItem.endAmount;
}
}
{
// Read consideration items & ensure they are fulfilled.
ConsiderationItem[] memory consideration = (
parameters.consideration
);
// Read length of consideration array & place on stack.
uint256 totalConsiderationItems = consideration.length;
// Iterate over each consideration item.
for (uint256 j = 0; j < totalConsiderationItems; ++j) {
ConsiderationItem memory considerationItem = (
consideration[j]
);
// Retrieve remaining amount on consideration item.
uint256 unmetAmount = considerationItem.startAmount;
// Revert if the remaining amount is not zero.
if (unmetAmount != 0) {
_revertConsiderationNotMet(i, j, unmetAmount);
}
// Utilize assembly to restore the original value.
assembly {
// Write recipient to startAmount.
mstore(
add(
considerationItem,
ReceivedItem_amount_offset
),
mload(
add(
considerationItem,
ConsiderationItem_recipient_offset
)
)
)
}
}
}
}
}
// Trigger any accumulated transfers via call to the conduit.
_triggerIfArmed(accumulator);
// Determine whether any native token balance remains.
uint256 remainingNativeTokenBalance;
assembly {
remainingNativeTokenBalance := selfbalance()
}
// Return any remaining native token balance to the caller.
if (remainingNativeTokenBalance != 0) {
_transferNativeTokens(
payable(msg.sender),
remainingNativeTokenBalance
);
}
// If any restricted or contract orders are present in the group of
// orders being fulfilled, perform any validateOrder or ratifyOrder
// calls after all executions and related transfers are complete.
if (containsNonOpen) {
// Iterate over each order a second time.
for (uint256 i = 0; i < totalOrders; ) {
// Ensure the order in question is being fulfilled.
if (availableOrders[i]) {
// Check restricted orders and contract orders.
_assertRestrictedAdvancedOrderValidity(
advancedOrders[i],
orderHashes,
orderHashes[i]
);
}
// Skip overflow checks as for loop is indexed starting at zero.
unchecked {
++i;
}
}
}
// Clear the reentrancy guard.
_clearReentrancyGuard();
// Return the array containing available orders.
return availableOrders;
}
/**
* @dev Internal function to emit an OrdersMatched event using the same
* memory region as the existing order hash array.
*
* @param orderHashes An array of order hashes to include as an argument for
* the OrdersMatched event.
*/
function _emitOrdersMatched(bytes32[] memory orderHashes) internal {
assembly {
// Load the array length from memory.
let length := mload(orderHashes)
// Get the full size of the event data - one word for the offset,
// one for the array length and one per hash.
let dataSize := add(TwoWords, shl(OneWordShift, length))
// Get pointer to start of data, reusing word before array length
// for the offset.
let dataPointer := sub(orderHashes, OneWord)
// Cache the existing word in memory at the offset pointer.
let cache := mload(dataPointer)
// Write an offset of 32.
mstore(dataPointer, OneWord)
// Emit the OrdersMatched event.
log1(dataPointer, dataSize, OrdersMatchedTopic0)
// Restore the cached word.
mstore(dataPointer, cache)
}
}
/**
* @dev Internal function to match an arbitrary number of full or partial
* orders, each with an arbitrary number of items for offer and
* consideration, supplying criteria resolvers containing specific
* token identifiers and associated proofs as well as fulfillments
* allocating offer components to consideration components.
*
* @param advancedOrders The advanced orders to match. Note that both the
* offerer and fulfiller on each order must first
* approve this contract (or their conduit if
* indicated by the order) to transfer any relevant
* tokens on their behalf and each consideration
* recipient must implement `onERC1155Received` in
* order to receive ERC1155 tokens. Also note that
* the offer and consideration components for each
* order must have no remainder after multiplying
* the respective amount with the supplied fraction
* in order for the group of partial fills to be
* considered valid.
* @param criteriaResolvers An array where each element contains a reference
* to a specific order as well as that order's
* offer or consideration, a token identifier, and
* a proof that the supplied token identifier is
* contained in the order's merkle root. Note that
* an empty root indicates that any (transferable)
* token identifier is valid and that no associated
* proof needs to be supplied.
* @param fulfillments An array of elements allocating offer components
* to consideration components. Note that each
* consideration component must be fully met in
* order for the match operation to be valid.
* @param recipient The intended recipient for all unspent offer
* item amounts.
*
* @return executions An array of elements indicating the sequence of
* transfers performed as part of matching the given
* orders.
*/
function _matchAdvancedOrders(
AdvancedOrder[] memory advancedOrders,
CriteriaResolver[] memory criteriaResolvers,
Fulfillment[] memory fulfillments,
address recipient
) internal returns (Execution[] memory /* executions */) {
// Create a `true` boolean variable to indicate that invalid orders
// should revert. Does not use a constant to avoid function
// specialization in solc that would increase contract size.
bool revertOnInvalid = _runTimeConstantTrue();
// Validate orders, update order status, and determine item amounts.
(
bytes32[] memory orderHashes,
bool containsNonOpen
) = _validateOrdersAndPrepareToFulfill(
advancedOrders,
criteriaResolvers,
revertOnInvalid,
advancedOrders.length,
recipient
);
// Emit OrdersMatched event, providing an array of matched order hashes.
_emitOrdersMatched(orderHashes);
// Fulfill the orders using the supplied fulfillments and recipient.
return
_fulfillAdvancedOrders(
advancedOrders,
fulfillments,
orderHashes,
recipient,
containsNonOpen
);
}
/**
* @dev Internal function to fulfill an arbitrary number of orders, either
* full or partial, after validating, adjusting amounts, and applying
* criteria resolvers.
*
* @param advancedOrders The orders to match, including a fraction to
* attempt to fill for each order.
* @param fulfillments An array of elements allocating offer components
* to consideration components. Note that the final
* amount of each consideration component must be
* zero for a match operation to be considered valid.
* @param orderHashes An array of order hashes for each order.
* @param recipient The intended recipient for all items that do not
* already have a designated recipient and are not
* used as part of a provided fulfillment.
* @param containsNonOpen A boolean indicating whether any restricted or
* contract orders are present within the provided
* array of advanced orders.
*
* @return executions An array of elements indicating the sequence of
* transfers performed as part of matching the given
* orders.
*/
function _fulfillAdvancedOrders(
AdvancedOrder[] memory advancedOrders,
Fulfillment[] memory fulfillments,
bytes32[] memory orderHashes,
address recipient,
bool containsNonOpen
) internal returns (Execution[] memory executions) {
// Retrieve fulfillments array length and place on the stack.
uint256 totalFulfillments = fulfillments.length;
// Allocate executions by fulfillment and apply them to each execution.
executions = new Execution[](totalFulfillments);
// Skip overflow checks as all for loops are indexed starting at zero.
unchecked {
// Iterate over each fulfillment.
for (uint256 i = 0; i < totalFulfillments; ++i) {
/// Retrieve the fulfillment in question.
Fulfillment memory fulfillment = fulfillments[i];
// Derive the execution corresponding with the fulfillment and
// assign it to the executions array.
executions[i] = _applyFulfillment(
advancedOrders,
fulfillment.offerComponents,
fulfillment.considerationComponents,
i
);
}
}
// Perform final checks and execute orders.
_performFinalChecksAndExecuteOrders(
advancedOrders,
executions,
orderHashes,
recipient,
containsNonOpen
);
// Return the executions array.
return executions;
}
/**
* @dev Internal view function to determine whether a status update failure
* should cause a revert or allow a skipped order. The call must revert
* if an `authorizeOrder` call has been successfully performed and the
* status update cannot be performed, regardless of whether the order
* could be otherwise marked as skipped. Note that a revert is not
* required on a failed update if the call originates from the zone, as
* no `authorizeOrder` call is performed in that case.
*
* @param orderParameters The order parameters in question.
* @param revertOnInvalid A boolean indicating whether the call should
* revert for non-restricted order types.
*
* @return revertOnFailedUpdate A boolean indicating whether the order
* should revert on a failed status update.
*/
function _revertOnFailedUpdate(
OrderParameters memory orderParameters,
bool revertOnInvalid
) internal view returns (bool revertOnFailedUpdate) {
OrderType orderType = orderParameters.orderType;
address zone = orderParameters.zone;
assembly {
revertOnFailedUpdate := or(
revertOnInvalid,
and(gt(orderType, 1), iszero(eq(caller(), zone)))
)
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
type CalldataPointer is uint256;
type ReturndataPointer is uint256;
type MemoryPointer is uint256;
using CalldataPointerLib for CalldataPointer global;
using MemoryPointerLib for MemoryPointer global;
using ReturndataPointerLib for ReturndataPointer global;
using CalldataReaders for CalldataPointer global;
using ReturndataReaders for ReturndataPointer global;
using MemoryReaders for MemoryPointer global;
using MemoryWriters for MemoryPointer global;
CalldataPointer constant CalldataStart = CalldataPointer.wrap(0x04);
MemoryPointer constant FreeMemoryPPtr = MemoryPointer.wrap(0x40);
MemoryPointer constant ZeroSlotPtr = MemoryPointer.wrap(0x60);
uint256 constant IdentityPrecompileAddress = 0x4;
uint256 constant OffsetOrLengthMask = 0xffffffff;
uint256 constant _OneWord = 0x20;
uint256 constant _FreeMemoryPointerSlot = 0x40;
/// @dev Allocates `size` bytes in memory by increasing the free memory pointer
/// and returns the memory pointer to the first byte of the allocated region.
// (Free functions cannot have visibility.)
// solhint-disable-next-line func-visibility
function malloc(uint256 size) pure returns (MemoryPointer mPtr) {
assembly {
mPtr := mload(_FreeMemoryPointerSlot)
mstore(_FreeMemoryPointerSlot, add(mPtr, size))
}
}
// (Free functions cannot have visibility.)
// solhint-disable-next-line func-visibility
function getFreeMemoryPointer() pure returns (MemoryPointer mPtr) {
mPtr = FreeMemoryPPtr.readMemoryPointer();
}
// (Free functions cannot have visibility.)
// solhint-disable-next-line func-visibility
function setFreeMemoryPointer(MemoryPointer mPtr) pure {
FreeMemoryPPtr.write(mPtr);
}
library CalldataPointerLib {
function lt(
CalldataPointer a,
CalldataPointer b
) internal pure returns (bool c) {
assembly {
c := lt(a, b)
}
}
function gt(
CalldataPointer a,
CalldataPointer b
) internal pure returns (bool c) {
assembly {
c := gt(a, b)
}
}
function eq(
CalldataPointer a,
CalldataPointer b
) internal pure returns (bool c) {
assembly {
c := eq(a, b)
}
}
function isNull(CalldataPointer a) internal pure returns (bool b) {
assembly {
b := iszero(a)
}
}
/// @dev Resolves an offset stored at `cdPtr + headOffset` to a calldata.
/// pointer `cdPtr` must point to some parent object with a dynamic
/// type's head stored at `cdPtr + headOffset`.
function pptrOffset(
CalldataPointer cdPtr,
uint256 headOffset
) internal pure returns (CalldataPointer cdPtrChild) {
cdPtrChild = cdPtr.offset(
cdPtr.offset(headOffset).readUint256() & OffsetOrLengthMask
);
}
/// @dev Resolves an offset stored at `cdPtr` to a calldata pointer.
/// `cdPtr` must point to some parent object with a dynamic type as its
/// first member, e.g. `struct { bytes data; }`
function pptr(
CalldataPointer cdPtr
) internal pure returns (CalldataPointer cdPtrChild) {
cdPtrChild = cdPtr.offset(cdPtr.readUint256() & OffsetOrLengthMask);
}
/// @dev Returns the calldata pointer one word after `cdPtr`.
function next(
CalldataPointer cdPtr
) internal pure returns (CalldataPointer cdPtrNext) {
assembly {
cdPtrNext := add(cdPtr, _OneWord)
}
}
/// @dev Returns the calldata pointer `_offset` bytes after `cdPtr`.
function offset(
CalldataPointer cdPtr,
uint256 _offset
) internal pure returns (CalldataPointer cdPtrNext) {
assembly {
cdPtrNext := add(cdPtr, _offset)
}
}
/// @dev Copies `size` bytes from calldata starting at `src` to memory at
/// `dst`.
function copy(
CalldataPointer src,
MemoryPointer dst,
uint256 size
) internal pure {
assembly {
calldatacopy(dst, src, size)
}
}
}
library ReturndataPointerLib {
function lt(
ReturndataPointer a,
ReturndataPointer b
) internal pure returns (bool c) {
assembly {
c := lt(a, b)
}
}
function gt(
ReturndataPointer a,
ReturndataPointer b
) internal pure returns (bool c) {
assembly {
c := gt(a, b)
}
}
function eq(
ReturndataPointer a,
ReturndataPointer b
) internal pure returns (bool c) {
assembly {
c := eq(a, b)
}
}
function isNull(ReturndataPointer a) internal pure returns (bool b) {
assembly {
b := iszero(a)
}
}
/// @dev Resolves an offset stored at `rdPtr + headOffset` to a returndata
/// pointer. `rdPtr` must point to some parent object with a dynamic
/// type's head stored at `rdPtr + headOffset`.
function pptrOffset(
ReturndataPointer rdPtr,
uint256 headOffset
) internal pure returns (ReturndataPointer rdPtrChild) {
rdPtrChild = rdPtr.offset(
rdPtr.offset(headOffset).readUint256() & OffsetOrLengthMask
);
}
/// @dev Resolves an offset stored at `rdPtr` to a returndata pointer.
/// `rdPtr` must point to some parent object with a dynamic type as its
/// first member, e.g. `struct { bytes data; }`
function pptr(
ReturndataPointer rdPtr
) internal pure returns (ReturndataPointer rdPtrChild) {
rdPtrChild = rdPtr.offset(rdPtr.readUint256() & OffsetOrLengthMask);
}
/// @dev Returns the returndata pointer one word after `cdPtr`.
function next(
ReturndataPointer rdPtr
) internal pure returns (ReturndataPointer rdPtrNext) {
assembly {
rdPtrNext := add(rdPtr, _OneWord)
}
}
/// @dev Returns the returndata pointer `_offset` bytes after `cdPtr`.
function offset(
ReturndataPointer rdPtr,
uint256 _offset
) internal pure returns (ReturndataPointer rdPtrNext) {
assembly {
rdPtrNext := add(rdPtr, _offset)
}
}
/// @dev Copies `size` bytes from returndata starting at `src` to memory at
/// `dst`.
function copy(
ReturndataPointer src,
MemoryPointer dst,
uint256 size
) internal pure {
assembly {
returndatacopy(dst, src, size)
}
}
}
library MemoryPointerLib {
function copy(
MemoryPointer src,
MemoryPointer dst,
uint256 size
) internal view {
assembly {
let success := staticcall(
gas(),
IdentityPrecompileAddress,
src,
size,
dst,
size
)
if or(iszero(returndatasize()), iszero(success)) {
revert(0, 0)
}
}
}
function lt(
MemoryPointer a,
MemoryPointer b
) internal pure returns (bool c) {
assembly {
c := lt(a, b)
}
}
function gt(
MemoryPointer a,
MemoryPointer b
) internal pure returns (bool c) {
assembly {
c := gt(a, b)
}
}
function eq(
MemoryPointer a,
MemoryPointer b
) internal pure returns (bool c) {
assembly {
c := eq(a, b)
}
}
function isNull(MemoryPointer a) internal pure returns (bool b) {
assembly {
b := iszero(a)
}
}
function hash(
MemoryPointer ptr,
uint256 length
) internal pure returns (bytes32 _hash) {
assembly {
_hash := keccak256(ptr, length)
}
}
/// @dev Returns the memory pointer one word after `mPtr`.
function next(
MemoryPointer mPtr
) internal pure returns (MemoryPointer mPtrNext) {
assembly {
mPtrNext := add(mPtr, _OneWord)
}
}
/// @dev Returns the memory pointer `_offset` bytes after `mPtr`.
function offset(
MemoryPointer mPtr,
uint256 _offset
) internal pure returns (MemoryPointer mPtrNext) {
assembly {
mPtrNext := add(mPtr, _offset)
}
}
/// @dev Resolves a pointer at `mPtr + headOffset` to a memory
/// pointer. `mPtr` must point to some parent object with a dynamic
/// type's pointer stored at `mPtr + headOffset`.
function pptrOffset(
MemoryPointer mPtr,
uint256 headOffset
) internal pure returns (MemoryPointer mPtrChild) {
mPtrChild = mPtr.offset(headOffset).readMemoryPointer();
}
/// @dev Resolves a pointer stored at `mPtr` to a memory pointer.
/// `mPtr` must point to some parent object with a dynamic type as its
/// first member, e.g. `struct { bytes data; }`
function pptr(
MemoryPointer mPtr
) internal pure returns (MemoryPointer mPtrChild) {
mPtrChild = mPtr.readMemoryPointer();
}
}
library CalldataReaders {
/// @dev Reads the value at `cdPtr` and applies a mask to return only the
/// last 4 bytes.
function readMaskedUint256(
CalldataPointer cdPtr
) internal pure returns (uint256 value) {
value = cdPtr.readUint256() & OffsetOrLengthMask;
}
/// @dev Reads the bool at `cdPtr` in calldata.
function readBool(
CalldataPointer cdPtr
) internal pure returns (bool value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the address at `cdPtr` in calldata.
function readAddress(
CalldataPointer cdPtr
) internal pure returns (address value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes1 at `cdPtr` in calldata.
function readBytes1(
CalldataPointer cdPtr
) internal pure returns (bytes1 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes2 at `cdPtr` in calldata.
function readBytes2(
CalldataPointer cdPtr
) internal pure returns (bytes2 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes3 at `cdPtr` in calldata.
function readBytes3(
CalldataPointer cdPtr
) internal pure returns (bytes3 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes4 at `cdPtr` in calldata.
function readBytes4(
CalldataPointer cdPtr
) internal pure returns (bytes4 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes5 at `cdPtr` in calldata.
function readBytes5(
CalldataPointer cdPtr
) internal pure returns (bytes5 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes6 at `cdPtr` in calldata.
function readBytes6(
CalldataPointer cdPtr
) internal pure returns (bytes6 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes7 at `cdPtr` in calldata.
function readBytes7(
CalldataPointer cdPtr
) internal pure returns (bytes7 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes8 at `cdPtr` in calldata.
function readBytes8(
CalldataPointer cdPtr
) internal pure returns (bytes8 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes9 at `cdPtr` in calldata.
function readBytes9(
CalldataPointer cdPtr
) internal pure returns (bytes9 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes10 at `cdPtr` in calldata.
function readBytes10(
CalldataPointer cdPtr
) internal pure returns (bytes10 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes11 at `cdPtr` in calldata.
function readBytes11(
CalldataPointer cdPtr
) internal pure returns (bytes11 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes12 at `cdPtr` in calldata.
function readBytes12(
CalldataPointer cdPtr
) internal pure returns (bytes12 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes13 at `cdPtr` in calldata.
function readBytes13(
CalldataPointer cdPtr
) internal pure returns (bytes13 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes14 at `cdPtr` in calldata.
function readBytes14(
CalldataPointer cdPtr
) internal pure returns (bytes14 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes15 at `cdPtr` in calldata.
function readBytes15(
CalldataPointer cdPtr
) internal pure returns (bytes15 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes16 at `cdPtr` in calldata.
function readBytes16(
CalldataPointer cdPtr
) internal pure returns (bytes16 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes17 at `cdPtr` in calldata.
function readBytes17(
CalldataPointer cdPtr
) internal pure returns (bytes17 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes18 at `cdPtr` in calldata.
function readBytes18(
CalldataPointer cdPtr
) internal pure returns (bytes18 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes19 at `cdPtr` in calldata.
function readBytes19(
CalldataPointer cdPtr
) internal pure returns (bytes19 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes20 at `cdPtr` in calldata.
function readBytes20(
CalldataPointer cdPtr
) internal pure returns (bytes20 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes21 at `cdPtr` in calldata.
function readBytes21(
CalldataPointer cdPtr
) internal pure returns (bytes21 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes22 at `cdPtr` in calldata.
function readBytes22(
CalldataPointer cdPtr
) internal pure returns (bytes22 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes23 at `cdPtr` in calldata.
function readBytes23(
CalldataPointer cdPtr
) internal pure returns (bytes23 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes24 at `cdPtr` in calldata.
function readBytes24(
CalldataPointer cdPtr
) internal pure returns (bytes24 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes25 at `cdPtr` in calldata.
function readBytes25(
CalldataPointer cdPtr
) internal pure returns (bytes25 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes26 at `cdPtr` in calldata.
function readBytes26(
CalldataPointer cdPtr
) internal pure returns (bytes26 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes27 at `cdPtr` in calldata.
function readBytes27(
CalldataPointer cdPtr
) internal pure returns (bytes27 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes28 at `cdPtr` in calldata.
function readBytes28(
CalldataPointer cdPtr
) internal pure returns (bytes28 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes29 at `cdPtr` in calldata.
function readBytes29(
CalldataPointer cdPtr
) internal pure returns (bytes29 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes30 at `cdPtr` in calldata.
function readBytes30(
CalldataPointer cdPtr
) internal pure returns (bytes30 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes31 at `cdPtr` in calldata.
function readBytes31(
CalldataPointer cdPtr
) internal pure returns (bytes31 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the bytes32 at `cdPtr` in calldata.
function readBytes32(
CalldataPointer cdPtr
) internal pure returns (bytes32 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint8 at `cdPtr` in calldata.
function readUint8(
CalldataPointer cdPtr
) internal pure returns (uint8 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint16 at `cdPtr` in calldata.
function readUint16(
CalldataPointer cdPtr
) internal pure returns (uint16 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint24 at `cdPtr` in calldata.
function readUint24(
CalldataPointer cdPtr
) internal pure returns (uint24 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint32 at `cdPtr` in calldata.
function readUint32(
CalldataPointer cdPtr
) internal pure returns (uint32 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint40 at `cdPtr` in calldata.
function readUint40(
CalldataPointer cdPtr
) internal pure returns (uint40 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint48 at `cdPtr` in calldata.
function readUint48(
CalldataPointer cdPtr
) internal pure returns (uint48 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint56 at `cdPtr` in calldata.
function readUint56(
CalldataPointer cdPtr
) internal pure returns (uint56 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint64 at `cdPtr` in calldata.
function readUint64(
CalldataPointer cdPtr
) internal pure returns (uint64 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint72 at `cdPtr` in calldata.
function readUint72(
CalldataPointer cdPtr
) internal pure returns (uint72 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint80 at `cdPtr` in calldata.
function readUint80(
CalldataPointer cdPtr
) internal pure returns (uint80 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint88 at `cdPtr` in calldata.
function readUint88(
CalldataPointer cdPtr
) internal pure returns (uint88 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint96 at `cdPtr` in calldata.
function readUint96(
CalldataPointer cdPtr
) internal pure returns (uint96 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint104 at `cdPtr` in calldata.
function readUint104(
CalldataPointer cdPtr
) internal pure returns (uint104 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint112 at `cdPtr` in calldata.
function readUint112(
CalldataPointer cdPtr
) internal pure returns (uint112 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint120 at `cdPtr` in calldata.
function readUint120(
CalldataPointer cdPtr
) internal pure returns (uint120 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint128 at `cdPtr` in calldata.
function readUint128(
CalldataPointer cdPtr
) internal pure returns (uint128 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint136 at `cdPtr` in calldata.
function readUint136(
CalldataPointer cdPtr
) internal pure returns (uint136 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint144 at `cdPtr` in calldata.
function readUint144(
CalldataPointer cdPtr
) internal pure returns (uint144 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint152 at `cdPtr` in calldata.
function readUint152(
CalldataPointer cdPtr
) internal pure returns (uint152 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint160 at `cdPtr` in calldata.
function readUint160(
CalldataPointer cdPtr
) internal pure returns (uint160 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint168 at `cdPtr` in calldata.
function readUint168(
CalldataPointer cdPtr
) internal pure returns (uint168 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint176 at `cdPtr` in calldata.
function readUint176(
CalldataPointer cdPtr
) internal pure returns (uint176 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint184 at `cdPtr` in calldata.
function readUint184(
CalldataPointer cdPtr
) internal pure returns (uint184 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint192 at `cdPtr` in calldata.
function readUint192(
CalldataPointer cdPtr
) internal pure returns (uint192 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint200 at `cdPtr` in calldata.
function readUint200(
CalldataPointer cdPtr
) internal pure returns (uint200 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint208 at `cdPtr` in calldata.
function readUint208(
CalldataPointer cdPtr
) internal pure returns (uint208 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint216 at `cdPtr` in calldata.
function readUint216(
CalldataPointer cdPtr
) internal pure returns (uint216 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint224 at `cdPtr` in calldata.
function readUint224(
CalldataPointer cdPtr
) internal pure returns (uint224 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint232 at `cdPtr` in calldata.
function readUint232(
CalldataPointer cdPtr
) internal pure returns (uint232 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint240 at `cdPtr` in calldata.
function readUint240(
CalldataPointer cdPtr
) internal pure returns (uint240 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint248 at `cdPtr` in calldata.
function readUint248(
CalldataPointer cdPtr
) internal pure returns (uint248 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the uint256 at `cdPtr` in calldata.
function readUint256(
CalldataPointer cdPtr
) internal pure returns (uint256 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int8 at `cdPtr` in calldata.
function readInt8(
CalldataPointer cdPtr
) internal pure returns (int8 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int16 at `cdPtr` in calldata.
function readInt16(
CalldataPointer cdPtr
) internal pure returns (int16 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int24 at `cdPtr` in calldata.
function readInt24(
CalldataPointer cdPtr
) internal pure returns (int24 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int32 at `cdPtr` in calldata.
function readInt32(
CalldataPointer cdPtr
) internal pure returns (int32 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int40 at `cdPtr` in calldata.
function readInt40(
CalldataPointer cdPtr
) internal pure returns (int40 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int48 at `cdPtr` in calldata.
function readInt48(
CalldataPointer cdPtr
) internal pure returns (int48 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int56 at `cdPtr` in calldata.
function readInt56(
CalldataPointer cdPtr
) internal pure returns (int56 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int64 at `cdPtr` in calldata.
function readInt64(
CalldataPointer cdPtr
) internal pure returns (int64 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int72 at `cdPtr` in calldata.
function readInt72(
CalldataPointer cdPtr
) internal pure returns (int72 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int80 at `cdPtr` in calldata.
function readInt80(
CalldataPointer cdPtr
) internal pure returns (int80 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int88 at `cdPtr` in calldata.
function readInt88(
CalldataPointer cdPtr
) internal pure returns (int88 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int96 at `cdPtr` in calldata.
function readInt96(
CalldataPointer cdPtr
) internal pure returns (int96 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int104 at `cdPtr` in calldata.
function readInt104(
CalldataPointer cdPtr
) internal pure returns (int104 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int112 at `cdPtr` in calldata.
function readInt112(
CalldataPointer cdPtr
) internal pure returns (int112 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int120 at `cdPtr` in calldata.
function readInt120(
CalldataPointer cdPtr
) internal pure returns (int120 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int128 at `cdPtr` in calldata.
function readInt128(
CalldataPointer cdPtr
) internal pure returns (int128 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int136 at `cdPtr` in calldata.
function readInt136(
CalldataPointer cdPtr
) internal pure returns (int136 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int144 at `cdPtr` in calldata.
function readInt144(
CalldataPointer cdPtr
) internal pure returns (int144 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int152 at `cdPtr` in calldata.
function readInt152(
CalldataPointer cdPtr
) internal pure returns (int152 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int160 at `cdPtr` in calldata.
function readInt160(
CalldataPointer cdPtr
) internal pure returns (int160 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int168 at `cdPtr` in calldata.
function readInt168(
CalldataPointer cdPtr
) internal pure returns (int168 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int176 at `cdPtr` in calldata.
function readInt176(
CalldataPointer cdPtr
) internal pure returns (int176 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int184 at `cdPtr` in calldata.
function readInt184(
CalldataPointer cdPtr
) internal pure returns (int184 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int192 at `cdPtr` in calldata.
function readInt192(
CalldataPointer cdPtr
) internal pure returns (int192 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int200 at `cdPtr` in calldata.
function readInt200(
CalldataPointer cdPtr
) internal pure returns (int200 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int208 at `cdPtr` in calldata.
function readInt208(
CalldataPointer cdPtr
) internal pure returns (int208 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int216 at `cdPtr` in calldata.
function readInt216(
CalldataPointer cdPtr
) internal pure returns (int216 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int224 at `cdPtr` in calldata.
function readInt224(
CalldataPointer cdPtr
) internal pure returns (int224 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int232 at `cdPtr` in calldata.
function readInt232(
CalldataPointer cdPtr
) internal pure returns (int232 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int240 at `cdPtr` in calldata.
function readInt240(
CalldataPointer cdPtr
) internal pure returns (int240 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int248 at `cdPtr` in calldata.
function readInt248(
CalldataPointer cdPtr
) internal pure returns (int248 value) {
assembly {
value := calldataload(cdPtr)
}
}
/// @dev Reads the int256 at `cdPtr` in calldata.
function readInt256(
CalldataPointer cdPtr
) internal pure returns (int256 value) {
assembly {
value := calldataload(cdPtr)
}
}
}
library ReturndataReaders {
/// @dev Reads value at `rdPtr` & applies a mask to return only last 4 bytes
function readMaskedUint256(
ReturndataPointer rdPtr
) internal pure returns (uint256 value) {
value = rdPtr.readUint256() & OffsetOrLengthMask;
}
/// @dev Reads the bool at `rdPtr` in returndata.
function readBool(
ReturndataPointer rdPtr
) internal pure returns (bool value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the address at `rdPtr` in returndata.
function readAddress(
ReturndataPointer rdPtr
) internal pure returns (address value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes1 at `rdPtr` in returndata.
function readBytes1(
ReturndataPointer rdPtr
) internal pure returns (bytes1 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes2 at `rdPtr` in returndata.
function readBytes2(
ReturndataPointer rdPtr
) internal pure returns (bytes2 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes3 at `rdPtr` in returndata.
function readBytes3(
ReturndataPointer rdPtr
) internal pure returns (bytes3 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes4 at `rdPtr` in returndata.
function readBytes4(
ReturndataPointer rdPtr
) internal pure returns (bytes4 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes5 at `rdPtr` in returndata.
function readBytes5(
ReturndataPointer rdPtr
) internal pure returns (bytes5 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes6 at `rdPtr` in returndata.
function readBytes6(
ReturndataPointer rdPtr
) internal pure returns (bytes6 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes7 at `rdPtr` in returndata.
function readBytes7(
ReturndataPointer rdPtr
) internal pure returns (bytes7 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes8 at `rdPtr` in returndata.
function readBytes8(
ReturndataPointer rdPtr
) internal pure returns (bytes8 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes9 at `rdPtr` in returndata.
function readBytes9(
ReturndataPointer rdPtr
) internal pure returns (bytes9 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes10 at `rdPtr` in returndata.
function readBytes10(
ReturndataPointer rdPtr
) internal pure returns (bytes10 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes11 at `rdPtr` in returndata.
function readBytes11(
ReturndataPointer rdPtr
) internal pure returns (bytes11 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes12 at `rdPtr` in returndata.
function readBytes12(
ReturndataPointer rdPtr
) internal pure returns (bytes12 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes13 at `rdPtr` in returndata.
function readBytes13(
ReturndataPointer rdPtr
) internal pure returns (bytes13 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes14 at `rdPtr` in returndata.
function readBytes14(
ReturndataPointer rdPtr
) internal pure returns (bytes14 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes15 at `rdPtr` in returndata.
function readBytes15(
ReturndataPointer rdPtr
) internal pure returns (bytes15 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes16 at `rdPtr` in returndata.
function readBytes16(
ReturndataPointer rdPtr
) internal pure returns (bytes16 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes17 at `rdPtr` in returndata.
function readBytes17(
ReturndataPointer rdPtr
) internal pure returns (bytes17 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes18 at `rdPtr` in returndata.
function readBytes18(
ReturndataPointer rdPtr
) internal pure returns (bytes18 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes19 at `rdPtr` in returndata.
function readBytes19(
ReturndataPointer rdPtr
) internal pure returns (bytes19 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes20 at `rdPtr` in returndata.
function readBytes20(
ReturndataPointer rdPtr
) internal pure returns (bytes20 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes21 at `rdPtr` in returndata.
function readBytes21(
ReturndataPointer rdPtr
) internal pure returns (bytes21 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes22 at `rdPtr` in returndata.
function readBytes22(
ReturndataPointer rdPtr
) internal pure returns (bytes22 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes23 at `rdPtr` in returndata.
function readBytes23(
ReturndataPointer rdPtr
) internal pure returns (bytes23 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes24 at `rdPtr` in returndata.
function readBytes24(
ReturndataPointer rdPtr
) internal pure returns (bytes24 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes25 at `rdPtr` in returndata.
function readBytes25(
ReturndataPointer rdPtr
) internal pure returns (bytes25 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes26 at `rdPtr` in returndata.
function readBytes26(
ReturndataPointer rdPtr
) internal pure returns (bytes26 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes27 at `rdPtr` in returndata.
function readBytes27(
ReturndataPointer rdPtr
) internal pure returns (bytes27 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes28 at `rdPtr` in returndata.
function readBytes28(
ReturndataPointer rdPtr
) internal pure returns (bytes28 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes29 at `rdPtr` in returndata.
function readBytes29(
ReturndataPointer rdPtr
) internal pure returns (bytes29 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes30 at `rdPtr` in returndata.
function readBytes30(
ReturndataPointer rdPtr
) internal pure returns (bytes30 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes31 at `rdPtr` in returndata.
function readBytes31(
ReturndataPointer rdPtr
) internal pure returns (bytes31 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the bytes32 at `rdPtr` in returndata.
function readBytes32(
ReturndataPointer rdPtr
) internal pure returns (bytes32 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint8 at `rdPtr` in returndata.
function readUint8(
ReturndataPointer rdPtr
) internal pure returns (uint8 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint16 at `rdPtr` in returndata.
function readUint16(
ReturndataPointer rdPtr
) internal pure returns (uint16 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint24 at `rdPtr` in returndata.
function readUint24(
ReturndataPointer rdPtr
) internal pure returns (uint24 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint32 at `rdPtr` in returndata.
function readUint32(
ReturndataPointer rdPtr
) internal pure returns (uint32 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint40 at `rdPtr` in returndata.
function readUint40(
ReturndataPointer rdPtr
) internal pure returns (uint40 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint48 at `rdPtr` in returndata.
function readUint48(
ReturndataPointer rdPtr
) internal pure returns (uint48 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint56 at `rdPtr` in returndata.
function readUint56(
ReturndataPointer rdPtr
) internal pure returns (uint56 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint64 at `rdPtr` in returndata.
function readUint64(
ReturndataPointer rdPtr
) internal pure returns (uint64 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint72 at `rdPtr` in returndata.
function readUint72(
ReturndataPointer rdPtr
) internal pure returns (uint72 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint80 at `rdPtr` in returndata.
function readUint80(
ReturndataPointer rdPtr
) internal pure returns (uint80 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint88 at `rdPtr` in returndata.
function readUint88(
ReturndataPointer rdPtr
) internal pure returns (uint88 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint96 at `rdPtr` in returndata.
function readUint96(
ReturndataPointer rdPtr
) internal pure returns (uint96 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint104 at `rdPtr` in returndata.
function readUint104(
ReturndataPointer rdPtr
) internal pure returns (uint104 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint112 at `rdPtr` in returndata.
function readUint112(
ReturndataPointer rdPtr
) internal pure returns (uint112 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint120 at `rdPtr` in returndata.
function readUint120(
ReturndataPointer rdPtr
) internal pure returns (uint120 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint128 at `rdPtr` in returndata.
function readUint128(
ReturndataPointer rdPtr
) internal pure returns (uint128 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint136 at `rdPtr` in returndata.
function readUint136(
ReturndataPointer rdPtr
) internal pure returns (uint136 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint144 at `rdPtr` in returndata.
function readUint144(
ReturndataPointer rdPtr
) internal pure returns (uint144 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint152 at `rdPtr` in returndata.
function readUint152(
ReturndataPointer rdPtr
) internal pure returns (uint152 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint160 at `rdPtr` in returndata.
function readUint160(
ReturndataPointer rdPtr
) internal pure returns (uint160 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint168 at `rdPtr` in returndata.
function readUint168(
ReturndataPointer rdPtr
) internal pure returns (uint168 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint176 at `rdPtr` in returndata.
function readUint176(
ReturndataPointer rdPtr
) internal pure returns (uint176 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint184 at `rdPtr` in returndata.
function readUint184(
ReturndataPointer rdPtr
) internal pure returns (uint184 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint192 at `rdPtr` in returndata.
function readUint192(
ReturndataPointer rdPtr
) internal pure returns (uint192 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint200 at `rdPtr` in returndata.
function readUint200(
ReturndataPointer rdPtr
) internal pure returns (uint200 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint208 at `rdPtr` in returndata.
function readUint208(
ReturndataPointer rdPtr
) internal pure returns (uint208 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint216 at `rdPtr` in returndata.
function readUint216(
ReturndataPointer rdPtr
) internal pure returns (uint216 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint224 at `rdPtr` in returndata.
function readUint224(
ReturndataPointer rdPtr
) internal pure returns (uint224 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint232 at `rdPtr` in returndata.
function readUint232(
ReturndataPointer rdPtr
) internal pure returns (uint232 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint240 at `rdPtr` in returndata.
function readUint240(
ReturndataPointer rdPtr
) internal pure returns (uint240 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint248 at `rdPtr` in returndata.
function readUint248(
ReturndataPointer rdPtr
) internal pure returns (uint248 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the uint256 at `rdPtr` in returndata.
function readUint256(
ReturndataPointer rdPtr
) internal pure returns (uint256 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int8 at `rdPtr` in returndata.
function readInt8(
ReturndataPointer rdPtr
) internal pure returns (int8 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int16 at `rdPtr` in returndata.
function readInt16(
ReturndataPointer rdPtr
) internal pure returns (int16 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int24 at `rdPtr` in returndata.
function readInt24(
ReturndataPointer rdPtr
) internal pure returns (int24 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int32 at `rdPtr` in returndata.
function readInt32(
ReturndataPointer rdPtr
) internal pure returns (int32 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int40 at `rdPtr` in returndata.
function readInt40(
ReturndataPointer rdPtr
) internal pure returns (int40 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int48 at `rdPtr` in returndata.
function readInt48(
ReturndataPointer rdPtr
) internal pure returns (int48 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int56 at `rdPtr` in returndata.
function readInt56(
ReturndataPointer rdPtr
) internal pure returns (int56 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int64 at `rdPtr` in returndata.
function readInt64(
ReturndataPointer rdPtr
) internal pure returns (int64 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int72 at `rdPtr` in returndata.
function readInt72(
ReturndataPointer rdPtr
) internal pure returns (int72 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int80 at `rdPtr` in returndata.
function readInt80(
ReturndataPointer rdPtr
) internal pure returns (int80 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int88 at `rdPtr` in returndata.
function readInt88(
ReturndataPointer rdPtr
) internal pure returns (int88 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int96 at `rdPtr` in returndata.
function readInt96(
ReturndataPointer rdPtr
) internal pure returns (int96 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int104 at `rdPtr` in returndata.
function readInt104(
ReturndataPointer rdPtr
) internal pure returns (int104 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int112 at `rdPtr` in returndata.
function readInt112(
ReturndataPointer rdPtr
) internal pure returns (int112 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int120 at `rdPtr` in returndata.
function readInt120(
ReturndataPointer rdPtr
) internal pure returns (int120 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int128 at `rdPtr` in returndata.
function readInt128(
ReturndataPointer rdPtr
) internal pure returns (int128 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int136 at `rdPtr` in returndata.
function readInt136(
ReturndataPointer rdPtr
) internal pure returns (int136 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int144 at `rdPtr` in returndata.
function readInt144(
ReturndataPointer rdPtr
) internal pure returns (int144 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int152 at `rdPtr` in returndata.
function readInt152(
ReturndataPointer rdPtr
) internal pure returns (int152 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int160 at `rdPtr` in returndata.
function readInt160(
ReturndataPointer rdPtr
) internal pure returns (int160 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int168 at `rdPtr` in returndata.
function readInt168(
ReturndataPointer rdPtr
) internal pure returns (int168 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int176 at `rdPtr` in returndata.
function readInt176(
ReturndataPointer rdPtr
) internal pure returns (int176 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int184 at `rdPtr` in returndata.
function readInt184(
ReturndataPointer rdPtr
) internal pure returns (int184 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int192 at `rdPtr` in returndata.
function readInt192(
ReturndataPointer rdPtr
) internal pure returns (int192 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int200 at `rdPtr` in returndata.
function readInt200(
ReturndataPointer rdPtr
) internal pure returns (int200 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int208 at `rdPtr` in returndata.
function readInt208(
ReturndataPointer rdPtr
) internal pure returns (int208 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int216 at `rdPtr` in returndata.
function readInt216(
ReturndataPointer rdPtr
) internal pure returns (int216 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int224 at `rdPtr` in returndata.
function readInt224(
ReturndataPointer rdPtr
) internal pure returns (int224 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int232 at `rdPtr` in returndata.
function readInt232(
ReturndataPointer rdPtr
) internal pure returns (int232 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int240 at `rdPtr` in returndata.
function readInt240(
ReturndataPointer rdPtr
) internal pure returns (int240 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int248 at `rdPtr` in returndata.
function readInt248(
ReturndataPointer rdPtr
) internal pure returns (int248 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
/// @dev Reads the int256 at `rdPtr` in returndata.
function readInt256(
ReturndataPointer rdPtr
) internal pure returns (int256 value) {
assembly {
returndatacopy(0, rdPtr, _OneWord)
value := mload(0)
}
}
}
library MemoryReaders {
/// @dev Reads the memory pointer at `mPtr` in memory.
function readMemoryPointer(
MemoryPointer mPtr
) internal pure returns (MemoryPointer value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads value at `mPtr` & applies a mask to return only last 4 bytes
function readMaskedUint256(
MemoryPointer mPtr
) internal pure returns (uint256 value) {
value = mPtr.readUint256() & OffsetOrLengthMask;
}
/// @dev Reads the bool at `mPtr` in memory.
function readBool(MemoryPointer mPtr) internal pure returns (bool value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the address at `mPtr` in memory.
function readAddress(
MemoryPointer mPtr
) internal pure returns (address value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes1 at `mPtr` in memory.
function readBytes1(
MemoryPointer mPtr
) internal pure returns (bytes1 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes2 at `mPtr` in memory.
function readBytes2(
MemoryPointer mPtr
) internal pure returns (bytes2 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes3 at `mPtr` in memory.
function readBytes3(
MemoryPointer mPtr
) internal pure returns (bytes3 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes4 at `mPtr` in memory.
function readBytes4(
MemoryPointer mPtr
) internal pure returns (bytes4 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes5 at `mPtr` in memory.
function readBytes5(
MemoryPointer mPtr
) internal pure returns (bytes5 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes6 at `mPtr` in memory.
function readBytes6(
MemoryPointer mPtr
) internal pure returns (bytes6 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes7 at `mPtr` in memory.
function readBytes7(
MemoryPointer mPtr
) internal pure returns (bytes7 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes8 at `mPtr` in memory.
function readBytes8(
MemoryPointer mPtr
) internal pure returns (bytes8 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes9 at `mPtr` in memory.
function readBytes9(
MemoryPointer mPtr
) internal pure returns (bytes9 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes10 at `mPtr` in memory.
function readBytes10(
MemoryPointer mPtr
) internal pure returns (bytes10 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes11 at `mPtr` in memory.
function readBytes11(
MemoryPointer mPtr
) internal pure returns (bytes11 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes12 at `mPtr` in memory.
function readBytes12(
MemoryPointer mPtr
) internal pure returns (bytes12 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes13 at `mPtr` in memory.
function readBytes13(
MemoryPointer mPtr
) internal pure returns (bytes13 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes14 at `mPtr` in memory.
function readBytes14(
MemoryPointer mPtr
) internal pure returns (bytes14 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes15 at `mPtr` in memory.
function readBytes15(
MemoryPointer mPtr
) internal pure returns (bytes15 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes16 at `mPtr` in memory.
function readBytes16(
MemoryPointer mPtr
) internal pure returns (bytes16 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes17 at `mPtr` in memory.
function readBytes17(
MemoryPointer mPtr
) internal pure returns (bytes17 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes18 at `mPtr` in memory.
function readBytes18(
MemoryPointer mPtr
) internal pure returns (bytes18 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes19 at `mPtr` in memory.
function readBytes19(
MemoryPointer mPtr
) internal pure returns (bytes19 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes20 at `mPtr` in memory.
function readBytes20(
MemoryPointer mPtr
) internal pure returns (bytes20 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes21 at `mPtr` in memory.
function readBytes21(
MemoryPointer mPtr
) internal pure returns (bytes21 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes22 at `mPtr` in memory.
function readBytes22(
MemoryPointer mPtr
) internal pure returns (bytes22 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes23 at `mPtr` in memory.
function readBytes23(
MemoryPointer mPtr
) internal pure returns (bytes23 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes24 at `mPtr` in memory.
function readBytes24(
MemoryPointer mPtr
) internal pure returns (bytes24 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes25 at `mPtr` in memory.
function readBytes25(
MemoryPointer mPtr
) internal pure returns (bytes25 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes26 at `mPtr` in memory.
function readBytes26(
MemoryPointer mPtr
) internal pure returns (bytes26 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes27 at `mPtr` in memory.
function readBytes27(
MemoryPointer mPtr
) internal pure returns (bytes27 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes28 at `mPtr` in memory.
function readBytes28(
MemoryPointer mPtr
) internal pure returns (bytes28 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes29 at `mPtr` in memory.
function readBytes29(
MemoryPointer mPtr
) internal pure returns (bytes29 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes30 at `mPtr` in memory.
function readBytes30(
MemoryPointer mPtr
) internal pure returns (bytes30 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes31 at `mPtr` in memory.
function readBytes31(
MemoryPointer mPtr
) internal pure returns (bytes31 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the bytes32 at `mPtr` in memory.
function readBytes32(
MemoryPointer mPtr
) internal pure returns (bytes32 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint8 at `mPtr` in memory.
function readUint8(MemoryPointer mPtr) internal pure returns (uint8 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint16 at `mPtr` in memory.
function readUint16(
MemoryPointer mPtr
) internal pure returns (uint16 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint24 at `mPtr` in memory.
function readUint24(
MemoryPointer mPtr
) internal pure returns (uint24 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint32 at `mPtr` in memory.
function readUint32(
MemoryPointer mPtr
) internal pure returns (uint32 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint40 at `mPtr` in memory.
function readUint40(
MemoryPointer mPtr
) internal pure returns (uint40 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint48 at `mPtr` in memory.
function readUint48(
MemoryPointer mPtr
) internal pure returns (uint48 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint56 at `mPtr` in memory.
function readUint56(
MemoryPointer mPtr
) internal pure returns (uint56 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint64 at `mPtr` in memory.
function readUint64(
MemoryPointer mPtr
) internal pure returns (uint64 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint72 at `mPtr` in memory.
function readUint72(
MemoryPointer mPtr
) internal pure returns (uint72 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint80 at `mPtr` in memory.
function readUint80(
MemoryPointer mPtr
) internal pure returns (uint80 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint88 at `mPtr` in memory.
function readUint88(
MemoryPointer mPtr
) internal pure returns (uint88 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint96 at `mPtr` in memory.
function readUint96(
MemoryPointer mPtr
) internal pure returns (uint96 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint104 at `mPtr` in memory.
function readUint104(
MemoryPointer mPtr
) internal pure returns (uint104 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint112 at `mPtr` in memory.
function readUint112(
MemoryPointer mPtr
) internal pure returns (uint112 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint120 at `mPtr` in memory.
function readUint120(
MemoryPointer mPtr
) internal pure returns (uint120 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint128 at `mPtr` in memory.
function readUint128(
MemoryPointer mPtr
) internal pure returns (uint128 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint136 at `mPtr` in memory.
function readUint136(
MemoryPointer mPtr
) internal pure returns (uint136 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint144 at `mPtr` in memory.
function readUint144(
MemoryPointer mPtr
) internal pure returns (uint144 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint152 at `mPtr` in memory.
function readUint152(
MemoryPointer mPtr
) internal pure returns (uint152 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint160 at `mPtr` in memory.
function readUint160(
MemoryPointer mPtr
) internal pure returns (uint160 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint168 at `mPtr` in memory.
function readUint168(
MemoryPointer mPtr
) internal pure returns (uint168 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint176 at `mPtr` in memory.
function readUint176(
MemoryPointer mPtr
) internal pure returns (uint176 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint184 at `mPtr` in memory.
function readUint184(
MemoryPointer mPtr
) internal pure returns (uint184 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint192 at `mPtr` in memory.
function readUint192(
MemoryPointer mPtr
) internal pure returns (uint192 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint200 at `mPtr` in memory.
function readUint200(
MemoryPointer mPtr
) internal pure returns (uint200 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint208 at `mPtr` in memory.
function readUint208(
MemoryPointer mPtr
) internal pure returns (uint208 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint216 at `mPtr` in memory.
function readUint216(
MemoryPointer mPtr
) internal pure returns (uint216 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint224 at `mPtr` in memory.
function readUint224(
MemoryPointer mPtr
) internal pure returns (uint224 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint232 at `mPtr` in memory.
function readUint232(
MemoryPointer mPtr
) internal pure returns (uint232 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint240 at `mPtr` in memory.
function readUint240(
MemoryPointer mPtr
) internal pure returns (uint240 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint248 at `mPtr` in memory.
function readUint248(
MemoryPointer mPtr
) internal pure returns (uint248 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the uint256 at `mPtr` in memory.
function readUint256(
MemoryPointer mPtr
) internal pure returns (uint256 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int8 at `mPtr` in memory.
function readInt8(MemoryPointer mPtr) internal pure returns (int8 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int16 at `mPtr` in memory.
function readInt16(MemoryPointer mPtr) internal pure returns (int16 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int24 at `mPtr` in memory.
function readInt24(MemoryPointer mPtr) internal pure returns (int24 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int32 at `mPtr` in memory.
function readInt32(MemoryPointer mPtr) internal pure returns (int32 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int40 at `mPtr` in memory.
function readInt40(MemoryPointer mPtr) internal pure returns (int40 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int48 at `mPtr` in memory.
function readInt48(MemoryPointer mPtr) internal pure returns (int48 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int56 at `mPtr` in memory.
function readInt56(MemoryPointer mPtr) internal pure returns (int56 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int64 at `mPtr` in memory.
function readInt64(MemoryPointer mPtr) internal pure returns (int64 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int72 at `mPtr` in memory.
function readInt72(MemoryPointer mPtr) internal pure returns (int72 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int80 at `mPtr` in memory.
function readInt80(MemoryPointer mPtr) internal pure returns (int80 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int88 at `mPtr` in memory.
function readInt88(MemoryPointer mPtr) internal pure returns (int88 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int96 at `mPtr` in memory.
function readInt96(MemoryPointer mPtr) internal pure returns (int96 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int104 at `mPtr` in memory.
function readInt104(
MemoryPointer mPtr
) internal pure returns (int104 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int112 at `mPtr` in memory.
function readInt112(
MemoryPointer mPtr
) internal pure returns (int112 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int120 at `mPtr` in memory.
function readInt120(
MemoryPointer mPtr
) internal pure returns (int120 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int128 at `mPtr` in memory.
function readInt128(
MemoryPointer mPtr
) internal pure returns (int128 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int136 at `mPtr` in memory.
function readInt136(
MemoryPointer mPtr
) internal pure returns (int136 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int144 at `mPtr` in memory.
function readInt144(
MemoryPointer mPtr
) internal pure returns (int144 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int152 at `mPtr` in memory.
function readInt152(
MemoryPointer mPtr
) internal pure returns (int152 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int160 at `mPtr` in memory.
function readInt160(
MemoryPointer mPtr
) internal pure returns (int160 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int168 at `mPtr` in memory.
function readInt168(
MemoryPointer mPtr
) internal pure returns (int168 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int176 at `mPtr` in memory.
function readInt176(
MemoryPointer mPtr
) internal pure returns (int176 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int184 at `mPtr` in memory.
function readInt184(
MemoryPointer mPtr
) internal pure returns (int184 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int192 at `mPtr` in memory.
function readInt192(
MemoryPointer mPtr
) internal pure returns (int192 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int200 at `mPtr` in memory.
function readInt200(
MemoryPointer mPtr
) internal pure returns (int200 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int208 at `mPtr` in memory.
function readInt208(
MemoryPointer mPtr
) internal pure returns (int208 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int216 at `mPtr` in memory.
function readInt216(
MemoryPointer mPtr
) internal pure returns (int216 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int224 at `mPtr` in memory.
function readInt224(
MemoryPointer mPtr
) internal pure returns (int224 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int232 at `mPtr` in memory.
function readInt232(
MemoryPointer mPtr
) internal pure returns (int232 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int240 at `mPtr` in memory.
function readInt240(
MemoryPointer mPtr
) internal pure returns (int240 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int248 at `mPtr` in memory.
function readInt248(
MemoryPointer mPtr
) internal pure returns (int248 value) {
assembly {
value := mload(mPtr)
}
}
/// @dev Reads the int256 at `mPtr` in memory.
function readInt256(
MemoryPointer mPtr
) internal pure returns (int256 value) {
assembly {
value := mload(mPtr)
}
}
}
library MemoryWriters {
/// @dev Writes `valuePtr` to memory at `mPtr`.
function write(MemoryPointer mPtr, MemoryPointer valuePtr) internal pure {
assembly {
mstore(mPtr, valuePtr)
}
}
/// @dev Writes a boolean `value` to `mPtr` in memory.
function write(MemoryPointer mPtr, bool value) internal pure {
assembly {
mstore(mPtr, value)
}
}
/// @dev Writes an address `value` to `mPtr` in memory.
function write(MemoryPointer mPtr, address value) internal pure {
assembly {
mstore(mPtr, value)
}
}
/// @dev Writes a bytes32 `value` to `mPtr` in memory.
/// Separate name to disambiguate literal write parameters.
function writeBytes32(MemoryPointer mPtr, bytes32 value) internal pure {
assembly {
mstore(mPtr, value)
}
}
/// @dev Writes a uint256 `value` to `mPtr` in memory.
function write(MemoryPointer mPtr, uint256 value) internal pure {
assembly {
mstore(mPtr, value)
}
}
/// @dev Writes an int256 `value` to `mPtr` in memory.
/// Separate name to disambiguate literal write parameters.
function writeInt(MemoryPointer mPtr, int256 value) internal pure {
assembly {
mstore(mPtr, value)
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
/*
* -------------------------- Disambiguation & Other Notes ---------------------
* - The term "head" is used as it is in the documentation for ABI encoding,
* but only in reference to dynamic types, i.e. it always refers to the
* offset or pointer to the body of a dynamic type. In calldata, the head
* is always an offset (relative to the parent object), while in memory,
* the head is always the pointer to the body. More information found here:
* https://docs.soliditylang.org/en/v0.8.17/abi-spec.html#argument-encoding
* - Note that the length of an array is separate from and precedes the
* head of the array.
*
* - The term "body" is used in place of the term "head" used in the ABI
* documentation. It refers to the start of the data for a dynamic type,
* e.g. the first word of a struct or the first word of the first element
* in an array.
*
* - The term "pointer" is used to describe the absolute position of a value
* and never an offset relative to another value.
* - The suffix "_ptr" refers to a memory pointer.
* - The suffix "_cdPtr" refers to a calldata pointer.
*
* - The term "offset" is used to describe the position of a value relative
* to some parent value. For example, OrderParameters_conduit_offset is the
* offset to the "conduit" value in the OrderParameters struct relative to
* the start of the body.
* - Note: Offsets are used to derive pointers.
*
* - Some structs have pointers defined for all of their fields in this file.
* Lines which are commented out are fields that are not used in the
* codebase but have been left in for readability.
*/
// Declare constants for name, version, and reentrancy sentinel values.
// Name is right padded, so it touches the length which is left padded. This
// enables writing both values at once. Length goes at byte 95 in memory, and
// name fills bytes 96-109, so both values can be written left-padded to 77.
uint256 constant NameLengthPtr = 0x4D;
uint256 constant NameWithLength = 0x0d436F6E73696465726174696F6E;
uint256 constant information_version_offset = 0;
uint256 constant information_version_cd_offset = 0x60;
uint256 constant information_domainSeparator_offset = 0x20;
uint256 constant information_conduitController_offset = 0x40;
uint256 constant information_versionLengthPtr = 0x63;
uint256 constant information_versionWithLength = 0x03312e36; // 1.6
uint256 constant information_length = 0xa0;
// uint256(uint32(bytes4(keccak256("_REENTRANCY_GUARD_SLOT"))))
uint256 constant _REENTRANCY_GUARD_SLOT = 0x929eee14;
/*
*
* --------------------------------------------------------------------------+
* Opcode | Mnemonic | Stack | Memory |
* --------------------------------------------------------------------------|
* 60 0x02 | PUSH1 0x02 | 0x02 | |
* 60 0x1e | PUSH1 0x1e | 0x1e 0x02 | |
* 61 0x3d5c | PUSH2 0x3d5c | 0x3d5c 0x1e 0x02 | |
* 3d | RETURNDATASIZE | 0 0x3d5c 0x1e 0x02 | |
* |
* ::: store deployed bytecode in memory: (3d) RETURNDATASIZE (5c) TLOAD ::: |
* 52 | MSTORE | 0x1e 0x02 | [0..0x20): 0x3d5c |
* f3 | RETURN | | [0..0x20): 0x3d5c |
* --------------------------------------------------------------------------+
*/
uint256 constant _TLOAD_TEST_PAYLOAD = 0x6002_601e_613d5c_3d_52_f3;
uint256 constant _TLOAD_TEST_PAYLOAD_LENGTH = 0x0a;
uint256 constant _TLOAD_TEST_PAYLOAD_OFFSET = 0x16;
uint256 constant _NOT_ENTERED_TSTORE = 0;
uint256 constant _ENTERED_TSTORE = 1;
uint256 constant _ENTERED_AND_ACCEPTING_NATIVE_TOKENS_TSTORE = 2;
uint256 constant _TSTORE_ENABLED_SSTORE = 0;
uint256 constant _NOT_ENTERED_SSTORE = 1;
uint256 constant _ENTERED_SSTORE = 2;
uint256 constant _ENTERED_AND_ACCEPTING_NATIVE_TOKENS_SSTORE = 3;
uint256 constant Offset_fulfillAdvancedOrder_criteriaResolvers = 0x20;
uint256 constant Offset_fulfillAvailableOrders_offerFulfillments = 0x20;
uint256 constant Offset_fulfillAvailableOrders_considerationFulfillments = 0x40;
uint256 constant Offset_fulfillAvailableAdvancedOrders_criteriaResolvers = 0x20;
uint256 constant Offset_fulfillAvailableAdvancedOrders_offerFulfillments = 0x40;
uint256 constant Offset_fulfillAvailableAdvancedOrders_cnsdrationFlflmnts =
(0x60);
uint256 constant Offset_matchOrders_fulfillments = 0x20;
uint256 constant Offset_matchAdvancedOrders_criteriaResolvers = 0x20;
uint256 constant Offset_matchAdvancedOrders_fulfillments = 0x40;
// Common Offsets
// Offsets for identically positioned fields shared by:
// OfferItem, ConsiderationItem, SpentItem, ReceivedItem
uint256 constant Selector_length = 0x4;
uint256 constant Common_token_offset = 0x20;
uint256 constant Common_identifier_offset = 0x40;
uint256 constant Common_amount_offset = 0x60;
uint256 constant Common_endAmount_offset = 0x80;
uint256 constant SpentItem_size = 0x80;
uint256 constant SpentItem_size_shift = 0x7;
uint256 constant OfferItem_size = 0xa0;
uint256 constant OfferItem_size_with_head_pointer = 0xc0;
uint256 constant ReceivedItem_size_excluding_recipient = 0x80;
uint256 constant ReceivedItem_size = 0xa0;
uint256 constant ReceivedItem_amount_offset = 0x60;
uint256 constant ReceivedItem_recipient_offset = 0x80;
uint256 constant ReceivedItem_CommonParams_size = 0x60;
uint256 constant ConsiderationItem_size = 0xc0;
uint256 constant ConsiderationItem_size_with_head_pointer = 0xe0;
uint256 constant ConsiderationItem_recipient_offset = 0xa0;
// Store the same constant in an abbreviated format for a line length fix.
uint256 constant ConsiderItem_recipient_offset = 0xa0;
uint256 constant Execution_offerer_offset = 0x20;
uint256 constant Execution_conduit_offset = 0x40;
// uint256 constant OrderParameters_offerer_offset = 0x00;
uint256 constant OrderParameters_zone_offset = 0x20;
uint256 constant OrderParameters_offer_head_offset = 0x40;
uint256 constant OrderParameters_consideration_head_offset = 0x60;
// uint256 constant OrderParameters_orderType_offset = 0x80;
uint256 constant OrderParameters_startTime_offset = 0xa0;
uint256 constant OrderParameters_endTime_offset = 0xc0;
uint256 constant OrderParameters_zoneHash_offset = 0xe0;
uint256 constant OrderParameters_salt_offset = 0x100;
uint256 constant OrderParameters_conduit_offset = 0x120;
uint256 constant OrderParameters_counter_offset = 0x140;
uint256 constant Fulfillment_itemIndex_offset = 0x20;
uint256 constant AdvancedOrder_head_size = 0xa0;
uint256 constant AdvancedOrder_numerator_offset = 0x20;
uint256 constant AdvancedOrder_denominator_offset = 0x40;
uint256 constant AdvancedOrder_signature_offset = 0x60;
uint256 constant AdvancedOrder_extraData_offset = 0x80;
uint256 constant OrderStatus_ValidatedAndNotCancelled = 1;
uint256 constant OrderStatus_filledNumerator_offset = 0x10;
uint256 constant OrderStatus_filledDenominator_offset = 0x88;
uint256 constant OrderStatus_ValidatedAndNotCancelledAndFullyFilled = (
0x0000000000000000000000000000010000000000000000000000000000010001
);
uint256 constant ThirtyOneBytes = 0x1f;
uint256 constant OneWord = 0x20;
uint256 constant TwoWords = 0x40;
uint256 constant ThreeWords = 0x60;
uint256 constant FourWords = 0x80;
uint256 constant FiveWords = 0xa0;
uint256 constant OneWordShift = 0x5;
uint256 constant TwoWordsShift = 0x6;
uint256 constant SixtyThreeBytes = 0x3f;
uint256 constant OnlyFullWordMask = 0xffffffe0;
uint256 constant FreeMemoryPointerSlot = 0x40;
uint256 constant ZeroSlot = 0x60;
uint256 constant DefaultFreeMemoryPointer = 0x80;
uint256 constant Slot0x80 = 0x80;
uint256 constant Slot0xA0 = 0xa0;
uint256 constant BasicOrder_common_params_size = 0xa0;
uint256 constant BasicOrder_considerationHashesArray_ptr = 0x160;
uint256 constant BasicOrder_receivedItemByteMap =
(0x0000010102030000000000000000000000000000000000000000000000000000);
uint256 constant BasicOrder_offeredItemByteMap =
(0x0203020301010000000000000000000000000000000000000000000000000000);
uint256 constant BasicOrder_consideration_offset_from_offer = 0xa0;
bytes32 constant OrdersMatchedTopic0 =
(0x4b9f2d36e1b4c93de62cc077b00b1a91d84b6c31b4a14e012718dcca230689e7);
uint256 constant EIP712_Order_size = 0x180;
uint256 constant EIP712_OfferItem_size = 0xc0;
uint256 constant EIP712_ConsiderationItem_size = 0xe0;
uint256 constant AdditionalRecipient_size = 0x40;
uint256 constant AdditionalRecipient_size_shift = 0x6;
uint256 constant EIP712_DomainSeparator_offset = 0x02;
uint256 constant EIP712_OrderHash_offset = 0x22;
uint256 constant EIP712_DigestPayload_size = 0x42;
uint256 constant EIP712_domainData_nameHash_offset = 0x20;
uint256 constant EIP712_domainData_versionHash_offset = 0x40;
uint256 constant EIP712_domainData_chainId_offset = 0x60;
uint256 constant EIP712_domainData_verifyingContract_offset = 0x80;
uint256 constant EIP712_domainData_size = 0xa0;
// Minimum BulkOrder proof size: 64 bytes for signature + 3 for key + 32 for 1
// sibling. Maximum BulkOrder proof size: 65 bytes for signature + 3 for key +
// 768 for 24 siblings.
uint256 constant BulkOrderProof_minSize = 0x63;
uint256 constant BulkOrderProof_rangeSize = 0x2e2;
uint256 constant BulkOrderProof_lengthAdjustmentBeforeMask = 0x1d;
uint256 constant BulkOrderProof_lengthRangeAfterMask = 0x2;
uint256 constant BulkOrderProof_keyShift = 0xe8;
uint256 constant BulkOrderProof_keySize = 0x3;
uint256 constant BulkOrder_Typehash_Height_One =
(0x3ca2711d29384747a8f61d60aad3c450405f7aaff5613541dee28df2d6986d32);
uint256 constant BulkOrder_Typehash_Height_Two =
(0xbf8e29b89f29ed9b529c154a63038ffca562f8d7cd1e2545dda53a1b582dde30);
uint256 constant BulkOrder_Typehash_Height_Three =
(0x53c6f6856e13104584dd0797ca2b2779202dc2597c6066a42e0d8fe990b0024d);
uint256 constant BulkOrder_Typehash_Height_Four =
(0xa02eb7ff164c884e5e2c336dc85f81c6a93329d8e9adf214b32729b894de2af1);
uint256 constant BulkOrder_Typehash_Height_Five =
(0x39c9d33c18e050dda0aeb9a8086fb16fc12d5d64536780e1da7405a800b0b9f6);
uint256 constant BulkOrder_Typehash_Height_Six =
(0x1c19f71958cdd8f081b4c31f7caf5c010b29d12950be2fa1c95070dc47e30b55);
uint256 constant BulkOrder_Typehash_Height_Seven =
(0xca74fab2fece9a1d58234a274220ad05ca096a92ef6a1ca1750b9d90c948955c);
uint256 constant BulkOrder_Typehash_Height_Eight =
(0x7ff98d9d4e55d876c5cfac10b43c04039522f3ddfb0ea9bfe70c68cfb5c7cc14);
uint256 constant BulkOrder_Typehash_Height_Nine =
(0xbed7be92d41c56f9e59ac7a6272185299b815ddfabc3f25deb51fe55fe2f9e8a);
uint256 constant BulkOrder_Typehash_Height_Ten =
(0xd1d97d1ef5eaa37a4ee5fbf234e6f6d64eb511eb562221cd7edfbdde0848da05);
uint256 constant BulkOrder_Typehash_Height_Eleven =
(0x896c3f349c4da741c19b37fec49ed2e44d738e775a21d9c9860a69d67a3dae53);
uint256 constant BulkOrder_Typehash_Height_Twelve =
(0xbb98d87cc12922b83759626c5f07d72266da9702d19ffad6a514c73a89002f5f);
uint256 constant BulkOrder_Typehash_Height_Thirteen =
(0xe6ae19322608dd1f8a8d56aab48ed9c28be489b689f4b6c91268563efc85f20e);
uint256 constant BulkOrder_Typehash_Height_Fourteen =
(0x6b5b04cbae4fcb1a9d78e7b2dfc51a36933d023cf6e347e03d517b472a852590);
uint256 constant BulkOrder_Typehash_Height_Fifteen =
(0xd1eb68309202b7106b891e109739dbbd334a1817fe5d6202c939e75cf5e35ca9);
uint256 constant BulkOrder_Typehash_Height_Sixteen =
(0x1da3eed3ecef6ebaa6e5023c057ec2c75150693fd0dac5c90f4a142f9879fde8);
uint256 constant BulkOrder_Typehash_Height_Seventeen =
(0xeee9a1392aa395c7002308119a58f2582777a75e54e0c1d5d5437bd2e8bf6222);
uint256 constant BulkOrder_Typehash_Height_Eighteen =
(0xc3939feff011e53ab8c35ca3370aad54c5df1fc2938cd62543174fa6e7d85877);
uint256 constant BulkOrder_Typehash_Height_Nineteen =
(0x0efca7572ac20f5ae84db0e2940674f7eca0a4726fa1060ffc2d18cef54b203d);
uint256 constant BulkOrder_Typehash_Height_Twenty =
(0x5a4f867d3d458dabecad65f6201ceeaba0096df2d0c491cc32e6ea4e64350017);
uint256 constant BulkOrder_Typehash_Height_TwentyOne =
(0x80987079d291feebf21c2230e69add0f283cee0b8be492ca8050b4185a2ff719);
uint256 constant BulkOrder_Typehash_Height_TwentyTwo =
(0x3bd8cff538aba49a9c374c806d277181e9651624b3e31111bc0624574f8bca1d);
uint256 constant BulkOrder_Typehash_Height_TwentyThree =
(0x5d6a3f098a0bc373f808c619b1bb4028208721b3c4f8d6bc8a874d659814eb76);
uint256 constant BulkOrder_Typehash_Height_TwentyFour =
(0x1d51df90cba8de7637ca3e8fe1e3511d1dc2f23487d05dbdecb781860c21ac1c);
uint256 constant receivedItemsHash_ptr = 0x60;
/*
* Memory layout in _prepareBasicFulfillmentFromCalldata of
* data for OrderFulfilled
*
* event OrderFulfilled(
* bytes32 orderHash,
* address indexed offerer,
* address indexed zone,
* address fulfiller,
* SpentItem[] offer,
* > (itemType, token, id, amount)
* ReceivedItem[] consideration
* > (itemType, token, id, amount, recipient)
* )
*
* - 0x00: orderHash
* - 0x20: fulfiller
* - 0x40: offer offset (0x80)
* - 0x60: consideration offset (0x120)
* - 0x80: offer.length (1)
* - 0xa0: offerItemType
* - 0xc0: offerToken
* - 0xe0: offerIdentifier
* - 0x100: offerAmount
* - 0x120: consideration.length (1 + additionalRecipients.length)
* - 0x140: considerationItemType
* - 0x160: considerationToken
* - 0x180: considerationIdentifier
* - 0x1a0: considerationAmount
* - 0x1c0: considerationRecipient
* - ...
*/
// Minimum length of the OrderFulfilled event data.
// Must be added to the size of the ReceivedItem array for additionalRecipients
// (0xa0 * additionalRecipients.length) to calculate full size of the buffer.
uint256 constant OrderFulfilled_baseSize = 0x1e0;
uint256 constant OrderFulfilled_selector =
(0x9d9af8e38d66c62e2c12f0225249fd9d721c54b83f48d9352c97c6cacdcb6f31);
// Minimum offset in memory to OrderFulfilled event data.
// Must be added to the size of the EIP712 hash array for additionalRecipients
// (32 * additionalRecipients.length) to calculate the pointer to event data.
uint256 constant OrderFulfilled_baseOffset = 0x180;
uint256 constant OrderFulfilled_consideration_length_baseOffset = 0x2a0;
uint256 constant OrderFulfilled_offer_length_baseOffset = 0x200;
uint256 constant OrderFulfilled_offer_length_offset_relativeTo_baseOffset = (
0x80
);
uint256 constant OrderFulfilled_offer_itemType_offset_relativeTo_baseOffset = (
0xa0
);
uint256 constant OrderFulfilled_offer_token_offset_relativeTo_baseOffset = 0xc0;
// Related constants used for restricted order checks on basic orders.
uint256 constant OrderFulfilled_baseDataSize = 0x160;
// uint256 constant ValidateOrder_offerDataOffset = 0x184;
// uint256 constant RatifyOrder_offerDataOffset = 0xc4;
// uint256 constant OrderFulfilled_orderHash_offset = 0x00;
uint256 constant OrderFulfilled_fulfiller_offset = 0x20;
uint256 constant OrderFulfilled_offer_head_offset = 0x40;
uint256 constant OrderFulfilled_offer_body_offset = 0x80;
uint256 constant OrderFulfilled_consideration_head_offset = 0x60;
uint256 constant OrderFulfilled_consideration_body_offset = 0x120;
/*
* 3 memory slots/words for `authorizeOrder` and `validateOrder` calldata
* to be used for tails of extra data (length 0) and order hashes (length 1)
*/
uint256 constant OrderFulfilled_post_memory_region_reservedBytes = 0x60;
/*
* OrderFulfilled_offer_length_baseOffset - 12 * 0x20
* we back up 12 words from where the `OrderFulfilled`'s data
* for spent items start to be rewritten for `authorizeOrder`
* and `validateOrder`. Let the reference pointer be `ptr`
* pointing to the `OrderFulfilled`'s spent item array's length memory
* position then we would have:
*
* ptr - 0x0180 : zero-padded calldata selector
* ptr - 0x0160 : ZoneParameter's struct head (0x20)
* ptr - 0x0140 : order hash
* ptr - 0x0120 : fulfiller (msg.sender)
* ptr - 0x0100 : offerer
* ptr - 0x00e0 : spent items' head
* ptr - 0x00c0 : received items' head
* ptr - 0x00a0 : extra data / context head
* ptr - 0x0080 : order hashes head
* ptr - 0x0060 : start time
* ptr - 0x0040 : end time
* ptr - 0x0020 : zone hash
* ptr - 0x0000 : offer.length (1)
* ...
*
* Note that the padded calldata selector will be at minimum at the
* 0x80 memory slot.
*/
uint256 constant authorizeOrder_calldata_baseOffset = (
OrderFulfilled_offer_length_baseOffset - 0x180
);
// BasicOrderParameters
uint256 constant BasicOrder_parameters_cdPtr = 0x04;
uint256 constant BasicOrder_considerationToken_cdPtr = 0x24;
uint256 constant BasicOrder_considerationIdentifier_cdPtr = 0x44;
uint256 constant BasicOrder_considerationAmount_cdPtr = 0x64;
uint256 constant BasicOrder_offerer_cdPtr = 0x84;
uint256 constant BasicOrder_zone_cdPtr = 0xa4;
uint256 constant BasicOrder_offerToken_cdPtr = 0xc4;
uint256 constant BasicOrder_offerIdentifier_cdPtr = 0xe4;
uint256 constant BasicOrder_offerAmount_cdPtr = 0x104;
uint256 constant BasicOrder_basicOrderParameters_cd_offset = 0x24;
uint256 constant BasicOrder_basicOrderType_cdPtr = 0x124;
uint256 constant BasicOrder_startTime_cdPtr = 0x144;
uint256 constant BasicOrder_endTime_cdPtr = 0x164;
// uint256 constant BasicOrder_zoneHash_cdPtr = 0x184;
// uint256 constant BasicOrder_salt_cdPtr = 0x1a4;
uint256 constant BasicOrder_offererConduit_cdPtr = 0x1c4;
uint256 constant BasicOrder_fulfillerConduit_cdPtr = 0x1e4;
uint256 constant BasicOrder_totalOriginalAdditionalRecipients_cdPtr = 0x204;
uint256 constant BasicOrder_additionalRecipients_head_cdPtr = 0x224;
uint256 constant BasicOrder_signature_cdPtr = 0x244;
uint256 constant BasicOrder_additionalRecipients_length_cdPtr = 0x264;
uint256 constant BasicOrder_addlRecipients_length_cdPtr = 0x264;
uint256 constant BasicOrder_additionalRecipients_data_cdPtr = 0x284;
uint256 constant BasicOrder_parameters_ptr = 0x20;
uint256 constant BasicOrder_basicOrderType_range = 0x18; // 24 values
/*
* Memory layout in _prepareBasicFulfillmentFromCalldata of
* EIP712 data for ConsiderationItem
* - 0x80: ConsiderationItem EIP-712 typehash (constant)
* - 0xa0: itemType
* - 0xc0: token
* - 0xe0: identifier
* - 0x100: startAmount
* - 0x120: endAmount
* - 0x140: recipient
*/
uint256 constant BasicOrder_considerationItem_typeHash_ptr = 0x80; // memoryPtr
uint256 constant BasicOrder_considerationItem_itemType_ptr = 0xa0;
uint256 constant BasicOrder_considerationItem_token_ptr = 0xc0;
uint256 constant BasicOrder_considerationItem_identifier_ptr = 0xe0;
uint256 constant BasicOrder_considerationItem_startAmount_ptr = 0x100;
uint256 constant BasicOrder_considerationItem_endAmount_ptr = 0x120;
// uint256 constant BasicOrder_considerationItem_recipient_ptr = 0x140;
/*
* Memory layout in _prepareBasicFulfillmentFromCalldata of
* EIP712 data for OfferItem
* - 0x80: OfferItem EIP-712 typehash (constant)
* - 0xa0: itemType
* - 0xc0: token
* - 0xe0: identifier (reused for offeredItemsHash)
* - 0x100: startAmount
* - 0x120: endAmount
*/
uint256 constant BasicOrder_offerItem_typeHash_ptr = 0x80;
uint256 constant BasicOrder_offerItem_itemType_ptr = 0xa0;
uint256 constant BasicOrder_offerItem_token_ptr = 0xc0;
// uint256 constant BasicOrder_offerItem_identifier_ptr = 0xe0;
// uint256 constant BasicOrder_offerItem_startAmount_ptr = 0x100;
uint256 constant BasicOrder_offerItem_endAmount_ptr = 0x120;
/*
* Memory layout in _prepareBasicFulfillmentFromCalldata of
* EIP712 data for Order
* - 0x80: Order EIP-712 typehash (constant)
* - 0xa0: orderParameters.offerer
* - 0xc0: orderParameters.zone
* - 0xe0: keccak256(abi.encodePacked(offerHashes))
* - 0x100: keccak256(abi.encodePacked(considerationHashes))
* - 0x120: orderType
* - 0x140: startTime
* - 0x160: endTime
* - 0x180: zoneHash
* - 0x1a0: salt
* - 0x1c0: conduit
* - 0x1e0: _counters[orderParameters.offerer] (from storage)
*/
uint256 constant BasicOrder_order_typeHash_ptr = 0x80;
uint256 constant BasicOrder_order_offerer_ptr = 0xa0;
// uint256 constant BasicOrder_order_zone_ptr = 0xc0;
uint256 constant BasicOrder_order_offerHashes_ptr = 0xe0;
uint256 constant BasicOrder_order_considerationHashes_ptr = 0x100;
uint256 constant BasicOrder_order_orderType_ptr = 0x120;
uint256 constant BasicOrder_order_startTime_ptr = 0x140;
// uint256 constant BasicOrder_order_endTime_ptr = 0x160;
// uint256 constant BasicOrder_order_zoneHash_ptr = 0x180;
// uint256 constant BasicOrder_order_salt_ptr = 0x1a0;
// uint256 constant BasicOrder_order_conduitKey_ptr = 0x1c0;
uint256 constant BasicOrder_order_counter_ptr = 0x1e0;
uint256 constant BasicOrder_additionalRecipients_head_ptr = 0x240;
uint256 constant BasicOrder_signature_ptr = 0x260;
uint256 constant BasicOrder_startTimeThroughZoneHash_size = 0x60;
uint256 constant ContractOrder_orderHash_offerer_shift = 0x60;
uint256 constant Counter_blockhash_shift = 0x80;
// Signature-related
bytes32 constant EIP2098_allButHighestBitMask =
(0x7fffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff);
bytes32 constant ECDSA_twentySeventhAndTwentyEighthBytesSet =
(0x0000000000000000000000000000000000000000000000000000000101000000);
uint256 constant ECDSA_MaxLength = 65;
uint256 constant ECDSA_signature_s_offset = 0x40;
uint256 constant ECDSA_signature_v_offset = 0x60;
bytes32 constant EIP1271_isValidSignature_selector =
(0x1626ba7e00000000000000000000000000000000000000000000000000000000);
uint256 constant EIP1271_isValidSignature_digest_negativeOffset = 0x40;
uint256 constant EIP1271_isValidSignature_selector_negativeOffset = 0x44;
uint256 constant EIP1271_isValidSignature_calldata_baseLength = 0x64;
uint256 constant EIP1271_isValidSignature_signature_head_offset = 0x40;
uint256 constant EIP_712_PREFIX =
(0x1901000000000000000000000000000000000000000000000000000000000000);
uint256 constant ExtraGasBuffer = 0x20;
uint256 constant CostPerWord = 0x3;
uint256 constant MemoryExpansionCoefficientShift = 0x9;
uint256 constant Create2AddressDerivation_ptr = 0x0b;
uint256 constant Create2AddressDerivation_length = 0x55;
uint256 constant MaskOverByteTwelve =
(0x0000000000000000000000ff0000000000000000000000000000000000000000);
uint256 constant MaskOverLastTwentyBytes =
(0x000000000000000000000000ffffffffffffffffffffffffffffffffffffffff);
uint256 constant AddressDirtyUpperBitThreshold =
(0x0000000000000000000000010000000000000000000000000000000000000000);
uint256 constant MaskOverFirstFourBytes =
(0xffffffff00000000000000000000000000000000000000000000000000000000);
uint256 constant Conduit_execute_signature =
(0x4ce34aa200000000000000000000000000000000000000000000000000000000);
uint256 constant MaxUint8 = 0xff;
uint256 constant MaxUint120 = 0xffffffffffffffffffffffffffffff;
uint256 constant Conduit_execute_ConduitTransfer_ptr = 0x20;
uint256 constant Conduit_execute_ConduitTransfer_length = 0x01;
uint256 constant Conduit_execute_ConduitTransfer_offset_ptr = 0x04;
uint256 constant Conduit_execute_ConduitTransfer_length_ptr = 0x24;
uint256 constant Conduit_execute_transferItemType_ptr = 0x44;
uint256 constant Conduit_execute_transferToken_ptr = 0x64;
uint256 constant Conduit_execute_transferFrom_ptr = 0x84;
uint256 constant Conduit_execute_transferTo_ptr = 0xa4;
uint256 constant Conduit_execute_transferIdentifier_ptr = 0xc4;
uint256 constant Conduit_execute_transferAmount_ptr = 0xe4;
uint256 constant OneConduitExecute_size = 0x104;
// Sentinel value to indicate that the conduit accumulator is not armed.
uint256 constant AccumulatorDisarmed = 0x20;
uint256 constant AccumulatorArmed = 0x40;
uint256 constant Accumulator_conduitKey_ptr = 0x20;
uint256 constant Accumulator_selector_ptr = 0x40;
uint256 constant Accumulator_array_offset_ptr = 0x44;
uint256 constant Accumulator_array_length_ptr = 0x64;
uint256 constant Accumulator_itemSizeOffsetDifference = 0x3c;
uint256 constant Accumulator_array_offset = 0x20;
uint256 constant Conduit_transferItem_size = 0xc0;
uint256 constant Conduit_transferItem_token_ptr = 0x20;
uint256 constant Conduit_transferItem_from_ptr = 0x40;
uint256 constant Conduit_transferItem_to_ptr = 0x60;
uint256 constant Conduit_transferItem_identifier_ptr = 0x80;
uint256 constant Conduit_transferItem_amount_ptr = 0xa0;
uint256 constant Ecrecover_precompile = 0x1;
uint256 constant Ecrecover_args_size = 0x80;
uint256 constant Signature_lower_v = 27;
// Bitmask that only gives a non-zero value if masked with a non-match selector.
uint256 constant NonMatchSelector_MagicMask =
(0x4000000000000000000000000000000000000000000000000000000000);
// First bit indicates that a NATIVE offer items has been used and the 231st bit
// indicates that a non match selector has been called.
uint256 constant NonMatchSelector_InvalidErrorValue =
(0x4000000000000000000000000000000000000000000000000000000001);
/**
* @dev Selector and offsets for generateOrder
*
* function generateOrder(
* address fulfiller,
* SpentItem[] calldata minimumReceived,
* SpentItem[] calldata maximumSpent,
* bytes calldata context
* )
*/
uint256 constant generateOrder_selector = 0x98919765;
uint256 constant generateOrder_selector_offset = 0x1c;
uint256 constant generateOrder_head_offset = 0x04;
uint256 constant generateOrder_minimumReceived_head_offset = 0x20;
uint256 constant generateOrder_maximumSpent_head_offset = 0x40;
uint256 constant generateOrder_context_head_offset = 0x60;
uint256 constant generateOrder_base_tail_offset = 0x80;
uint256 constant generateOrder_maximum_returned_array_length = 0xffff;
uint256 constant ratifyOrder_selector = 0xf4dd92ce;
uint256 constant ratifyOrder_selector_offset = 0x1c;
uint256 constant ratifyOrder_head_offset = 0x04;
// uint256 constant ratifyOrder_offer_head_offset = 0x00;
uint256 constant ratifyOrder_consideration_head_offset = 0x20;
uint256 constant ratifyOrder_context_head_offset = 0x40;
uint256 constant ratifyOrder_orderHashes_head_offset = 0x60;
uint256 constant ratifyOrder_contractNonce_offset = 0x80;
uint256 constant ratifyOrder_base_tail_offset = 0xa0;
uint256 constant validateOrder_selector = 0x17b1f942;
uint256 constant validateOrder_selector_offset = 0x1c;
uint256 constant validateOrder_head_offset = 0x04;
uint256 constant validateOrder_zoneParameters_offset = 0x20;
uint256 constant authorizeOrder_selector = 0x01e4d72a;
uint256 constant authorizeOrder_selector_offset = 0x1c;
uint256 constant authorizeOrder_head_offset = 0x04;
uint256 constant authorizeOrder_zoneParameters_offset = 0x20;
// uint256 constant ZoneParameters_orderHash_offset = 0x00;
uint256 constant ZoneParameters_fulfiller_offset = 0x20;
uint256 constant ZoneParameters_offerer_offset = 0x40;
uint256 constant ZoneParameters_offer_head_offset = 0x60;
uint256 constant ZoneParameters_consideration_head_offset = 0x80;
uint256 constant ZoneParameters_extraData_head_offset = 0xa0;
uint256 constant ZoneParameters_orderHashes_head_offset = 0xc0;
uint256 constant ZoneParameters_startTime_offset = 0xe0;
uint256 constant ZoneParameters_endTime_offset = 0x100;
uint256 constant ZoneParameters_zoneHash_offset = 0x120;
uint256 constant ZoneParameters_base_tail_offset = 0x140;
uint256 constant ZoneParameters_selectorAndPointer_length = 0x24;
uint256 constant ZoneParameters_basicOrderFixedElements_length = 0x44;
// ConsiderationDecoder Constants
uint256 constant OrderParameters_head_size = 0x0160;
uint256 constant OrderParameters_totalOriginalConsiderationItems_offset = (
0x0140
);
uint256 constant AdvancedOrderPlusOrderParameters_head_size = 0x0200;
uint256 constant Order_signature_offset = 0x20;
uint256 constant Order_head_size = 0x40;
uint256 constant AdvancedOrder_fixed_segment_0 = 0x40;
uint256 constant CriteriaResolver_head_size = 0xa0;
uint256 constant CriteriaResolver_fixed_segment_0 = 0x80;
uint256 constant CriteriaResolver_criteriaProof_offset = 0x80;
uint256 constant FulfillmentComponent_mem_tail_size = 0x40;
uint256 constant FulfillmentComponent_mem_tail_size_shift = 0x6;
uint256 constant Fulfillment_head_size = 0x40;
uint256 constant Fulfillment_considerationComponents_offset = 0x20;
uint256 constant OrderComponents_OrderParameters_common_head_size = 0x0140;
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
enum OrderType {
// 0: no partial fills, anyone can execute
FULL_OPEN,
// 1: partial fills supported, anyone can execute
PARTIAL_OPEN,
// 2: no partial fills, only offerer or zone can execute
FULL_RESTRICTED,
// 3: partial fills supported, only offerer or zone can execute
PARTIAL_RESTRICTED,
// 4: contract order type
CONTRACT
}
enum BasicOrderType {
// 0: no partial fills, anyone can execute
ETH_TO_ERC721_FULL_OPEN,
// 1: partial fills supported, anyone can execute
ETH_TO_ERC721_PARTIAL_OPEN,
// 2: no partial fills, only offerer or zone can execute
ETH_TO_ERC721_FULL_RESTRICTED,
// 3: partial fills supported, only offerer or zone can execute
ETH_TO_ERC721_PARTIAL_RESTRICTED,
// 4: no partial fills, anyone can execute
ETH_TO_ERC1155_FULL_OPEN,
// 5: partial fills supported, anyone can execute
ETH_TO_ERC1155_PARTIAL_OPEN,
// 6: no partial fills, only offerer or zone can execute
ETH_TO_ERC1155_FULL_RESTRICTED,
// 7: partial fills supported, only offerer or zone can execute
ETH_TO_ERC1155_PARTIAL_RESTRICTED,
// 8: no partial fills, anyone can execute
ERC20_TO_ERC721_FULL_OPEN,
// 9: partial fills supported, anyone can execute
ERC20_TO_ERC721_PARTIAL_OPEN,
// 10: no partial fills, only offerer or zone can execute
ERC20_TO_ERC721_FULL_RESTRICTED,
// 11: partial fills supported, only offerer or zone can execute
ERC20_TO_ERC721_PARTIAL_RESTRICTED,
// 12: no partial fills, anyone can execute
ERC20_TO_ERC1155_FULL_OPEN,
// 13: partial fills supported, anyone can execute
ERC20_TO_ERC1155_PARTIAL_OPEN,
// 14: no partial fills, only offerer or zone can execute
ERC20_TO_ERC1155_FULL_RESTRICTED,
// 15: partial fills supported, only offerer or zone can execute
ERC20_TO_ERC1155_PARTIAL_RESTRICTED,
// 16: no partial fills, anyone can execute
ERC721_TO_ERC20_FULL_OPEN,
// 17: partial fills supported, anyone can execute
ERC721_TO_ERC20_PARTIAL_OPEN,
// 18: no partial fills, only offerer or zone can execute
ERC721_TO_ERC20_FULL_RESTRICTED,
// 19: partial fills supported, only offerer or zone can execute
ERC721_TO_ERC20_PARTIAL_RESTRICTED,
// 20: no partial fills, anyone can execute
ERC1155_TO_ERC20_FULL_OPEN,
// 21: partial fills supported, anyone can execute
ERC1155_TO_ERC20_PARTIAL_OPEN,
// 22: no partial fills, only offerer or zone can execute
ERC1155_TO_ERC20_FULL_RESTRICTED,
// 23: partial fills supported, only offerer or zone can execute
ERC1155_TO_ERC20_PARTIAL_RESTRICTED
}
enum BasicOrderRouteType {
// 0: provide Ether (or other native token) to receive offered ERC721 item.
ETH_TO_ERC721,
// 1: provide Ether (or other native token) to receive offered ERC1155 item.
ETH_TO_ERC1155,
// 2: provide ERC20 item to receive offered ERC721 item.
ERC20_TO_ERC721,
// 3: provide ERC20 item to receive offered ERC1155 item.
ERC20_TO_ERC1155,
// 4: provide ERC721 item to receive offered ERC20 item.
ERC721_TO_ERC20,
// 5: provide ERC1155 item to receive offered ERC20 item.
ERC1155_TO_ERC20
}
enum ItemType {
// 0: ETH on mainnet, MATIC on polygon, etc.
NATIVE,
// 1: ERC20 items (ERC777 and ERC20 analogues could also technically work)
ERC20,
// 2: ERC721 items
ERC721,
// 3: ERC1155 items
ERC1155,
// 4: ERC721 items where a number of tokenIds are supported
ERC721_WITH_CRITERIA,
// 5: ERC1155 items where a number of ids are supported
ERC1155_WITH_CRITERIA
}
enum Side {
// 0: Items that can be spent
OFFER,
// 1: Items that must be received
CONSIDERATION
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
ItemType,
OrderType
} from "seaport-types/src/lib/ConsiderationEnums.sol";
import {
AdvancedOrder,
ConsiderationItem,
CriteriaResolver,
OfferItem,
OrderParameters,
ReceivedItem,
SpentItem
} from "seaport-types/src/lib/ConsiderationStructs.sol";
import { BasicOrderFulfiller } from "./BasicOrderFulfiller.sol";
import { CriteriaResolution } from "./CriteriaResolution.sol";
import { AmountDeriver } from "./AmountDeriver.sol";
import {
_revertInsufficientNativeTokensSupplied,
_revertInvalidNativeOfferItem
} from "seaport-types/src/lib/ConsiderationErrors.sol";
import {
AccumulatorDisarmed,
ConsiderationItem_recipient_offset,
ReceivedItem_amount_offset,
ReceivedItem_recipient_offset
} from "seaport-types/src/lib/ConsiderationConstants.sol";
/**
* @title OrderFulfiller
* @author 0age
* @notice OrderFulfiller contains logic related to order fulfillment where a
* single order is being fulfilled and where basic order fulfillment is
* not available as an option.
*/
contract OrderFulfiller is
BasicOrderFulfiller,
CriteriaResolution,
AmountDeriver
{
/**
* @dev Derive and set hashes, reference chainId, and associated domain
* separator during deployment.
*
* @param conduitController A contract that deploys conduits, or proxies
* that may optionally be used to transfer approved
* ERC20/721/1155 tokens.
*/
constructor(
address conduitController
) BasicOrderFulfiller(conduitController) {}
/**
* @dev Internal function to validate an order and update its status, adjust
* prices based on current time, apply criteria resolvers, determine
* what portion to fill, and transfer relevant tokens.
*
* @param advancedOrder The order to fulfill as well as the fraction
* to fill. Note that all offer and consideration
* components must divide with no remainder for
* the partial fill to be valid.
* @param criteriaResolvers An array where each element contains a
* reference to a specific offer or
* consideration, a token identifier, and a proof
* that the supplied token identifier is
* contained in the order's merkle root. Note
* that a criteria of zero indicates that any
* (transferable) token identifier is valid and
* that no proof needs to be supplied.
* @param fulfillerConduitKey A bytes32 value indicating what conduit, if
* any, to source the fulfiller's token approvals
* from. The zero hash signifies that no conduit
* should be used, with direct approvals set on
* Consideration.
* @param recipient The intended recipient for all received items.
*
* @return A boolean indicating whether the order has been fulfilled.
*/
function _validateAndFulfillAdvancedOrder(
AdvancedOrder memory advancedOrder,
CriteriaResolver[] memory criteriaResolvers,
bytes32 fulfillerConduitKey,
address recipient
) internal returns (bool) {
// Retrieve the order parameters and order type.
OrderParameters memory orderParameters = advancedOrder.parameters;
OrderType orderType = orderParameters.orderType;
// Ensure this function cannot be triggered during a reentrant call.
_setReentrancyGuard(
// Native tokens accepted during execution for contract order types.
orderType == OrderType.CONTRACT
);
// Validate order, update status, and determine fraction to fill.
(
bytes32 orderHash,
uint256 fillNumerator,
uint256 fillDenominator
) = _validateOrder(advancedOrder, _runTimeConstantTrue());
// Create an array with length 1 containing the order.
AdvancedOrder[] memory advancedOrders = new AdvancedOrder[](1);
// Populate the order as the first and only element of the new array.
advancedOrders[0] = advancedOrder;
// Apply criteria resolvers using generated orders and details arrays.
_applyCriteriaResolvers(advancedOrders, criteriaResolvers);
// Derive each item transfer with the appropriate fractional amount.
_applyFractions(
orderParameters,
fillNumerator,
fillDenominator,
recipient
);
// Declare an empty length-1 array to hold the order hash, but do not
// write to it until after the order has been authorized or generated.
bytes32[] memory orderHashes = new bytes32[](1);
// Declare a boolean that cannot be optimized out by the compiler
// outside of the if-else statement so it can be used in either.
bool _true = _runTimeConstantTrue();
if (orderType != OrderType.CONTRACT) {
_assertRestrictedAdvancedOrderAuthorization(
advancedOrder,
orderHashes,
orderHash,
0
);
_updateStatus(orderHash, fillNumerator, fillDenominator, _true);
} else {
// Return the generated order based on the order params and the
// provided extra data.
orderHash = _getGeneratedOrder(
orderParameters,
advancedOrder.extraData,
_true
);
}
_transferEach(orderParameters, fulfillerConduitKey, recipient);
// Write the order hash to the orderHashes array.
orderHashes[0] = orderHash;
// Ensure restricted orders have a valid submitter or pass a zone check.
_assertRestrictedAdvancedOrderValidity(
advancedOrder,
orderHashes,
orderHash
);
// Emit an event signifying that the order has been fulfilled.
_emitOrderFulfilledEvent(
orderHash,
orderParameters.offerer,
orderParameters.zone,
recipient,
orderParameters.offer,
orderParameters.consideration
);
// Clear the reentrancy guard.
_clearReentrancyGuard();
return true;
}
/**
* @dev Internal function to derive the amount to transfer for each item in
* a given order based on the fraction to fill and the current time.
*
* @param orderParameters The parameters for the fulfilled order.
* @param numerator A value indicating the portion of the order
* that should be filled.
* @param denominator A value indicating the total order size.
* @param recipient The intended recipient for all received items.
*/
function _applyFractions(
OrderParameters memory orderParameters,
uint256 numerator,
uint256 denominator,
address recipient
) internal view {
// Read start time & end time from order parameters and place on stack.
uint256 startTime = orderParameters.startTime;
uint256 endTime = orderParameters.endTime;
// As of solidity 0.6.0, inline assembly cannot directly access function
// definitions, but can still access locally scoped function variables.
// This means that a local variable to reference the internal function
// definition (using the same type), along with a local variable with
// the desired type, must first be created. Then, the original function
// pointer can be recast to the desired type.
/**
* Repurpose existing OfferItem memory regions on the offer array for
* the order by overriding the _transfer function pointer to accept a
* modified OfferItem argument in place of the usual ReceivedItem:
*
* ========= OfferItem ========== ====== ReceivedItem ======
* ItemType itemType; ------------> ItemType itemType;
* address token; ----------------> address token;
* uint256 identifierOrCriteria; -> uint256 identifier;
* uint256 startAmount; ----------> uint256 amount;
* uint256 endAmount; ------------> address recipient;
*/
// Declare a nested scope to minimize stack depth.
unchecked {
// Read offer array length from memory and place on stack.
uint256 totalOfferItems = orderParameters.offer.length;
// Create a variable to indicate whether the order has any
// native offer items
uint256 anyNativeItems;
// Iterate over each offer on the order.
// Skip overflow check as for loop is indexed starting at zero.
for (uint256 i = 0; i < totalOfferItems; ++i) {
// Retrieve the offer item.
OfferItem memory offerItem = orderParameters.offer[i];
// Offer items for the native token can not be received outside
// of a match order function except as part of a contract order.
{
ItemType itemType = offerItem.itemType;
assembly {
anyNativeItems := or(anyNativeItems, iszero(itemType))
}
}
// Declare an additional nested scope to minimize stack depth.
{
// Apply fill fraction to get offer item amount to transfer.
uint256 amount = _applyFraction(
offerItem.startAmount,
offerItem.endAmount,
numerator,
denominator,
startTime,
endTime,
_runTimeConstantFalse()
);
// Utilize assembly to set overloaded offerItem arguments.
assembly {
// Write new fractional amount to startAmount as amount.
mstore(
add(offerItem, ReceivedItem_amount_offset),
amount
)
// Write recipient to endAmount.
mstore(
add(offerItem, ReceivedItem_recipient_offset),
recipient
)
}
}
}
// If a non-contract order has native offer items, throw with an
// `InvalidNativeOfferItem` custom error.
{
OrderType orderType = orderParameters.orderType;
uint256 invalidNativeOfferItem;
assembly {
invalidNativeOfferItem := and(
// Note that this check requires that there are no
// order types beyond the current set (0-4). It will
// need to be modified when adding more order types.
lt(orderType, 4),
anyNativeItems
)
}
if (invalidNativeOfferItem != 0) {
_revertInvalidNativeOfferItem();
}
}
}
/**
* Repurpose existing ConsiderationItem memory regions on the
* consideration array for the order by overriding the _transfer
* function pointer to accept a modified ConsiderationItem argument in
* place of the usual ReceivedItem:
*
* ====== ConsiderationItem ===== ====== ReceivedItem ======
* ItemType itemType; ------------> ItemType itemType;
* address token; ----------------> address token;
* uint256 identifierOrCriteria;--> uint256 identifier;
* uint256 startAmount; ----------> uint256 amount;
* uint256 endAmount; /----> address recipient;
* address recipient; ------/
*/
// Declare a nested scope to minimize stack depth.
unchecked {
// Read consideration array length from memory and place on stack.
uint256 totalConsiderationItems = orderParameters
.consideration
.length;
// Iterate over each consideration item on the order.
// Skip overflow check as for loop is indexed starting at zero.
for (uint256 i = 0; i < totalConsiderationItems; ++i) {
// Retrieve the consideration item.
ConsiderationItem memory considerationItem = (
orderParameters.consideration[i]
);
// Apply fraction & derive considerationItem amount to transfer.
uint256 amount = _applyFraction(
considerationItem.startAmount,
considerationItem.endAmount,
numerator,
denominator,
startTime,
endTime,
_runTimeConstantTrue()
);
// Use assembly to set overloaded considerationItem arguments.
assembly {
// Write derived fractional amount to startAmount as amount.
mstore(
add(considerationItem, ReceivedItem_amount_offset),
amount
)
// Write original recipient to endAmount as recipient.
mstore(
add(considerationItem, ReceivedItem_recipient_offset),
mload(
add(
considerationItem,
ConsiderationItem_recipient_offset
)
)
)
}
}
}
}
/**
* @dev Internal function to transfer each item contained in a given single
* order fulfillment.
*
* @param orderParameters The parameters for the fulfilled order.
* @param fulfillerConduitKey A bytes32 value indicating what conduit, if
* any, to source the fulfiller's token approvals
* from. The zero hash signifies that no conduit
* should be used, with direct approvals set on
* Consideration.
* @param recipient The intended recipient for all received items.
*/
function _transferEach(
OrderParameters memory orderParameters,
bytes32 fulfillerConduitKey,
address recipient
) internal {
// Initialize an accumulator array. From this point forward, no new
// memory regions can be safely allocated until the accumulator is no
// longer being utilized, as the accumulator operates in an open-ended
// fashion from this memory pointer; existing memory may still be
// accessed and modified, however.
bytes memory accumulator = new bytes(AccumulatorDisarmed);
// As of solidity 0.6.0, inline assembly cannot directly access function
// definitions, but can still access locally scoped function variables.
// This means that a local variable to reference the internal function
// definition (using the same type), along with a local variable with
// the desired type, must first be created. Then, the original function
// pointer can be recast to the desired type.
/**
* Repurpose existing OfferItem memory regions on the offer array for
* the order by overriding the _transfer function pointer to accept a
* modified OfferItem argument in place of the usual ReceivedItem:
*
* ========= OfferItem ========== ====== ReceivedItem ======
* ItemType itemType; ------------> ItemType itemType;
* address token; ----------------> address token;
* uint256 identifierOrCriteria; -> uint256 identifier;
* uint256 startAmount; ----------> uint256 amount;
* uint256 endAmount; ------------> address recipient;
*/
// Declare a nested scope to minimize stack depth.
unchecked {
// Read offer array length from memory and place on stack.
uint256 totalOfferItems = orderParameters.offer.length;
// Iterate over each offer on the order.
// Skip overflow check as for loop is indexed starting at zero.
for (uint256 i = 0; i < totalOfferItems; ++i) {
// Retrieve the offer item.
OfferItem memory offerItem = orderParameters.offer[i];
// Utilize assembly to set overloaded offerItem arguments.
assembly {
// Write recipient to endAmount.
mstore(
add(offerItem, ReceivedItem_recipient_offset),
recipient
)
}
// Transfer the item from the offerer to the recipient.
_toOfferItemInput(_transfer)(
offerItem,
orderParameters.offerer,
orderParameters.conduitKey,
accumulator
);
}
}
// Declare a variable for the available native token balance.
uint256 nativeTokenBalance;
/**
* Repurpose existing ConsiderationItem memory regions on the
* consideration array for the order by overriding the _transfer
* function pointer to accept a modified ConsiderationItem argument in
* place of the usual ReceivedItem:
*
* ====== ConsiderationItem ===== ====== ReceivedItem ======
* ItemType itemType; ------------> ItemType itemType;
* address token; ----------------> address token;
* uint256 identifierOrCriteria;--> uint256 identifier;
* uint256 startAmount; ----------> uint256 amount;
* uint256 endAmount; /----> address recipient;
* address recipient; ------/
*/
// Declare a nested scope to minimize stack depth.
unchecked {
// Read consideration array length from memory and place on stack.
uint256 totalConsiderationItems = orderParameters
.consideration
.length;
// Iterate over each consideration item on the order.
// Skip overflow check as for loop is indexed starting at zero.
for (uint256 i = 0; i < totalConsiderationItems; ++i) {
// Retrieve the consideration item.
ConsiderationItem memory considerationItem = (
orderParameters.consideration[i]
);
if (considerationItem.itemType == ItemType.NATIVE) {
// Get the current available balance of native tokens.
assembly {
nativeTokenBalance := selfbalance()
}
// Ensure that sufficient native tokens are still available.
if (considerationItem.startAmount > nativeTokenBalance) {
_revertInsufficientNativeTokensSupplied();
}
}
// Transfer item from caller to recipient specified by the item.
_toConsiderationItemInput(_transfer)(
considerationItem,
msg.sender,
fulfillerConduitKey,
accumulator
);
}
}
// Trigger any remaining accumulated transfers via call to the conduit.
_triggerIfArmed(accumulator);
// Determine whether any native token balance remains.
assembly {
nativeTokenBalance := selfbalance()
}
// Return any remaining native token balance to the caller.
if (nativeTokenBalance != 0) {
_transferNativeTokens(payable(msg.sender), nativeTokenBalance);
}
}
/**
* @dev Internal function to emit an OrderFulfilled event. OfferItems are
* translated into SpentItems and ConsiderationItems are translated
* into ReceivedItems.
*
* @param orderHash The order hash.
* @param offerer The offerer for the order.
* @param zone The zone for the order.
* @param recipient The recipient of the order, or the null address if
* the order was fulfilled via order matching.
* @param offer The offer items for the order.
* @param consideration The consideration items for the order.
*/
function _emitOrderFulfilledEvent(
bytes32 orderHash,
address offerer,
address zone,
address recipient,
OfferItem[] memory offer,
ConsiderationItem[] memory consideration
) internal {
// Cast already-modified offer memory region as spent items.
SpentItem[] memory spentItems;
assembly {
spentItems := offer
}
// Cast already-modified consideration memory region as received items.
ReceivedItem[] memory receivedItems;
assembly {
receivedItems := consideration
}
// Emit an event signifying that the order has been fulfilled.
emit OrderFulfilled(
orderHash,
offerer,
zone,
recipient,
spentItems,
receivedItems
);
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import { ItemType, Side } from "seaport-types/src/lib/ConsiderationEnums.sol";
import {
AdvancedOrder,
Execution,
FulfillmentComponent,
ReceivedItem
} from "seaport-types/src/lib/ConsiderationStructs.sol";
import {
_revertMissingFulfillmentComponentOnAggregation
} from "seaport-types/src/lib/ConsiderationErrors.sol";
import {
FulfillmentApplicationErrors
} from "seaport-types/src/interfaces/FulfillmentApplicationErrors.sol";
import {
AdvancedOrder_numerator_offset,
Common_amount_offset,
Common_identifier_offset,
Common_token_offset,
Execution_conduit_offset,
Execution_offerer_offset,
Fulfillment_itemIndex_offset,
OneWord,
OneWordShift,
OrderParameters_conduit_offset,
OrderParameters_consideration_head_offset,
OrderParameters_offer_head_offset,
ReceivedItem_CommonParams_size,
ReceivedItem_recipient_offset,
ReceivedItem_size
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
Error_selector_offset,
InvalidFulfillmentComponentData_error_length,
InvalidFulfillmentComponentData_error_selector,
MismatchedOfferAndConsiderationComponents_error_idx_ptr,
MismatchedOfferAndConsiderationComponents_error_length,
MismatchedOfferAndConsiderationComponents_error_selector,
MissingItemAmount_error_length,
MissingItemAmount_error_selector,
OfferAndConsiderationRequiredOnFulfillment_error_length,
OfferAndConsiderationRequiredOnFulfillment_error_selector,
Panic_arithmetic,
Panic_error_code_ptr,
Panic_error_length,
Panic_error_selector
} from "seaport-types/src/lib/ConsiderationErrorConstants.sol";
/**
* @title FulfillmentApplier
* @author 0age
* @notice FulfillmentApplier contains logic related to applying fulfillments,
* both as part of order matching (where offer items are matched to
* consideration items) as well as fulfilling available orders (where
* order items and consideration items are independently aggregated).
*/
contract FulfillmentApplier is FulfillmentApplicationErrors {
/**
* @dev Internal pure function to match offer items to consideration items
* on a group of orders via a supplied fulfillment.
*
* @param advancedOrders The orders to match.
* @param offerComponents An array designating offer components to
* match to consideration components.
* @param considerationComponents An array designating consideration
* components to match to offer components.
* Note that each consideration amount must
* be zero in order for the match operation
* to be valid.
* @param fulfillmentIndex The index of the fulfillment being
* applied.
*
* @return execution The transfer performed as a result of the fulfillment.
*/
function _applyFulfillment(
AdvancedOrder[] memory advancedOrders,
FulfillmentComponent[] memory offerComponents,
FulfillmentComponent[] memory considerationComponents,
uint256 fulfillmentIndex
) internal pure returns (Execution memory execution) {
// Ensure 1+ of both offer and consideration components are supplied.
assembly {
if or(
iszero(mload(offerComponents)),
iszero(mload(considerationComponents))
) {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(
0,
OfferAndConsiderationRequiredOnFulfillment_error_selector
)
// revert(abi.encodeWithSignature(
// "OfferAndConsiderationRequiredOnFulfillment()"
// ))
revert(
Error_selector_offset,
OfferAndConsiderationRequiredOnFulfillment_error_length
)
}
}
// Declare a new Execution struct.
Execution memory considerationExecution;
// Validate & aggregate consideration items to new Execution object.
_aggregateValidFulfillmentConsiderationItems(
advancedOrders,
considerationComponents,
considerationExecution,
address(0),
bytes32(0)
);
// Retrieve the consideration item from the execution struct.
ReceivedItem memory considerationItem = considerationExecution.item;
// Skip aggregating offer items if no consideration items are available.
if (considerationItem.amount == 0) {
return considerationExecution;
}
// Validate & aggregate offer items to Execution object.
_aggregateValidFulfillmentOfferItems(
advancedOrders,
offerComponents,
execution,
considerationItem.recipient
);
ReceivedItem memory executionItem = execution.item;
// Ensure offer & consideration item types, tokens, & identifiers match.
// (a != b || c != d || e != f) == (((a ^ b) | (c ^ d) | (e ^ f)) != 0),
// but the second expression requires less gas to evaluate.
assembly {
if or(
or(
xor(
mload(executionItem), // no offset for item type
mload(considerationItem) // no offset for item type
),
xor(
mload(add(executionItem, Common_token_offset)),
mload(add(considerationItem, Common_token_offset))
)
),
xor(
mload(add(executionItem, Common_identifier_offset)),
mload(add(considerationItem, Common_identifier_offset))
)
) {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(
0,
MismatchedOfferAndConsiderationComponents_error_selector
)
// Store fulfillment index argument.
mstore(
MismatchedOfferAndConsiderationComponents_error_idx_ptr,
fulfillmentIndex
)
// Revert: `MismatchedOfferAndConsiderationComponents(uint256)`
revert(
Error_selector_offset,
MismatchedOfferAndConsiderationComponents_error_length
)
}
}
// If total consideration amount exceeds the offer amount...
if (considerationItem.amount > executionItem.amount) {
// Retrieve the first consideration component from the fulfillment.
FulfillmentComponent memory targetComponent = (
considerationComponents[0]
);
// Skip underflow check as the conditional being true implies that
// considerationItem.amount > execution.item.amount.
unchecked {
// Add excess consideration item amount to original order array.
advancedOrders[targetComponent.orderIndex]
.parameters
.consideration[targetComponent.itemIndex]
.startAmount = (considerationItem.amount -
executionItem.amount);
}
} else {
// Retrieve the first offer component from the fulfillment.
FulfillmentComponent memory targetComponent = offerComponents[0];
// Skip underflow check as the conditional being false implies that
// execution.item.amount >= considerationItem.amount.
unchecked {
// Add excess offer item amount to the original array of orders.
advancedOrders[targetComponent.orderIndex]
.parameters
.offer[targetComponent.itemIndex]
.startAmount = (executionItem.amount -
considerationItem.amount);
}
// Reduce total offer amount to equal the consideration amount.
executionItem.amount = considerationItem.amount;
}
// Return the final execution that will be triggered for relevant items.
return execution; // Execution(executionItem, offerer, conduitKey);
}
/**
* @dev Internal view function to aggregate offer or consideration items
* from a group of orders into a single execution via a supplied array
* of fulfillment components. Items that are not available to aggregate
* will not be included in the aggregated execution.
*
* @param advancedOrders The orders to aggregate.
* @param side The side (i.e. offer or consideration).
* @param fulfillmentComponents An array designating item components to
* aggregate if part of an available order.
* @param fulfillerConduitKey A bytes32 value indicating what conduit, if
* any, to source the fulfiller's token
* approvals from. The zero hash signifies that
* no conduit should be used, with approvals
* set directly on this contract.
* @param recipient The intended recipient for all received
* items.
*
* @return execution The transfer performed as a result of the fulfillment.
*/
function _aggregateAvailable(
AdvancedOrder[] memory advancedOrders,
Side side,
FulfillmentComponent[] memory fulfillmentComponents,
bytes32 fulfillerConduitKey,
address recipient
) internal view returns (Execution memory execution) {
// Skip overflow / underflow checks; conditions checked or unreachable.
unchecked {
// Retrieve fulfillment components array length and place on stack.
// Ensure at least one fulfillment component has been supplied.
if (fulfillmentComponents.length == 0) {
_revertMissingFulfillmentComponentOnAggregation(side);
}
// If the fulfillment components are offer components...
if (side == Side.OFFER) {
// Return execution for aggregated items provided by offerer.
_aggregateValidFulfillmentOfferItems(
advancedOrders,
fulfillmentComponents,
execution,
payable(recipient)
);
} else {
// Otherwise, fulfillment components are consideration
// components. Return execution for aggregated items provided by
// the fulfiller.
_aggregateValidFulfillmentConsiderationItems(
advancedOrders,
fulfillmentComponents,
execution,
msg.sender,
fulfillerConduitKey
);
}
}
}
/**
* @dev Internal pure function to aggregate a group of offer items using
* supplied directives on which component items are candidates for
* aggregation, skipping items on orders that are not available.
*
* @param advancedOrders The orders to aggregate offer items from.
* @param offerComponents An array of FulfillmentComponent structs
* indicating the order index and item index of each
* candidate offer item for aggregation.
* @param execution The execution to apply the aggregation to.
* @param recipient The intended recipient for the received item.
*/
function _aggregateValidFulfillmentOfferItems(
AdvancedOrder[] memory advancedOrders,
FulfillmentComponent[] memory offerComponents,
Execution memory execution,
address payable recipient
) internal pure {
assembly {
// Declare a variable for the final aggregated item amount.
let amount
// Declare a variable to track errors encountered with amount.
let errorBuffer
// Declare a variable for the hash of itemType, token, & identifier.
let dataHash
// Iterate over each offer component.
for {
// Create variable to track position in offerComponents head.
let fulfillmentHeadPtr := offerComponents
// Get position of the last element in head of array.
let endPtr := add(
offerComponents,
shl(OneWordShift, mload(offerComponents))
)
} lt(fulfillmentHeadPtr, endPtr) {
} {
// Increment position in considerationComponents head.
fulfillmentHeadPtr := add(fulfillmentHeadPtr, OneWord)
// Ensure that the order index is not out of range.
if iszero(
lt(mload(mload(fulfillmentHeadPtr)), mload(advancedOrders))
) {
throwInvalidFulfillmentComponentData()
}
// Read advancedOrders[orderIndex] pointer from its array head.
let orderPtr := mload(
// Calculate head position of advancedOrders[orderIndex]
add(
add(advancedOrders, OneWord),
shl(OneWordShift, mload(mload(fulfillmentHeadPtr)))
)
)
// Read the pointer to OrderParameters from the AdvancedOrder.
let paramsPtr := mload(orderPtr)
// Retrieve item index using an offset of fulfillment pointer.
let itemIndex := mload(
add(mload(fulfillmentHeadPtr), Fulfillment_itemIndex_offset)
)
let offerItemPtr
{
// Load the offer array pointer.
let offerArrPtr := mload(
add(paramsPtr, OrderParameters_offer_head_offset)
)
// If the offer item index is out of range or the numerator
// is zero, skip this item.
if or(
iszero(lt(itemIndex, mload(offerArrPtr))),
iszero(
mload(add(orderPtr, AdvancedOrder_numerator_offset))
)
) {
continue
}
// Retrieve offer item pointer using the item index.
offerItemPtr := mload(
add(
// Get pointer to beginning of receivedItem.
add(offerArrPtr, OneWord),
// Calculate offset to pointer for the order.
shl(OneWordShift, itemIndex)
)
)
}
// Declare a separate scope for the amount update.
{
// Retrieve amount pointer using consideration item pointer.
let amountPtr := add(offerItemPtr, Common_amount_offset)
// Add offer item amount to execution amount.
let newAmount := add(amount, mload(amountPtr))
// Update error buffer:
// 1 = zero amount, 2 = overflow, 3 = both.
errorBuffer := or(
errorBuffer,
or(
shl(1, lt(newAmount, amount)),
iszero(mload(amountPtr))
)
)
// Update the amount to the new, summed amount.
amount := newAmount
// Zero out amount on original item to indicate it is spent.
mstore(amountPtr, 0)
}
// Retrieve ReceivedItem pointer from Execution.
let receivedItem := mload(execution)
// Check if this is the first valid fulfillment item.
switch iszero(dataHash)
case 1 {
// On first valid item, populate the received item in memory
// for later comparison.
// Set the item type on the received item.
mstore(receivedItem, mload(offerItemPtr))
// Set the token on the received item.
mstore(
add(receivedItem, Common_token_offset),
mload(add(offerItemPtr, Common_token_offset))
)
// Set the identifier on the received item.
mstore(
add(receivedItem, Common_identifier_offset),
mload(add(offerItemPtr, Common_identifier_offset))
)
// Set the recipient on the received item.
mstore(
add(receivedItem, ReceivedItem_recipient_offset),
recipient
)
// Set offerer on returned execution using order pointer.
mstore(
add(execution, Execution_offerer_offset),
mload(paramsPtr)
)
// Set execution conduitKey via order pointer offset.
mstore(
add(execution, Execution_conduit_offset),
mload(add(paramsPtr, OrderParameters_conduit_offset))
)
// Calculate the hash of (itemType, token, identifier).
dataHash := keccak256(
receivedItem,
ReceivedItem_CommonParams_size
)
// If component index > 0, swap component pointer with
// pointer to first component so that any remainder after
// fulfillment can be added back to the first item.
let firstFulfillmentHeadPtr := add(offerComponents, OneWord)
if xor(firstFulfillmentHeadPtr, fulfillmentHeadPtr) {
let fulfillmentPtr := mload(fulfillmentHeadPtr)
mstore(firstFulfillmentHeadPtr, fulfillmentPtr)
}
}
default {
// Compare every subsequent item to the first.
if or(
or(
// The offerer must match on both items.
xor(
mload(paramsPtr),
mload(add(execution, Execution_offerer_offset))
),
// The conduit key must match on both items.
xor(
mload(
add(
paramsPtr,
OrderParameters_conduit_offset
)
),
mload(add(execution, Execution_conduit_offset))
)
),
// The itemType, token, and identifier must match.
xor(
dataHash,
keccak256(
offerItemPtr,
ReceivedItem_CommonParams_size
)
)
) {
// Throw if any of the requirements are not met.
throwInvalidFulfillmentComponentData()
}
}
}
// Write final amount to execution.
mstore(add(mload(execution), Common_amount_offset), amount)
// Determine whether the error buffer contains a nonzero error code.
if errorBuffer {
// If errorBuffer is 1, an item had an amount of zero.
if eq(errorBuffer, 1) {
// Store left-padded selector with push4 (reduces bytecode)
// mem[28:32] = selector
mstore(0, MissingItemAmount_error_selector)
// revert(abi.encodeWithSignature("MissingItemAmount()"))
revert(
Error_selector_offset,
MissingItemAmount_error_length
)
}
// If errorBuffer is not 1 or 0, the sum overflowed.
// Panic!
throwOverflow()
}
// Declare function for reverts on invalid fulfillment data.
function throwInvalidFulfillmentComponentData() {
// Store left-padded selector (uses push4 and reduces code size)
mstore(0, InvalidFulfillmentComponentData_error_selector)
// revert(abi.encodeWithSignature(
// "InvalidFulfillmentComponentData()"
// ))
revert(
Error_selector_offset,
InvalidFulfillmentComponentData_error_length
)
}
// Declare function for reverts due to arithmetic overflows.
function throwOverflow() {
// Store the Panic error signature.
mstore(0, Panic_error_selector)
// Store the arithmetic (0x11) panic code.
mstore(Panic_error_code_ptr, Panic_arithmetic)
// revert(abi.encodeWithSignature("Panic(uint256)", 0x11))
revert(Error_selector_offset, Panic_error_length)
}
}
}
/**
* @dev Internal pure function to aggregate a group of consideration items
* using supplied directives on which component items are candidates
* for aggregation, skipping items on orders that are not available.
* Note that this function depends on memory layout affected by an
* earlier call to _validateOrdersAndPrepareToFulfill. The memory for
* the consideration arrays needs to be updated before calling
* _aggregateValidFulfillmentConsiderationItems.
* _validateOrdersAndPrepareToFulfill is called in _matchAdvancedOrders
* and _fulfillAvailableAdvancedOrders in the current version.
*
* @param advancedOrders The orders to aggregate consideration
* items from.
* @param considerationComponents An array of FulfillmentComponent structs
* indicating the order index and item index
* of each candidate consideration item for
* aggregation.
* @param execution The execution to apply the aggregation to.
* @param offerer The address of the offerer to set on the
* execution.
* @param conduitKey A bytes32 value indicating the conduit key
* to set on the execution.
*/
function _aggregateValidFulfillmentConsiderationItems(
AdvancedOrder[] memory advancedOrders,
FulfillmentComponent[] memory considerationComponents,
Execution memory execution,
address offerer,
bytes32 conduitKey
) internal pure {
// Utilize assembly in order to efficiently aggregate the items.
assembly {
// Declare a variable for the final aggregated item amount.
let amount
// Create variable to track errors encountered with amount.
let errorBuffer
// Declare variable for hash(itemType, token, identifier, recipient)
let dataHash
// Iterate over each consideration component.
for {
// Track position in considerationComponents head.
let fulfillmentHeadPtr := considerationComponents
// Get position of the last element in head of array.
let endPtr := add(
considerationComponents,
shl(OneWordShift, mload(considerationComponents))
)
} lt(fulfillmentHeadPtr, endPtr) {
} {
// Increment position in considerationComponents head.
fulfillmentHeadPtr := add(fulfillmentHeadPtr, OneWord)
// Retrieve the order index using the fulfillment pointer.
let orderIndex := mload(mload(fulfillmentHeadPtr))
// Ensure that the order index is not out of range.
if iszero(lt(orderIndex, mload(advancedOrders))) {
throwInvalidFulfillmentComponentData()
}
// Read advancedOrders[orderIndex] pointer from its array head.
let orderPtr := mload(
// Derive head position of advancedOrders[orderIndex].
add(
add(advancedOrders, OneWord),
shl(OneWordShift, orderIndex)
)
)
// Retrieve item index using an offset of fulfillment pointer.
let itemIndex := mload(
add(mload(fulfillmentHeadPtr), Fulfillment_itemIndex_offset)
)
let considerationItemPtr
{
// Load consideration array pointer.
let considerationArrPtr := mload(
add(
// Read OrderParameters pointer from the order.
mload(orderPtr),
OrderParameters_consideration_head_offset
)
)
// If the consideration item index is out of range or the
// numerator is zero, skip this item.
if or(
iszero(lt(itemIndex, mload(considerationArrPtr))),
iszero(
mload(add(orderPtr, AdvancedOrder_numerator_offset))
)
) {
continue
}
// Retrieve consideration item pointer using the item index.
considerationItemPtr := mload(
add(
// Get pointer to beginning of receivedItem.
add(considerationArrPtr, OneWord),
// Calculate offset to pointer for the order.
shl(OneWordShift, itemIndex)
)
)
}
// Declare a separate scope for the amount update.
{
// Retrieve amount pointer using consideration item pointer.
let amountPtr := add(
considerationItemPtr,
Common_amount_offset
)
// Add consideration item amount to execution amount.
let newAmount := add(amount, mload(amountPtr))
// Update error buffer:
// 1 = zero amount, 2 = overflow, 3 = both.
errorBuffer := or(
errorBuffer,
or(
shl(1, lt(newAmount, amount)),
iszero(mload(amountPtr))
)
)
// Update the amount to the new, summed amount.
amount := newAmount
// Zero out original item amount to indicate it is credited.
mstore(amountPtr, 0)
}
// Retrieve ReceivedItem pointer from Execution.
let receivedItem := mload(execution)
switch iszero(dataHash)
case 1 {
// On first valid item, populate the received item in
// memory for later comparison.
// Set the item type on the received item.
mstore(receivedItem, mload(considerationItemPtr))
// Set the token on the received item.
mstore(
add(receivedItem, Common_token_offset),
mload(add(considerationItemPtr, Common_token_offset))
)
// Set the identifier on the received item.
mstore(
add(receivedItem, Common_identifier_offset),
mload(
add(considerationItemPtr, Common_identifier_offset)
)
)
// Set the recipient on the received item. Note that this
// depends on the memory layout established by the
// _validateOrdersAndPrepareToFulfill function.
mstore(
add(receivedItem, ReceivedItem_recipient_offset),
mload(
add(
considerationItemPtr,
ReceivedItem_recipient_offset
)
)
)
// Set provided offerer on the execution.
mstore(add(execution, Execution_offerer_offset), offerer)
// Set provided conduitKey on the execution.
mstore(add(execution, Execution_conduit_offset), conduitKey)
// Calculate the hash of (itemType, token, identifier,
// recipient). This is run after amount is set to zero, so
// there will be one blank word after identifier included in
// the hash buffer.
dataHash := keccak256(
considerationItemPtr,
ReceivedItem_size
)
// If component index > 0, swap component pointer with
// pointer to first component so that any remainder after
// fulfillment can be added back to the first item.
let firstFulfillmentHeadPtr := add(
considerationComponents,
OneWord
)
if xor(firstFulfillmentHeadPtr, fulfillmentHeadPtr) {
let fulfillmentPtr := mload(fulfillmentHeadPtr)
mstore(firstFulfillmentHeadPtr, fulfillmentPtr)
}
}
default {
// Compare every subsequent item to the first; the item
// type, token, identifier and recipient must match.
if xor(
dataHash,
// Calculate the hash of (itemType, token, identifier,
// recipient). This is run after amount is set to zero,
// so there will be one blank word after identifier
// included in the hash buffer.
keccak256(considerationItemPtr, ReceivedItem_size)
) {
// Throw if any of the requirements are not met.
throwInvalidFulfillmentComponentData()
}
}
}
// Retrieve ReceivedItem pointer from Execution.
let receivedItem := mload(execution)
// Write final amount to execution.
mstore(add(receivedItem, Common_amount_offset), amount)
// Determine whether the error buffer contains a nonzero error code.
if errorBuffer {
// If errorBuffer is 1, an item had an amount of zero.
if eq(errorBuffer, 1) {
// Store left-padded selector with push4, mem[28:32]
mstore(0, MissingItemAmount_error_selector)
// revert(abi.encodeWithSignature("MissingItemAmount()"))
revert(
Error_selector_offset,
MissingItemAmount_error_length
)
}
// If errorBuffer is not 1 or 0, `amount` overflowed.
// Panic!
throwOverflow()
}
// Declare function for reverts on invalid fulfillment data.
function throwInvalidFulfillmentComponentData() {
// Store the InvalidFulfillmentComponentData error signature.
mstore(0, InvalidFulfillmentComponentData_error_selector)
// revert(abi.encodeWithSignature(
// "InvalidFulfillmentComponentData()"
// ))
revert(
Error_selector_offset,
InvalidFulfillmentComponentData_error_length
)
}
// Declare function for reverts due to arithmetic overflows.
function throwOverflow() {
// Store the Panic error signature.
mstore(0, Panic_error_selector)
// Store the arithmetic (0x11) panic code.
mstore(Panic_error_code_ptr, Panic_arithmetic)
// revert(abi.encodeWithSignature("Panic(uint256)", 0x11))
revert(Error_selector_offset, Panic_error_length)
}
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.17;
import { Side } from "./ConsiderationEnums.sol";
import {
BadFraction_error_length,
BadFraction_error_selector,
CannotCancelOrder_error_length,
CannotCancelOrder_error_selector,
ConsiderationLengthNotEqualToTotalOriginal_error_length,
ConsiderationLengthNotEqualToTotalOriginal_error_selector,
ConsiderationNotMet_error_considerationIndex_ptr,
ConsiderationNotMet_error_length,
ConsiderationNotMet_error_orderIndex_ptr,
ConsiderationNotMet_error_selector,
ConsiderationNotMet_error_shortfallAmount_ptr,
CriteriaNotEnabledForItem_error_length,
CriteriaNotEnabledForItem_error_selector,
Error_selector_offset,
InsufficientNativeTokensSupplied_error_length,
InsufficientNativeTokensSupplied_error_selector,
InvalidBasicOrderParameterEncoding_error_length,
InvalidBasicOrderParameterEncoding_error_selector,
InvalidCallToConduit_error_conduit_ptr,
InvalidCallToConduit_error_length,
InvalidCallToConduit_error_selector,
InvalidConduit_error_conduit_ptr,
InvalidConduit_error_conduitKey_ptr,
InvalidConduit_error_length,
InvalidConduit_error_selector,
InvalidContractOrder_error_length,
InvalidContractOrder_error_orderHash_ptr,
InvalidContractOrder_error_selector,
InvalidERC721TransferAmount_error_amount_ptr,
InvalidERC721TransferAmount_error_length,
InvalidERC721TransferAmount_error_selector,
InvalidMsgValue_error_length,
InvalidMsgValue_error_selector,
InvalidMsgValue_error_value_ptr,
InvalidNativeOfferItem_error_length,
InvalidNativeOfferItem_error_selector,
InvalidProof_error_length,
InvalidProof_error_selector,
InvalidTime_error_endTime_ptr,
InvalidTime_error_length,
InvalidTime_error_selector,
InvalidTime_error_startTime_ptr,
MismatchedOfferAndConsiderationComponents_error_idx_ptr,
MismatchedOfferAndConsiderationComponents_error_length,
MismatchedOfferAndConsiderationComponents_error_selector,
MissingFulfillmentComponentOnAggregation_error_length,
MissingFulfillmentComponentOnAggregation_error_selector,
MissingFulfillmentComponentOnAggregation_error_side_ptr,
MissingOriginalConsiderationItems_error_length,
MissingOriginalConsiderationItems_error_selector,
NoReentrantCalls_error_length,
NoReentrantCalls_error_selector,
NoSpecifiedOrdersAvailable_error_length,
NoSpecifiedOrdersAvailable_error_selector,
OfferAndConsiderationRequiredOnFulfillment_error_length,
OfferAndConsiderationRequiredOnFulfillment_error_selector,
OrderAlreadyFilled_error_length,
OrderAlreadyFilled_error_orderHash_ptr,
OrderAlreadyFilled_error_selector,
OrderCriteriaResolverOutOfRange_error_length,
OrderCriteriaResolverOutOfRange_error_selector,
OrderCriteriaResolverOutOfRange_error_side_ptr,
OrderIsCancelled_error_length,
OrderIsCancelled_error_orderHash_ptr,
OrderIsCancelled_error_selector,
OrderPartiallyFilled_error_length,
OrderPartiallyFilled_error_orderHash_ptr,
OrderPartiallyFilled_error_selector,
PartialFillsNotEnabledForOrder_error_length,
PartialFillsNotEnabledForOrder_error_selector,
UnresolvedConsiderationCriteria_error_length,
UnresolvedConsiderationCriteria_error_orderIndex_ptr,
UnresolvedConsiderationCriteria_error_selector,
UnresolvedOfferCriteria_error_length,
UnresolvedOfferCriteria_error_offerIndex_ptr,
UnresolvedOfferCriteria_error_orderIndex_ptr,
UnresolvedOfferCriteria_error_selector,
UnusedItemParameters_error_length,
UnusedItemParameters_error_selector
} from "./ConsiderationErrorConstants.sol";
/**
* @dev Reverts the current transaction with a "BadFraction" error message.
*/
function _revertBadFraction() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, BadFraction_error_selector)
// revert(abi.encodeWithSignature("BadFraction()"))
revert(Error_selector_offset, BadFraction_error_length)
}
}
/**
* @dev Reverts the current transaction with a "ConsiderationNotMet" error
* message, including the provided order index, consideration index, and
* shortfall amount.
*
* @param orderIndex The index of the order that did not meet the
* consideration criteria.
* @param considerationIndex The index of the consideration item that did not
* meet its criteria.
* @param shortfallAmount The amount by which the consideration criteria were
* not met.
*/
function _revertConsiderationNotMet(
uint256 orderIndex,
uint256 considerationIndex,
uint256 shortfallAmount
) pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, ConsiderationNotMet_error_selector)
// Store arguments.
mstore(ConsiderationNotMet_error_orderIndex_ptr, orderIndex)
mstore(
ConsiderationNotMet_error_considerationIndex_ptr, considerationIndex
)
mstore(ConsiderationNotMet_error_shortfallAmount_ptr, shortfallAmount)
// revert(abi.encodeWithSignature(
// "ConsiderationNotMet(uint256,uint256,uint256)",
// orderIndex,
// considerationIndex,
// shortfallAmount
// ))
revert(Error_selector_offset, ConsiderationNotMet_error_length)
}
}
/**
* @dev Reverts the current transaction with a "CriteriaNotEnabledForItem" error
* message.
*/
function _revertCriteriaNotEnabledForItem() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, CriteriaNotEnabledForItem_error_selector)
// revert(abi.encodeWithSignature("CriteriaNotEnabledForItem()"))
revert(Error_selector_offset, CriteriaNotEnabledForItem_error_length)
}
}
/**
* @dev Reverts the current transaction with an
* "InsufficientNativeTokensSupplied" error message.
*/
function _revertInsufficientNativeTokensSupplied() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InsufficientNativeTokensSupplied_error_selector)
// revert(abi.encodeWithSignature("InsufficientNativeTokensSupplied()"))
revert(
Error_selector_offset, InsufficientNativeTokensSupplied_error_length
)
}
}
/**
* @dev Reverts the current transaction with an
* "InvalidBasicOrderParameterEncoding" error message.
*/
function _revertInvalidBasicOrderParameterEncoding() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InvalidBasicOrderParameterEncoding_error_selector)
// revert(abi.encodeWithSignature(
// "InvalidBasicOrderParameterEncoding()"
// ))
revert(
Error_selector_offset,
InvalidBasicOrderParameterEncoding_error_length
)
}
}
/**
* @dev Reverts the current transaction with an "InvalidCallToConduit" error
* message, including the provided address of the conduit that was called
* improperly.
*
* @param conduit The address of the conduit that was called improperly.
*/
function _revertInvalidCallToConduit(address conduit) pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InvalidCallToConduit_error_selector)
// Store argument.
mstore(InvalidCallToConduit_error_conduit_ptr, conduit)
// revert(abi.encodeWithSignature(
// "InvalidCallToConduit(address)",
// conduit
// ))
revert(Error_selector_offset, InvalidCallToConduit_error_length)
}
}
/**
* @dev Reverts the current transaction with an "CannotCancelOrder" error
* message.
*/
function _revertCannotCancelOrder() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, CannotCancelOrder_error_selector)
// revert(abi.encodeWithSignature("CannotCancelOrder()"))
revert(Error_selector_offset, CannotCancelOrder_error_length)
}
}
/**
* @dev Reverts the current transaction with an "InvalidConduit" error message,
* including the provided key and address of the invalid conduit.
*
* @param conduitKey The key of the invalid conduit.
* @param conduit The address of the invalid conduit.
*/
function _revertInvalidConduit(bytes32 conduitKey, address conduit) pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InvalidConduit_error_selector)
// Store arguments.
mstore(InvalidConduit_error_conduitKey_ptr, conduitKey)
mstore(InvalidConduit_error_conduit_ptr, conduit)
// revert(abi.encodeWithSignature(
// "InvalidConduit(bytes32,address)",
// conduitKey,
// conduit
// ))
revert(Error_selector_offset, InvalidConduit_error_length)
}
}
/**
* @dev Reverts the current transaction with an "InvalidERC721TransferAmount"
* error message.
*
* @param amount The invalid amount.
*/
function _revertInvalidERC721TransferAmount(uint256 amount) pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InvalidERC721TransferAmount_error_selector)
// Store argument.
mstore(InvalidERC721TransferAmount_error_amount_ptr, amount)
// revert(abi.encodeWithSignature(
// "InvalidERC721TransferAmount(uint256)",
// amount
// ))
revert(Error_selector_offset, InvalidERC721TransferAmount_error_length)
}
}
/**
* @dev Reverts the current transaction with an "InvalidMsgValue" error message,
* including the invalid value that was sent in the transaction's
* `msg.value` field.
*
* @param value The invalid value that was sent in the transaction's `msg.value`
* field.
*/
function _revertInvalidMsgValue(uint256 value) pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InvalidMsgValue_error_selector)
// Store argument.
mstore(InvalidMsgValue_error_value_ptr, value)
// revert(abi.encodeWithSignature("InvalidMsgValue(uint256)", value))
revert(Error_selector_offset, InvalidMsgValue_error_length)
}
}
/**
* @dev Reverts the current transaction with an "InvalidNativeOfferItem" error
* message.
*/
function _revertInvalidNativeOfferItem() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InvalidNativeOfferItem_error_selector)
// revert(abi.encodeWithSignature("InvalidNativeOfferItem()"))
revert(Error_selector_offset, InvalidNativeOfferItem_error_length)
}
}
/**
* @dev Reverts the current transaction with an "InvalidProof" error message.
*/
function _revertInvalidProof() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InvalidProof_error_selector)
// revert(abi.encodeWithSignature("InvalidProof()"))
revert(Error_selector_offset, InvalidProof_error_length)
}
}
/**
* @dev Reverts the current transaction with an "InvalidContractOrder" error
* message.
*
* @param orderHash The hash of the contract order that caused the error.
*/
function _revertInvalidContractOrder(bytes32 orderHash) pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InvalidContractOrder_error_selector)
// Store arguments.
mstore(InvalidContractOrder_error_orderHash_ptr, orderHash)
// revert(abi.encodeWithSignature(
// "InvalidContractOrder(bytes32)",
// orderHash
// ))
revert(Error_selector_offset, InvalidContractOrder_error_length)
}
}
/**
* @dev Reverts the current transaction with an "InvalidTime" error message.
*
* @param startTime The time at which the order becomes active.
* @param endTime The time at which the order becomes inactive.
*/
function _revertInvalidTime(uint256 startTime, uint256 endTime) pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InvalidTime_error_selector)
// Store arguments.
mstore(InvalidTime_error_startTime_ptr, startTime)
mstore(InvalidTime_error_endTime_ptr, endTime)
// revert(abi.encodeWithSignature(
// "InvalidTime(uint256,uint256)",
// startTime,
// endTime
// ))
revert(Error_selector_offset, InvalidTime_error_length)
}
}
/**
* @dev Reverts execution with a "MissingFulfillmentComponentOnAggregation"
* error message.
*
* @param side The side of the fulfillment component that is missing (0 for
* offer, 1 for consideration).
*
*/
function _revertMissingFulfillmentComponentOnAggregation(Side side) pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, MissingFulfillmentComponentOnAggregation_error_selector)
// Store argument.
mstore(MissingFulfillmentComponentOnAggregation_error_side_ptr, side)
// revert(abi.encodeWithSignature(
// "MissingFulfillmentComponentOnAggregation(uint8)",
// side
// ))
revert(
Error_selector_offset,
MissingFulfillmentComponentOnAggregation_error_length
)
}
}
/**
* @dev Reverts execution with a "MissingOriginalConsiderationItems" error
* message.
*/
function _revertMissingOriginalConsiderationItems() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, MissingOriginalConsiderationItems_error_selector)
// revert(abi.encodeWithSignature(
// "MissingOriginalConsiderationItems()"
// ))
revert(
Error_selector_offset,
MissingOriginalConsiderationItems_error_length
)
}
}
/**
* @dev Reverts execution with a "NoReentrantCalls" error message.
*/
function _revertNoReentrantCalls() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, NoReentrantCalls_error_selector)
// revert(abi.encodeWithSignature("NoReentrantCalls()"))
revert(Error_selector_offset, NoReentrantCalls_error_length)
}
}
/**
* @dev Reverts execution with a "NoSpecifiedOrdersAvailable" error message.
*/
function _revertNoSpecifiedOrdersAvailable() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, NoSpecifiedOrdersAvailable_error_selector)
// revert(abi.encodeWithSignature("NoSpecifiedOrdersAvailable()"))
revert(Error_selector_offset, NoSpecifiedOrdersAvailable_error_length)
}
}
/**
* @dev Reverts execution with an "OrderAlreadyFilled" error message.
*
* @param orderHash The hash of the order that has already been filled.
*/
function _revertOrderAlreadyFilled(bytes32 orderHash) pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, OrderAlreadyFilled_error_selector)
// Store argument.
mstore(OrderAlreadyFilled_error_orderHash_ptr, orderHash)
// revert(abi.encodeWithSignature(
// "OrderAlreadyFilled(bytes32)",
// orderHash
// ))
revert(Error_selector_offset, OrderAlreadyFilled_error_length)
}
}
/**
* @dev Reverts execution with an "OrderCriteriaResolverOutOfRange" error
* message.
*
* @param side The side of the criteria that is missing (0 for offer, 1 for
* consideration).
*
*/
function _revertOrderCriteriaResolverOutOfRange(Side side) pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, OrderCriteriaResolverOutOfRange_error_selector)
// Store argument.
mstore(OrderCriteriaResolverOutOfRange_error_side_ptr, side)
// revert(abi.encodeWithSignature(
// "OrderCriteriaResolverOutOfRange(uint8)",
// side
// ))
revert(
Error_selector_offset, OrderCriteriaResolverOutOfRange_error_length
)
}
}
/**
* @dev Reverts execution with an "OrderIsCancelled" error message.
*
* @param orderHash The hash of the order that has already been cancelled.
*/
function _revertOrderIsCancelled(bytes32 orderHash) pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, OrderIsCancelled_error_selector)
// Store argument.
mstore(OrderIsCancelled_error_orderHash_ptr, orderHash)
// revert(abi.encodeWithSignature(
// "OrderIsCancelled(bytes32)",
// orderHash
// ))
revert(Error_selector_offset, OrderIsCancelled_error_length)
}
}
/**
* @dev Reverts execution with an "OrderPartiallyFilled" error message.
*
* @param orderHash The hash of the order that has already been partially
* filled.
*/
function _revertOrderPartiallyFilled(bytes32 orderHash) pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, OrderPartiallyFilled_error_selector)
// Store argument.
mstore(OrderPartiallyFilled_error_orderHash_ptr, orderHash)
// revert(abi.encodeWithSignature(
// "OrderPartiallyFilled(bytes32)",
// orderHash
// ))
revert(Error_selector_offset, OrderPartiallyFilled_error_length)
}
}
/**
* @dev Reverts execution with a "PartialFillsNotEnabledForOrder" error message.
*/
function _revertPartialFillsNotEnabledForOrder() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, PartialFillsNotEnabledForOrder_error_selector)
// revert(abi.encodeWithSignature("PartialFillsNotEnabledForOrder()"))
revert(
Error_selector_offset, PartialFillsNotEnabledForOrder_error_length
)
}
}
/**
* @dev Reverts execution with an "UnusedItemParameters" error message.
*/
function _revertUnusedItemParameters() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, UnusedItemParameters_error_selector)
// revert(abi.encodeWithSignature("UnusedItemParameters()"))
revert(Error_selector_offset, UnusedItemParameters_error_length)
}
}
/**
* @dev Reverts execution with a "ConsiderationLengthNotEqualToTotalOriginal"
* error message.
*/
function _revertConsiderationLengthNotEqualToTotalOriginal() pure {
assembly {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, ConsiderationLengthNotEqualToTotalOriginal_error_selector)
// revert(abi.encodeWithSignature(
// "ConsiderationLengthNotEqualToTotalOriginal()"
// ))
revert(
Error_selector_offset,
ConsiderationLengthNotEqualToTotalOriginal_error_length
)
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
uint256 constant Error_selector_offset = 0x1c;
/*
* error MissingFulfillmentComponentOnAggregation(uint8 side)
* - Defined in FulfillmentApplicationErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: side
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant MissingFulfillmentComponentOnAggregation_error_selector = (
0x375c24c1
);
uint256 constant MissingFulfillmentComponentOnAggregation_error_side_ptr = 0x20;
uint256 constant MissingFulfillmentComponentOnAggregation_error_length = 0x24;
/*
* error OfferAndConsiderationRequiredOnFulfillment()
* - Defined in FulfillmentApplicationErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant OfferAndConsiderationRequiredOnFulfillment_error_selector = (
0x98e9db6e
);
uint256 constant OfferAndConsiderationRequiredOnFulfillment_error_length = 0x04;
/*
* error MismatchedFulfillmentOfferAndConsiderationComponents(
* uint256 fulfillmentIndex
* )
* - Defined in FulfillmentApplicationErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: fulfillmentIndex
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant MismatchedOfferAndConsiderationComponents_error_selector = (
0xbced929d
);
uint256 constant MismatchedOfferAndConsiderationComponents_error_idx_ptr = 0x20;
uint256 constant MismatchedOfferAndConsiderationComponents_error_length = 0x24;
/*
* error InvalidFulfillmentComponentData()
* - Defined in FulfillmentApplicationErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant InvalidFulfillmentComponentData_error_selector = 0x7fda7279;
uint256 constant InvalidFulfillmentComponentData_error_length = 0x04;
/*
* error InexactFraction()
* - Defined in AmountDerivationErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant InexactFraction_error_selector = 0xc63cf089;
uint256 constant InexactFraction_error_length = 0x04;
/*
* error OrderCriteriaResolverOutOfRange(uint8 side)
* - Defined in CriteriaResolutionErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: side
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant OrderCriteriaResolverOutOfRange_error_selector = 0x133c37c6;
uint256 constant OrderCriteriaResolverOutOfRange_error_side_ptr = 0x20;
uint256 constant OrderCriteriaResolverOutOfRange_error_length = 0x24;
/*
* error UnresolvedOfferCriteria(uint256 orderIndex, uint256 offerIndex)
* - Defined in CriteriaResolutionErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: orderIndex
* - 0x40: offerIndex
* Revert buffer is memory[0x1c:0x60]
*/
uint256 constant UnresolvedOfferCriteria_error_selector = 0xd6929332;
uint256 constant UnresolvedOfferCriteria_error_orderIndex_ptr = 0x20;
uint256 constant UnresolvedOfferCriteria_error_offerIndex_ptr = 0x40;
uint256 constant UnresolvedOfferCriteria_error_length = 0x44;
/*
* error UnresolvedConsiderationCriteria(
* uint256 orderIndex,
* uint256 considerationIndex
* )
* - Defined in CriteriaResolutionErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: orderIndex
* - 0x40: considerationIndex
* Revert buffer is memory[0x1c:0x60]
*/
uint256 constant UnresolvedConsiderationCriteria_error_selector = 0xa8930e9a;
uint256 constant UnresolvedConsiderationCriteria_error_orderIndex_ptr = 0x20;
uint256 constant UnresolvedConsiderationCriteria_error_itemIndex_ptr = 0x40;
uint256 constant UnresolvedConsiderationCriteria_error_length = 0x44;
/*
* error OfferCriteriaResolverOutOfRange()
* - Defined in CriteriaResolutionErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant OfferCriteriaResolverOutOfRange_error_selector = 0xbfb3f8ce;
// uint256 constant OfferCriteriaResolverOutOfRange_error_length = 0x04;
/*
* error ConsiderationCriteriaResolverOutOfRange()
* - Defined in CriteriaResolutionErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant ConsiderationCriteriaResolverOutOfRange_error_selector = (
0x6088d7de
);
uint256 constant ConsiderationCriteriaResolverOutOfRange_err_selector = (
0x6088d7de
);
// uint256 constant ConsiderationCriteriaResolverOutOfRange_error_length = 0x04;
/*
* error CriteriaNotEnabledForItem()
* - Defined in CriteriaResolutionErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant CriteriaNotEnabledForItem_error_selector = 0x94eb6af6;
uint256 constant CriteriaNotEnabledForItem_error_length = 0x04;
/*
* error InvalidProof()
* - Defined in CriteriaResolutionErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant InvalidProof_error_selector = 0x09bde339;
uint256 constant InvalidProof_error_length = 0x04;
/*
* error InvalidRestrictedOrder(bytes32 orderHash)
* - Defined in ZoneInteractionErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: orderHash
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant InvalidRestrictedOrder_error_selector = 0xfb5014fc;
uint256 constant InvalidRestrictedOrder_error_orderHash_ptr = 0x20;
uint256 constant InvalidRestrictedOrder_error_length = 0x24;
/*
* error InvalidContractOrder(bytes32 orderHash)
* - Defined in ZoneInteractionErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: orderHash
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant InvalidContractOrder_error_selector = 0x93979285;
uint256 constant InvalidContractOrder_error_orderHash_ptr = 0x20;
uint256 constant InvalidContractOrder_error_length = 0x24;
/*
* error BadSignatureV(uint8 v)
* - Defined in SignatureVerificationErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: v
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant BadSignatureV_error_selector = 0x1f003d0a;
uint256 constant BadSignatureV_error_v_ptr = 0x20;
uint256 constant BadSignatureV_error_length = 0x24;
/*
* error InvalidSigner()
* - Defined in SignatureVerificationErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant InvalidSigner_error_selector = 0x815e1d64;
uint256 constant InvalidSigner_error_length = 0x04;
/*
* error InvalidSignature()
* - Defined in SignatureVerificationErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant InvalidSignature_error_selector = 0x8baa579f;
uint256 constant InvalidSignature_error_length = 0x04;
/*
* error BadContractSignature()
* - Defined in SignatureVerificationErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant BadContractSignature_error_selector = 0x4f7fb80d;
uint256 constant BadContractSignature_error_length = 0x04;
/*
* error InvalidERC721TransferAmount(uint256 amount)
* - Defined in TokenTransferrerErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: amount
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant InvalidERC721TransferAmount_error_selector = 0x69f95827;
uint256 constant InvalidERC721TransferAmount_error_amount_ptr = 0x20;
uint256 constant InvalidERC721TransferAmount_error_length = 0x24;
/*
* error MissingItemAmount()
* - Defined in TokenTransferrerErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant MissingItemAmount_error_selector = 0x91b3e514;
uint256 constant MissingItemAmount_error_length = 0x04;
/*
* error UnusedItemParameters()
* - Defined in TokenTransferrerErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant UnusedItemParameters_error_selector = 0x6ab37ce7;
uint256 constant UnusedItemParameters_error_length = 0x04;
/*
* error NoReentrantCalls()
* - Defined in ReentrancyErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant NoReentrantCalls_error_selector = 0x7fa8a987;
uint256 constant NoReentrantCalls_error_length = 0x04;
/*
* error OrderAlreadyFilled(bytes32 orderHash)
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: orderHash
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant OrderAlreadyFilled_error_selector = 0x10fda3e1;
uint256 constant OrderAlreadyFilled_error_orderHash_ptr = 0x20;
uint256 constant OrderAlreadyFilled_error_length = 0x24;
/*
* error InvalidTime(uint256 startTime, uint256 endTime)
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: startTime
* - 0x40: endTime
* Revert buffer is memory[0x1c:0x60]
*/
uint256 constant InvalidTime_error_selector = 0x21ccfeb7;
uint256 constant InvalidTime_error_startTime_ptr = 0x20;
uint256 constant InvalidTime_error_endTime_ptr = 0x40;
uint256 constant InvalidTime_error_length = 0x44;
/*
* error InvalidConduit(bytes32 conduitKey, address conduit)
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: conduitKey
* - 0x40: conduit
* Revert buffer is memory[0x1c:0x60]
*/
uint256 constant InvalidConduit_error_selector = 0x1cf99b26;
uint256 constant InvalidConduit_error_conduitKey_ptr = 0x20;
uint256 constant InvalidConduit_error_conduit_ptr = 0x40;
uint256 constant InvalidConduit_error_length = 0x44;
/*
* error MissingOriginalConsiderationItems()
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant MissingOriginalConsiderationItems_error_selector = 0x466aa616;
uint256 constant MissingOriginalConsiderationItems_error_length = 0x04;
/*
* error InvalidCallToConduit(address conduit)
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: conduit
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant InvalidCallToConduit_error_selector = 0xd13d53d4;
uint256 constant InvalidCallToConduit_error_conduit_ptr = 0x20;
uint256 constant InvalidCallToConduit_error_length = 0x24;
/*
* error ConsiderationNotMet(
* uint256 orderIndex,
* uint256 considerationIndex,
* uint256 shortfallAmount
* )
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: orderIndex
* - 0x40: considerationIndex
* - 0x60: shortfallAmount
* Revert buffer is memory[0x1c:0x80]
*/
uint256 constant ConsiderationNotMet_error_selector = 0xa5f54208;
uint256 constant ConsiderationNotMet_error_orderIndex_ptr = 0x20;
uint256 constant ConsiderationNotMet_error_considerationIndex_ptr = 0x40;
uint256 constant ConsiderationNotMet_error_shortfallAmount_ptr = 0x60;
uint256 constant ConsiderationNotMet_error_length = 0x64;
/*
* error InsufficientNativeTokensSupplied()
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant InsufficientNativeTokensSupplied_error_selector = 0x8ffff980;
uint256 constant InsufficientNativeTokensSupplied_error_length = 0x04;
/*
* error NativeTokenTransferGenericFailure(address account, uint256 amount)
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: account
* - 0x40: amount
* Revert buffer is memory[0x1c:0x60]
*/
uint256 constant NativeTokenTransferGenericFailure_error_selector = 0xbc806b96;
uint256 constant NativeTokenTransferGenericFailure_error_account_ptr = 0x20;
uint256 constant NativeTokenTransferGenericFailure_error_amount_ptr = 0x40;
uint256 constant NativeTokenTransferGenericFailure_error_length = 0x44;
/*
* error PartialFillsNotEnabledForOrder()
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant PartialFillsNotEnabledForOrder_error_selector = 0xa11b63ff;
uint256 constant PartialFillsNotEnabledForOrder_error_length = 0x04;
/*
* error OrderIsCancelled(bytes32 orderHash)
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: orderHash
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant OrderIsCancelled_error_selector = 0x1a515574;
uint256 constant OrderIsCancelled_error_orderHash_ptr = 0x20;
uint256 constant OrderIsCancelled_error_length = 0x24;
/*
* error OrderPartiallyFilled(bytes32 orderHash)
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: orderHash
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant OrderPartiallyFilled_error_selector = 0xee9e0e63;
uint256 constant OrderPartiallyFilled_error_orderHash_ptr = 0x20;
uint256 constant OrderPartiallyFilled_error_length = 0x24;
/*
* error CannotCancelOrder()
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant CannotCancelOrder_error_selector = 0xfed398fc;
uint256 constant CannotCancelOrder_error_length = 0x04;
/*
* error BadFraction()
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant BadFraction_error_selector = 0x5a052b32;
uint256 constant BadFraction_error_length = 0x04;
/*
* error InvalidMsgValue(uint256 value)
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: value
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant InvalidMsgValue_error_selector = 0xa61be9f0;
uint256 constant InvalidMsgValue_error_value_ptr = 0x20;
uint256 constant InvalidMsgValue_error_length = 0x24;
/*
* error InvalidBasicOrderParameterEncoding()
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant InvalidBasicOrderParameterEncoding_error_selector = 0x39f3e3fd;
uint256 constant InvalidBasicOrderParameterEncoding_error_length = 0x04;
/*
* error NoSpecifiedOrdersAvailable()
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant NoSpecifiedOrdersAvailable_error_selector = 0xd5da9a1b;
uint256 constant NoSpecifiedOrdersAvailable_error_length = 0x04;
/*
* error InvalidNativeOfferItem()
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant InvalidNativeOfferItem_error_selector = 0x12d3f5a3;
uint256 constant InvalidNativeOfferItem_error_length = 0x04;
/*
* error ConsiderationLengthNotEqualToTotalOriginal()
* - Defined in ConsiderationEventsAndErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* Revert buffer is memory[0x1c:0x20]
*/
uint256 constant ConsiderationLengthNotEqualToTotalOriginal_error_selector = (
0x2165628a
);
uint256 constant ConsiderationLengthNotEqualToTotalOriginal_error_length = 0x04;
/*
* error Panic(uint256 code)
* - Built-in Solidity error
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: code
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant Panic_error_selector = 0x4e487b71;
uint256 constant Panic_error_code_ptr = 0x20;
uint256 constant Panic_error_length = 0x24;
uint256 constant Panic_arithmetic = 0x11;
// uint256 constant Panic_resource = 0x41;
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
BasicOrderRouteType,
ItemType,
OrderType
} from "seaport-types/src/lib/ConsiderationEnums.sol";
import {
BasicOrderParameters,
OrderStatus
} from "seaport-types/src/lib/ConsiderationStructs.sol";
import { OrderValidator } from "./OrderValidator.sol";
import {
_revertInsufficientNativeTokensSupplied,
_revertInvalidMsgValue,
_revertInvalidERC721TransferAmount,
_revertUnusedItemParameters
} from "seaport-types/src/lib/ConsiderationErrors.sol";
import {
AccumulatorDisarmed,
AdditionalRecipient_size_shift,
AdditionalRecipient_size,
BasicOrder_additionalRecipients_data_cdPtr,
BasicOrder_addlRecipients_length_cdPtr,
BasicOrder_basicOrderType_cdPtr,
BasicOrder_common_params_size,
BasicOrder_considerationAmount_cdPtr,
BasicOrder_considerationHashesArray_ptr,
BasicOrder_considerationIdentifier_cdPtr,
BasicOrder_considerationItem_endAmount_ptr,
BasicOrder_considerationItem_identifier_ptr,
BasicOrder_considerationItem_itemType_ptr,
BasicOrder_considerationItem_startAmount_ptr,
BasicOrder_considerationItem_token_ptr,
BasicOrder_considerationItem_typeHash_ptr,
BasicOrder_considerationToken_cdPtr,
BasicOrder_endTime_cdPtr,
BasicOrder_fulfillerConduit_cdPtr,
BasicOrder_offerAmount_cdPtr,
BasicOrder_offeredItemByteMap,
BasicOrder_offerer_cdPtr,
BasicOrder_offererConduit_cdPtr,
BasicOrder_offerIdentifier_cdPtr,
BasicOrder_offerItem_endAmount_ptr,
BasicOrder_offerItem_itemType_ptr,
BasicOrder_offerItem_token_ptr,
BasicOrder_offerItem_typeHash_ptr,
BasicOrder_offerToken_cdPtr,
BasicOrder_order_considerationHashes_ptr,
BasicOrder_order_counter_ptr,
BasicOrder_order_offerer_ptr,
BasicOrder_order_offerHashes_ptr,
BasicOrder_order_orderType_ptr,
BasicOrder_order_startTime_ptr,
BasicOrder_order_typeHash_ptr,
BasicOrder_receivedItemByteMap,
BasicOrder_startTime_cdPtr,
BasicOrder_totalOriginalAdditionalRecipients_cdPtr,
BasicOrder_zone_cdPtr,
Common_token_offset,
Conduit_execute_ConduitTransfer_length_ptr,
Conduit_execute_ConduitTransfer_length,
Conduit_execute_ConduitTransfer_offset_ptr,
Conduit_execute_ConduitTransfer_ptr,
Conduit_execute_signature,
Conduit_execute_transferAmount_ptr,
Conduit_execute_transferIdentifier_ptr,
Conduit_execute_transferFrom_ptr,
Conduit_execute_transferItemType_ptr,
Conduit_execute_transferTo_ptr,
Conduit_execute_transferToken_ptr,
EIP712_ConsiderationItem_size,
EIP712_OfferItem_size,
EIP712_Order_size,
FiveWords,
FourWords,
FreeMemoryPointerSlot,
MaskOverLastTwentyBytes,
OneConduitExecute_size,
OneWord,
OneWordShift,
OrderFulfilled_baseOffset,
OrderFulfilled_baseSize,
OrderFulfilled_consideration_body_offset,
OrderFulfilled_consideration_head_offset,
OrderFulfilled_consideration_length_baseOffset,
OrderFulfilled_fulfiller_offset,
OrderFulfilled_offer_body_offset,
OrderFulfilled_offer_head_offset,
OrderFulfilled_offer_length_baseOffset,
OrderFulfilled_offer_length_offset_relativeTo_baseOffset,
OrderFulfilled_offer_itemType_offset_relativeTo_baseOffset,
OrderFulfilled_offer_token_offset_relativeTo_baseOffset,
OrderFulfilled_post_memory_region_reservedBytes,
OrderFulfilled_selector,
ReceivedItem_amount_offset,
ReceivedItem_size,
receivedItemsHash_ptr,
ThreeWords,
TwoWords,
ZeroSlot
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
Error_selector_offset,
InvalidBasicOrderParameterEncoding_error_length,
InvalidBasicOrderParameterEncoding_error_selector,
InvalidTime_error_endTime_ptr,
InvalidTime_error_length,
InvalidTime_error_selector,
InvalidTime_error_startTime_ptr,
MissingOriginalConsiderationItems_error_length,
MissingOriginalConsiderationItems_error_selector,
UnusedItemParameters_error_length,
UnusedItemParameters_error_selector
} from "seaport-types/src/lib/ConsiderationErrorConstants.sol";
import {
CalldataPointer
} from "seaport-types/src/helpers/PointerLibraries.sol";
/**
* @title BasicOrderFulfiller
* @author 0age
* @notice BasicOrderFulfiller contains functionality for fulfilling "basic"
* orders with minimal overhead. See documentation for details on what
* qualifies as a basic order.
*/
contract BasicOrderFulfiller is OrderValidator {
/**
* @dev Derive and set hashes, reference chainId, and associated domain
* separator during deployment.
*
* @param conduitController A contract that deploys conduits, or proxies
* that may optionally be used to transfer approved
* ERC20/721/1155 tokens.
*/
constructor(address conduitController) OrderValidator(conduitController) {}
/**
* @dev Internal function to fulfill an order offering an ERC20, ERC721, or
* ERC1155 item by supplying Ether (or other native tokens), ERC20
* tokens, an ERC721 item, or an ERC1155 item as consideration. Six
* permutations are supported: Native token to ERC721, Native token to
* ERC1155, ERC20 to ERC721, ERC20 to ERC1155, ERC721 to ERC20, and
* ERC1155 to ERC20 (with native tokens supplied as msg.value). For an
* order to be eligible for fulfillment via this method, it must
* contain a single offer item (though that item may have a greater
* amount if the item is not an ERC721). An arbitrary number of
* "additional recipients" may also be supplied which will each receive
* native tokens or ERC20 items from the fulfiller as consideration.
* Refer to the documentation for a more comprehensive summary of how
* to utilize this method and what orders are compatible with it.
*
* @return A boolean indicating whether the order has been fulfilled.
*/
function _validateAndFulfillBasicOrder() internal returns (bool) {
// Declare enums for order type & route to extract from basicOrderType.
BasicOrderRouteType route;
OrderType orderType;
// Declare additional recipient item type to derive from the route type.
ItemType additionalRecipientsItemType;
bytes32 orderHash;
// Utilize assembly to extract the order type and the basic order route.
assembly {
// Read basicOrderType from calldata.
let basicOrderType := calldataload(BasicOrder_basicOrderType_cdPtr)
// Mask all but 2 least-significant bits to derive the order type.
orderType := and(basicOrderType, 3)
// Divide basicOrderType by four to derive the route.
route := shr(2, basicOrderType)
// If route > 1 additionalRecipient items are ERC20 (1) else native
// token (0).
additionalRecipientsItemType := gt(route, 1)
}
{
// Declare temporary variable for enforcing payable status.
bool correctPayableStatus;
// Utilize assembly to compare the route to the callvalue.
assembly {
// route 0 and 1 are payable, otherwise route is not payable.
correctPayableStatus := eq(
additionalRecipientsItemType,
iszero(callvalue())
)
}
// Revert if msg.value has not been supplied as part of payable
// routes or has been supplied as part of non-payable routes.
if (!correctPayableStatus) {
_revertInvalidMsgValue(msg.value);
}
}
// Declare more arguments that will be derived from route and calldata.
address additionalRecipientsToken;
ItemType offeredItemType;
bool offerTypeIsAdditionalRecipientsType;
uint256 callDataPointer;
// Declare scope for received item type to manage stack pressure.
{
ItemType receivedItemType;
// Utilize assembly to retrieve function arguments and cast types.
assembly {
// Check if offered item type == additional recipient item type.
offerTypeIsAdditionalRecipientsType := gt(route, 3)
// If route > 3 additionalRecipientsToken is at 0xc4 else 0x24.
additionalRecipientsToken := calldataload(
add(
BasicOrder_considerationToken_cdPtr,
mul(
offerTypeIsAdditionalRecipientsType,
BasicOrder_common_params_size
)
)
)
// If route > 2, receivedItemType is route - 2. If route is 2,
// the receivedItemType is ERC20 (1). Otherwise, it is native
// token (0).
receivedItemType := byte(route, BasicOrder_receivedItemByteMap)
// If route > 3, offeredItemType is ERC20 (1). Route is 2 or 3,
// offeredItemType = route. Route is 0 or 1, it is route + 2.
offeredItemType := byte(route, BasicOrder_offeredItemByteMap)
}
// Derive & validate order using parameters and update order status.
(orderHash, callDataPointer) = _prepareBasicFulfillmentFromCalldata(
orderType,
receivedItemType,
additionalRecipientsItemType,
additionalRecipientsToken,
offeredItemType
);
}
// Declare conduitKey argument used by transfer functions.
bytes32 conduitKey;
// Utilize assembly to derive conduit (if relevant) based on route.
assembly {
// use offerer conduit for routes 0-3, fulfiller conduit otherwise.
conduitKey := calldataload(
add(
BasicOrder_offererConduit_cdPtr,
shl(OneWordShift, offerTypeIsAdditionalRecipientsType)
)
)
}
// Transfer tokens based on the route.
if (additionalRecipientsItemType == ItemType.NATIVE) {
// Ensure neither consideration token nor identifier are set. Note
// that dirty upper bits in the consideration token will still cause
// this error to be thrown.
assembly {
if or(
calldataload(BasicOrder_considerationToken_cdPtr),
calldataload(BasicOrder_considerationIdentifier_cdPtr)
) {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, UnusedItemParameters_error_selector)
// revert(abi.encodeWithSignature("UnusedItemParameters()"))
revert(
Error_selector_offset,
UnusedItemParameters_error_length
)
}
}
// Transfer the ERC721 or ERC1155 item, bypassing the accumulator.
_transferIndividual721Or1155Item(offeredItemType, conduitKey);
// Transfer native to recipients, return excess to caller & wrap up.
_transferNativeTokensAndFinalize();
} else {
// Initialize an accumulator array. From this point forward, no new
// memory regions can be safely allocated until the accumulator is
// no longer being utilized, as the accumulator operates in an
// open-ended fashion from this memory pointer; existing memory may
// still be accessed and modified, however.
bytes memory accumulator = new bytes(AccumulatorDisarmed);
// Choose transfer method for ERC721 or ERC1155 item based on route.
if (route == BasicOrderRouteType.ERC20_TO_ERC721) {
// Transfer ERC721 to caller using offerer's conduit preference.
_transferERC721(
CalldataPointer
.wrap(BasicOrder_offerToken_cdPtr)
.readAddress(),
CalldataPointer
.wrap(BasicOrder_offerer_cdPtr)
.readAddress(),
msg.sender,
CalldataPointer
.wrap(BasicOrder_offerIdentifier_cdPtr)
.readUint256(),
CalldataPointer
.wrap(BasicOrder_offerAmount_cdPtr)
.readUint256(),
conduitKey,
accumulator
);
} else if (route == BasicOrderRouteType.ERC20_TO_ERC1155) {
// Transfer ERC1155 to caller with offerer's conduit preference.
_transferERC1155(
CalldataPointer
.wrap(BasicOrder_offerToken_cdPtr)
.readAddress(),
CalldataPointer
.wrap(BasicOrder_offerer_cdPtr)
.readAddress(),
msg.sender,
CalldataPointer
.wrap(BasicOrder_offerIdentifier_cdPtr)
.readUint256(),
CalldataPointer
.wrap(BasicOrder_offerAmount_cdPtr)
.readUint256(),
conduitKey,
accumulator
);
} else if (route == BasicOrderRouteType.ERC721_TO_ERC20) {
// Transfer ERC721 to offerer using caller's conduit preference.
_transferERC721(
CalldataPointer
.wrap(BasicOrder_considerationToken_cdPtr)
.readAddress(),
msg.sender,
CalldataPointer
.wrap(BasicOrder_offerer_cdPtr)
.readAddress(),
CalldataPointer
.wrap(BasicOrder_considerationIdentifier_cdPtr)
.readUint256(),
CalldataPointer
.wrap(BasicOrder_considerationAmount_cdPtr)
.readUint256(),
conduitKey,
accumulator
);
} else {
// route == BasicOrderRouteType.ERC1155_TO_ERC20
// Transfer ERC1155 to offerer with caller's conduit preference.
_transferERC1155(
CalldataPointer
.wrap(BasicOrder_considerationToken_cdPtr)
.readAddress(),
msg.sender,
CalldataPointer
.wrap(BasicOrder_offerer_cdPtr)
.readAddress(),
CalldataPointer
.wrap(BasicOrder_considerationIdentifier_cdPtr)
.readUint256(),
CalldataPointer
.wrap(BasicOrder_considerationAmount_cdPtr)
.readUint256(),
conduitKey,
accumulator
);
}
// Transfer ERC20 tokens to all recipients and wrap up.
_transferERC20AndFinalize(
offerTypeIsAdditionalRecipientsType,
accumulator
);
// Trigger any remaining accumulated transfers via call to conduit.
_triggerIfArmed(accumulator);
}
// Determine whether order is restricted and, if so, that it is valid.
_assertRestrictedBasicOrderValidity(
orderHash,
orderType,
callDataPointer
);
// Clear the reentrancy guard.
_clearReentrancyGuard();
return true;
}
/**
* @dev Internal function to prepare fulfillment of a basic order with
* manual calldata and memory access. This calculates the order hash,
* emits an OrderFulfilled event, and asserts basic order validity.
* Note that calldata offsets must be validated as this function
* accesses constant calldata pointers for dynamic types that match
* default ABI encoding, but valid ABI encoding can use arbitrary
* offsets. Checking that the offsets were produced by default encoding
* will ensure that other functions using Solidity's calldata accessors
* (which calculate pointers from the stored offsets) are reading the
* same data as the order hash is derived from. Also note that this
* function accesses memory directly.
*
* @param orderType The order type.
* @param receivedItemType The item type of the initial
* consideration item on the order.
* @param additionalRecipientsItemType The item type of any additional
* consideration item on the order.
* @param additionalRecipientsToken The ERC20 token contract address (if
* applicable) for any additional
* consideration item on the order.
* @param offeredItemType The item type of the offered item on
* the order.
* @return orderHash The calculated order hash.
*/
function _prepareBasicFulfillmentFromCalldata(
OrderType orderType,
ItemType receivedItemType,
ItemType additionalRecipientsItemType,
address additionalRecipientsToken,
ItemType offeredItemType
) internal returns (bytes32 orderHash, uint256 callDataPointer) {
// Ensure this function cannot be triggered during a reentrant call.
_setReentrancyGuard(false); // Native tokens rejected during execution.
// Verify that calldata offsets for all dynamic types were produced by
// default encoding. This ensures that the constants used for calldata
// pointers to dynamic types are the same as those calculated by
// Solidity using their offsets. Also verify that the basic order type
// is within range.
_assertValidBasicOrderParameters();
// Check for invalid time and missing original consideration items.
// Utilize assembly so that constant calldata pointers can be applied.
assembly {
// Ensure current timestamp is between order start time & end time.
if or(
gt(calldataload(BasicOrder_startTime_cdPtr), timestamp()),
iszero(gt(calldataload(BasicOrder_endTime_cdPtr), timestamp()))
) {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InvalidTime_error_selector)
// Store arguments.
mstore(
InvalidTime_error_startTime_ptr,
calldataload(BasicOrder_startTime_cdPtr)
)
mstore(
InvalidTime_error_endTime_ptr,
calldataload(BasicOrder_endTime_cdPtr)
)
// revert(abi.encodeWithSignature(
// "InvalidTime(uint256,uint256)",
// startTime,
// endTime
// ))
revert(Error_selector_offset, InvalidTime_error_length)
}
// Ensure consideration array length isn't less than total original.
if lt(
calldataload(BasicOrder_addlRecipients_length_cdPtr),
calldataload(BasicOrder_totalOriginalAdditionalRecipients_cdPtr)
) {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, MissingOriginalConsiderationItems_error_selector)
// revert(abi.encodeWithSignature(
// "MissingOriginalConsiderationItems()"
// ))
revert(
Error_selector_offset,
MissingOriginalConsiderationItems_error_length
)
}
}
{
/**
* First, handle consideration items. Memory Layout:
* 0x60: final hash of the array of consideration item hashes
* 0x80-0x160: reused space for EIP712 hashing of each item
* - 0x80: ConsiderationItem EIP-712 typehash (constant)
* - 0xa0: itemType
* - 0xc0: token
* - 0xe0: identifier
* - 0x100: startAmount
* - 0x120: endAmount
* - 0x140: recipient
* 0x160-END_ARR: array of consideration item hashes
* - 0x160: primary consideration item EIP712 hash
* - 0x180-END_ARR: additional recipient item EIP712 hashes
* END_ARR: beginning of data for OrderFulfilled event
* - END_ARR + 0x120: length of ReceivedItem array
* - END_ARR + 0x140: beginning of data for first ReceivedItem
* (Note: END_ARR = 0x180 + RECIPIENTS_LENGTH * 0x20)
*/
// Load consideration item typehash from runtime and place on stack.
bytes32 typeHash = _CONSIDERATION_ITEM_TYPEHASH;
// Utilize assembly to enable reuse of memory regions and use
// constant pointers when possible.
assembly {
/*
* 1. Calculate the EIP712 ConsiderationItem hash for the
* primary consideration item of the basic order.
*/
// Write ConsiderationItem type hash and item type to memory.
mstore(BasicOrder_considerationItem_typeHash_ptr, typeHash)
mstore(
BasicOrder_considerationItem_itemType_ptr,
receivedItemType
)
// Copy calldata region with (token, identifier, amount) from
// BasicOrderParameters to ConsiderationItem. The
// considerationAmount is written to startAmount and endAmount
// as basic orders do not have dynamic amounts.
calldatacopy(
BasicOrder_considerationItem_token_ptr,
BasicOrder_considerationToken_cdPtr,
ThreeWords
)
// Copy calldata region with considerationAmount and offerer
// from BasicOrderParameters to endAmount and recipient in
// ConsiderationItem.
calldatacopy(
BasicOrder_considerationItem_endAmount_ptr,
BasicOrder_considerationAmount_cdPtr,
TwoWords
)
// Calculate EIP712 ConsiderationItem hash and store it in the
// array of EIP712 consideration hashes.
mstore(
BasicOrder_considerationHashesArray_ptr,
keccak256(
BasicOrder_considerationItem_typeHash_ptr,
EIP712_ConsiderationItem_size
)
)
/*
* 2. Write a ReceivedItem struct for the primary consideration
* item to the consideration array in OrderFulfilled.
*/
// Get the additional recipients array length from calldata.
// This variable will later be repurposed to track the total
// original additional recipients instead of the total supplied.
let totalAdditionalRecipients := calldataload(
BasicOrder_addlRecipients_length_cdPtr
)
// Calculate pointer to length of OrderFulfilled consideration
// array. Note that this is based on total original additional
// recipients and not the supplied additional recipients, since
// the pointer only needs to be offset based on the size of the
// EIP-712 hashes used to derive the order hash (and the order
// hash does not take tips into account as part of derivation).
let eventConsiderationArrPtr := add(
OrderFulfilled_consideration_length_baseOffset,
shl(
OneWordShift,
calldataload(
BasicOrder_totalOriginalAdditionalRecipients_cdPtr
)
)
)
// Set the length of the consideration array to the number of
// additional recipients, plus one for the primary consideration
// item.
mstore(
eventConsiderationArrPtr,
add(totalAdditionalRecipients, 1)
)
// Overwrite the consideration array pointer so it points to the
// body of the first element
eventConsiderationArrPtr := add(
eventConsiderationArrPtr,
OneWord
)
// Set itemType at start of the ReceivedItem memory region.
mstore(eventConsiderationArrPtr, receivedItemType)
// Copy calldata region (token, identifier, amount & recipient)
// from BasicOrderParameters to ReceivedItem memory.
calldatacopy(
add(eventConsiderationArrPtr, Common_token_offset),
BasicOrder_considerationToken_cdPtr,
FourWords
)
/*
* 3. Calculate EIP712 ConsiderationItem hashes for original
* additional recipients and add a ReceivedItem for each to the
* consideration array in the OrderFulfilled event. The original
* additional recipients are all the consideration items signed
* by the offerer aside from the primary consideration items of
* the order. Uses memory region from 0x80-0x160 as a buffer for
* calculating EIP712 ConsiderationItem hashes.
*/
// Put pointer to consideration hashes array on the stack.
// This will be updated as each additional recipient is hashed
let
considerationHashesPtr
:= BasicOrder_considerationHashesArray_ptr
// Write item type, token, & identifier for additional recipient
// to memory region for hashing EIP712 ConsiderationItem; these
// values will be reused for each recipient.
mstore(
BasicOrder_considerationItem_itemType_ptr,
additionalRecipientsItemType
)
mstore(
BasicOrder_considerationItem_token_ptr,
additionalRecipientsToken
)
mstore(BasicOrder_considerationItem_identifier_ptr, 0)
// Declare a stack variable where all additional recipients will
// be combined to guard against providing dirty upper bits.
let combinedAdditionalRecipients
// Only iterate over the total original additional recipients
// (not the total supplied additional recipients) when deriving
// the order hash.
totalAdditionalRecipients := calldataload(
BasicOrder_totalOriginalAdditionalRecipients_cdPtr
)
let i := 0
for {
} lt(i, totalAdditionalRecipients) {
i := add(i, 1)
} {
/*
* Calculate EIP712 ConsiderationItem hash for recipient.
*/
// Retrieve calldata pointer for additional recipient.
let additionalRecipientCdPtr := add(
BasicOrder_additionalRecipients_data_cdPtr,
mul(AdditionalRecipient_size, i)
)
// Copy startAmount from calldata to the ConsiderationItem
// struct.
calldatacopy(
BasicOrder_considerationItem_startAmount_ptr,
additionalRecipientCdPtr,
OneWord
)
// Copy endAmount and recipient from calldata to the
// ConsiderationItem struct.
calldatacopy(
BasicOrder_considerationItem_endAmount_ptr,
additionalRecipientCdPtr,
AdditionalRecipient_size
)
// Include the recipient as part of combined recipients.
combinedAdditionalRecipients := or(
combinedAdditionalRecipients,
calldataload(add(additionalRecipientCdPtr, OneWord))
)
// Add 1 word to the pointer as part of each loop to reduce
// operations needed to get local offset into the array.
considerationHashesPtr := add(
considerationHashesPtr,
OneWord
)
// Calculate EIP712 ConsiderationItem hash and store it in
// the array of consideration hashes.
mstore(
considerationHashesPtr,
keccak256(
BasicOrder_considerationItem_typeHash_ptr,
EIP712_ConsiderationItem_size
)
)
/*
* Write ReceivedItem to OrderFulfilled data.
*/
// At this point, eventConsiderationArrPtr points to the
// beginning of the ReceivedItem struct of the previous
// element in the array. Increase it by the size of the
// struct to arrive at the pointer for the current element.
eventConsiderationArrPtr := add(
eventConsiderationArrPtr,
ReceivedItem_size
)
// Write itemType to the ReceivedItem struct.
mstore(
eventConsiderationArrPtr,
additionalRecipientsItemType
)
// Write token to the next word of the ReceivedItem struct.
mstore(
add(eventConsiderationArrPtr, OneWord),
additionalRecipientsToken
)
// Copy endAmount & recipient words to ReceivedItem struct.
calldatacopy(
add(
eventConsiderationArrPtr,
ReceivedItem_amount_offset
),
additionalRecipientCdPtr,
TwoWords
)
}
/*
* 4. Hash packed array of ConsiderationItem EIP712 hashes:
* `keccak256(abi.encodePacked(receivedItemHashes))`
* Note that it is set at 0x60 — all other memory begins at
* 0x80. 0x60 is the "zero slot" and will be restored at the end
* of the assembly section and before required by the compiler.
*/
mstore(
receivedItemsHash_ptr,
keccak256(
BasicOrder_considerationHashesArray_ptr,
shl(OneWordShift, add(totalAdditionalRecipients, 1))
)
)
/*
* 5. Add a ReceivedItem for each tip to the consideration array
* in the OrderFulfilled event. The tips are all the
* consideration items that were not signed by the offerer and
* were provided by the fulfiller.
*/
// Overwrite length to length of the additionalRecipients array.
totalAdditionalRecipients := calldataload(
BasicOrder_addlRecipients_length_cdPtr
)
for {
} lt(i, totalAdditionalRecipients) {
i := add(i, 1)
} {
// Retrieve calldata pointer for additional recipient.
let additionalRecipientCdPtr := add(
BasicOrder_additionalRecipients_data_cdPtr,
mul(AdditionalRecipient_size, i)
)
// At this point, eventConsiderationArrPtr points to the
// beginning of the ReceivedItem struct of the previous
// element in the array. Increase it by the size of the
// struct to arrive at the pointer for the current element.
eventConsiderationArrPtr := add(
eventConsiderationArrPtr,
ReceivedItem_size
)
// Write itemType to the ReceivedItem struct.
mstore(
eventConsiderationArrPtr,
additionalRecipientsItemType
)
// Write token to the next word of the ReceivedItem struct.
mstore(
add(eventConsiderationArrPtr, OneWord),
additionalRecipientsToken
)
// Copy endAmount & recipient words to ReceivedItem struct.
calldatacopy(
add(
eventConsiderationArrPtr,
ReceivedItem_amount_offset
),
additionalRecipientCdPtr,
TwoWords
)
// Include the recipient as part of combined recipients.
combinedAdditionalRecipients := or(
combinedAdditionalRecipients,
calldataload(add(additionalRecipientCdPtr, OneWord))
)
}
// Ensure no dirty upper bits on combined additional recipients.
if gt(combinedAdditionalRecipients, MaskOverLastTwentyBytes) {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InvalidBasicOrderParameterEncoding_error_selector)
// revert(abi.encodeWithSignature(
// "InvalidBasicOrderParameterEncoding()"
// ))
revert(
Error_selector_offset,
InvalidBasicOrderParameterEncoding_error_length
)
}
}
}
{
/**
* Next, handle offered items. Memory Layout:
* EIP712 data for OfferItem
* - 0x80: OfferItem EIP-712 typehash (constant)
* - 0xa0: itemType
* - 0xc0: token
* - 0xe0: identifier (reused for offeredItemsHash)
* - 0x100: startAmount
* - 0x120: endAmount
*/
// Place offer item typehash on the stack.
bytes32 typeHash = _OFFER_ITEM_TYPEHASH;
// Utilize assembly to enable reuse of memory regions when possible.
assembly {
/*
* 1. Calculate OfferItem EIP712 hash
*/
// Write the OfferItem typeHash to memory.
mstore(BasicOrder_offerItem_typeHash_ptr, typeHash)
// Write the OfferItem item type to memory.
mstore(BasicOrder_offerItem_itemType_ptr, offeredItemType)
// Copy calldata region with (offerToken, offerIdentifier,
// offerAmount) from OrderParameters to (token, identifier,
// startAmount) in OfferItem struct. The offerAmount is written
// to startAmount and endAmount as basic orders do not have
// dynamic amounts.
calldatacopy(
BasicOrder_offerItem_token_ptr,
BasicOrder_offerToken_cdPtr,
ThreeWords
)
// Copy offerAmount from calldata to endAmount in OfferItem
// struct.
calldatacopy(
BasicOrder_offerItem_endAmount_ptr,
BasicOrder_offerAmount_cdPtr,
OneWord
)
// Compute EIP712 OfferItem hash, write result to scratch space:
// `keccak256(abi.encode(offeredItem))`
mstore(
0,
keccak256(
BasicOrder_offerItem_typeHash_ptr,
EIP712_OfferItem_size
)
)
/*
* 2. Calculate hash of array of EIP712 hashes and write the
* result to the corresponding OfferItem struct:
* `keccak256(abi.encodePacked(offerItemHashes))`
*/
mstore(BasicOrder_order_offerHashes_ptr, keccak256(0, OneWord))
}
}
{
/**
* Once consideration items and offer items have been handled,
* derive the final order hash. Memory Layout:
* 0x80-0x1c0: EIP712 data for order
* - 0x80: Order EIP-712 typehash (constant)
* - 0xa0: orderParameters.offerer
* - 0xc0: orderParameters.zone
* - 0xe0: keccak256(abi.encodePacked(offerHashes))
* - 0x100: keccak256(abi.encodePacked(considerationHashes))
* - 0x120: orderParameters.basicOrderType (% 4 = orderType)
* - 0x140: orderParameters.startTime
* - 0x160: orderParameters.endTime
* - 0x180: orderParameters.zoneHash
* - 0x1a0: orderParameters.salt
* - 0x1c0: orderParameters.conduitKey
* - 0x1e0: _counters[orderParameters.offerer] (from storage)
*/
// Read the offerer from calldata and place on the stack.
address offerer;
assembly {
offerer := calldataload(BasicOrder_offerer_cdPtr)
}
// Read offerer's current counter from storage and place on stack.
uint256 counter = _getCounter(offerer);
// Load order typehash from runtime code and place on stack.
bytes32 typeHash = _ORDER_TYPEHASH;
assembly {
// Set the OrderItem typeHash in memory.
mstore(BasicOrder_order_typeHash_ptr, typeHash)
// Copy offerer and zone from OrderParameters in calldata to the
// Order struct.
calldatacopy(
BasicOrder_order_offerer_ptr,
BasicOrder_offerer_cdPtr,
TwoWords
)
// Copy receivedItemsHash from zero slot to the Order struct.
mstore(
BasicOrder_order_considerationHashes_ptr,
mload(receivedItemsHash_ptr)
)
// Write the supplied orderType to the Order struct.
mstore(BasicOrder_order_orderType_ptr, orderType)
// Copy startTime, endTime, zoneHash, salt & conduit from
// calldata to the Order struct.
calldatacopy(
BasicOrder_order_startTime_ptr,
BasicOrder_startTime_cdPtr,
FiveWords
)
// Write offerer's counter, retrieved from storage, to struct.
mstore(BasicOrder_order_counter_ptr, counter)
// Compute the EIP712 Order hash.
orderHash := keccak256(
BasicOrder_order_typeHash_ptr,
EIP712_Order_size
)
}
}
assembly {
/**
* After the order hash has been derived, emit OrderFulfilled event:
* event OrderFulfilled(
* bytes32 orderHash,
* address indexed offerer,
* address indexed zone,
* address fulfiller,
* SpentItem[] offer,
* > (itemType, token, id, amount)
* ReceivedItem[] consideration
* > (itemType, token, id, amount, recipient)
* )
* topic0 - OrderFulfilled event signature
* topic1 - offerer
* topic2 - zone
* data:
* - 0x00: orderHash
* - 0x20: fulfiller
* - 0x40: offer arr ptr (0x80)
* - 0x60: consideration arr ptr (0x120)
* - 0x80: offer arr len (1)
* - 0xa0: offer.itemType
* - 0xc0: offer.token
* - 0xe0: offer.identifier
* - 0x100: offer.amount
* - 0x120: 1 + recipients.length
* - 0x140: recipient 0
*/
// Derive pointer to start of OrderFulfilled event data.
let eventDataPtr := add(
OrderFulfilled_baseOffset,
shl(
OneWordShift,
calldataload(
BasicOrder_totalOriginalAdditionalRecipients_cdPtr
)
)
)
// Write the order hash to the head of the event's data region.
mstore(eventDataPtr, orderHash)
// Write the fulfiller (i.e. the caller) next for receiver argument.
mstore(add(eventDataPtr, OrderFulfilled_fulfiller_offset), caller())
// Write the SpentItem and ReceivedItem array offsets (constants).
mstore(
// SpentItem array offset
add(eventDataPtr, OrderFulfilled_offer_head_offset),
OrderFulfilled_offer_body_offset
)
mstore(
// ReceivedItem array offset
add(eventDataPtr, OrderFulfilled_consideration_head_offset),
OrderFulfilled_consideration_body_offset
)
// Set a length of 1 for the offer array.
mstore(
add(
eventDataPtr,
OrderFulfilled_offer_length_offset_relativeTo_baseOffset
),
1
)
// Write itemType to the SpentItem struct.
mstore(
add(
eventDataPtr,
OrderFulfilled_offer_itemType_offset_relativeTo_baseOffset
),
offeredItemType
)
// Copy calldata region with (offerToken, offerIdentifier,
// offerAmount) from OrderParameters to (token, identifier,
// amount) in SpentItem struct.
calldatacopy(
add(
eventDataPtr,
OrderFulfilled_offer_token_offset_relativeTo_baseOffset
),
BasicOrder_offerToken_cdPtr,
ThreeWords
)
// Derive total data size including SpentItem and ReceivedItem data.
// SpentItem portion is already included in the baseSize constant,
// as there can only be one element in the array.
let dataSize := add(
OrderFulfilled_baseSize,
mul(
calldataload(BasicOrder_addlRecipients_length_cdPtr),
ReceivedItem_size
)
)
// Emit OrderFulfilled log with three topics (the event signature
// as well as the two indexed arguments, the offerer and the zone).
log3(
// Supply the pointer for event data in memory.
eventDataPtr,
// Supply the size of event data in memory.
dataSize,
// Supply the OrderFulfilled event signature.
OrderFulfilled_selector,
// Supply the first topic (the offerer).
calldataload(BasicOrder_offerer_cdPtr),
// Supply the second topic (the zone).
calldataload(BasicOrder_zone_cdPtr)
)
// Restore the zero slot.
mstore(ZeroSlot, 0)
// Update the free memory pointer so that event data is persisted.
mstore(
FreeMemoryPointerSlot,
add(
eventDataPtr,
// Reserve extra 3 words to be used by `authorizeOrder` and
// `validatateOrder` if pre-post exection hook to the zone
// is required. These 3 memory slots will be used for the
// extra data/context and order hashes of the calldata.
add(
dataSize,
OrderFulfilled_post_memory_region_reservedBytes
)
)
)
}
// Verify the status of the derived order.
OrderStatus storage orderStatus = _validateBasicOrder(orderHash);
// Determine whether order is restricted and, if so, that it is valid.
callDataPointer = _assertRestrictedBasicOrderAuthorization(
orderHash,
orderType
);
// Update the status of the order and mark as fully filled.
_updateBasicOrderStatus(orderStatus);
// Return the derived order hash.
return (orderHash, callDataPointer);
}
/**
* @dev Internal function to transfer an individual ERC721 or ERC1155 item
* from a given originator to a given recipient. The accumulator will
* be bypassed, meaning that this function should be utilized in cases
* where multiple item transfers can be accumulated into a single
* conduit call. Sufficient approvals must be set, either on the
* respective conduit or on this contract. Note that this function may
* only be safely called as part of basic orders, as it assumes a
* specific calldata encoding structure that must first be validated.
*
* @param itemType The type of item to transfer, either ERC721 or ERC1155.
* @param conduitKey A bytes32 value indicating what corresponding conduit,
* if any, to source token approvals from. The zero hash
* signifies that no conduit should be used, with direct
* approvals set on this contract.
*/
function _transferIndividual721Or1155Item(
ItemType itemType,
bytes32 conduitKey
) internal {
// Retrieve token, from, identifier, and amount from calldata using
// fixed calldata offsets based on strict basic parameter encoding.
address token;
address from;
uint256 identifier;
uint256 amount;
assembly {
token := calldataload(BasicOrder_offerToken_cdPtr)
from := calldataload(BasicOrder_offerer_cdPtr)
identifier := calldataload(BasicOrder_offerIdentifier_cdPtr)
amount := calldataload(BasicOrder_offerAmount_cdPtr)
}
// Determine if the transfer is to be performed via a conduit.
if (conduitKey != bytes32(0)) {
// Ensure that the amount is non-zero.
_assertNonZeroAmount(amount);
// Use free memory pointer as calldata offset for the conduit call.
uint256 callDataOffset;
// Utilize assembly to place each argument in free memory.
assembly {
// Retrieve the free memory pointer and use it as the offset.
callDataOffset := mload(FreeMemoryPointerSlot)
// Write ConduitInterface.execute.selector to memory.
mstore(callDataOffset, Conduit_execute_signature)
// Write the offset to the ConduitTransfer array in memory.
mstore(
add(
callDataOffset,
Conduit_execute_ConduitTransfer_offset_ptr
),
Conduit_execute_ConduitTransfer_ptr
)
// Write the length of the ConduitTransfer array to memory.
mstore(
add(
callDataOffset,
Conduit_execute_ConduitTransfer_length_ptr
),
Conduit_execute_ConduitTransfer_length
)
// Write the item type to memory.
mstore(
add(callDataOffset, Conduit_execute_transferItemType_ptr),
itemType
)
// Write the token to memory.
mstore(
add(callDataOffset, Conduit_execute_transferToken_ptr),
token
)
// Write the transfer source to memory.
mstore(
add(callDataOffset, Conduit_execute_transferFrom_ptr),
from
)
// Write the transfer recipient (the caller) to memory.
mstore(
add(callDataOffset, Conduit_execute_transferTo_ptr),
caller()
)
// Write the token identifier to memory.
mstore(
add(callDataOffset, Conduit_execute_transferIdentifier_ptr),
identifier
)
// Write the transfer amount to memory.
mstore(
add(callDataOffset, Conduit_execute_transferAmount_ptr),
amount
)
}
// Perform the call to the conduit.
_callConduitUsingOffsets(
conduitKey,
callDataOffset,
OneConduitExecute_size
);
} else {
// Otherwise, determine whether it is an ERC721 or ERC1155 item.
if (itemType == ItemType.ERC721) {
// Ensure that exactly one 721 item is being transferred.
if (amount != 1) {
_revertInvalidERC721TransferAmount(amount);
}
// Perform transfer to caller via the token contract directly.
_performERC721Transfer(token, from, msg.sender, identifier);
} else {
// Ensure that the amount is non-zero.
_assertNonZeroAmount(amount);
// Perform transfer to caller via the token contract directly.
_performERC1155Transfer(
token,
from,
msg.sender,
identifier,
amount
);
}
}
}
/**
* @dev Internal function to transfer Ether (or other native tokens) to a
* given recipient as part of basic order fulfillment. Note that
* conduits are not utilized for native tokens as the transferred
* amount must be provided as msg.value. Also note that this function
* may only be safely called as part of basic orders, as it assumes a
* specific calldata encoding structure that must first be validated.
*/
function _transferNativeTokensAndFinalize() internal {
// Put native token value supplied by the caller on the stack.
uint256 nativeTokensRemaining = msg.value;
// Retrieve consideration amount, offerer, and total size of additional
// recipients data from calldata using fixed offsets and place on stack.
uint256 amount;
address payable to;
uint256 totalAdditionalRecipientsDataSize;
assembly {
amount := calldataload(BasicOrder_considerationAmount_cdPtr)
to := calldataload(BasicOrder_offerer_cdPtr)
totalAdditionalRecipientsDataSize := shl(
AdditionalRecipient_size_shift,
calldataload(BasicOrder_addlRecipients_length_cdPtr)
)
}
uint256 additionalRecipientAmount;
address payable recipient;
// Skip overflow check as for loop is indexed starting at zero.
unchecked {
// Iterate over additional recipient data by two-word element.
for (
uint256 i = 0;
i < totalAdditionalRecipientsDataSize;
i += AdditionalRecipient_size
) {
assembly {
// Retrieve calldata pointer for additional recipient.
let additionalRecipientCdPtr := add(
BasicOrder_additionalRecipients_data_cdPtr,
i
)
additionalRecipientAmount := calldataload(
additionalRecipientCdPtr
)
recipient := calldataload(
add(OneWord, additionalRecipientCdPtr)
)
}
// Ensure that sufficient native tokens are available.
if (additionalRecipientAmount > nativeTokensRemaining) {
_revertInsufficientNativeTokensSupplied();
}
// Reduce native token value available. Skip underflow check as
// subtracted value is confirmed above as less than remaining.
nativeTokensRemaining -= additionalRecipientAmount;
// Transfer native tokens to the additional recipient.
_transferNativeTokens(recipient, additionalRecipientAmount);
}
}
// Ensure that sufficient native tokens are still available.
if (amount > nativeTokensRemaining) {
_revertInsufficientNativeTokensSupplied();
}
// Transfer native tokens to the offerer.
_transferNativeTokens(to, amount);
// If any native tokens remain after transfers, return to the caller.
if (nativeTokensRemaining > amount) {
// Skip underflow check as nativeTokensRemaining > amount.
unchecked {
// Transfer remaining native tokens to the caller.
_transferNativeTokens(
payable(msg.sender),
nativeTokensRemaining - amount
);
}
}
}
/**
* @dev Internal function to transfer ERC20 tokens to a given recipient as
* part of basic order fulfillment. Note that this function may only be
* safely called as part of basic orders, as it assumes a specific
* calldata encoding structure that must first be validated. Also note
* that basic order parameters are retrieved using fixed offsets, this
* requires that strict basic order encoding has already been verified.
*
* @param fromOfferer A boolean indicating whether to decrement amount from
* the offered amount.
* @param accumulator An open-ended array that collects transfers to execute
* against a given conduit in a single call.
*/
function _transferERC20AndFinalize(
bool fromOfferer,
bytes memory accumulator
) internal {
// Declare from and to variables determined by fromOfferer value.
address from;
address to;
// Declare token and amount variables determined by fromOfferer value.
address token;
uint256 amount;
// Declare and check identifier variable within an isolated scope.
{
// Declare identifier variable determined by fromOfferer value.
uint256 identifier;
// Set ERC20 token transfer variables based on fromOfferer boolean.
if (fromOfferer) {
// Use offerer as from value, msg.sender as to value, and offer
// token, identifier, & amount values if token is from offerer.
assembly {
from := calldataload(BasicOrder_offerer_cdPtr)
to := caller()
token := calldataload(BasicOrder_offerToken_cdPtr)
identifier := calldataload(BasicOrder_offerIdentifier_cdPtr)
amount := calldataload(BasicOrder_offerAmount_cdPtr)
}
} else {
// Otherwise, use msg.sender as from value, offerer as to value,
// and consideration token, identifier, and amount values.
assembly {
from := caller()
to := calldataload(BasicOrder_offerer_cdPtr)
token := calldataload(BasicOrder_considerationToken_cdPtr)
identifier := calldataload(
BasicOrder_considerationIdentifier_cdPtr
)
amount := calldataload(BasicOrder_considerationAmount_cdPtr)
}
}
// Ensure that no identifier is supplied.
if (identifier != 0) {
_revertUnusedItemParameters();
}
}
// Determine the appropriate conduit to utilize.
bytes32 conduitKey;
// Utilize assembly to derive conduit (if relevant) based on route.
assembly {
// Use offerer conduit if fromOfferer, fulfiller conduit otherwise.
conduitKey := calldataload(
sub(
BasicOrder_fulfillerConduit_cdPtr,
shl(OneWordShift, fromOfferer)
)
)
}
// Retrieve total size of additional recipients data and place on stack.
uint256 totalAdditionalRecipientsDataSize;
assembly {
totalAdditionalRecipientsDataSize := shl(
AdditionalRecipient_size_shift,
calldataload(BasicOrder_addlRecipients_length_cdPtr)
)
}
uint256 additionalRecipientAmount;
address recipient;
// Iterate over each additional recipient.
for (uint256 i = 0; i < totalAdditionalRecipientsDataSize; ) {
assembly {
// Retrieve calldata pointer for additional recipient.
let additionalRecipientCdPtr := add(
BasicOrder_additionalRecipients_data_cdPtr,
i
)
additionalRecipientAmount := calldataload(
additionalRecipientCdPtr
)
recipient := calldataload(
add(OneWord, additionalRecipientCdPtr)
)
}
// Decrement the amount to transfer to fulfiller if indicated.
if (fromOfferer) {
amount -= additionalRecipientAmount;
}
// Transfer ERC20 tokens to additional recipient given approval.
_transferERC20(
token,
from,
recipient,
additionalRecipientAmount,
conduitKey,
accumulator
);
// Skip overflow check as for loop is indexed starting at zero.
unchecked {
i += AdditionalRecipient_size;
}
}
// Transfer ERC20 token amount (from account must have proper approval).
_transferERC20(token, from, to, amount, conduitKey, accumulator);
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
ItemType,
OrderType,
Side
} from "seaport-types/src/lib/ConsiderationEnums.sol";
import {
AdvancedOrder,
ConsiderationItem,
CriteriaResolver,
MemoryPointer,
OfferItem,
OrderParameters
} from "seaport-types/src/lib/ConsiderationStructs.sol";
import {
_revertCriteriaNotEnabledForItem,
_revertInvalidProof,
_revertOrderCriteriaResolverOutOfRange
} from "seaport-types/src/lib/ConsiderationErrors.sol";
import {
CriteriaResolutionErrors
} from "seaport-types/src/interfaces/CriteriaResolutionErrors.sol";
import {
OneWord,
OneWordShift,
OrderParameters_consideration_head_offset,
Selector_length,
TwoWords
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
ConsiderationCriteriaResolverOutOfRange_err_selector,
Error_selector_offset,
OfferCriteriaResolverOutOfRange_error_selector,
UnresolvedConsiderationCriteria_error_itemIndex_ptr,
UnresolvedConsiderationCriteria_error_length,
UnresolvedConsiderationCriteria_error_orderIndex_ptr,
UnresolvedConsiderationCriteria_error_selector,
UnresolvedOfferCriteria_error_selector
} from "seaport-types/src/lib/ConsiderationErrorConstants.sol";
/**
* @title CriteriaResolution
* @author 0age
* @notice CriteriaResolution contains a collection of pure functions related to
* resolving criteria-based items.
*/
contract CriteriaResolution is CriteriaResolutionErrors {
/**
* @dev Internal pure function to apply criteria resolvers containing
* specific token identifiers and associated proofs to order items.
*
* @param advancedOrders The orders to apply criteria resolvers to.
* @param criteriaResolvers An array where each element contains a
* reference to a specific order as well as that
* order's offer or consideration, a token
* identifier, and a proof that the supplied token
* identifier is contained in the order's merkle
* root. Note that a root of zero indicates that
* any transferable token identifier is valid and
* that no proof needs to be supplied.
*/
function _applyCriteriaResolvers(
AdvancedOrder[] memory advancedOrders,
CriteriaResolver[] memory criteriaResolvers
) internal pure {
// Skip overflow checks as all for loops are indexed starting at zero.
unchecked {
// Retrieve length of criteria resolvers array and place on stack.
uint256 totalCriteriaResolvers = criteriaResolvers.length;
// Retrieve length of orders array and place on stack.
uint256 totalAdvancedOrders = advancedOrders.length;
// Iterate over each criteria resolver.
for (uint256 i = 0; i < totalCriteriaResolvers; ++i) {
// Retrieve the criteria resolver.
CriteriaResolver memory criteriaResolver = (
criteriaResolvers[i]
);
// Read the order index from memory and place it on the stack.
uint256 orderIndex = criteriaResolver.orderIndex;
// Ensure that the order index is in range.
if (orderIndex >= totalAdvancedOrders) {
_revertOrderCriteriaResolverOutOfRange(
criteriaResolver.side
);
}
// Retrieve the referenced advanced order.
AdvancedOrder memory advancedOrder = advancedOrders[orderIndex];
// Skip criteria resolution for order if not fulfilled.
if (advancedOrder.numerator == 0) {
continue;
}
// Retrieve the parameters for the order.
OrderParameters memory orderParameters = (
advancedOrder.parameters
);
{
// Get a pointer to the list of items to give to
// _updateCriteriaItem. If the resolver refers to a
// consideration item, this array pointer will be replaced
// with the consideration array.
OfferItem[] memory items = orderParameters.offer;
// Read component index from memory and place it on stack.
uint256 componentIndex = criteriaResolver.index;
// Get error selector for `OfferCriteriaResolverOutOfRange`.
uint256 errorSelector = (
OfferCriteriaResolverOutOfRange_error_selector
);
// If the resolver refers to a consideration item...
if (criteriaResolver.side != Side.OFFER) {
// Get the pointer to `orderParameters.consideration`
// Using the array directly has a significant impact on
// the optimized compiler output.
MemoryPointer considerationPtr = orderParameters
.toMemoryPointer()
.pptrOffset(
OrderParameters_consideration_head_offset
);
// Replace the items pointer with a pointer to the
// consideration array.
assembly {
items := considerationPtr
}
// Replace the error selector with the selector for
// `ConsiderationCriteriaResolverOutOfRange`.
errorSelector = (
ConsiderationCriteriaResolverOutOfRange_err_selector
);
}
// Ensure that the component index is in range.
if (componentIndex >= items.length) {
assembly {
// Revert with either
// `OfferCriteriaResolverOutOfRange()` or
// `ConsiderationCriteriaResolverOutOfRange()`,
// depending on whether the resolver refers to a
// consideration item.
mstore(0, errorSelector)
// revert(abi.encodeWithSignature(
// "OfferCriteriaResolverOutOfRange()"
// ))
// or
// revert(abi.encodeWithSignature(
// "ConsiderationCriteriaResolverOutOfRange()"
// ))
revert(Error_selector_offset, Selector_length)
}
}
// Apply the criteria resolver to the item in question.
_updateCriteriaItem(
items,
componentIndex,
criteriaResolver
);
}
}
// Iterate over each advanced order.
for (uint256 i = 0; i < totalAdvancedOrders; ++i) {
// Retrieve the advanced order.
AdvancedOrder memory advancedOrder = advancedOrders[i];
// Skip criteria resolution for order if not fulfilled.
if (advancedOrder.numerator == 0) {
continue;
}
// Retrieve the parameters for the order.
OrderParameters memory orderParameters = (
advancedOrder.parameters
);
OrderType orderType = orderParameters.orderType;
_ensureAllRequiredCriteriaResolved(
i,
orderParameters.consideration,
orderType,
UnresolvedConsiderationCriteria_error_selector
);
_toOfferItemArgumentType(_ensureAllRequiredCriteriaResolved)(
i,
orderParameters.offer,
orderType,
UnresolvedOfferCriteria_error_selector
);
}
}
}
/**
* @dev Internal pure function to examine an array of items and ensure that
* all criteria-based items (with the exception of wildcard items on
* contract orders) have had a criteria resolver successfully applied.
*
* @param orderIndex The index of the order being examined.
* @param items The items to examine. These are consideration items
* in the default case, but offer items are also
* casted to consideration items as required.
* @param orderType The type of order being examined.
* @param revertSelector The selector to use when reverting.
*/
function _ensureAllRequiredCriteriaResolved(
uint256 orderIndex,
ConsiderationItem[] memory items,
OrderType orderType,
uint256 revertSelector
) internal pure {
// Read items array length from memory and place on stack.
uint256 totalItems = items.length;
// Iterate over each item on the order.
for (uint256 i = 0; i < totalItems; ++i) {
ConsiderationItem memory item = items[i];
// Revert if the item is still a criteria item unless the
// order is a contract order and the identifier is 0.
ItemType itemType = item.itemType;
uint256 identifierOrCriteria = item.identifierOrCriteria;
assembly {
if and(
gt(itemType, 3), // Criteria-based item
or(
iszero(eq(orderType, 4)), // not OrderType.CONTRACT
iszero(iszero(identifierOrCriteria)) // not wildcard
)
) {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, revertSelector)
// Store arguments.
mstore(
UnresolvedConsiderationCriteria_error_orderIndex_ptr,
orderIndex
)
mstore(
UnresolvedConsiderationCriteria_error_itemIndex_ptr,
i
)
// Revert with appropriate UnresolvedCriteria error message.
// Unresolved[Offer|Consideration]Criteria(uint256, uint256)
revert(
Error_selector_offset,
UnresolvedConsiderationCriteria_error_length
)
}
}
}
}
/**
* @dev Internal pure function to perform a function cast from a function
* that accepts consideration items to a function that accepts offer
* items, used by _ensureAllRequiredCriteriaResolved to ensure that
* all necessary criteria items have been resolved for an order.
*
* @param inFn The function that accepts consideration items.
* @param outFn The function that accepts offer items.
*/
function _toOfferItemArgumentType(
function(uint256, ConsiderationItem[] memory, OrderType, uint256)
internal
pure inFn
)
internal
pure
returns (
function(uint256, OfferItem[] memory, OrderType, uint256)
internal
pure outFn
)
{
assembly {
outFn := inFn
}
}
/**
* @dev Internal pure function to update a criteria item.
*
* @param offer The offer containing the item to update.
* @param componentIndex The index of the item to update.
* @param criteriaResolver The criteria resolver to use to update the item.
*/
function _updateCriteriaItem(
OfferItem[] memory offer,
uint256 componentIndex,
CriteriaResolver memory criteriaResolver
) internal pure {
// Retrieve relevant item using the component index.
OfferItem memory offerItem = offer[componentIndex];
// Read item type and criteria from memory & place on stack.
ItemType itemType = offerItem.itemType;
// Ensure the specified item type indicates criteria usage.
if (!_isItemWithCriteria(itemType)) {
_revertCriteriaNotEnabledForItem();
}
uint256 identifierOrCriteria = offerItem.identifierOrCriteria;
// If criteria is not 0 (i.e. a collection-wide criteria-based item)...
if (identifierOrCriteria != uint256(0)) {
// Verify identifier inclusion in criteria root using proof.
_verifyProof(
criteriaResolver.identifier,
identifierOrCriteria,
criteriaResolver.criteriaProof
);
} else if (criteriaResolver.criteriaProof.length != 0) {
// Revert if non-empty proof is supplied for a collection-wide item.
_revertInvalidProof();
}
// Update item type to remove criteria usage.
// Use assembly to operate on ItemType enum as a number.
ItemType newItemType;
assembly {
// Item type 4 becomes 2 and item type 5 becomes 3.
newItemType := sub(itemType, 2)
}
offerItem.itemType = newItemType;
// Update identifier w/ supplied identifier.
offerItem.identifierOrCriteria = criteriaResolver.identifier;
}
/**
* @dev Internal pure function to check whether a given item type represents
* a criteria-based ERC721 or ERC1155 item (e.g. an item that can be
* resolved to one of a number of different identifiers at the time of
* order fulfillment).
*
* @param itemType The item type in question.
*
* @return withCriteria A boolean indicating that the item type in question
* represents a criteria-based item.
*/
function _isItemWithCriteria(
ItemType itemType
) internal pure returns (bool withCriteria) {
// ERC721WithCriteria is ItemType 4. ERC1155WithCriteria is ItemType 5.
assembly {
withCriteria := gt(itemType, 3)
}
}
/**
* @dev Internal pure function to ensure that a given element is contained
* in a merkle root via a supplied proof.
*
* @param leaf The element for which to prove inclusion.
* @param root The merkle root that inclusion will be proved against.
* @param proof The merkle proof.
*/
function _verifyProof(
uint256 leaf,
uint256 root,
bytes32[] memory proof
) internal pure {
// Declare a variable that will be used to determine proof validity.
bool isValid;
// Utilize assembly to efficiently verify the proof against the root.
assembly {
// Store the leaf at the beginning of scratch space.
mstore(0, leaf)
// Derive the hash of the leaf to use as the initial proof element.
let computedHash := keccak256(0, OneWord)
// Get memory start location of the first element in proof array.
let data := add(proof, OneWord)
// Iterate over each proof element to compute the root hash.
for {
// Left shift by 5 is equivalent to multiplying by 0x20.
let end := add(data, shl(OneWordShift, mload(proof)))
} lt(data, end) {
// Increment by one word at a time.
data := add(data, OneWord)
} {
// Get the proof element.
let loadedData := mload(data)
// Sort proof elements and place them in scratch space.
// Slot of `computedHash` in scratch space.
// If the condition is true: 0x20, otherwise: 0x00.
let scratch := shl(OneWordShift, gt(computedHash, loadedData))
// Store elements to hash contiguously in scratch space. Scratch
// space is 64 bytes (0x00 - 0x3f) & both elements are 32 bytes.
mstore(scratch, computedHash)
mstore(xor(scratch, OneWord), loadedData)
// Derive the updated hash.
computedHash := keccak256(0, TwoWords)
}
// Compare the final hash to the supplied root.
isValid := eq(computedHash, root)
}
// Revert if computed hash does not equal supplied root.
if (!isValid) {
_revertInvalidProof();
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
AmountDerivationErrors
} from "seaport-types/src/interfaces/AmountDerivationErrors.sol";
import {
Error_selector_offset,
InexactFraction_error_length,
InexactFraction_error_selector
} from "seaport-types/src/lib/ConsiderationErrorConstants.sol";
/**
* @title AmountDeriver
* @author 0age
* @notice AmountDeriver contains view and pure functions related to deriving
* item amounts based on partial fill quantity and on linear
* interpolation based on current time when the start amount and end
* amount differ.
*/
contract AmountDeriver is AmountDerivationErrors {
/**
* @dev Internal view function to derive the current amount of a given item
* based on the current price, the starting price, and the ending
* price. If the start and end prices differ, the current price will be
* interpolated on a linear basis. Note that this function expects that
* the startTime parameter of orderParameters is not greater than the
* current block timestamp and that the endTime parameter is greater
* than the current block timestamp. If this condition is not upheld,
* duration / elapsed / remaining variables will underflow.
*
* @param startAmount The starting amount of the item.
* @param endAmount The ending amount of the item.
* @param startTime The starting time of the order.
* @param endTime The end time of the order.
* @param roundUp A boolean indicating whether the resultant amount
* should be rounded up or down.
*
* @return amount The current amount.
*/
function _locateCurrentAmount(
uint256 startAmount,
uint256 endAmount,
uint256 startTime,
uint256 endTime,
bool roundUp
) internal view returns (uint256 amount) {
// Only modify end amount if it doesn't already equal start amount.
if (startAmount != endAmount) {
// Declare variables to derive in the subsequent unchecked scope.
uint256 duration;
uint256 elapsed;
uint256 remaining;
// Skip underflow checks as startTime <= block.timestamp < endTime.
unchecked {
// Derive the duration for the order and place it on the stack.
duration = endTime - startTime;
// Derive time elapsed since the order started & place on stack.
elapsed = block.timestamp - startTime;
// Derive time remaining until order expires and place on stack.
remaining = duration - elapsed;
}
// Aggregate new amounts weighted by time with rounding factor.
uint256 totalBeforeDivision = ((startAmount * remaining) +
(endAmount * elapsed));
// Use assembly to combine operations and skip divide-by-zero check.
assembly {
// Multiply by iszero(iszero(totalBeforeDivision)) to ensure
// amount is set to zero if totalBeforeDivision is zero,
// as intermediate overflow can occur if it is zero.
amount := mul(
iszero(iszero(totalBeforeDivision)),
// Subtract 1 from the numerator and add 1 to the result
// if roundUp is true to get proper rounding direction.
// Division is performed with no zero check as duration
// cannot be zero as long as startTime < endTime.
add(
div(sub(totalBeforeDivision, roundUp), duration),
roundUp
)
)
}
// Return the current amount.
return amount;
}
// Return the original amount as startAmount == endAmount.
return endAmount;
}
/**
* @dev Internal pure function to return a fraction of a given value and to
* ensure the resultant value does not have any fractional component.
* Note that this function assumes that zero will never be supplied as
* the denominator parameter; invalid / undefined behavior will result
* should a denominator of zero be provided.
*
* @param numerator A value indicating the portion of the order that
* should be filled.
* @param denominator A value indicating the total size of the order. Note
* that this value cannot be equal to zero.
* @param value The value for which to compute the fraction.
*
* @return newValue The value after applying the fraction.
*/
function _getFraction(
uint256 numerator,
uint256 denominator,
uint256 value
) internal pure returns (uint256 newValue) {
// Return value early in cases where the fraction resolves to 1.
if (numerator == denominator) {
return value;
}
// Ensure fraction can be applied to the value with no remainder. Note
// that the denominator cannot be zero.
assembly {
// Ensure new value contains no remainder via mulmod operator.
// Credit to @hrkrshnn + @axic for proposing this optimal solution.
if mulmod(value, numerator, denominator) {
// Store left-padded selector with push4, mem[28:32] = selector
mstore(0, InexactFraction_error_selector)
// revert(abi.encodeWithSignature("InexactFraction()"))
revert(Error_selector_offset, InexactFraction_error_length)
}
}
// Multiply the numerator by the value and ensure no overflow occurs.
uint256 valueTimesNumerator = value * numerator;
// Divide by the denominator (note that denominator cannot be zero).
assembly {
// Perform division without zero check.
newValue := div(valueTimesNumerator, denominator)
}
}
/**
* @dev Internal view function to apply a fraction to a consideration
* or offer item.
*
* @param startAmount The starting amount of the item.
* @param endAmount The ending amount of the item.
* @param numerator A value indicating the portion of the order that
* should be filled.
* @param denominator A value indicating the total size of the order.
* @param startTime The starting time of the order.
* @param endTime The end time of the order.
* @param roundUp A boolean indicating whether the resultant
* amount should be rounded up or down.
*
* @return amount The received item to transfer with the final amount.
*/
function _applyFraction(
uint256 startAmount,
uint256 endAmount,
uint256 numerator,
uint256 denominator,
uint256 startTime,
uint256 endTime,
bool roundUp
) internal view returns (uint256 amount) {
// If start amount equals end amount, apply fraction to end amount.
if (startAmount == endAmount) {
// Apply fraction to end amount.
amount = _getFraction(numerator, denominator, endAmount);
} else {
// Otherwise, apply fraction to both and interpolated final amount.
amount = _locateCurrentAmount(
_getFraction(numerator, denominator, startAmount),
_getFraction(numerator, denominator, endAmount),
startTime,
endTime,
roundUp
);
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
import { Side } from "../lib/ConsiderationEnums.sol";
/**
* @title FulfillmentApplicationErrors
* @author 0age
* @notice FulfillmentApplicationErrors contains errors related to fulfillment
* application and aggregation.
*/
interface FulfillmentApplicationErrors {
/**
* @dev Revert with an error when a fulfillment is provided that does not
* declare at least one component as part of a call to fulfill
* available orders.
*/
error MissingFulfillmentComponentOnAggregation(Side side);
/**
* @dev Revert with an error when a fulfillment is provided that does not
* declare at least one offer component and at least one consideration
* component.
*/
error OfferAndConsiderationRequiredOnFulfillment();
/**
* @dev Revert with an error when the initial offer item named by a
* fulfillment component does not match the type, token, identifier,
* or conduit preference of the initial consideration item.
*
* @param fulfillmentIndex The index of the fulfillment component that
* does not match the initial offer item.
*/
error MismatchedFulfillmentOfferAndConsiderationComponents(
uint256 fulfillmentIndex
);
/**
* @dev Revert with an error when an order or item index are out of range
* or a fulfillment component does not match the type, token,
* identifier, or conduit preference of the initial consideration item.
*/
error InvalidFulfillmentComponentData();
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import { OrderType } from "seaport-types/src/lib/ConsiderationEnums.sol";
import {
AdvancedOrder,
ConsiderationItem,
OfferItem,
Order,
OrderComponents,
OrderParameters,
OrderStatus
} from "seaport-types/src/lib/ConsiderationStructs.sol";
import {
_revertBadFraction,
_revertCannotCancelOrder,
_revertConsiderationLengthNotEqualToTotalOriginal,
_revertInvalidContractOrder,
_revertPartialFillsNotEnabledForOrder
} from "seaport-types/src/lib/ConsiderationErrors.sol";
import { Executor } from "./Executor.sol";
import { ZoneInteraction } from "./ZoneInteraction.sol";
import { MemoryPointer } from "seaport-types/src/helpers/PointerLibraries.sol";
import {
AdvancedOrder_denominator_offset,
AdvancedOrder_numerator_offset,
BasicOrder_basicOrderParameters_cd_offset,
BasicOrder_offerer_cdPtr,
BasicOrder_signature_cdPtr,
Common_amount_offset,
Common_endAmount_offset,
Common_identifier_offset,
Common_token_offset,
ConsiderItem_recipient_offset,
ContractOrder_orderHash_offerer_shift,
MaxUint120,
OrderStatus_filledDenominator_offset,
OrderStatus_filledNumerator_offset,
OrderStatus_ValidatedAndNotCancelled,
OrderStatus_ValidatedAndNotCancelledAndFullyFilled,
ReceivedItem_recipient_offset
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
Error_selector_offset,
Panic_arithmetic,
Panic_error_code_ptr,
Panic_error_length,
Panic_error_selector
} from "seaport-types/src/lib/ConsiderationErrorConstants.sol";
import {
CalldataPointer
} from "seaport-types/src/helpers/PointerLibraries.sol";
/**
* @title OrderValidator
* @author 0age
* @notice OrderValidator contains functionality related to validating orders
* and updating their status.
*/
contract OrderValidator is Executor, ZoneInteraction {
// Track status of each order (validated, cancelled, and fraction filled).
mapping(bytes32 => OrderStatus) private _orderStatus;
// Track nonces for contract offerers.
mapping(address => uint256) internal _contractNonces;
/**
* @dev Derive and set hashes, reference chainId, and associated domain
* separator during deployment.
*
* @param conduitController A contract that deploys conduits, or proxies
* that may optionally be used to transfer approved
* ERC20/721/1155 tokens.
*/
constructor(address conduitController) Executor(conduitController) {}
/**
* @dev Internal function to verify the status of a basic order.
* Note that this function may only be safely called as part of basic
* orders, as it assumes a specific calldata encoding structure that
* must first be validated.
*
* @param orderHash The hash of the order.
*/
function _validateBasicOrder(
bytes32 orderHash
) internal view returns (OrderStatus storage orderStatus) {
// Retrieve offerer directly using fixed calldata offset based on strict
// basic parameter encoding.
address offerer;
assembly {
offerer := calldataload(BasicOrder_offerer_cdPtr)
}
// Retrieve the order status for the given order hash.
orderStatus = _orderStatus[orderHash];
// Ensure order is fillable and is not cancelled.
_verifyOrderStatus(
orderHash,
orderStatus,
true, // Only allow unused orders when fulfilling basic orders.
_runTimeConstantTrue() // Signifies to revert if order is invalid.
);
unchecked {
// If the order is not already validated, verify supplied signature.
if (!orderStatus.isValidated) {
_verifySignature(
offerer,
orderHash,
_toBytesReturnType(_decodeBytes)(
// Wrap the absolute pointer to the order signature as a
// CalldataPointer.
CalldataPointer.wrap(
// Read the relative pointer to the order signature.
CalldataPointer
.wrap(BasicOrder_signature_cdPtr)
.readMaskedUint256() +
// Add the BasicOrderParameters struct offset to
// the relative pointer.
BasicOrder_basicOrderParameters_cd_offset
)
)
);
}
}
}
/**
* @dev Internal function to update the status of a basic order, assuming
* all validation has already been performed.
*
* @param orderStatus A storage pointer referencing the order status.
*/
function _updateBasicOrderStatus(OrderStatus storage orderStatus) internal {
// Utilize assembly to efficiently update the order status.
assembly {
// Update order status as validated, not cancelled, & fully filled.
sstore(
orderStatus.slot,
OrderStatus_ValidatedAndNotCancelledAndFullyFilled
)
}
}
/**
* @dev Internal function to validate an order, determine what portion to
* fill, and update its status. The desired fill amount is supplied as
* a fraction, as is the returned amount to fill.
*
* @param advancedOrder The order to fulfill as well as the fraction to
* fill. Note that all offer and consideration
* amounts must divide with no remainder in order
* for a partial fill to be valid.
* @param revertOnInvalid A boolean indicating whether to revert if the
* order is invalid due to the time or status.
*
* @return orderHash The order hash.
* @return numerator A value indicating the portion of the order that
* will be filled.
* @return denominator A value indicating the total size of the order.
*/
function _validateOrder(
AdvancedOrder memory advancedOrder,
bool revertOnInvalid
)
internal
view
returns (bytes32 orderHash, uint256 numerator, uint256 denominator)
{
// Retrieve the parameters for the order.
OrderParameters memory orderParameters = advancedOrder.parameters;
// Ensure current timestamp falls between order start time and end time.
if (
!_verifyTime(
orderParameters.startTime,
orderParameters.endTime,
revertOnInvalid
)
) {
// Assuming an invalid time and no revert, return zeroed out values.
return (bytes32(0), 0, 0);
}
// Read numerator and denominator from memory and place on the stack.
// Note that overflowed values are masked.
assembly {
numerator := and(
mload(add(advancedOrder, AdvancedOrder_numerator_offset)),
MaxUint120
)
denominator := and(
mload(add(advancedOrder, AdvancedOrder_denominator_offset)),
MaxUint120
)
}
// Declare variable for tracking the validity of the supplied fraction.
bool invalidFraction;
// If the order is a contract order, return the generated order.
if (orderParameters.orderType == OrderType.CONTRACT) {
// Ensure that the numerator and denominator are both equal to 1.
assembly {
// (1 ^ nd =/= 0) => (nd =/= 1) => (n =/= 1) || (d =/= 1)
// It's important that the values are 120-bit masked before
// multiplication is applied. Otherwise, the last implication
// above is not correct (mod 2^256).
invalidFraction := xor(mul(numerator, denominator), 1)
}
// Revert if the supplied numerator and denominator are not valid.
if (invalidFraction) {
_revertBadFraction();
}
// Return a placeholder orderHash and a fill fraction of 1/1.
// The real orderHash will be returned by _getGeneratedOrder.
return (bytes32(uint256(1)), 1, 1);
}
// Ensure numerator does not exceed denominator and is not zero.
assembly {
invalidFraction := or(gt(numerator, denominator), iszero(numerator))
}
// Revert if the supplied numerator and denominator are not valid.
if (invalidFraction) {
_revertBadFraction();
}
// If attempting partial fill (n < d) check order type & ensure support.
if (
_doesNotSupportPartialFills(
orderParameters.orderType,
numerator,
denominator
)
) {
// Revert if partial fill was attempted on an unsupported order.
_revertPartialFillsNotEnabledForOrder();
}
// Retrieve current counter & use it w/ parameters to derive order hash.
orderHash = _assertConsiderationLengthAndGetOrderHash(orderParameters);
// Retrieve the order status using the derived order hash.
OrderStatus storage orderStatus = _orderStatus[orderHash];
// Ensure order is fillable and is not cancelled.
if (
// Allow partially used orders to be filled.
!_verifyOrderStatus(orderHash, orderStatus, false, revertOnInvalid)
) {
// Assuming an invalid order status and no revert, return zero fill.
return (orderHash, 0, 0);
}
// If the order is not already validated, verify the supplied signature.
if (!orderStatus.isValidated) {
_verifySignature(
orderParameters.offerer,
orderHash,
advancedOrder.signature
);
}
// Utilize assembly to determine the fraction to fill and update status.
assembly {
let orderStatusSlot := orderStatus.slot
// Read filled amount as numerator and denominator and put on stack.
let filledNumerator := sload(orderStatusSlot)
let filledDenominator := shr(
OrderStatus_filledDenominator_offset,
filledNumerator
)
// "Loop" until the appropriate fill fraction has been determined.
for {
} 1 {
} {
// If no portion of the order has been filled yet...
if iszero(filledDenominator) {
// fill the full supplied fraction.
filledNumerator := numerator
// Exit the "loop" early.
break
}
// Shift and mask to calculate the current filled numerator.
filledNumerator := and(
shr(OrderStatus_filledNumerator_offset, filledNumerator),
MaxUint120
)
// If denominator of 1 supplied, fill entire remaining amount.
if eq(denominator, 1) {
// Set the amount to fill to the remaining amount.
numerator := sub(filledDenominator, filledNumerator)
// Set the fill size to the current size.
denominator := filledDenominator
// Exit the "loop" early.
break
}
// If supplied denominator is equal to the current one:
if eq(denominator, filledDenominator) {
// Increment the filled numerator by the new numerator.
filledNumerator := add(numerator, filledNumerator)
// Once adjusted, if current + supplied numerator exceeds
// the denominator:
let carry := mul(
sub(filledNumerator, denominator),
gt(filledNumerator, denominator)
)
// reduce the amount to fill by the excess.
numerator := sub(numerator, carry)
// Exit the "loop" early.
break
}
// Otherwise, if supplied denominator differs from current one:
// Scale the filled amount up by the supplied size.
filledNumerator := mul(filledNumerator, denominator)
// Scale the supplied amount and size up by the current size.
numerator := mul(numerator, filledDenominator)
denominator := mul(denominator, filledDenominator)
// Increment the filled numerator by the new numerator.
filledNumerator := add(numerator, filledNumerator)
// Once adjusted, if current + supplied numerator exceeds
// denominator:
let carry := mul(
sub(filledNumerator, denominator),
gt(filledNumerator, denominator)
)
// reduce the amount to fill by the excess.
numerator := sub(numerator, carry)
// Reduce the filled amount by the excess as well.
filledNumerator := sub(filledNumerator, carry)
// Check denominator for uint120 overflow.
if gt(denominator, MaxUint120) {
// Derive greatest common divisor using euclidean algorithm.
function gcd(_a, _b) -> out {
// "Loop" until only one non-zero value remains.
for {
} _b {
} {
// Assign the second value to a temporary variable.
let _c := _b
// Derive the modulus of the two values.
_b := mod(_a, _c)
// Set the first value to the temporary value.
_a := _c
}
// Return the remaining non-zero value.
out := _a
}
// Determine the amount to scale down the fill fractions.
let scaleDown := gcd(
numerator,
gcd(filledNumerator, denominator)
)
// Ensure that the divisor is at least one.
let safeScaleDown := add(scaleDown, iszero(scaleDown))
// Scale fractional values down by gcd.
numerator := div(numerator, safeScaleDown)
denominator := div(denominator, safeScaleDown)
// Perform the overflow check a second time.
if gt(denominator, MaxUint120) {
// Store the Panic error signature.
mstore(0, Panic_error_selector)
// Store the arithmetic (0x11) panic code.
mstore(Panic_error_code_ptr, Panic_arithmetic)
// revert(abi.encodeWithSignature(
// "Panic(uint256)", 0x11
// ))
revert(Error_selector_offset, Panic_error_length)
}
}
// Exit the "loop" now that all evaluation is complete.
break
}
}
}
/**
* @dev Internal function to update the status of an order by applying the
* supplied fill fraction to the remaining order fraction. If
* revertOnInvalid is true, the function will revert if the order is
* unavailable or if it is not possible to apply the supplied fill
* fraction to the remaining amount (e.g., if there is not enough
* of the order remaining to fill the supplied fraction, or if the
* fractions cannot be represented by two uint120 values).
*
* @param orderHash The hash of the order.
* @param numerator The numerator of the fraction filled to write to
* the order status.
* @param denominator The denominator of the fraction filled to write to
* the order status.
* @param revertOnInvalid Whether to revert if an order is already filled.
*/
function _updateStatus(
bytes32 orderHash,
uint256 numerator,
uint256 denominator,
bool revertOnInvalid
) internal returns (bool) {
// Retrieve the order status using the derived order hash.
OrderStatus storage orderStatus = _orderStatus[orderHash];
bool hasCarry = false;
uint256 orderStatusSlot;
uint256 filledNumerator;
// Utilize assembly to determine the fraction to fill and update status.
assembly {
orderStatusSlot := orderStatus.slot
// Read filled amount as numerator and denominator and put on stack.
filledNumerator := sload(orderStatusSlot)
let filledDenominator := shr(
OrderStatus_filledDenominator_offset,
filledNumerator
)
// "Loop" until the appropriate fill fraction has been determined.
for {
} 1 {
} {
// If no portion of the order has been filled yet...
if iszero(filledDenominator) {
// fill the full supplied fraction.
filledNumerator := numerator
// Exit the "loop" early.
break
}
// Shift and mask to calculate the current filled numerator.
filledNumerator := and(
shr(OrderStatus_filledNumerator_offset, filledNumerator),
MaxUint120
)
// If supplied denominator is equal to the current one:
if eq(denominator, filledDenominator) {
// Increment the filled numerator by the new numerator.
filledNumerator := add(numerator, filledNumerator)
hasCarry := gt(filledNumerator, denominator)
// Exit the "loop" early.
break
}
// Otherwise, if supplied denominator differs from current one:
// Scale the filled amount up by the supplied size.
filledNumerator := mul(filledNumerator, denominator)
// Scale the supplied amount and size up by the current size.
numerator := mul(numerator, filledDenominator)
denominator := mul(denominator, filledDenominator)
// Increment the filled numerator by the new numerator.
filledNumerator := add(numerator, filledNumerator)
hasCarry := gt(filledNumerator, denominator)
// Check filledNumerator and denominator for uint120 overflow.
if or(
gt(filledNumerator, MaxUint120),
gt(denominator, MaxUint120)
) {
// Derive greatest common divisor using euclidean algorithm.
function gcd(_a, _b) -> out {
// "Loop" until only one non-zero value remains.
for {
} _b {
} {
// Assign the second value to a temporary variable.
let _c := _b
// Derive the modulus of the two values.
_b := mod(_a, _c)
// Set the first value to the temporary value.
_a := _c
}
// Return the remaining non-zero value.
out := _a
}
// Determine amount to scale down the new filled fraction.
let scaleDown := gcd(filledNumerator, denominator)
// Ensure that the divisor is at least one.
let safeScaleDown := add(scaleDown, iszero(scaleDown))
// Scale new filled fractional values down by gcd.
filledNumerator := div(filledNumerator, safeScaleDown)
denominator := div(denominator, safeScaleDown)
// Perform the overflow check a second time.
if or(
gt(filledNumerator, MaxUint120),
gt(denominator, MaxUint120)
) {
// Store the Panic error signature.
mstore(0, Panic_error_selector)
// Store the arithmetic (0x11) panic code.
mstore(Panic_error_code_ptr, Panic_arithmetic)
// revert(abi.encodeWithSignature(
// "Panic(uint256)", 0x11
// ))
revert(Error_selector_offset, Panic_error_length)
}
}
// Exit the "loop" now that all evaluation is complete.
break
}
}
if (hasCarry) {
if (revertOnInvalid) {
revert OrderAlreadyFilled(orderHash);
} else {
return false;
}
}
assembly {
// Update order status and fill amount, packing struct values.
// [denominator: 15 bytes] [numerator: 15 bytes]
// [isCancelled: 1 byte] [isValidated: 1 byte]
sstore(
orderStatusSlot,
or(
OrderStatus_ValidatedAndNotCancelled,
or(
shl(
OrderStatus_filledNumerator_offset,
filledNumerator
),
shl(OrderStatus_filledDenominator_offset, denominator)
)
)
)
}
return true;
}
/**
* @dev Internal function to generate a contract order. When a
* collection-wide criteria-based item (criteria = 0) is provided as an
* input to a contract order, the contract offerer has full latitude to
* choose any identifier it wants mid-flight, which differs from the
* usual behavior. For regular criteria-based orders with
* identifierOrCriteria = 0, the fulfiller can pick which identifier to
* receive by providing a CriteriaResolver. For contract offers with
* identifierOrCriteria = 0, Seaport does not expect a corresponding
* CriteriaResolver, and will revert if one is provided.
*
* @param orderParameters The parameters for the order.
* @param context The context for generating the order.
* @param revertOnInvalid Whether to revert on invalid input.
*
* @return orderHash The order hash.
*/
function _getGeneratedOrder(
OrderParameters memory orderParameters,
bytes memory context,
bool revertOnInvalid
) internal returns (bytes32 orderHash) {
// Ensure that consideration array length is equal to the total original
// consideration items value.
if (
orderParameters.consideration.length !=
orderParameters.totalOriginalConsiderationItems
) {
_revertConsiderationLengthNotEqualToTotalOriginal();
}
{
address offerer = orderParameters.offerer;
bool success;
(MemoryPointer cdPtr, uint256 size) = _encodeGenerateOrder(
orderParameters,
context
);
assembly {
success := call(gas(), offerer, 0, cdPtr, size, 0, 0)
}
{
// Note: overflow impossible; nonce can't increment that high.
uint256 contractNonce;
unchecked {
// Note: nonce will be incremented even for skipped orders,
// and even if generateOrder's return data does not satisfy
// all the constraints. This is the case when errorBuffer
// != 0 and revertOnInvalid == false.
contractNonce = _contractNonces[offerer]++;
}
assembly {
// Shift offerer address up 96 bytes and combine with nonce.
orderHash := xor(
contractNonce,
shl(ContractOrder_orderHash_offerer_shift, offerer)
)
}
}
// Revert or skip if the call to generate the contract order failed.
if (!success) {
if (revertOnInvalid) {
_revertWithReasonIfOneIsReturned();
_revertInvalidContractOrder(orderHash);
}
return bytes32(0);
}
}
// From this point onward, do not allow for skipping orders as the
// contract offerer may have modified state in expectation of any named
// consideration items being sent to their designated recipients.
// Decode the returned contract order and/or update the error buffer.
(
uint256 errorBuffer,
OfferItem[] memory offer,
ConsiderationItem[] memory consideration
) = _convertGetGeneratedOrderResult(_decodeGenerateOrderReturndata)(
orderParameters.offer,
orderParameters.consideration
);
// Revert if the returndata could not be decoded correctly.
if (errorBuffer != 0) {
_revertInvalidContractOrder(orderHash);
}
// Assign the returned offer item in place of the original item.
orderParameters.offer = offer;
// Assign returned consideration item in place of the original item.
orderParameters.consideration = consideration;
// Return the order hash.
return orderHash;
}
/**
* @dev Internal function to cancel an arbitrary number of orders. Note that
* only the offerer or the zone of a given order may cancel it. Callers
* should ensure that the intended order was cancelled by calling
* `getOrderStatus` and confirming that `isCancelled` returns `true`.
* Also note that contract orders are not cancellable.
*
* @param orders The orders to cancel.
*
* @return cancelled A boolean indicating whether the supplied orders were
* successfully cancelled.
*/
function _cancel(
OrderComponents[] calldata orders
) internal returns (bool cancelled) {
// Ensure that the reentrancy guard is not currently set.
_assertNonReentrant();
// Declare variables outside of the loop.
OrderStatus storage orderStatus;
// Declare a variable for tracking invariants in the loop.
bool anyInvalidCallerOrContractOrder;
// Skip overflow check as for loop is indexed starting at zero.
unchecked {
// Read length of the orders array from memory and place on stack.
uint256 totalOrders = orders.length;
// Iterate over each order.
for (uint256 i = 0; i < totalOrders; ) {
// Retrieve the order.
OrderComponents calldata order = orders[i];
address offerer = order.offerer;
address zone = order.zone;
OrderType orderType = order.orderType;
assembly {
// If caller is neither the offerer nor zone, or a contract
// order is present, flag anyInvalidCallerOrContractOrder.
anyInvalidCallerOrContractOrder := or(
anyInvalidCallerOrContractOrder,
// orderType == CONTRACT ||
// !(caller == offerer || caller == zone)
or(
eq(orderType, 4),
iszero(
or(eq(caller(), offerer), eq(caller(), zone))
)
)
)
}
bytes32 orderHash = _deriveOrderHash(
_toOrderParametersReturnType(
_decodeOrderComponentsAsOrderParameters
)(order.toCalldataPointer()),
order.counter
);
// Retrieve the order status using the derived order hash.
orderStatus = _orderStatus[orderHash];
// Update the order status as not valid and cancelled.
orderStatus.isValidated = false;
orderStatus.isCancelled = true;
// Emit an event signifying that the order has been cancelled.
emit OrderCancelled(orderHash, offerer, zone);
// Increment counter inside body of loop for gas efficiency.
++i;
}
}
if (anyInvalidCallerOrContractOrder) {
_revertCannotCancelOrder();
}
// Return a boolean indicating that orders were successfully cancelled.
cancelled = true;
}
/**
* @dev Internal function to validate an arbitrary number of orders, thereby
* registering their signatures as valid and allowing the fulfiller to
* skip signature verification on fulfillment. Note that validated
* orders may still be unfulfillable due to invalid item amounts or
* other factors; callers should determine whether validated orders are
* fulfillable by simulating the fulfillment call prior to execution.
* Also note that anyone can validate a signed order, but only the
* offerer can validate an order without supplying a signature.
*
* @param orders The orders to validate.
*
* @return validated A boolean indicating whether the supplied orders were
* successfully validated.
*/
function _validate(
Order[] memory orders
) internal returns (bool validated) {
// Ensure that the reentrancy guard is not currently set.
_assertNonReentrant();
// Declare variables outside of the loop.
OrderStatus storage orderStatus;
bytes32 orderHash;
address offerer;
// Skip overflow check as for loop is indexed starting at zero.
unchecked {
// Read length of the orders array from memory and place on stack.
uint256 totalOrders = orders.length;
// Iterate over each order.
for (uint256 i = 0; i < totalOrders; ++i) {
// Retrieve the order.
Order memory order = orders[i];
// Retrieve the order parameters.
OrderParameters memory orderParameters = order.parameters;
// Skip contract orders.
if (orderParameters.orderType == OrderType.CONTRACT) {
continue;
}
// Move offerer from memory to the stack.
offerer = orderParameters.offerer;
// Get current counter & use it w/ params to derive order hash.
orderHash = _assertConsiderationLengthAndGetOrderHash(
orderParameters
);
// Retrieve the order status using the derived order hash.
orderStatus = _orderStatus[orderHash];
// Ensure order is fillable and retrieve the filled amount.
_verifyOrderStatus(
orderHash,
orderStatus,
false, // Signifies that partially filled orders are valid.
_runTimeConstantTrue() // Revert if order is invalid.
);
// If the order has not already been validated...
if (!orderStatus.isValidated) {
// Ensure that consideration array length is equal to the
// total original consideration items value.
if (
orderParameters.consideration.length !=
orderParameters.totalOriginalConsiderationItems
) {
_revertConsiderationLengthNotEqualToTotalOriginal();
}
// Verify the supplied signature.
_verifySignature(offerer, orderHash, order.signature);
// Update order status to mark the order as valid.
orderStatus.isValidated = true;
// Emit an event signifying the order has been validated.
emit OrderValidated(orderHash, orderParameters);
}
}
}
// Return a boolean indicating that orders were successfully validated.
validated = true;
}
/**
* @dev Internal view function to retrieve the status of a given order by
* hash, including whether the order has been cancelled or validated
* and the fraction of the order that has been filled.
*
* @param orderHash The order hash in question.
*
* @return isValidated A boolean indicating whether the order in question
* has been validated (i.e. previously approved or
* partially filled).
* @return isCancelled A boolean indicating whether the order in question
* has been cancelled.
* @return totalFilled The total portion of the order that has been filled
* (i.e. the "numerator").
* @return totalSize The total size of the order that is either filled or
* unfilled (i.e. the "denominator").
*/
function _getOrderStatus(
bytes32 orderHash
)
internal
view
returns (
bool isValidated,
bool isCancelled,
uint256 totalFilled,
uint256 totalSize
)
{
// Retrieve the order status using the order hash.
OrderStatus storage orderStatus = _orderStatus[orderHash];
// Return the fields on the order status.
return (
orderStatus.isValidated,
orderStatus.isCancelled,
orderStatus.numerator,
orderStatus.denominator
);
}
/**
* @dev Internal pure function to check whether a given order type indicates
* that partial fills are not supported (e.g. only "full fills" are
* allowed for the order in question).
*
* @param orderType The order type in question.
* @param numerator The numerator in question.
* @param denominator The denominator in question.
*
* @return isFullOrder A boolean indicating whether the order type only
* supports full fills.
*/
function _doesNotSupportPartialFills(
OrderType orderType,
uint256 numerator,
uint256 denominator
) internal pure returns (bool isFullOrder) {
// The "full" order types are even, while "partial" order types are odd.
// Bitwise and by 1 is equivalent to modulo by 2, but 2 gas cheaper. The
// check is only necessary if numerator is less than denominator.
assembly {
// Equivalent to `uint256(orderType) & 1 == 0`.
isFullOrder := and(
lt(numerator, denominator),
iszero(and(orderType, 1))
)
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
import { Side } from "../lib/ConsiderationEnums.sol";
/**
* @title CriteriaResolutionErrors
* @author 0age
* @notice CriteriaResolutionErrors contains all errors related to criteria
* resolution.
*/
interface CriteriaResolutionErrors {
/**
* @dev Revert with an error when providing a criteria resolver that refers
* to an order that has not been supplied.
*
* @param side The side of the order that was not supplied.
*/
error OrderCriteriaResolverOutOfRange(Side side);
/**
* @dev Revert with an error if an offer item still has unresolved criteria
* after applying all criteria resolvers.
*
* @param orderIndex The index of the order that contains the offer item.
* @param offerIndex The index of the offer item that still has unresolved
* criteria.
*/
error UnresolvedOfferCriteria(uint256 orderIndex, uint256 offerIndex);
/**
* @dev Revert with an error if a consideration item still has unresolved
* criteria after applying all criteria resolvers.
*
* @param orderIndex The index of the order that contains the
* consideration item.
* @param considerationIndex The index of the consideration item that still
* has unresolved criteria.
*/
error UnresolvedConsiderationCriteria(
uint256 orderIndex,
uint256 considerationIndex
);
/**
* @dev Revert with an error when providing a criteria resolver that refers
* to an order with an offer item that has not been supplied.
*/
error OfferCriteriaResolverOutOfRange();
/**
* @dev Revert with an error when providing a criteria resolver that refers
* to an order with a consideration item that has not been supplied.
*/
error ConsiderationCriteriaResolverOutOfRange();
/**
* @dev Revert with an error when providing a criteria resolver that refers
* to an order with an item that does not expect a criteria to be
* resolved.
*/
error CriteriaNotEnabledForItem();
/**
* @dev Revert with an error when providing a criteria resolver that
* contains an invalid proof with respect to the given item and
* chosen identifier.
*/
error InvalidProof();
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
/**
* @title AmountDerivationErrors
* @author 0age
* @notice AmountDerivationErrors contains errors related to amount derivation.
*/
interface AmountDerivationErrors {
/**
* @dev Revert with an error when attempting to apply a fraction as part of
* a partial fill that does not divide the target amount cleanly.
*/
error InexactFraction();
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
ConduitInterface
} from "seaport-types/src/interfaces/ConduitInterface.sol";
import {
ConduitItemType
} from "seaport-types/src/conduit/lib/ConduitEnums.sol";
import { ItemType } from "seaport-types/src/lib/ConsiderationEnums.sol";
import { ReceivedItem } from "seaport-types/src/lib/ConsiderationStructs.sol";
import { Verifiers } from "./Verifiers.sol";
import { TokenTransferrer } from "./TokenTransferrer.sol";
import {
Accumulator_array_length_ptr,
Accumulator_array_offset_ptr,
Accumulator_array_offset,
Accumulator_conduitKey_ptr,
Accumulator_itemSizeOffsetDifference,
Accumulator_selector_ptr,
AccumulatorArmed,
AccumulatorDisarmed,
Conduit_transferItem_amount_ptr,
Conduit_transferItem_from_ptr,
Conduit_transferItem_identifier_ptr,
Conduit_transferItem_size,
Conduit_transferItem_to_ptr,
Conduit_transferItem_token_ptr,
FreeMemoryPointerSlot,
OneWord,
TwoWords
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
Error_selector_offset,
NativeTokenTransferGenericFailure_error_account_ptr,
NativeTokenTransferGenericFailure_error_amount_ptr,
NativeTokenTransferGenericFailure_error_length,
NativeTokenTransferGenericFailure_error_selector
} from "seaport-types/src/lib/ConsiderationErrorConstants.sol";
import {
_revertInvalidCallToConduit,
_revertInvalidConduit,
_revertInvalidERC721TransferAmount,
_revertUnusedItemParameters
} from "seaport-types/src/lib/ConsiderationErrors.sol";
/**
* @title Executor
* @author 0age
* @notice Executor contains functions related to processing executions (i.e.
* transferring items, either directly or via conduits).
*/
contract Executor is Verifiers, TokenTransferrer {
/**
* @dev Derive and set hashes, reference chainId, and associated domain
* separator during deployment.
*
* @param conduitController A contract that deploys conduits, or proxies
* that may optionally be used to transfer approved
* ERC20/721/1155 tokens.
*/
constructor(address conduitController) Verifiers(conduitController) {}
/**
* @dev Internal function to transfer a given item, either directly or via
* a corresponding conduit.
*
* @param item The item to transfer, including an amount and a
* recipient.
* @param from The account supplying the item.
* @param conduitKey A bytes32 value indicating what corresponding conduit,
* if any, to source token approvals from. The zero hash
* signifies that no conduit should be used, with direct
* approvals set on this contract.
* @param accumulator An open-ended array that collects transfers to execute
* against a given conduit in a single call.
*/
function _transfer(
ReceivedItem memory item,
address from,
bytes32 conduitKey,
bytes memory accumulator
) internal {
// If the item type indicates Ether or a native token...
if (item.itemType == ItemType.NATIVE) {
// Ensure neither the token nor the identifier parameters are set.
if ((uint160(item.token) | item.identifier) != 0) {
_revertUnusedItemParameters();
}
// transfer the native tokens to the recipient.
_transferNativeTokens(item.recipient, item.amount);
} else if (item.itemType == ItemType.ERC20) {
// Ensure that no identifier is supplied.
if (item.identifier != 0) {
_revertUnusedItemParameters();
}
// Transfer ERC20 tokens from the source to the recipient.
_transferERC20(
item.token,
from,
item.recipient,
item.amount,
conduitKey,
accumulator
);
} else if (item.itemType == ItemType.ERC721) {
// Transfer ERC721 token from the source to the recipient.
_transferERC721(
item.token,
from,
item.recipient,
item.identifier,
item.amount,
conduitKey,
accumulator
);
} else {
// Transfer ERC1155 token from the source to the recipient.
_transferERC1155(
item.token,
from,
item.recipient,
item.identifier,
item.amount,
conduitKey,
accumulator
);
}
}
/**
* @dev Internal function to transfer Ether or other native tokens to a
* given recipient.
*
* @param to The recipient of the transfer.
* @param amount The amount to transfer.
*/
function _transferNativeTokens(
address payable to,
uint256 amount
) internal {
// Ensure that the supplied amount is non-zero.
_assertNonZeroAmount(amount);
// Declare a variable indicating whether the call was successful or not.
bool success;
assembly {
// Transfer the native token and store if it succeeded or not.
success := call(gas(), to, amount, 0, 0, 0, 0)
}
// If the call fails...
if (!success) {
// Revert and pass the revert reason along if one was returned.
_revertWithReasonIfOneIsReturned();
// Otherwise, revert with a generic error message.
assembly {
// Store left-padded selector with push4, mem[28:32] = selector
mstore(0, NativeTokenTransferGenericFailure_error_selector)
// Write `to` and `amount` arguments.
mstore(NativeTokenTransferGenericFailure_error_account_ptr, to)
mstore(
NativeTokenTransferGenericFailure_error_amount_ptr,
amount
)
// revert(abi.encodeWithSignature(
// "NativeTokenTransferGenericFailure(address,uint256)",
// to,
// amount
// ))
revert(
Error_selector_offset,
NativeTokenTransferGenericFailure_error_length
)
}
}
}
/**
* @dev Internal function to transfer ERC20 tokens from a given originator
* to a given recipient using a given conduit if applicable. Sufficient
* approvals must be set on this contract or on a respective conduit.
*
* @param token The ERC20 token to transfer.
* @param from The originator of the transfer.
* @param to The recipient of the transfer.
* @param amount The amount to transfer.
* @param conduitKey A bytes32 value indicating what corresponding conduit,
* if any, to source token approvals from. The zero hash
* signifies that no conduit should be used, with direct
* approvals set on this contract.
* @param accumulator An open-ended array that collects transfers to execute
* against a given conduit in a single call.
*/
function _transferERC20(
address token,
address from,
address to,
uint256 amount,
bytes32 conduitKey,
bytes memory accumulator
) internal {
// Ensure that the supplied amount is non-zero.
_assertNonZeroAmount(amount);
// Trigger accumulated transfers if the conduits differ.
_triggerIfArmedAndNotAccumulatable(accumulator, conduitKey);
// If no conduit has been specified...
if (conduitKey == bytes32(0)) {
// Perform the token transfer directly.
_performERC20Transfer(token, from, to, amount);
} else {
// Insert the call to the conduit into the accumulator.
_insert(
conduitKey,
accumulator,
ConduitItemType.ERC20,
token,
from,
to,
uint256(0),
amount
);
}
}
/**
* @dev Internal function to transfer a single ERC721 token from a given
* originator to a given recipient. Sufficient approvals must be set,
* either on the respective conduit or on this contract itself.
*
* @param token The ERC721 token to transfer.
* @param from The originator of the transfer.
* @param to The recipient of the transfer.
* @param identifier The tokenId to transfer.
* @param amount The amount to transfer (must be 1 for ERC721).
* @param conduitKey A bytes32 value indicating what corresponding conduit,
* if any, to source token approvals from. The zero hash
* signifies that no conduit should be used, with direct
* approvals set on this contract.
* @param accumulator An open-ended array that collects transfers to execute
* against a given conduit in a single call.
*/
function _transferERC721(
address token,
address from,
address to,
uint256 identifier,
uint256 amount,
bytes32 conduitKey,
bytes memory accumulator
) internal {
// Trigger accumulated transfers if the conduits differ.
_triggerIfArmedAndNotAccumulatable(accumulator, conduitKey);
// If no conduit has been specified...
if (conduitKey == bytes32(0)) {
// Ensure that exactly one 721 item is being transferred.
if (amount != 1) {
_revertInvalidERC721TransferAmount(amount);
}
// Perform transfer via the token contract directly.
_performERC721Transfer(token, from, to, identifier);
} else {
// Insert the call to the conduit into the accumulator.
_insert(
conduitKey,
accumulator,
ConduitItemType.ERC721,
token,
from,
to,
identifier,
amount
);
}
}
/**
* @dev Internal function to transfer ERC1155 tokens from a given originator
* to a given recipient. Sufficient approvals must be set, either on
* the respective conduit or on this contract itself.
*
* @param token The ERC1155 token to transfer.
* @param from The originator of the transfer.
* @param to The recipient of the transfer.
* @param identifier The id to transfer.
* @param amount The amount to transfer.
* @param conduitKey A bytes32 value indicating what corresponding conduit,
* if any, to source token approvals from. The zero hash
* signifies that no conduit should be used, with direct
* approvals set on this contract.
* @param accumulator An open-ended array that collects transfers to execute
* against a given conduit in a single call.
*/
function _transferERC1155(
address token,
address from,
address to,
uint256 identifier,
uint256 amount,
bytes32 conduitKey,
bytes memory accumulator
) internal {
// Ensure that the supplied amount is non-zero.
_assertNonZeroAmount(amount);
// Trigger accumulated transfers if the conduits differ.
_triggerIfArmedAndNotAccumulatable(accumulator, conduitKey);
// If no conduit has been specified...
if (conduitKey == bytes32(0)) {
// Perform transfer via the token contract directly.
_performERC1155Transfer(token, from, to, identifier, amount);
} else {
// Insert the call to the conduit into the accumulator.
_insert(
conduitKey,
accumulator,
ConduitItemType.ERC1155,
token,
from,
to,
identifier,
amount
);
}
}
/**
* @dev Internal function to trigger a call to the conduit currently held by
* the accumulator if the accumulator contains item transfers (i.e. it
* is "armed") and the supplied conduit key does not match the key held
* by the accumulator.
*
* @param accumulator An open-ended array that collects transfers to execute
* against a given conduit in a single call.
* @param conduitKey A bytes32 value indicating what corresponding conduit,
* if any, to source token approvals from. The zero hash
* signifies that no conduit should be used, with direct
* approvals set on this contract.
*/
function _triggerIfArmedAndNotAccumulatable(
bytes memory accumulator,
bytes32 conduitKey
) internal {
// Retrieve the current conduit key from the accumulator.
bytes32 accumulatorConduitKey = _getAccumulatorConduitKey(accumulator);
// Perform conduit call if the set key does not match the supplied key.
if (accumulatorConduitKey != conduitKey) {
_triggerIfArmed(accumulator);
}
}
/**
* @dev Internal function to trigger a call to the conduit currently held by
* the accumulator if the accumulator contains item transfers (i.e. it
* is "armed").
*
* @param accumulator An open-ended array that collects transfers to execute
* against a given conduit in a single call.
*/
function _triggerIfArmed(bytes memory accumulator) internal {
// Exit if the accumulator is not "armed".
if (accumulator.length != AccumulatorArmed) {
return;
}
// Retrieve the current conduit key from the accumulator.
bytes32 accumulatorConduitKey = _getAccumulatorConduitKey(accumulator);
// Perform conduit call.
_trigger(accumulatorConduitKey, accumulator);
}
/**
* @dev Internal function to trigger a call to the conduit corresponding to
* a given conduit key, supplying all accumulated item transfers. The
* accumulator will be "disarmed" and reset in the process.
*
* @param conduitKey A bytes32 value indicating what corresponding conduit,
* if any, to source token approvals from. The zero hash
* signifies that no conduit should be used, with direct
* approvals set on this contract.
* @param accumulator An open-ended array that collects transfers to execute
* against a given conduit in a single call.
*/
function _trigger(bytes32 conduitKey, bytes memory accumulator) internal {
// Declare variables for offset in memory & size of calldata to conduit.
uint256 callDataOffset;
uint256 callDataSize;
// Call the conduit with all the accumulated transfers.
assembly {
// Call begins at third word; the first is length or "armed" status,
// and the second is the current conduit key.
callDataOffset := add(accumulator, TwoWords)
// 68 + items * 192
callDataSize := add(
Accumulator_array_offset_ptr,
mul(
mload(add(accumulator, Accumulator_array_length_ptr)),
Conduit_transferItem_size
)
)
}
// Call conduit derived from conduit key & supply accumulated transfers.
_callConduitUsingOffsets(conduitKey, callDataOffset, callDataSize);
// Reset accumulator length to signal that it is now "disarmed".
assembly {
mstore(accumulator, AccumulatorDisarmed)
}
}
/**
* @dev Internal function to perform a call to the conduit corresponding to
* a given conduit key based on the offset and size of the calldata in
* question in memory.
*
* @param conduitKey A bytes32 value indicating what corresponding
* conduit, if any, to source token approvals from.
* The zero hash signifies that no conduit should be
* used, with direct approvals set on this contract.
* @param callDataOffset The memory pointer where calldata is contained.
* @param callDataSize The size of calldata in memory.
*/
function _callConduitUsingOffsets(
bytes32 conduitKey,
uint256 callDataOffset,
uint256 callDataSize
) internal {
// Derive the address of the conduit using the conduit key.
address conduit = _deriveConduit(conduitKey);
bool success;
bytes4 result;
// call the conduit.
assembly {
// Ensure first word of scratch space is empty.
mstore(0, 0)
// Perform call, placing first word of return data in scratch space.
success := call(
gas(),
conduit,
0,
callDataOffset,
callDataSize,
0,
OneWord
)
// Take value from scratch space and place it on the stack.
result := mload(0)
}
// If the call failed...
if (!success) {
// Pass along whatever revert reason was given by the conduit.
_revertWithReasonIfOneIsReturned();
// Otherwise, revert with a generic error.
_revertInvalidCallToConduit(conduit);
}
// Ensure result was extracted and matches magic value.
if (result != ConduitInterface.execute.selector) {
_revertInvalidConduit(conduitKey, conduit);
}
}
/**
* @dev Internal pure function to retrieve the current conduit key set for
* the accumulator.
*
* @param accumulator An open-ended array that collects transfers to execute
* against a given conduit in a single call.
*
* @return accumulatorConduitKey The conduit key currently set for the
* accumulator.
*/
function _getAccumulatorConduitKey(
bytes memory accumulator
) internal pure returns (bytes32 accumulatorConduitKey) {
// Retrieve the current conduit key from the accumulator.
assembly {
accumulatorConduitKey := mload(
add(accumulator, Accumulator_conduitKey_ptr)
)
}
}
/**
* @dev Internal pure function to place an item transfer into an accumulator
* that collects a series of transfers to execute against a given
* conduit in a single call.
*
* @param conduitKey A bytes32 value indicating what corresponding conduit,
* if any, to source token approvals from. The zero hash
* signifies that no conduit should be used, with direct
* approvals set on this contract.
* @param accumulator An open-ended array that collects transfers to execute
* against a given conduit in a single call.
* @param itemType The type of the item to transfer.
* @param token The token to transfer.
* @param from The originator of the transfer.
* @param to The recipient of the transfer.
* @param identifier The tokenId to transfer.
* @param amount The amount to transfer.
*/
function _insert(
bytes32 conduitKey,
bytes memory accumulator,
ConduitItemType itemType,
address token,
address from,
address to,
uint256 identifier,
uint256 amount
) internal pure {
uint256 elements;
// "Arm" and prime accumulator if it's not already armed. The sentinel
// value is held in the length of the accumulator array.
if (accumulator.length == AccumulatorDisarmed) {
elements = 1;
bytes4 selector = ConduitInterface.execute.selector;
assembly {
mstore(accumulator, AccumulatorArmed) // "arm" the accumulator.
mstore(add(accumulator, Accumulator_conduitKey_ptr), conduitKey)
mstore(add(accumulator, Accumulator_selector_ptr), selector)
mstore(
add(accumulator, Accumulator_array_offset_ptr),
Accumulator_array_offset
)
mstore(add(accumulator, Accumulator_array_length_ptr), elements)
}
} else {
// Otherwise, increase the number of elements by one.
assembly {
elements := add(
mload(add(accumulator, Accumulator_array_length_ptr)),
1
)
mstore(add(accumulator, Accumulator_array_length_ptr), elements)
}
}
// Insert the item.
assembly {
let itemPointer := sub(
add(accumulator, mul(elements, Conduit_transferItem_size)),
Accumulator_itemSizeOffsetDifference
)
mstore(itemPointer, itemType)
mstore(add(itemPointer, Conduit_transferItem_token_ptr), token)
mstore(add(itemPointer, Conduit_transferItem_from_ptr), from)
mstore(add(itemPointer, Conduit_transferItem_to_ptr), to)
mstore(
add(itemPointer, Conduit_transferItem_identifier_ptr),
identifier
)
mstore(add(itemPointer, Conduit_transferItem_amount_ptr), amount)
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import { OrderType } from "seaport-types/src/lib/ConsiderationEnums.sol";
import {
AdvancedOrder,
BasicOrderParameters,
OrderParameters
} from "seaport-types/src/lib/ConsiderationStructs.sol";
import {
ZoneInteractionErrors
} from "seaport-types/src/interfaces/ZoneInteractionErrors.sol";
import { LowLevelHelpers } from "./LowLevelHelpers.sol";
import { ConsiderationEncoder } from "./ConsiderationEncoder.sol";
import {
CalldataPointer,
MemoryPointer,
OffsetOrLengthMask,
ZeroSlotPtr
} from "seaport-types/src/helpers/PointerLibraries.sol";
import {
authorizeOrder_selector_offset,
BasicOrder_zone_cdPtr,
ContractOrder_orderHash_offerer_shift,
MaskOverFirstFourBytes,
OneWord,
OrderParameters_salt_offset,
OrderParameters_zone_offset,
validateOrder_selector_offset
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
Error_selector_offset,
InvalidContractOrder_error_selector,
InvalidRestrictedOrder_error_length,
InvalidRestrictedOrder_error_orderHash_ptr,
InvalidRestrictedOrder_error_selector
} from "seaport-types/src/lib/ConsiderationErrorConstants.sol";
/**
* @title ZoneInteraction
* @author 0age
* @notice ZoneInteraction contains logic related to interacting with zones.
*/
contract ZoneInteraction is
ConsiderationEncoder,
ZoneInteractionErrors,
LowLevelHelpers
{
/**
* @dev Internal function to determine if an order has a restricted order
* type and, if so, to ensure that either the zone is the caller or
* that a call to `validateOrder` on the zone returns a magic value
* indicating that the order is currently valid. Note that contract
* orders are not accessible via the basic fulfillment method.
*
* @param orderHash The hash of the order.
* @param orderType The order type.
*/
function _assertRestrictedBasicOrderAuthorization(
bytes32 orderHash,
OrderType orderType
) internal returns (uint256 callDataPointer) {
// Order type 2-3 require zone be caller or zone to approve.
// Note that in cases where fulfiller == zone, the restricted order
// validation will be skipped.
if (
_isRestrictedAndCallerNotZone(
orderType,
CalldataPointer.wrap(BasicOrder_zone_cdPtr).readAddress()
)
) {
// Encode the `authorizeOrder` call in memory.
(
MemoryPointer callData,
uint256 size,
uint256 memoryLocationForOrderHashes
) = _encodeAuthorizeBasicOrder(orderHash);
// Write the error selector to memory at the zero slot where it can
// be used to revert with a specific error message.
ZeroSlotPtr.write(InvalidRestrictedOrder_error_selector);
// Perform `authorizeOrder` call & ensure magic value was returned.
_callAndCheckStatus(
CalldataPointer.wrap(BasicOrder_zone_cdPtr).readAddress(),
orderHash,
callData.offset(authorizeOrder_selector_offset),
size
);
// Restore the zero slot.
ZeroSlotPtr.write(0);
// Register the calldata pointer for the encoded calldata.
callDataPointer = MemoryPointer.unwrap(callData);
// Utilize unchecked logic as size value cannot be so large as to
// cause an overflow.
unchecked {
// Write the packed encoding of size and memory location for
// order hashes to memory at the head of the encoded calldata.
callData.write(
((size + OneWord) << 128) | memoryLocationForOrderHashes
);
}
}
}
/**
* @dev Internal function to determine if an order has a restricted order
* type and, if so, to ensure that either the zone is the caller or
* that a call to `validateOrder` on the zone returns a magic value
* indicating that the order is currently valid. Note that contract
* orders are not accessible via the basic fulfillment method.
*
* @param orderHash The hash of the order.
* @param orderType The order type.
* @param callDataPtr The pointer to the call data for the basic order.
* Note that the initial value will contain the size
* and the memory location for order hashes length.
*/
function _assertRestrictedBasicOrderValidity(
bytes32 orderHash,
OrderType orderType,
uint256 callDataPtr
) internal {
// Order type 2-3 require zone be caller or zone to approve.
// Note that in cases where fulfiller == zone, the restricted order
// validation will be skipped.
if (
_isRestrictedAndCallerNotZone(
orderType,
CalldataPointer.wrap(BasicOrder_zone_cdPtr).readAddress()
)
) {
// Cast the call data pointer to a memory pointer.
MemoryPointer callData = MemoryPointer.wrap(callDataPtr);
// Retrieve the size and memory location for order hashes from the
// head of the encoded calldata where it was previously written.
uint256 sizeAndMemoryLocationForOrderHashes = (
callData.readUint256()
);
// Split the packed encoding to retrieve size and memory location.
uint256 size = sizeAndMemoryLocationForOrderHashes >> 128;
uint256 memoryLocationForOrderHashes = (
sizeAndMemoryLocationForOrderHashes & OffsetOrLengthMask
);
// Encode the `validateOrder` call in memory.
_encodeValidateBasicOrder(callData, memoryLocationForOrderHashes);
// Account for the offset of the selector in the encoded call data.
callData = callData.offset(validateOrder_selector_offset);
// Write the error selector to memory at the zero slot where it can
// be used to revert with a specific error message.
ZeroSlotPtr.write(InvalidRestrictedOrder_error_selector);
// Perform `validateOrder` call and ensure magic value was returned.
_callAndCheckStatus(
CalldataPointer.wrap(BasicOrder_zone_cdPtr).readAddress(),
orderHash,
callData,
size
);
// Restore the zero slot.
ZeroSlotPtr.write(0);
}
}
/**
* @dev Internal function to determine the pre-execution validity of
* restricted orders, signaling whether or not the order is valid.
* Restricted orders where the caller is not the zone must
* successfully call `authorizeOrder` with the correct magic value
* returned.
*
* @param advancedOrder The advanced order in question.
* @param orderHashes The order hashes of each order included as part
* of the current fulfillment.
* @param orderHash The hash of the order.
* @param orderIndex The index of the order.
* @param revertOnInvalid Whether to revert if the call is invalid.
*
* @return isValid True if the order is valid, false otherwise (unless
* revertOnInvalid is true, in which case this function
* will revert).
*/
function _checkRestrictedAdvancedOrderAuthorization(
AdvancedOrder memory advancedOrder,
bytes32[] memory orderHashes,
bytes32 orderHash,
uint256 orderIndex,
bool revertOnInvalid
) internal returns (bool isValid) {
// Retrieve the parameters of the order in question.
OrderParameters memory parameters = advancedOrder.parameters;
// OrderType 2-3 require zone to be caller or approve via validateOrder.
if (
_isRestrictedAndCallerNotZone(parameters.orderType, parameters.zone)
) {
// Encode the `validateOrder` call in memory.
(MemoryPointer callData, uint256 size) = _encodeAuthorizeOrder(
orderHash,
parameters,
advancedOrder.extraData,
orderHashes,
orderIndex
);
// Perform call and ensure a corresponding magic value was returned.
return
_callAndCheckStatusWithSkip(
parameters.zone,
orderHash,
callData,
size,
InvalidRestrictedOrder_error_selector,
revertOnInvalid
);
}
return true;
}
/**
* @dev Internal function to determine the pre-execution validity of
* restricted orders and to revert if the order is invalid.
* Restricted orders where the caller is not the zone must
* successfully call `authorizeOrder` with the correct magic value
* returned.
*
* @param advancedOrder The advanced order in question.
* @param orderHashes The order hashes of each order included as part
* of the current fulfillment.
* @param orderHash The hash of the order.
* @param orderIndex The index of the order.
*/
function _assertRestrictedAdvancedOrderAuthorization(
AdvancedOrder memory advancedOrder,
bytes32[] memory orderHashes,
bytes32 orderHash,
uint256 orderIndex
) internal {
// Retrieve the parameters of the order in question.
OrderParameters memory parameters = advancedOrder.parameters;
// OrderType 2-3 requires zone to call or approve via authorizeOrder.
if (
_isRestrictedAndCallerNotZone(parameters.orderType, parameters.zone)
) {
// Encode the `authorizeOrder` call in memory.
(MemoryPointer callData, uint256 size) = _encodeAuthorizeOrder(
orderHash,
parameters,
advancedOrder.extraData,
orderHashes,
orderIndex
);
// Write the error selector to memory at the zero slot where it can
// be used to revert with a specific error message.
ZeroSlotPtr.write(InvalidRestrictedOrder_error_selector);
// Perform call and ensure a corresponding magic value was returned.
_callAndCheckStatus(parameters.zone, orderHash, callData, size);
// Restore the zero slot.
ZeroSlotPtr.write(0);
}
}
/**
* @dev Internal function to determine the post-execution validity of
* restricted and contract orders. Restricted orders where the caller
* is not the zone must successfully call `validateOrder` with the
* correct magic value returned. Contract orders must successfully call
* `ratifyOrder` with the correct magic value returned.
*
* @param advancedOrder The advanced order in question.
* @param orderHashes The order hashes of each order included as part of
* the current fulfillment.
* @param orderHash The hash of the order.
*/
function _assertRestrictedAdvancedOrderValidity(
AdvancedOrder memory advancedOrder,
bytes32[] memory orderHashes,
bytes32 orderHash
) internal {
// Declare variables that will be assigned based on the order type.
address target;
uint256 errorSelector;
MemoryPointer callData;
uint256 size;
// Retrieve the parameters of the order in question.
OrderParameters memory parameters = advancedOrder.parameters;
// OrderType 2-3 require zone to be caller or approve via validateOrder.
if (
_isRestrictedAndCallerNotZone(parameters.orderType, parameters.zone)
) {
// Encode the `validateOrder` call in memory.
(callData, size) = _encodeValidateOrder(
parameters
.toMemoryPointer()
.offset(OrderParameters_salt_offset)
.readUint256(),
orderHashes
);
// Set the target to the zone.
target = (
parameters
.toMemoryPointer()
.offset(OrderParameters_zone_offset)
.readAddress()
);
// Set the restricted-order-specific error selector.
errorSelector = InvalidRestrictedOrder_error_selector;
} else if (parameters.orderType == OrderType.CONTRACT) {
// Set the target to the offerer (note the offerer has no offset).
target = parameters.toMemoryPointer().readAddress();
// Shift the target 96 bits to the left.
uint256 shiftedOfferer;
assembly {
shiftedOfferer := shl(
ContractOrder_orderHash_offerer_shift,
target
)
}
// Encode the `ratifyOrder` call in memory.
(callData, size) = _encodeRatifyOrder(
orderHash,
parameters,
advancedOrder.extraData,
orderHashes,
shiftedOfferer
);
// Set the contract-order-specific error selector.
errorSelector = InvalidContractOrder_error_selector;
} else {
return;
}
// Write the error selector to memory at the zero slot where it can be
// used to revert with a specific error message.
ZeroSlotPtr.write(errorSelector);
// Perform call and ensure a corresponding magic value was returned.
_callAndCheckStatus(target, orderHash, callData, size);
// Restore the zero slot.
ZeroSlotPtr.write(0);
}
/**
* @dev Determines whether the specified order type is restricted and the
* caller is not the specified zone.
*
* @param orderType The type of the order to check.
* @param zone The address of the zone to check against.
*
* @return mustValidate True if the order type is restricted and the caller
* is not the specified zone, false otherwise.
*/
function _isRestrictedAndCallerNotZone(
OrderType orderType,
address zone
) internal view returns (bool mustValidate) {
// Utilize assembly to efficiently perform the check.
assembly {
mustValidate := and(
// Note that this check requires that there are no order
// types beyond the current set (0-4). It will need to be
// modified if more order types are added.
and(lt(orderType, 4), gt(orderType, 1)),
iszero(eq(caller(), zone))
)
}
}
/**
* @dev Calls the specified target with the given data and checks the status
* of the call. Revert reasons will be "bubbled up" if one is returned,
* otherwise reverting calls will throw a generic error based on the
* supplied error handler. Note that the custom error selector must
* already be in memory at the zero slot when this function is called.
*
* @param target The address of the contract to call.
* @param orderHash The hash of the order associated with the call.
* @param callData The data to pass to the contract call.
* @param size The size of calldata.
*/
function _callAndCheckStatus(
address target,
bytes32 orderHash,
MemoryPointer callData,
uint256 size
) internal {
bool success;
bool magicMatch;
assembly {
// Get magic value from the selector at start of provided calldata.
let magic := and(mload(callData), MaskOverFirstFourBytes)
// Clear the start of scratch space.
mstore(0, 0)
// Perform call, placing result in the first word of scratch space.
success := call(gas(), target, 0, callData, size, 0, OneWord)
// Determine if returned magic value matches the calldata selector.
magicMatch := eq(magic, mload(0))
}
// Revert if the call was not successful.
if (!success) {
// Revert and pass reason along if one was returned.
_revertWithReasonIfOneIsReturned();
// If no reason was returned, revert with supplied error selector.
assembly {
// The error selector is already in memory at the zero slot.
mstore(0x80, orderHash)
// revert(abi.encodeWithSelector(
// "InvalidRestrictedOrder(bytes32)",
// orderHash
// ))
revert(0x7c, InvalidRestrictedOrder_error_length)
}
}
// Revert if the correct magic value was not returned.
if (!magicMatch) {
// Revert with a generic error message.
assembly {
// The error selector is already in memory at the zero slot.
mstore(0x80, orderHash)
// revert(abi.encodeWithSelector(
// "InvalidRestrictedOrder(bytes32)",
// orderHash
// ))
revert(0x7c, InvalidRestrictedOrder_error_length)
}
}
}
/**
* @dev Calls the specified target with the given data and checks the status
* of the call. Revert reasons will be "bubbled up" if one is returned,
* otherwise reverting calls will throw a generic error based on the
* supplied error handler.
*
* @param target The address of the contract to call.
* @param orderHash The hash of the order associated with the call.
* @param callData The data to pass to the contract call.
* @param size The size of calldata.
* @param errorSelector The error handling function to call if the call
* fails or the magic value does not match.
* @param revertOnInvalid Whether to revert if the call is invalid. Must
* still revert if the call returns invalid data.
*/
function _callAndCheckStatusWithSkip(
address target,
bytes32 orderHash,
MemoryPointer callData,
uint256 size,
uint256 errorSelector,
bool revertOnInvalid
) internal returns (bool) {
bool success;
bool magicMatch;
assembly {
// Get magic value from the selector at start of provided calldata.
let magic := and(mload(callData), MaskOverFirstFourBytes)
// Clear the start of scratch space.
mstore(0, 0)
// Perform call, placing result in the first word of scratch space.
success := call(gas(), target, 0, callData, size, 0, OneWord)
// Determine if returned magic value matches the calldata selector.
magicMatch := eq(magic, mload(0))
}
// Revert or return false if the call was not successful.
if (!success) {
if (!revertOnInvalid) {
return false;
}
// Revert and pass reason along if one was returned.
_revertWithReasonIfOneIsReturned();
// If no reason was returned, revert with supplied error selector.
assembly {
mstore(0, errorSelector)
mstore(InvalidRestrictedOrder_error_orderHash_ptr, orderHash)
// revert(abi.encodeWithSelector(
// "InvalidRestrictedOrder(bytes32)",
// orderHash
// ))
revert(
Error_selector_offset,
InvalidRestrictedOrder_error_length
)
}
}
// Revert if the correct magic value was not returned.
if (!magicMatch) {
// Revert with a generic error message.
assembly {
mstore(0, errorSelector)
mstore(InvalidRestrictedOrder_error_orderHash_ptr, orderHash)
// revert(abi.encodeWithSelector(
// "InvalidRestrictedOrder(bytes32)",
// orderHash
// ))
revert(
Error_selector_offset,
InvalidRestrictedOrder_error_length
)
}
}
return true;
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
import {
ConduitBatch1155Transfer,
ConduitTransfer
} from "../conduit/lib/ConduitStructs.sol";
/**
* @title ConduitInterface
* @author 0age
* @notice ConduitInterface contains all external function interfaces, events,
* and errors for conduit contracts.
*/
interface ConduitInterface {
/**
* @dev Revert with an error when attempting to execute transfers using a
* caller that does not have an open channel.
*/
error ChannelClosed(address channel);
/**
* @dev Revert with an error when attempting to update a channel to the
* current status of that channel.
*/
error ChannelStatusAlreadySet(address channel, bool isOpen);
/**
* @dev Revert with an error when attempting to execute a transfer for an
* item that does not have an ERC20/721/1155 item type.
*/
error InvalidItemType();
/**
* @dev Revert with an error when attempting to update the status of a
* channel from a caller that is not the conduit controller.
*/
error InvalidController();
/**
* @dev Emit an event whenever a channel is opened or closed.
*
* @param channel The channel that has been updated.
* @param open A boolean indicating whether the conduit is open or not.
*/
event ChannelUpdated(address indexed channel, bool open);
/**
* @notice Execute a sequence of ERC20/721/1155 transfers. Only a caller
* with an open channel can call this function.
*
* @param transfers The ERC20/721/1155 transfers to perform.
*
* @return magicValue A magic value indicating that the transfers were
* performed successfully.
*/
function execute(
ConduitTransfer[] calldata transfers
) external returns (bytes4 magicValue);
/**
* @notice Execute a sequence of batch 1155 transfers. Only a caller with an
* open channel can call this function.
*
* @param batch1155Transfers The 1155 batch transfers to perform.
*
* @return magicValue A magic value indicating that the transfers were
* performed successfully.
*/
function executeBatch1155(
ConduitBatch1155Transfer[] calldata batch1155Transfers
) external returns (bytes4 magicValue);
/**
* @notice Execute a sequence of transfers, both single and batch 1155. Only
* a caller with an open channel can call this function.
*
* @param standardTransfers The ERC20/721/1155 transfers to perform.
* @param batch1155Transfers The 1155 batch transfers to perform.
*
* @return magicValue A magic value indicating that the transfers were
* performed successfully.
*/
function executeWithBatch1155(
ConduitTransfer[] calldata standardTransfers,
ConduitBatch1155Transfer[] calldata batch1155Transfers
) external returns (bytes4 magicValue);
/**
* @notice Open or close a given channel. Only callable by the controller.
*
* @param channel The channel to open or close.
* @param isOpen The status of the channel (either open or closed).
*/
function updateChannel(address channel, bool isOpen) external;
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
enum ConduitItemType {
NATIVE, // unused
ERC20,
ERC721,
ERC1155
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import { OrderStatus } from "seaport-types/src/lib/ConsiderationStructs.sol";
import { Assertions } from "./Assertions.sol";
import { SignatureVerification } from "./SignatureVerification.sol";
import {
_revertInvalidTime,
_revertOrderAlreadyFilled,
_revertOrderIsCancelled,
_revertOrderPartiallyFilled
} from "seaport-types/src/lib/ConsiderationErrors.sol";
import {
BulkOrderProof_keyShift,
BulkOrderProof_keySize,
BulkOrderProof_lengthAdjustmentBeforeMask,
BulkOrderProof_lengthRangeAfterMask,
BulkOrderProof_minSize,
BulkOrderProof_rangeSize,
ECDSA_MaxLength,
OneWord,
OneWordShift,
ThirtyOneBytes,
TwoWords
} from "seaport-types/src/lib/ConsiderationConstants.sol";
/**
* @title Verifiers
* @author 0age
* @notice Verifiers contains functions for performing verifications.
*/
contract Verifiers is Assertions, SignatureVerification {
/**
* @dev Derive and set hashes, reference chainId, and associated domain
* separator during deployment.
*
* @param conduitController A contract that deploys conduits, or proxies
* that may optionally be used to transfer approved
* ERC20/721/1155 tokens.
*/
constructor(address conduitController) Assertions(conduitController) {}
/**
* @dev Internal view function to ensure that the current time falls within
* an order's valid timespan.
*
* @param startTime The time at which the order becomes active.
* @param endTime The time at which the order becomes inactive.
* @param revertOnInvalid A boolean indicating whether to revert if the
* order is not active.
*
* @return valid A boolean indicating whether the order is active.
*/
function _verifyTime(
uint256 startTime,
uint256 endTime,
bool revertOnInvalid
) internal view returns (bool valid) {
// Mark as valid if order has started and has not already ended.
assembly {
valid := and(
iszero(gt(startTime, timestamp())),
gt(endTime, timestamp())
)
}
// Only revert on invalid if revertOnInvalid has been supplied as true.
if (revertOnInvalid && !valid) {
_revertInvalidTime(startTime, endTime);
}
}
/**
* @dev Internal view function to verify the signature of an order. An
* ERC-1271 fallback will be attempted if either the signature length
* is not 64 or 65 bytes or if the recovered signer does not match the
* supplied offerer. Note that in cases where a 64 or 65 byte signature
* is supplied, only standard ECDSA signatures that recover to a
* non-zero address are supported.
*
* @param offerer The offerer for the order.
* @param orderHash The order hash.
* @param signature A signature from the offerer indicating that the order
* has been approved.
*/
function _verifySignature(
address offerer,
bytes32 orderHash,
bytes memory signature
) internal view {
// Determine whether the offerer is the caller.
bool offererIsCaller;
assembly {
offererIsCaller := eq(offerer, caller())
}
// Skip signature verification if the offerer is the caller.
if (offererIsCaller) {
return;
}
// Derive the EIP-712 domain separator.
bytes32 domainSeparator = _domainSeparator();
// Derive original EIP-712 digest using domain separator and order hash.
bytes32 originalDigest = _deriveEIP712Digest(
domainSeparator,
orderHash
);
// Read the length of the signature from memory and place on the stack.
uint256 originalSignatureLength = signature.length;
// Determine effective digest if signature has a valid bulk order size.
bytes32 digest;
if (_isValidBulkOrderSize(originalSignatureLength)) {
// Rederive order hash and digest using bulk order proof.
(orderHash) = _computeBulkOrderProof(signature, orderHash);
digest = _deriveEIP712Digest(domainSeparator, orderHash);
} else {
// Supply the original digest as the effective digest.
digest = originalDigest;
}
// Ensure that the signature for the digest is valid for the offerer.
_assertValidSignature(
offerer,
digest,
originalDigest,
originalSignatureLength,
signature
);
}
/**
* @dev Determines whether the specified bulk order size is valid.
*
* @param signatureLength The signature length of the bulk order to check.
*
* @return validLength True if bulk order size is valid, false otherwise.
*/
function _isValidBulkOrderSize(
uint256 signatureLength
) internal pure returns (bool validLength) {
// Utilize assembly to validate the length; the equivalent logic is
// (64 + x) + 3 + 32y where (0 <= x <= 1) and (1 <= y <= 24).
assembly {
validLength := and(
lt(
sub(signatureLength, BulkOrderProof_minSize),
BulkOrderProof_rangeSize
),
lt(
and(
add(
signatureLength,
BulkOrderProof_lengthAdjustmentBeforeMask
),
ThirtyOneBytes
),
BulkOrderProof_lengthRangeAfterMask
)
)
}
}
/**
* @dev Computes the bulk order hash for the specified proof and leaf. Note
* that if an index that exceeds the number of orders in the bulk order
* payload will instead "wrap around" and refer to an earlier index.
*
* @param proofAndSignature The proof and signature of the bulk order.
* @param leaf The leaf of the bulk order tree.
*
* @return bulkOrderHash The bulk order hash.
*/
function _computeBulkOrderProof(
bytes memory proofAndSignature,
bytes32 leaf
) internal pure returns (bytes32 bulkOrderHash) {
// Declare arguments for the root hash and the height of the proof.
bytes32 root;
uint256 height;
// Utilize assembly to efficiently derive the root hash using the proof.
assembly {
// Retrieve the length of the proof, key, and signature combined.
let fullLength := mload(proofAndSignature)
// If proofAndSignature has odd length, it is a compact signature
// with 64 bytes.
let signatureLength := sub(ECDSA_MaxLength, and(fullLength, 1))
// Derive height (or depth of tree) with signature and proof length.
height := shr(OneWordShift, sub(fullLength, signatureLength))
// Update the length in memory to only include the signature.
mstore(proofAndSignature, signatureLength)
// Derive the pointer for the key using the signature length.
let keyPtr := add(proofAndSignature, add(OneWord, signatureLength))
// Retrieve the three-byte key using the derived pointer.
let key := shr(BulkOrderProof_keyShift, mload(keyPtr))
/// Retrieve pointer to first proof element by applying a constant
// for the key size to the derived key pointer.
let proof := add(keyPtr, BulkOrderProof_keySize)
// Compute level 1.
let scratchPtr1 := shl(OneWordShift, and(key, 1))
mstore(scratchPtr1, leaf)
mstore(xor(scratchPtr1, OneWord), mload(proof))
// Compute remaining proofs.
for {
let i := 1
} lt(i, height) {
i := add(i, 1)
} {
proof := add(proof, OneWord)
let scratchPtr := shl(OneWordShift, and(shr(i, key), 1))
mstore(scratchPtr, keccak256(0, TwoWords))
mstore(xor(scratchPtr, OneWord), mload(proof))
}
// Compute root hash.
root := keccak256(0, TwoWords)
}
// Retrieve appropriate typehash constant based on height.
bytes32 rootTypeHash = _lookupBulkOrderTypehash(height);
// Use the typehash and the root hash to derive final bulk order hash.
assembly {
mstore(0, rootTypeHash)
mstore(OneWord, root)
bulkOrderHash := keccak256(0, TwoWords)
}
}
/**
* @dev Internal view function to validate that a given order is fillable
* and not cancelled based on the order status.
*
* @param orderHash The order hash.
* @param orderStatus The status of the order, including whether it has
* been cancelled and the fraction filled.
* @param onlyAllowUnused A boolean flag indicating whether partial fills
* are supported by the calling function.
* @param revertOnInvalid A boolean indicating whether to revert if the
* order has been cancelled or filled beyond the
* allowable amount.
*
* @return valid A boolean indicating whether the order is valid.
*/
function _verifyOrderStatus(
bytes32 orderHash,
OrderStatus storage orderStatus,
bool onlyAllowUnused,
bool revertOnInvalid
) internal view returns (bool valid) {
// Ensure that the order has not been cancelled.
if (orderStatus.isCancelled) {
// Only revert if revertOnInvalid has been supplied as true.
if (revertOnInvalid) {
_revertOrderIsCancelled(orderHash);
}
// Return false as the order status is invalid.
return false;
}
// Read order status numerator from storage and place on stack.
uint256 orderStatusNumerator = orderStatus.numerator;
// If the order is not entirely unused...
if (orderStatusNumerator != 0) {
// ensure the order has not been partially filled when not allowed.
if (onlyAllowUnused) {
// Always revert on partial fills when onlyAllowUnused is true.
_revertOrderPartiallyFilled(orderHash);
}
// Otherwise, ensure that order has not been entirely filled.
else if (orderStatusNumerator >= orderStatus.denominator) {
// Only revert if revertOnInvalid has been supplied as true.
if (revertOnInvalid) {
_revertOrderAlreadyFilled(orderHash);
}
// Return false as the order status is invalid.
return false;
}
}
// Return true as the order status is valid.
valid = true;
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.14;
import {
BadReturnValueFromERC20OnTransfer_error_amount_ptr,
BadReturnValueFromERC20OnTransfer_error_from_ptr,
BadReturnValueFromERC20OnTransfer_error_length,
BadReturnValueFromERC20OnTransfer_error_selector,
BadReturnValueFromERC20OnTransfer_error_to_ptr,
BadReturnValueFromERC20OnTransfer_error_token_ptr,
BatchTransfer1155Params_amounts_head_ptr,
BatchTransfer1155Params_calldata_baseSize,
BatchTransfer1155Params_data_head_ptr,
BatchTransfer1155Params_data_length_basePtr,
BatchTransfer1155Params_ids_head_ptr,
BatchTransfer1155Params_ids_length_offset,
BatchTransfer1155Params_ids_length_ptr,
BatchTransfer1155Params_ptr,
ConduitBatch1155Transfer_amounts_length_baseOffset,
ConduitBatch1155Transfer_from_offset,
ConduitBatch1155Transfer_ids_head_offset,
ConduitBatch1155Transfer_ids_length_offset,
ConduitBatch1155Transfer_usable_head_size,
ConduitBatchTransfer_amounts_head_offset,
CostPerWord,
DefaultFreeMemoryPointer,
ERC1155_safeBatchTransferFrom_signature,
ERC1155_safeTransferFrom_amount_ptr,
ERC1155_safeTransferFrom_data_length_offset,
ERC1155_safeTransferFrom_data_length_ptr,
ERC1155_safeTransferFrom_data_offset_ptr,
ERC1155_safeTransferFrom_from_ptr,
ERC1155_safeTransferFrom_id_ptr,
ERC1155_safeTransferFrom_length,
ERC1155_safeTransferFrom_sig_ptr,
ERC1155_safeTransferFrom_signature,
ERC1155_safeTransferFrom_to_ptr,
ERC1155BatchTransferGenericFailure_error_signature,
ERC1155BatchTransferGenericFailure_ids_offset,
ERC1155BatchTransferGenericFailure_token_ptr,
ERC20_transferFrom_amount_ptr,
ERC20_transferFrom_from_ptr,
ERC20_transferFrom_length,
ERC20_transferFrom_sig_ptr,
ERC20_transferFrom_signature,
ERC20_transferFrom_to_ptr,
ERC721_transferFrom_from_ptr,
ERC721_transferFrom_id_ptr,
ERC721_transferFrom_length,
ERC721_transferFrom_sig_ptr,
ERC721_transferFrom_signature,
ERC721_transferFrom_to_ptr,
ExtraGasBuffer,
FreeMemoryPointerSlot,
Generic_error_selector_offset,
Invalid1155BatchTransferEncoding_length,
Invalid1155BatchTransferEncoding_ptr,
Invalid1155BatchTransferEncoding_selector,
MemoryExpansionCoefficientShift,
NoContract_error_account_ptr,
NoContract_error_length,
NoContract_error_selector,
OneWord,
OneWordShift,
Slot0x80,
Slot0xA0,
Slot0xC0,
ThirtyOneBytes,
TokenTransferGenericFailure_err_identifier_ptr,
TokenTransferGenericFailure_error_amount_ptr,
TokenTransferGenericFailure_error_from_ptr,
TokenTransferGenericFailure_error_identifier_ptr,
TokenTransferGenericFailure_error_length,
TokenTransferGenericFailure_error_selector,
TokenTransferGenericFailure_error_to_ptr,
TokenTransferGenericFailure_error_token_ptr,
TwoWords,
TwoWordsShift,
ZeroSlot
} from "seaport-types/src/lib/TokenTransferrerConstants.sol";
import {
TokenTransferrerErrors
} from "seaport-types/src/interfaces/TokenTransferrerErrors.sol";
import {
ConduitBatch1155Transfer
} from "seaport-types/src/conduit/lib/ConduitStructs.sol";
/**
* @title TokenTransferrer
* @author 0age
* @custom:coauthor d1ll0n
* @custom:coauthor transmissions11
* @notice TokenTransferrer is a library for performing optimized ERC20, ERC721,
* ERC1155, and batch ERC1155 transfers, used by both Seaport as well as
* by conduits deployed by the ConduitController. Use great caution when
* considering these functions for use in other codebases, as there are
* significant side effects and edge cases that need to be thoroughly
* understood and carefully addressed.
*/
contract TokenTransferrer is TokenTransferrerErrors {
/**
* @dev Internal function to transfer ERC20 tokens from a given originator
* to a given recipient. Sufficient approvals must be set on the
* contract performing the transfer.
*
* @param token The ERC20 token to transfer.
* @param from The originator of the transfer.
* @param to The recipient of the transfer.
* @param amount The amount to transfer.
*/
function _performERC20Transfer(
address token,
address from,
address to,
uint256 amount
) internal {
// Utilize assembly to perform an optimized ERC20 token transfer.
assembly {
// The free memory pointer memory slot will be used when populating
// call data for the transfer; read the value and restore it later.
let memPointer := mload(FreeMemoryPointerSlot)
// Write call data into memory, starting with function selector.
mstore(ERC20_transferFrom_sig_ptr, ERC20_transferFrom_signature)
mstore(ERC20_transferFrom_from_ptr, from)
mstore(ERC20_transferFrom_to_ptr, to)
mstore(ERC20_transferFrom_amount_ptr, amount)
// Make call & copy up to 32 bytes of return data to scratch space.
// Scratch space does not need to be cleared ahead of time, as the
// subsequent check will ensure that either at least a full word of
// return data is received (in which case it will be overwritten) or
// that no data is received (in which case scratch space will be
// ignored) on a successful call to the given token.
let callStatus := call(
gas(),
token,
0,
ERC20_transferFrom_sig_ptr,
ERC20_transferFrom_length,
0,
OneWord
)
// Determine whether transfer was successful using status & result.
let success := and(
// Set success to whether the call reverted, if not check it
// either returned exactly 1 (can't just be non-zero data),
// or had no return data.
or(
and(eq(mload(0), 1), gt(returndatasize(), 31)),
iszero(returndatasize())
),
callStatus
)
// Handle cases where either the transfer failed or no data was
// returned. Group these, as most transfers will succeed with data.
// Equivalent to `or(iszero(success), iszero(returndatasize()))`
// but after it's inverted for JUMPI this expression is cheaper.
if iszero(and(success, iszero(iszero(returndatasize())))) {
// If the token has no code or the transfer failed: Equivalent
// to `or(iszero(success), iszero(extcodesize(token)))` but
// after it's inverted for JUMPI this expression is cheaper.
if iszero(and(iszero(iszero(extcodesize(token))), success)) {
// If the transfer failed:
if iszero(success) {
// If it was due to a revert:
if iszero(callStatus) {
// If it returned a message, bubble it up as long as
// sufficient gas remains to do so:
if returndatasize() {
// Ensure that sufficient gas is available to
// copy returndata while expanding memory where
// necessary. Start by computing the word size
// of returndata and allocated memory. Round up
// to the nearest full word.
let returnDataWords := shr(
OneWordShift,
add(returndatasize(), ThirtyOneBytes)
)
// Note: use the free memory pointer in place of
// msize() to work around a Yul warning that
// prevents accessing msize directly when the IR
// pipeline is activated.
let msizeWords := shr(OneWordShift, memPointer)
// Next, compute the cost of the returndatacopy.
let cost := mul(CostPerWord, returnDataWords)
// Then, compute cost of new memory allocation.
if gt(returnDataWords, msizeWords) {
cost := add(
cost,
add(
mul(
sub(
returnDataWords,
msizeWords
),
CostPerWord
),
shr(
MemoryExpansionCoefficientShift,
sub(
mul(
returnDataWords,
returnDataWords
),
mul(msizeWords, msizeWords)
)
)
)
)
}
// Finally, add a small constant and compare to
// gas remaining; bubble up the revert data if
// enough gas is still available.
if lt(add(cost, ExtraGasBuffer), gas()) {
// Copy returndata to memory; overwrite
// existing memory.
returndatacopy(0, 0, returndatasize())
// Revert, specifying memory region with
// copied returndata.
revert(0, returndatasize())
}
}
// Store left-padded selector with push4, mem[28:32]
mstore(
0,
TokenTransferGenericFailure_error_selector
)
mstore(
TokenTransferGenericFailure_error_token_ptr,
token
)
mstore(
TokenTransferGenericFailure_error_from_ptr,
from
)
mstore(TokenTransferGenericFailure_error_to_ptr, to)
mstore(
TokenTransferGenericFailure_err_identifier_ptr,
0
)
mstore(
TokenTransferGenericFailure_error_amount_ptr,
amount
)
// revert(abi.encodeWithSignature(
// "TokenTransferGenericFailure(
// address,address,address,uint256,uint256
// )", token, from, to, identifier, amount
// ))
revert(
Generic_error_selector_offset,
TokenTransferGenericFailure_error_length
)
}
// Otherwise revert with a message about the token
// returning false or non-compliant return values.
// Store left-padded selector with push4, mem[28:32]
mstore(
0,
BadReturnValueFromERC20OnTransfer_error_selector
)
mstore(
BadReturnValueFromERC20OnTransfer_error_token_ptr,
token
)
mstore(
BadReturnValueFromERC20OnTransfer_error_from_ptr,
from
)
mstore(
BadReturnValueFromERC20OnTransfer_error_to_ptr,
to
)
mstore(
BadReturnValueFromERC20OnTransfer_error_amount_ptr,
amount
)
// revert(abi.encodeWithSignature(
// "BadReturnValueFromERC20OnTransfer(
// address,address,address,uint256
// )", token, from, to, amount
// ))
revert(
Generic_error_selector_offset,
BadReturnValueFromERC20OnTransfer_error_length
)
}
// Otherwise, revert with error about token not having code:
// Store left-padded selector with push4, mem[28:32]
mstore(0, NoContract_error_selector)
mstore(NoContract_error_account_ptr, token)
// revert(abi.encodeWithSignature(
// "NoContract(address)", account
// ))
revert(
Generic_error_selector_offset,
NoContract_error_length
)
}
// Otherwise, the token just returned no data despite the call
// having succeeded; no need to optimize for this as it's not
// technically ERC20 compliant.
}
// Restore the original free memory pointer.
mstore(FreeMemoryPointerSlot, memPointer)
// Restore the zero slot to zero.
mstore(ZeroSlot, 0)
}
}
/**
* @dev Internal function to transfer an ERC721 token from a given
* originator to a given recipient. Sufficient approvals must be set on
* the contract performing the transfer. Note that this function does
* not check whether the receiver can accept the ERC721 token (i.e. it
* does not use `safeTransferFrom`).
*
* @param token The ERC721 token to transfer.
* @param from The originator of the transfer.
* @param to The recipient of the transfer.
* @param identifier The tokenId to transfer.
*/
function _performERC721Transfer(
address token,
address from,
address to,
uint256 identifier
) internal {
// Utilize assembly to perform an optimized ERC721 token transfer.
assembly {
// If the token has no code, revert.
if iszero(extcodesize(token)) {
// Store left-padded selector with push4, mem[28:32] = selector
mstore(0, NoContract_error_selector)
mstore(NoContract_error_account_ptr, token)
// revert(abi.encodeWithSignature(
// "NoContract(address)", account
// ))
revert(Generic_error_selector_offset, NoContract_error_length)
}
// The free memory pointer memory slot will be used when populating
// call data for the transfer; read the value and restore it later.
let memPointer := mload(FreeMemoryPointerSlot)
// Write call data to memory starting with function selector.
mstore(ERC721_transferFrom_sig_ptr, ERC721_transferFrom_signature)
mstore(ERC721_transferFrom_from_ptr, from)
mstore(ERC721_transferFrom_to_ptr, to)
mstore(ERC721_transferFrom_id_ptr, identifier)
// Perform the call, ignoring return data.
let success := call(
gas(),
token,
0,
ERC721_transferFrom_sig_ptr,
ERC721_transferFrom_length,
0,
0
)
// If the transfer reverted:
if iszero(success) {
// If it returned a message, bubble it up as long as sufficient
// gas remains to do so:
if returndatasize() {
// Ensure that sufficient gas is available to copy
// returndata while expanding memory where necessary. Start
// by computing word size of returndata & allocated memory.
// Round up to the nearest full word.
let returnDataWords := shr(
OneWordShift,
add(returndatasize(), ThirtyOneBytes)
)
// Note: use the free memory pointer in place of msize() to
// work around a Yul warning that prevents accessing msize
// directly when the IR pipeline is activated.
let msizeWords := shr(OneWordShift, memPointer)
// Next, compute the cost of the returndatacopy.
let cost := mul(CostPerWord, returnDataWords)
// Then, compute cost of new memory allocation.
if gt(returnDataWords, msizeWords) {
cost := add(
cost,
add(
mul(
sub(returnDataWords, msizeWords),
CostPerWord
),
shr(
MemoryExpansionCoefficientShift,
sub(
mul(returnDataWords, returnDataWords),
mul(msizeWords, msizeWords)
)
)
)
)
}
// Finally, add a small constant and compare to gas
// remaining; bubble up the revert data if enough gas is
// still available.
if lt(add(cost, ExtraGasBuffer), gas()) {
// Copy returndata to memory; overwrite existing memory.
returndatacopy(0, 0, returndatasize())
// Revert, giving memory region with copied returndata.
revert(0, returndatasize())
}
}
// Otherwise revert with a generic error message.
// Store left-padded selector with push4, mem[28:32] = selector
mstore(0, TokenTransferGenericFailure_error_selector)
mstore(TokenTransferGenericFailure_error_token_ptr, token)
mstore(TokenTransferGenericFailure_error_from_ptr, from)
mstore(TokenTransferGenericFailure_error_to_ptr, to)
mstore(
TokenTransferGenericFailure_error_identifier_ptr,
identifier
)
mstore(TokenTransferGenericFailure_error_amount_ptr, 1)
// revert(abi.encodeWithSignature(
// "TokenTransferGenericFailure(
// address,address,address,uint256,uint256
// )", token, from, to, identifier, amount
// ))
revert(
Generic_error_selector_offset,
TokenTransferGenericFailure_error_length
)
}
// Restore the original free memory pointer.
mstore(FreeMemoryPointerSlot, memPointer)
// Restore the zero slot to zero.
mstore(ZeroSlot, 0)
}
}
/**
* @dev Internal function to transfer ERC1155 tokens from a given
* originator to a given recipient. Sufficient approvals must be set on
* the contract performing the transfer and contract recipients must
* implement the ERC1155TokenReceiver interface to indicate that they
* are willing to accept the transfer.
*
* @param token The ERC1155 token to transfer.
* @param from The originator of the transfer.
* @param to The recipient of the transfer.
* @param identifier The id to transfer.
* @param amount The amount to transfer.
*/
function _performERC1155Transfer(
address token,
address from,
address to,
uint256 identifier,
uint256 amount
) internal {
// Utilize assembly to perform an optimized ERC1155 token transfer.
assembly {
// If the token has no code, revert.
if iszero(extcodesize(token)) {
// Store left-padded selector with push4, mem[28:32] = selector
mstore(0, NoContract_error_selector)
mstore(NoContract_error_account_ptr, token)
// revert(abi.encodeWithSignature(
// "NoContract(address)", account
// ))
revert(Generic_error_selector_offset, NoContract_error_length)
}
// The following memory slots will be used when populating call data
// for the transfer; read the values and restore them later.
let memPointer := mload(FreeMemoryPointerSlot)
let slot0x80 := mload(Slot0x80)
let slot0xA0 := mload(Slot0xA0)
let slot0xC0 := mload(Slot0xC0)
// Write call data into memory, beginning with function selector.
mstore(
ERC1155_safeTransferFrom_sig_ptr,
ERC1155_safeTransferFrom_signature
)
mstore(ERC1155_safeTransferFrom_from_ptr, from)
mstore(ERC1155_safeTransferFrom_to_ptr, to)
mstore(ERC1155_safeTransferFrom_id_ptr, identifier)
mstore(ERC1155_safeTransferFrom_amount_ptr, amount)
mstore(
ERC1155_safeTransferFrom_data_offset_ptr,
ERC1155_safeTransferFrom_data_length_offset
)
mstore(ERC1155_safeTransferFrom_data_length_ptr, 0)
// Perform the call, ignoring return data.
let success := call(
gas(),
token,
0,
ERC1155_safeTransferFrom_sig_ptr,
ERC1155_safeTransferFrom_length,
0,
0
)
// If the transfer reverted:
if iszero(success) {
// If it returned a message, bubble it up as long as sufficient
// gas remains to do so:
if returndatasize() {
// Ensure that sufficient gas is available to copy
// returndata while expanding memory where necessary. Start
// by computing word size of returndata & allocated memory.
// Round up to the nearest full word.
let returnDataWords := shr(
OneWordShift,
add(returndatasize(), ThirtyOneBytes)
)
// Note: use the free memory pointer in place of msize() to
// work around a Yul warning that prevents accessing msize
// directly when the IR pipeline is activated.
let msizeWords := shr(OneWordShift, memPointer)
// Next, compute the cost of the returndatacopy.
let cost := mul(CostPerWord, returnDataWords)
// Then, compute cost of new memory allocation.
if gt(returnDataWords, msizeWords) {
cost := add(
cost,
add(
mul(
sub(returnDataWords, msizeWords),
CostPerWord
),
shr(
MemoryExpansionCoefficientShift,
sub(
mul(returnDataWords, returnDataWords),
mul(msizeWords, msizeWords)
)
)
)
)
}
// Finally, add a small constant and compare to gas
// remaining; bubble up the revert data if enough gas is
// still available.
if lt(add(cost, ExtraGasBuffer), gas()) {
// Copy returndata to memory; overwrite existing memory.
returndatacopy(0, 0, returndatasize())
// Revert, giving memory region with copied returndata.
revert(0, returndatasize())
}
}
// Otherwise revert with a generic error message.
// Store left-padded selector with push4, mem[28:32] = selector
mstore(0, TokenTransferGenericFailure_error_selector)
mstore(TokenTransferGenericFailure_error_token_ptr, token)
mstore(TokenTransferGenericFailure_error_from_ptr, from)
mstore(TokenTransferGenericFailure_error_to_ptr, to)
mstore(
TokenTransferGenericFailure_error_identifier_ptr,
identifier
)
mstore(TokenTransferGenericFailure_error_amount_ptr, amount)
// revert(abi.encodeWithSignature(
// "TokenTransferGenericFailure(
// address,address,address,uint256,uint256
// )", token, from, to, identifier, amount
// ))
revert(
Generic_error_selector_offset,
TokenTransferGenericFailure_error_length
)
}
mstore(Slot0x80, slot0x80) // Restore slot 0x80.
mstore(Slot0xA0, slot0xA0) // Restore slot 0xA0.
mstore(Slot0xC0, slot0xC0) // Restore slot 0xC0.
// Restore the original free memory pointer.
mstore(FreeMemoryPointerSlot, memPointer)
// Restore the zero slot to zero.
mstore(ZeroSlot, 0)
}
}
/**
* @dev Internal function to transfer ERC1155 tokens from a given
* originator to a given recipient. Sufficient approvals must be set on
* the contract performing the transfer and contract recipients must
* implement the ERC1155TokenReceiver interface to indicate that they
* are willing to accept the transfer. NOTE: this function is not
* memory-safe; it will overwrite existing memory, restore the free
* memory pointer to the default value, and overwrite the zero slot.
* This function should only be called once memory is no longer
* required and when uninitialized arrays are not utilized, and memory
* should be considered fully corrupted (aside from the existence of a
* default-value free memory pointer) after calling this function.
*
* @param batchTransfers The group of 1155 batch transfers to perform.
*/
function _performERC1155BatchTransfers(
ConduitBatch1155Transfer[] calldata batchTransfers
) internal {
// Utilize assembly to perform optimized batch 1155 transfers.
assembly {
let len := batchTransfers.length
// Pointer to first head in the array, which is offset to the struct
// at each index. This gets incremented after each loop to avoid
// multiplying by 32 to get the offset for each element.
let nextElementHeadPtr := batchTransfers.offset
// Pointer to beginning of the head of the array. This is the
// reference position each offset references. It's held static to
// let each loop calculate the data position for an element.
let arrayHeadPtr := nextElementHeadPtr
// Write the function selector, which will be reused for each call:
// safeBatchTransferFrom(address,address,uint256[],uint256[],bytes)
mstore(
ConduitBatch1155Transfer_from_offset,
ERC1155_safeBatchTransferFrom_signature
)
// Iterate over each batch transfer.
for {
let i := 0
} lt(i, len) {
i := add(i, 1)
} {
// Read the offset to the beginning of the element and add
// it to pointer to the beginning of the array head to get
// the absolute position of the element in calldata.
let elementPtr := add(
arrayHeadPtr,
calldataload(nextElementHeadPtr)
)
// Retrieve the token from calldata.
let token := calldataload(elementPtr)
// If the token has no code, revert.
if iszero(extcodesize(token)) {
// Store left-padded selector with push4, mem[28:32]
mstore(0, NoContract_error_selector)
mstore(NoContract_error_account_ptr, token)
// revert(abi.encodeWithSignature(
// "NoContract(address)", account
// ))
revert(
Generic_error_selector_offset,
NoContract_error_length
)
}
// Get the total number of supplied ids.
let idsLength := calldataload(
add(elementPtr, ConduitBatch1155Transfer_ids_length_offset)
)
// Determine the expected offset for the amounts array.
let expectedAmountsOffset := add(
ConduitBatch1155Transfer_amounts_length_baseOffset,
shl(OneWordShift, idsLength)
)
// Validate struct encoding.
let invalidEncoding := iszero(
and(
// ids.length == amounts.length
eq(
idsLength,
calldataload(add(elementPtr, expectedAmountsOffset))
),
and(
// ids_offset == 0xa0
eq(
calldataload(
add(
elementPtr,
ConduitBatch1155Transfer_ids_head_offset
)
),
ConduitBatch1155Transfer_ids_length_offset
),
// amounts_offset == 0xc0 + ids.length*32
eq(
calldataload(
add(
elementPtr,
ConduitBatchTransfer_amounts_head_offset
)
),
expectedAmountsOffset
)
)
)
)
// Revert with an error if the encoding is not valid.
if invalidEncoding {
// Store left-padded selector with push4, mem[28:32]
mstore(
Invalid1155BatchTransferEncoding_ptr,
Invalid1155BatchTransferEncoding_selector
)
// revert(abi.encodeWithSignature(
// "Invalid1155BatchTransferEncoding()"
// ))
revert(
Invalid1155BatchTransferEncoding_ptr,
Invalid1155BatchTransferEncoding_length
)
}
// Update the offset position for the next loop
nextElementHeadPtr := add(nextElementHeadPtr, OneWord)
// Copy the first section of calldata (before dynamic values).
calldatacopy(
BatchTransfer1155Params_ptr,
add(elementPtr, ConduitBatch1155Transfer_from_offset),
ConduitBatch1155Transfer_usable_head_size
)
// Determine size of calldata required for ids and amounts. Note
// that the size includes both lengths as well as the data.
let idsAndAmountsSize := add(
TwoWords,
shl(TwoWordsShift, idsLength)
)
// Update the offset for the data array in memory.
mstore(
BatchTransfer1155Params_data_head_ptr,
add(
BatchTransfer1155Params_ids_length_offset,
idsAndAmountsSize
)
)
// Set the length of the data array in memory to zero.
mstore(
add(
BatchTransfer1155Params_data_length_basePtr,
idsAndAmountsSize
),
0
)
// Determine the total calldata size for the call to transfer.
let transferDataSize := add(
BatchTransfer1155Params_calldata_baseSize,
idsAndAmountsSize
)
// Copy second section of calldata (including dynamic values).
calldatacopy(
BatchTransfer1155Params_ids_length_ptr,
add(elementPtr, ConduitBatch1155Transfer_ids_length_offset),
idsAndAmountsSize
)
// Perform the call to transfer 1155 tokens.
let success := call(
gas(),
token,
0,
ConduitBatch1155Transfer_from_offset, // Data start.
transferDataSize, // Location of the length of callData.
0,
0
)
// If the transfer reverted:
if iszero(success) {
// If it returned a message, bubble it up as long as
// sufficient gas remains to do so:
if returndatasize() {
// Ensure that sufficient gas is available to copy
// returndata while expanding memory where necessary.
// Start by computing word size of returndata and
// allocated memory. Round up to the nearest full word.
let returnDataWords := shr(
OneWordShift,
add(returndatasize(), ThirtyOneBytes)
)
// Note: use transferDataSize in place of msize() to
// work around a Yul warning that prevents accessing
// msize directly when the IR pipeline is activated.
// The free memory pointer is not used here because
// this function does almost all memory management
// manually and does not update it, and transferDataSize
// should be the largest memory value used (unless a
// previous batch was larger).
let msizeWords := shr(OneWordShift, transferDataSize)
// Next, compute the cost of the returndatacopy.
let cost := mul(CostPerWord, returnDataWords)
// Then, compute cost of new memory allocation.
if gt(returnDataWords, msizeWords) {
cost := add(
cost,
add(
mul(
sub(returnDataWords, msizeWords),
CostPerWord
),
shr(
MemoryExpansionCoefficientShift,
sub(
mul(
returnDataWords,
returnDataWords
),
mul(msizeWords, msizeWords)
)
)
)
)
}
// Finally, add a small constant and compare to gas
// remaining; bubble up the revert data if enough gas is
// still available.
if lt(add(cost, ExtraGasBuffer), gas()) {
// Copy returndata to memory; overwrite existing.
returndatacopy(0, 0, returndatasize())
// Revert with memory region containing returndata.
revert(0, returndatasize())
}
}
// Set the error signature.
mstore(
0,
ERC1155BatchTransferGenericFailure_error_signature
)
// Write the token.
mstore(ERC1155BatchTransferGenericFailure_token_ptr, token)
// Increase the offset to ids by 32.
mstore(
BatchTransfer1155Params_ids_head_ptr,
ERC1155BatchTransferGenericFailure_ids_offset
)
// Increase the offset to amounts by 32.
mstore(
BatchTransfer1155Params_amounts_head_ptr,
add(
OneWord,
mload(BatchTransfer1155Params_amounts_head_ptr)
)
)
// Return modified region. The total size stays the same as
// `token` uses the same number of bytes as `data.length`.
revert(0, transferDataSize)
}
}
// Reset the free memory pointer to the default value; memory must
// be assumed to be dirtied and not reused from this point forward.
// Also note that the zero slot is not reset to zero, meaning empty
// arrays cannot be safely created or utilized until it is restored.
mstore(FreeMemoryPointerSlot, DefaultFreeMemoryPointer)
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
/**
* @title ZoneInteractionErrors
* @author 0age
* @notice ZoneInteractionErrors contains errors related to zone interaction.
*/
interface ZoneInteractionErrors {
/**
* @dev Revert with an error when attempting to fill an order that specifies
* a restricted submitter as its order type when not submitted by
* either the offerer or the order's zone or approved as valid by the
* zone in question via a call to `isValidOrder`.
*
* @param orderHash The order hash for the invalid restricted order.
*/
error InvalidRestrictedOrder(bytes32 orderHash);
/**
* @dev Revert with an error when attempting to fill a contract order that
* fails to generate an order successfully, that does not adhere to the
* requirements for minimum spent or maximum received supplied by the
* fulfiller, or that fails the post-execution `ratifyOrder` check..
*
* @param orderHash The order hash for the invalid contract order.
*/
error InvalidContractOrder(bytes32 orderHash);
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
CostPerWord,
ExtraGasBuffer,
FreeMemoryPointerSlot,
MemoryExpansionCoefficientShift,
OneWord,
OneWordShift,
ThirtyOneBytes
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
MemoryPointer,
MemoryPointerLib
} from "seaport-types/src/helpers/PointerLibraries.sol";
import {
AdvancedOrder,
Execution
} from "seaport-types/src/lib/ConsiderationStructs.sol";
/**
* @title LowLevelHelpers
* @author 0age
* @notice LowLevelHelpers contains logic for performing various low-level
* operations.
*/
contract LowLevelHelpers {
/**
* @dev Internal view function to revert and pass along the revert reason if
* data was returned by the last call and that the size of that data
* does not exceed the currently allocated memory size.
*/
function _revertWithReasonIfOneIsReturned() internal view {
assembly {
// If it returned a message, bubble it up as long as sufficient gas
// remains to do so:
if returndatasize() {
// Ensure that sufficient gas is available to copy returndata
// while expanding memory where necessary. Start by computing
// the word size of returndata and allocated memory.
let returnDataWords := shr(
OneWordShift,
add(returndatasize(), ThirtyOneBytes)
)
// Note: use the free memory pointer in place of msize() to work
// around a Yul warning that prevents accessing msize directly
// when the IR pipeline is activated.
let msizeWords := shr(
OneWordShift,
mload(FreeMemoryPointerSlot)
)
// Next, compute the cost of the returndatacopy.
let cost := mul(CostPerWord, returnDataWords)
// Then, compute cost of new memory allocation.
if gt(returnDataWords, msizeWords) {
cost := add(
cost,
add(
mul(sub(returnDataWords, msizeWords), CostPerWord),
shr(
MemoryExpansionCoefficientShift,
sub(
mul(returnDataWords, returnDataWords),
mul(msizeWords, msizeWords)
)
)
)
)
}
// Finally, add a small constant and compare to gas remaining;
// bubble up the revert data if enough gas is still available.
if lt(add(cost, ExtraGasBuffer), gas()) {
// Copy returndata to memory; overwrite existing memory.
returndatacopy(0, 0, returndatasize())
// Revert, specifying memory region with copied returndata.
revert(0, returndatasize())
}
}
}
}
/**
* @dev Internal view function to branchlessly select either the caller (if
* a supplied recipient is equal to zero) or the supplied recipient (if
* that recipient is a nonzero value).
*
* @param recipient The supplied recipient.
*
* @return updatedRecipient The updated recipient.
*/
function _substituteCallerForEmptyRecipient(
address recipient
) internal view returns (address updatedRecipient) {
// Utilize assembly to perform a branchless operation on the recipient.
assembly {
// Add caller to recipient if recipient equals 0; otherwise add 0.
updatedRecipient := add(recipient, mul(iszero(recipient), caller()))
}
}
/**
* @dev Internal pure function to cast a `bool` value to a `uint256` value.
*
* @param b The `bool` value to cast.
*
* @return u The `uint256` value.
*/
function _cast(bool b) internal pure returns (uint256 u) {
assembly {
u := b
}
}
/**
* @dev Internal pure function to cast the `pptrOffset` function from
* `MemoryPointerLib` to a function that takes a memory array of
* `AdvancedOrder` and an offset in memory and returns the
* `AdvancedOrder` whose pointer is stored at that offset from the
* array length.
*/
function _getReadAdvancedOrderByOffset()
internal
pure
returns (
function(AdvancedOrder[] memory, uint256)
internal
pure
returns (AdvancedOrder memory) fn2
)
{
function(MemoryPointer, uint256)
internal
pure
returns (MemoryPointer) fn1 = MemoryPointerLib.pptrOffset;
assembly {
fn2 := fn1
}
}
/**
* @dev Internal pure function to cast the `pptrOffset` function from
* `MemoryPointerLib` to a function that takes a memory array of
* `Execution` and an offset in memory and returns the
* `Execution` whose pointer is stored at that offset from the
* array length.
*/
function _getReadExecutionByOffset()
internal
pure
returns (
function(Execution[] memory, uint256)
internal
pure
returns (Execution memory) fn2
)
{
function(MemoryPointer, uint256)
internal
pure
returns (MemoryPointer) fn1 = MemoryPointerLib.pptrOffset;
assembly {
fn2 := fn1
}
}
/**
* @dev Internal pure function to return a `true` value that solc
* will not recognize as a compile time constant.
*
* This function is used to bypass function specialization for
* functions which take a constant boolean as an input parameter.
*
* This should only be used in cases where specialization has a
* negligible impact on the gas cost of the function.
*
* Note: assumes the calldatasize is non-zero.
*/
function _runTimeConstantTrue() internal pure returns (bool) {
return msg.data.length > 0;
}
/**
* @dev Internal pure function to return a `false` value that solc
* will not recognize as a compile time constant.
*
* This function is used to bypass function specialization for
* functions which take a constant boolean as an input parameter.
*
* This should only be used in cases where specialization has a
* negligible impact on the gas cost of the function.
*
* Note: assumes the calldatasize is non-zero.
*/
function _runTimeConstantFalse() internal pure returns (bool) {
return msg.data.length == 0;
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
authorizeOrder_calldata_baseOffset,
authorizeOrder_head_offset,
authorizeOrder_selector_offset,
authorizeOrder_selector,
authorizeOrder_zoneParameters_offset,
BasicOrder_addlRecipients_length_cdPtr,
BasicOrder_common_params_size,
BasicOrder_consideration_offset_from_offer,
BasicOrder_offerer_cdPtr,
BasicOrder_startTime_cdPtr,
BasicOrder_startTimeThroughZoneHash_size,
BasicOrder_totalOriginalAdditionalRecipients_cdPtr,
Common_amount_offset,
Common_identifier_offset,
Common_token_offset,
generateOrder_base_tail_offset,
generateOrder_context_head_offset,
generateOrder_head_offset,
generateOrder_maximumSpent_head_offset,
generateOrder_minimumReceived_head_offset,
generateOrder_selector_offset,
generateOrder_selector,
OneWord,
OneWordShift,
OnlyFullWordMask,
OrderFulfilled_baseDataSize,
OrderFulfilled_offer_length_baseOffset,
OrderParameters_consideration_head_offset,
OrderParameters_endTime_offset,
OrderParameters_offer_head_offset,
OrderParameters_startTime_offset,
OrderParameters_zoneHash_offset,
ratifyOrder_base_tail_offset,
ratifyOrder_consideration_head_offset,
ratifyOrder_context_head_offset,
ratifyOrder_contractNonce_offset,
ratifyOrder_head_offset,
ratifyOrder_orderHashes_head_offset,
ratifyOrder_selector_offset,
ratifyOrder_selector,
ReceivedItem_size,
Selector_length,
SixtyThreeBytes,
SpentItem_size_shift,
SpentItem_size,
validateOrder_selector,
validateOrder_selector_offset,
ZoneParameters_base_tail_offset,
ZoneParameters_basicOrderFixedElements_length,
ZoneParameters_consideration_head_offset,
ZoneParameters_endTime_offset,
ZoneParameters_extraData_head_offset,
ZoneParameters_fulfiller_offset,
ZoneParameters_offer_head_offset,
ZoneParameters_offerer_offset,
ZoneParameters_orderHashes_head_offset,
ZoneParameters_selectorAndPointer_length,
ZoneParameters_startTime_offset,
ZoneParameters_zoneHash_offset
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
BasicOrderParameters,
OrderParameters
} from "seaport-types/src/lib/ConsiderationStructs.sol";
import {
CalldataPointer,
getFreeMemoryPointer,
setFreeMemoryPointer,
MemoryPointer,
OffsetOrLengthMask
} from "seaport-types/src/helpers/PointerLibraries.sol";
contract ConsiderationEncoder {
/**
* @dev Takes a bytes array and casts it to a memory pointer.
*
* @param obj A bytes array in memory.
*
* @return ptr A memory pointer to the start of the bytes array in memory.
*/
function toMemoryPointer(
bytes memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Takes an array of bytes32 types and casts it to a memory pointer.
*
* @param obj An array of bytes32 types in memory.
*
* @return ptr A memory pointer to the start of the array of bytes32 types
* in memory.
*/
function toMemoryPointer(
bytes32[] memory obj
) internal pure returns (MemoryPointer ptr) {
assembly {
ptr := obj
}
}
/**
* @dev Takes a bytes array in memory and copies it to a new location in
* memory.
*
* @param src A memory pointer referencing the bytes array to be copied (and
* pointing to the length of the bytes array).
* @param src A memory pointer referencing the location in memory to copy
* the bytes array to (and pointing to the length of the copied
* bytes array).
*
* @return size The size of the bytes array.
*/
function _encodeBytes(
MemoryPointer src,
MemoryPointer dst
) internal view returns (uint256 size) {
unchecked {
// Mask the length of the bytes array to protect against overflow
// and round up to the nearest word.
// Note: `size` also includes the 1 word that stores the length.
size = (src.readUint256() + SixtyThreeBytes) & OnlyFullWordMask;
// Copy the bytes array to the new memory location.
src.copy(dst, size);
}
}
/**
* @dev Takes an OrderParameters struct and a context bytes array in memory
* and encodes it as `generateOrder` calldata.
*
* @param orderParameters The OrderParameters struct used to construct the
* encoded `generateOrder` calldata.
* @param context The context bytes array used to construct the
* encoded `generateOrder` calldata.
*
* @return dst A memory pointer referencing the encoded `generateOrder`
* calldata.
* @return size The size of the bytes array.
*/
function _encodeGenerateOrder(
OrderParameters memory orderParameters,
bytes memory context
) internal view returns (MemoryPointer dst, uint256 size) {
// Get the memory pointer for the OrderParameters struct.
MemoryPointer src = orderParameters.toMemoryPointer();
// Get free memory pointer to write calldata to.
dst = getFreeMemoryPointer();
// Write generateOrder selector and get pointer to start of calldata.
dst.write(generateOrder_selector);
dst = dst.offset(generateOrder_selector_offset);
// Get pointer to the beginning of the encoded data.
MemoryPointer dstHead = dst.offset(generateOrder_head_offset);
// Write `fulfiller` to calldata.
dstHead.write(msg.sender);
// Initialize tail offset, used to populate the minimumReceived array.
uint256 tailOffset = generateOrder_base_tail_offset;
// Write offset to minimumReceived.
dstHead.offset(generateOrder_minimumReceived_head_offset).write(
tailOffset
);
// Get memory pointer to `orderParameters.offer.length`.
MemoryPointer srcOfferPointer = src
.offset(OrderParameters_offer_head_offset)
.readMemoryPointer();
// Encode the offer array as a `SpentItem[]`.
uint256 minimumReceivedSize = _encodeSpentItems(
srcOfferPointer,
dstHead.offset(tailOffset)
);
unchecked {
// Increment tail offset, now used to populate maximumSpent array.
tailOffset += minimumReceivedSize;
}
// Write offset to maximumSpent.
dstHead.offset(generateOrder_maximumSpent_head_offset).write(
tailOffset
);
// Get memory pointer to `orderParameters.consideration.length`.
MemoryPointer srcConsiderationPointer = src
.offset(OrderParameters_consideration_head_offset)
.readMemoryPointer();
// Encode the consideration array as a `SpentItem[]`.
uint256 maximumSpentSize = _encodeSpentItems(
srcConsiderationPointer,
dstHead.offset(tailOffset)
);
unchecked {
// Increment tail offset, now used to populate context array.
tailOffset += maximumSpentSize;
}
// Write offset to context.
dstHead.offset(generateOrder_context_head_offset).write(tailOffset);
// Get memory pointer to context.
MemoryPointer srcContext = toMemoryPointer(context);
// Encode context as a bytes array.
uint256 contextSize = _encodeBytes(
srcContext,
dstHead.offset(tailOffset)
);
unchecked {
// Increment the tail offset, now used to determine final size.
tailOffset += contextSize;
// Derive the final size by including the selector.
size = Selector_length + tailOffset;
}
}
/**
* @dev Takes an order hash (e.g. offerer shifted 96 bits to the left XOR'd
* with the contract nonce in the case of contract orders), an
* OrderParameters struct, context bytes array, and an array of order
* hashes for each order included as part of the current fulfillment
* and encodes it as `ratifyOrder` calldata.
*
* @param orderHash The order hash (e.g. shl(0x60, offerer) ^ nonce).
* @param orderParameters The OrderParameters struct used to construct the
* encoded `ratifyOrder` calldata.
* @param context The context bytes array used to construct the
* encoded `ratifyOrder` calldata.
* @param orderHashes An array of bytes32 values representing the order
* hashes of all orders included as part of the
* current fulfillment.
* @param shiftedOfferer The offerer for the order, shifted 96 bits to the
* left.
*
* @return dst A memory pointer referencing the encoded `ratifyOrder`
* calldata.
* @return size The size of the bytes array.
*/
function _encodeRatifyOrder(
bytes32 orderHash, // e.g. shl(0x60, offerer) ^ contract nonce
OrderParameters memory orderParameters,
bytes memory context, // encoded based on the schemaID
bytes32[] memory orderHashes,
uint256 shiftedOfferer
) internal view returns (MemoryPointer dst, uint256 size) {
// Get free memory pointer to write calldata to. This isn't allocated as
// it is only used for a single function call.
dst = getFreeMemoryPointer();
// Write ratifyOrder selector and get pointer to start of calldata.
dst.write(ratifyOrder_selector);
dst = dst.offset(ratifyOrder_selector_offset);
// Get pointer to the beginning of the encoded data.
MemoryPointer dstHead = dst.offset(ratifyOrder_head_offset);
// Write contractNonce to calldata via xor(orderHash, shiftedOfferer).
dstHead.offset(ratifyOrder_contractNonce_offset).write(
uint256(orderHash) ^ shiftedOfferer
);
// Initialize tail offset, used to populate the offer array.
uint256 tailOffset = ratifyOrder_base_tail_offset;
MemoryPointer src = orderParameters.toMemoryPointer();
// Write offset to `offer`.
dstHead.write(tailOffset);
// Get memory pointer to `orderParameters.offer.length`.
MemoryPointer srcOfferPointer = src
.offset(OrderParameters_offer_head_offset)
.readMemoryPointer();
// Encode the offer array as a `SpentItem[]`.
uint256 offerSize = _encodeSpentItems(
srcOfferPointer,
dstHead.offset(tailOffset)
);
unchecked {
// Increment tail offset, now used to populate consideration array.
tailOffset += offerSize;
}
// Write offset to consideration.
dstHead.offset(ratifyOrder_consideration_head_offset).write(tailOffset);
// Get pointer to `orderParameters.consideration.length`.
MemoryPointer srcConsiderationPointer = src
.offset(OrderParameters_consideration_head_offset)
.readMemoryPointer();
// Encode the consideration array as a `ReceivedItem[]`.
uint256 considerationSize = _encodeConsiderationAsReceivedItems(
srcConsiderationPointer,
dstHead.offset(tailOffset)
);
unchecked {
// Increment tail offset, now used to populate context array.
tailOffset += considerationSize;
}
// Write offset to context.
dstHead.offset(ratifyOrder_context_head_offset).write(tailOffset);
// Encode context.
uint256 contextSize = _encodeBytes(
toMemoryPointer(context),
dstHead.offset(tailOffset)
);
unchecked {
// Increment tail offset, now used to populate orderHashes array.
tailOffset += contextSize;
}
// Write offset to orderHashes.
dstHead.offset(ratifyOrder_orderHashes_head_offset).write(tailOffset);
// Encode orderHashes.
uint256 orderHashesSize = _encodeOrderHashes(
toMemoryPointer(orderHashes),
dstHead.offset(tailOffset)
);
unchecked {
// Increment the tail offset, now used to determine final size.
tailOffset += orderHashesSize;
// Derive the final size by including the selector.
size = Selector_length + tailOffset;
}
}
/**
* @dev Takes an order hash, OrderParameters struct, extraData bytes array,
* and array of order hashes for each order included as part of the
* current fulfillment and encodes it as `authorizeOrder` calldata.
* Note that future, new versions of this contract may end up writing
* to a memory region that might have been potentially dirtied by the
* accumulator. Since the book-keeping for the accumulator does not
* update the free memory pointer, it will be necessary to ensure that
* all bytes in the memory in the range [dst, dst+size) are fully
* updated/written to in this function.
*
* @param orderHash The order hash.
* @param orderParameters The OrderParameters struct used to construct the
* encoded `authorizeOrder` calldata.
* @param extraData The extraData bytes array used to construct the
* encoded `authorizeOrder` calldata.
* @param orderHashes An array of bytes32 values representing the order
* hashes of all available orders validated thus far
* as part of current fulfillment.
* Note that this differs from the orderHashes array
* passed to `validateOrder` in that the latter
* includes *all* available and validated orders
* in the final fulfillment, as it is only a subset
* of the final fulfilled orderHashes.
*
* @return dst A memory pointer referencing the encoded `authorizeOrder`
* calldata.
* @return size The size of the bytes array.
*/
function _encodeAuthorizeOrder(
bytes32 orderHash,
OrderParameters memory orderParameters,
bytes memory extraData,
bytes32[] memory orderHashes,
uint256 orderIndex
) internal view returns (MemoryPointer dst, uint256 size) {
// Get free memory pointer to write calldata to.
MemoryPointer ptr = getFreeMemoryPointer();
dst = ptr;
// Write authorizeOrder selector and get pointer to start of calldata.
dst.write(authorizeOrder_selector);
dst = dst.offset(authorizeOrder_selector_offset);
// Get pointer to the beginning of the encoded data.
MemoryPointer dstHead = dst.offset(authorizeOrder_head_offset);
// Write offset to zoneParameters to start of calldata.
dstHead.write(authorizeOrder_zoneParameters_offset);
// Reuse `dstHead` as pointer to zoneParameters.
dstHead = dstHead.offset(authorizeOrder_zoneParameters_offset);
// Write orderHash and fulfiller to zoneParameters.
dstHead.writeBytes32(orderHash);
dstHead.offset(ZoneParameters_fulfiller_offset).write(msg.sender);
// Get the memory pointer to the order parameters struct.
MemoryPointer src = orderParameters.toMemoryPointer();
// Copy offerer, startTime, endTime and zoneHash to zoneParameters.
dstHead.offset(ZoneParameters_offerer_offset).write(src.readUint256());
dstHead.offset(ZoneParameters_startTime_offset).write(
src.offset(OrderParameters_startTime_offset).readUint256()
);
dstHead.offset(ZoneParameters_endTime_offset).write(
src.offset(OrderParameters_endTime_offset).readUint256()
);
dstHead.offset(ZoneParameters_zoneHash_offset).write(
src.offset(OrderParameters_zoneHash_offset).readUint256()
);
// Initialize tail offset, used to populate the offer array.
uint256 tailOffset = ZoneParameters_base_tail_offset;
// Write offset to `offer`.
dstHead.offset(ZoneParameters_offer_head_offset).write(tailOffset);
// Get pointer to `orderParameters.offer.length`.
MemoryPointer srcOfferPointer = src
.offset(OrderParameters_offer_head_offset)
.readMemoryPointer();
// Encode the offer array as a `SpentItem[]`.
uint256 offerSize = _encodeSpentItems(
srcOfferPointer,
dstHead.offset(tailOffset)
);
unchecked {
// Increment tail offset, now used to populate consideration array.
tailOffset += offerSize;
}
// Write offset to consideration.
dstHead.offset(ZoneParameters_consideration_head_offset).write(
tailOffset
);
// Get pointer to `orderParameters.consideration.length`.
MemoryPointer srcConsiderationPointer = src
.offset(OrderParameters_consideration_head_offset)
.readMemoryPointer();
// Encode the consideration array as a `ReceivedItem[]`.
uint256 considerationSize = _encodeConsiderationAsReceivedItems(
srcConsiderationPointer,
dstHead.offset(tailOffset)
);
unchecked {
// Increment tail offset, now used to populate extraData array.
tailOffset += considerationSize;
}
// Write offset to extraData.
dstHead.offset(ZoneParameters_extraData_head_offset).write(tailOffset);
unchecked {
// Copy extraData.
uint256 extraDataSize = _encodeBytes(
toMemoryPointer(extraData),
dstHead.offset(tailOffset)
);
// Increment tail offset, now used to populate orderHashes array.
tailOffset += extraDataSize;
}
// Write offset to orderHashes.
dstHead.offset(ZoneParameters_orderHashes_head_offset).write(
tailOffset
);
// Encode the order hashes array.
MemoryPointer orderHashesLengthLocation = dstHead.offset(tailOffset);
unchecked {
uint256 orderHashesSize = _encodeOrderHashes(
toMemoryPointer(orderHashes),
orderHashesLengthLocation
);
// Increment the tail offset, now used to determine final size.
tailOffset += orderHashesSize;
// Derive final size including selector and ZoneParameters pointer.
size = ZoneParameters_selectorAndPointer_length + tailOffset;
}
// Update the free memory pointer.
setFreeMemoryPointer(dst.offset(size));
// Track the pointer, size (when performing validateOrder) and pointer
// to orderHashes length by overriding the salt value on the order.
orderParameters.salt = ((MemoryPointer.unwrap(ptr) << 128) |
(size << 64) |
MemoryPointer.unwrap(orderHashesLengthLocation));
// Write the shortened orderHashes array length.
orderHashesLengthLocation.write(orderIndex);
// Modify encoding size to account for the shorter orderHashes array.
size -= (orderHashes.length - orderIndex) << OneWordShift;
}
/**
* @dev Takes an order hash, OrderParameters struct, extraData bytes array,
* and array of order hashes for each order included as part of the
* current fulfillment and encodes it as `validateOrder` calldata.
* Note that future, new versions of this contract may end up writing
* to a memory region that might have been potentially dirtied by the
* accumulator. Since the book-keeping for the accumulator does not
* update the free memory pointer, it will be necessary to ensure that
* all bytes in the memory in the range [dst, dst+size) are fully
* updated/written to in this function.
*
* @param salt The salt on the order, which has been repurposed
* to contain relevant pointers and encoding size.
* @param orderHashes An array of bytes32 values representing the order
* hashes of all orders included as part of the
* current fulfillment.
*
* @return dst A memory pointer referencing the encoded `validateOrder`
* calldata.
* @return size The size of the bytes array.
*/
function _encodeValidateOrder(
uint256 salt,
bytes32[] memory orderHashes
) internal view returns (MemoryPointer dst, uint256 size) {
dst = MemoryPointer.wrap(salt >> 128);
size = (salt >> 64) & OffsetOrLengthMask;
MemoryPointer orderHashesLengthLocation = MemoryPointer.wrap(
salt & OffsetOrLengthMask
);
// Write validateOrder selector.
dst.write(validateOrder_selector);
dst = dst.offset(validateOrder_selector_offset);
// Encode the order hashes array. Note that this currently modifies
// order hashes that are known to be properly encoded already and could
// therefore be skipped.
_encodeOrderHashes(
toMemoryPointer(orderHashes),
orderHashesLengthLocation
);
}
/**
* @dev Takes an order hash and BasicOrderParameters struct (from calldata)
* and encodes it as `authorizeOrder` calldata. Note that memory data
* is reused from `OrderFulfilled` event data, and the rest of the
* calldata is prefixed and postfixed to this memory region. Note that
* the memory region before the spent and received items on the
* `OrderFulfilled` event are overwritten, which implies that this
* function will need to be modified should the layout of that event
* data change in the future.
*
* @param orderHash The order hash.
*
* @return ptr A memory pointer referencing the encoded `authorizeOrder`
* calldata with extra padding at the start to word align.
* @return size The size of the bytes array.
*/
function _encodeAuthorizeBasicOrder(
bytes32 orderHash
)
internal
view
returns (
MemoryPointer ptr,
uint256 size,
uint256 memoryLocationForOrderHashes
)
{
unchecked {
// Derive offset to pre `OrderFulfilled`'s spent item event data
// using base offset & total original recipients.
ptr = MemoryPointer.wrap(
authorizeOrder_calldata_baseOffset +
(CalldataPointer
.wrap(
BasicOrder_totalOriginalAdditionalRecipients_cdPtr
)
.readUint256() << OneWordShift)
);
}
MemoryPointer dst = ptr;
// Write authorizeOrder selector and get pointer to start of calldata.
dst.write(authorizeOrder_selector);
dst = dst.offset(authorizeOrder_selector_offset);
// Get pointer to the beginning of the encoded data.
MemoryPointer dstHead = dst.offset(authorizeOrder_head_offset);
// Write offset to zoneParameters to start of calldata.
dstHead.write(authorizeOrder_zoneParameters_offset);
// Reuse `dstHead` as pointer to zoneParameters.
dstHead = dstHead.offset(authorizeOrder_zoneParameters_offset);
// Write offerer, orderHash and fulfiller to zoneParameters.
dstHead.writeBytes32(orderHash);
dstHead.offset(ZoneParameters_fulfiller_offset).write(msg.sender);
dstHead.offset(ZoneParameters_offerer_offset).write(
CalldataPointer.wrap(BasicOrder_offerer_cdPtr).readAddress()
);
// Copy startTime, endTime and zoneHash to zoneParameters.
CalldataPointer.wrap(BasicOrder_startTime_cdPtr).copy(
dstHead.offset(ZoneParameters_startTime_offset),
BasicOrder_startTimeThroughZoneHash_size
);
// Initialize tail offset, used for the offer + consideration arrays.
uint256 tailOffset = ZoneParameters_base_tail_offset;
// Write offset to offer from event data into target calldata.
dstHead.offset(ZoneParameters_offer_head_offset).write(tailOffset);
unchecked {
// Write consideration offset next (located 5 words after offer).
dstHead.offset(ZoneParameters_consideration_head_offset).write(
tailOffset + BasicOrder_consideration_offset_from_offer
);
// Retrieve the length of additional recipients.
uint256 additionalRecipientsLength = CalldataPointer
.wrap(BasicOrder_addlRecipients_length_cdPtr)
.readUint256();
// Derive size of offer and consideration data.
// 2 words (lengths) + 4 (offer data) + 5 (consideration 1) + 5 * ar
uint256 offerAndConsiderationSize = OrderFulfilled_baseDataSize +
(additionalRecipientsLength * ReceivedItem_size);
// Increment tail offset, now used to populate extraData array.
tailOffset += offerAndConsiderationSize;
}
// Write empty bytes for extraData.
dstHead.offset(ZoneParameters_extraData_head_offset).write(tailOffset);
dstHead.offset(tailOffset).write(0);
unchecked {
// Increment tail offset, now used to populate orderHashes array.
tailOffset += OneWord;
}
// Write offset to orderHashes.
dstHead.offset(ZoneParameters_orderHashes_head_offset).write(
tailOffset
);
memoryLocationForOrderHashes = MemoryPointer.unwrap(
dstHead.offset(tailOffset)
);
// Write length = 0 to the orderHashes array.
dstHead.offset(tailOffset).write(0);
unchecked {
// Write the single order hash to the orderHashes array.
dstHead.offset(tailOffset + OneWord).writeBytes32(orderHash);
// Final size: selector, ZoneParameters pointer, orderHashes & tail.
size = ZoneParameters_basicOrderFixedElements_length + tailOffset;
}
}
/**
* @dev Takes pointers to already-encoded data and modifies it so that
* it is properly formatted for a `validateOrder` call.
*
* @param dst A memory pointer referencing the
* encoded `validateOrder` calldata.
* @param memoryLocationForOrderHashes A memory pointer referencing where
* to encode orderHashes length of 1.
*/
function _encodeValidateBasicOrder(
MemoryPointer dst,
uint256 memoryLocationForOrderHashes
) internal pure {
// Write validateOrder selector and get pointer to start of calldata.
dst.write(validateOrder_selector);
// Write length = 1 to the orderHashes array. Note that size should now
// be one word larger than the provided size.
MemoryPointer.wrap(memoryLocationForOrderHashes).write(1);
}
/**
* @dev Takes a memory pointer to an array of bytes32 values representing
* the order hashes included as part of the fulfillment and a memory
* pointer to a location to copy it to, and copies the source data to
* the destination in memory.
*
* @param srcLength A memory pointer referencing the order hashes array to
* be copied (and pointing to the length of the array).
* @param dstLength A memory pointer referencing the location in memory to
* copy the orderHashes array to (and pointing to the
* length of the copied array).
*
* @return size The size of the order hashes array (including the length).
*/
function _encodeOrderHashes(
MemoryPointer srcLength,
MemoryPointer dstLength
) internal view returns (uint256 size) {
// Read length of the array from source and write to destination.
uint256 length = srcLength.readUint256();
dstLength.write(length);
unchecked {
// Determine head & tail size as one word per element in the array.
uint256 headAndTailSize = length << OneWordShift;
// Copy the tail starting from the next element of the source to the
// next element of the destination.
srcLength.next().copy(dstLength.next(), headAndTailSize);
// Set size to the length of the tail plus one word for length.
size = headAndTailSize + OneWord;
}
}
/**
* @dev Takes a memory pointer to an offer or consideration array and a
* memory pointer to a location to copy it to, and copies the source
* data to the destination in memory as a SpentItem array.
*
* @param srcLength A memory pointer referencing the offer or consideration
* array to be copied as a SpentItem array (and pointing to
* the length of the original array).
* @param dstLength A memory pointer referencing the location in memory to
* copy the offer array to (and pointing to the length of
* the copied array).
*
* @return size The size of the SpentItem array (including the length).
*/
function _encodeSpentItems(
MemoryPointer srcLength,
MemoryPointer dstLength
) internal pure returns (uint256 size) {
assembly {
// Read length of the array from source and write to destination.
let length := mload(srcLength)
mstore(dstLength, length)
// Get pointer to first item's head position in the array,
// containing the item's pointer in memory. The head pointer will be
// incremented until it reaches the tail position (start of the
// array data).
let mPtrHead := add(srcLength, OneWord)
// Position in memory to write next item for calldata. Since
// SpentItem has a fixed length, the array elements do not contain
// head elements in calldata, they are concatenated together after
// the array length.
let cdPtrData := add(dstLength, OneWord)
// Pointer to end of array head in memory.
let mPtrHeadEnd := add(mPtrHead, shl(OneWordShift, length))
for {
} lt(mPtrHead, mPtrHeadEnd) {
} {
// Read pointer to data for array element from head position.
let mPtrTail := mload(mPtrHead)
// Copy itemType, token, identifier, amount to calldata.
mstore(cdPtrData, mload(mPtrTail))
mstore(
add(cdPtrData, Common_token_offset),
mload(add(mPtrTail, Common_token_offset))
)
mstore(
add(cdPtrData, Common_identifier_offset),
mload(add(mPtrTail, Common_identifier_offset))
)
mstore(
add(cdPtrData, Common_amount_offset),
mload(add(mPtrTail, Common_amount_offset))
)
mPtrHead := add(mPtrHead, OneWord)
cdPtrData := add(cdPtrData, SpentItem_size)
}
size := add(OneWord, shl(SpentItem_size_shift, length))
}
}
/**
* @dev Takes a memory pointer to an consideration array and a memory
* pointer to a location to copy it to, and copies the source data to
* the destination in memory as a ReceivedItem array.
*
* @param srcLength A memory pointer referencing the consideration array to
* be copied as a ReceivedItem array (and pointing to the
* length of the original array).
* @param dstLength A memory pointer referencing the location in memory to
* copy the consideration array to as a ReceivedItem array
* (and pointing to the length of the new array).
*
* @return size The size of the ReceivedItem array (including the length).
*/
function _encodeConsiderationAsReceivedItems(
MemoryPointer srcLength,
MemoryPointer dstLength
) internal view returns (uint256 size) {
unchecked {
// Read length of the array from source and write to destination.
uint256 length = srcLength.readUint256();
dstLength.write(length);
// Get pointer to first item's head position in the array,
// containing the item's pointer in memory. The head pointer will be
// incremented until it reaches the tail position (start of the
// array data).
MemoryPointer srcHead = srcLength.next();
MemoryPointer srcHeadEnd = srcHead.offset(length << OneWordShift);
// Position in memory to write next item for calldata. Since
// ReceivedItem has a fixed length, the array elements do not
// contain offsets in calldata, they are concatenated together after
// the array length.
MemoryPointer dstHead = dstLength.next();
while (srcHead.lt(srcHeadEnd)) {
MemoryPointer srcTail = srcHead.pptr();
srcTail.copy(dstHead, ReceivedItem_size);
srcHead = srcHead.next();
dstHead = dstHead.offset(ReceivedItem_size);
}
size = OneWord + (length * ReceivedItem_size);
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
import { ConduitItemType } from "./ConduitEnums.sol";
/**
* @dev A ConduitTransfer is a struct that contains the information needed for a
* conduit to transfer an item from one address to another.
*/
struct ConduitTransfer {
ConduitItemType itemType;
address token;
address from;
address to;
uint256 identifier;
uint256 amount;
}
/**
* @dev A ConduitBatch1155Transfer is a struct that contains the information
* needed for a conduit to transfer a batch of ERC-1155 tokens from one
* address to another.
*/
struct ConduitBatch1155Transfer {
address token;
address from;
address to;
uint256[] ids;
uint256[] amounts;
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
OrderParameters
} from "seaport-types/src/lib/ConsiderationStructs.sol";
import { GettersAndDerivers } from "./GettersAndDerivers.sol";
import {
TokenTransferrerErrors
} from "seaport-types/src/interfaces/TokenTransferrerErrors.sol";
import { CounterManager } from "./CounterManager.sol";
import {
AdditionalRecipient_size_shift,
AddressDirtyUpperBitThreshold,
BasicOrder_additionalRecipients_head_cdPtr,
BasicOrder_additionalRecipients_head_ptr,
BasicOrder_addlRecipients_length_cdPtr,
BasicOrder_basicOrderType_cdPtr,
BasicOrder_basicOrderType_range,
BasicOrder_considerationToken_cdPtr,
BasicOrder_offerer_cdPtr,
BasicOrder_offerToken_cdPtr,
BasicOrder_parameters_cdPtr,
BasicOrder_parameters_ptr,
BasicOrder_signature_cdPtr,
BasicOrder_signature_ptr,
BasicOrder_zone_cdPtr
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
Error_selector_offset,
MissingItemAmount_error_length,
MissingItemAmount_error_selector
} from "seaport-types/src/lib/ConsiderationErrorConstants.sol";
import {
_revertInvalidBasicOrderParameterEncoding,
_revertMissingOriginalConsiderationItems
} from "seaport-types/src/lib/ConsiderationErrors.sol";
/**
* @title Assertions
* @author 0age
* @notice Assertions contains logic for making various assertions that do not
* fit neatly within a dedicated semantic scope.
*/
contract Assertions is
GettersAndDerivers,
CounterManager,
TokenTransferrerErrors
{
/**
* @dev Derive and set hashes, reference chainId, and associated domain
* separator during deployment.
*
* @param conduitController A contract that deploys conduits, or proxies
* that may optionally be used to transfer approved
* ERC20/721/1155 tokens.
*/
constructor(
address conduitController
) GettersAndDerivers(conduitController) {}
/**
* @dev Internal view function to ensure that the supplied consideration
* array length on a given set of order parameters is not less than the
* original consideration array length for that order and to retrieve
* the current counter for a given order's offerer and zone and use it
* to derive the order hash.
*
* @param orderParameters The parameters of the order to hash.
*
* @return The hash.
*/
function _assertConsiderationLengthAndGetOrderHash(
OrderParameters memory orderParameters
) internal view returns (bytes32) {
// Ensure supplied consideration array length is not less than original.
_assertConsiderationLengthIsNotLessThanOriginalConsiderationLength(
orderParameters.consideration.length,
orderParameters.totalOriginalConsiderationItems
);
// Derive and return order hash using current counter for the offerer.
return
_deriveOrderHash(
orderParameters,
_getCounter(orderParameters.offerer)
);
}
/**
* @dev Internal pure function to ensure that the supplied consideration
* array length for an order to be fulfilled is not less than the
* original consideration array length for that order.
*
* @param suppliedConsiderationItemTotal The number of consideration items
* supplied when fulfilling the order.
* @param originalConsiderationItemTotal The number of consideration items
* supplied on initial order creation.
*/
function _assertConsiderationLengthIsNotLessThanOriginalConsiderationLength(
uint256 suppliedConsiderationItemTotal,
uint256 originalConsiderationItemTotal
) internal pure {
// Ensure supplied consideration array length is not less than original.
if (suppliedConsiderationItemTotal < originalConsiderationItemTotal) {
_revertMissingOriginalConsiderationItems();
}
}
/**
* @dev Internal pure function to ensure that a given item amount is not
* zero.
*
* @param amount The amount to check.
*/
function _assertNonZeroAmount(uint256 amount) internal pure {
assembly {
if iszero(amount) {
// Store left-padded selector with push4, mem[28:32] = selector
mstore(0, MissingItemAmount_error_selector)
// revert(abi.encodeWithSignature("MissingItemAmount()"))
revert(Error_selector_offset, MissingItemAmount_error_length)
}
}
}
/**
* @dev Internal pure function to validate calldata offsets for dynamic
* types in BasicOrderParameters and other parameters. This ensures
* that functions using the calldata object normally will be using the
* same data as the assembly functions and that values that are bound
* to a given range are within that range. Note that no parameters are
* supplied as all basic order functions use the same calldata
* encoding.
*/
function _assertValidBasicOrderParameters() internal pure {
// Declare a boolean designating basic order parameter offset validity.
bool validOffsets;
// Utilize assembly in order to read offset data directly from calldata.
assembly {
/*
* Checks:
* 1. Order parameters struct offset == 0x20
* 2. Additional recipients arr offset == 0x240
* 3. Signature offset == 0x260 + (recipients.length * 0x40)
* 4. BasicOrderType between 0 and 23 (i.e. < 24)
* 5. Offerer, zone, offer token, and consideration token have no
* upper dirty bits — each argument is type(uint160).max or less
*/
validOffsets := and(
and(
and(
// Order parameters at cd 0x04 offset = 0x20.
eq(
calldataload(BasicOrder_parameters_cdPtr),
BasicOrder_parameters_ptr
),
// Additional recipients at cd 0x224 offset = 0x240.
eq(
calldataload(
BasicOrder_additionalRecipients_head_cdPtr
),
BasicOrder_additionalRecipients_head_ptr
)
),
// Signature offset = 0x260 + recipients.length * 0x40.
eq(
// Load signature offset from calldata 0x244.
calldataload(BasicOrder_signature_cdPtr),
// Expected offset = start of recipients + len * 64.
add(
BasicOrder_signature_ptr,
shl(
// Each additional recipient length = 0x40.
AdditionalRecipient_size_shift,
// Additional recipients length at cd 0x264.
calldataload(
BasicOrder_addlRecipients_length_cdPtr
)
)
)
)
),
and(
// Ensure BasicOrderType parameter is less than 0x18.
lt(
// BasicOrderType parameter = calldata offset 0x124.
calldataload(BasicOrder_basicOrderType_cdPtr),
// Value should be less than 24.
BasicOrder_basicOrderType_range
),
// Ensure no dirty upper bits are present on offerer,
// zone, offer token, or consideration token.
lt(
or(
or(
// Offerer parameter = calldata offset 0x84.
calldataload(BasicOrder_offerer_cdPtr),
// Zone parameter = calldata offset 0xa4.
calldataload(BasicOrder_zone_cdPtr)
),
or(
// Offer token parameter = cd offset 0xc4.
calldataload(BasicOrder_offerToken_cdPtr),
// Consideration parameter = offset 0x24.
calldataload(
BasicOrder_considerationToken_cdPtr
)
)
),
AddressDirtyUpperBitThreshold
)
)
)
}
// Revert with an error if basic order parameter offsets are invalid.
if (!validOffsets) {
_revertInvalidBasicOrderParameterEncoding();
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
SignatureVerificationErrors
} from "seaport-types/src/interfaces/SignatureVerificationErrors.sol";
import { LowLevelHelpers } from "./LowLevelHelpers.sol";
import {
ECDSA_MaxLength,
ECDSA_signature_s_offset,
ECDSA_signature_v_offset,
ECDSA_twentySeventhAndTwentyEighthBytesSet,
Ecrecover_args_size,
Ecrecover_precompile,
EIP1271_isValidSignature_calldata_baseLength,
EIP1271_isValidSignature_digest_negativeOffset,
EIP1271_isValidSignature_selector_negativeOffset,
EIP1271_isValidSignature_selector,
EIP1271_isValidSignature_signature_head_offset,
EIP2098_allButHighestBitMask,
MaxUint8,
OneWord,
Signature_lower_v
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
BadContractSignature_error_length,
BadContractSignature_error_selector,
BadSignatureV_error_length,
BadSignatureV_error_selector,
BadSignatureV_error_v_ptr,
Error_selector_offset,
InvalidSignature_error_length,
InvalidSignature_error_selector,
InvalidSigner_error_length,
InvalidSigner_error_selector
} from "seaport-types/src/lib/ConsiderationErrorConstants.sol";
/**
* @title SignatureVerification
* @author 0age
* @notice SignatureVerification contains logic for verifying signatures.
*/
contract SignatureVerification is SignatureVerificationErrors, LowLevelHelpers {
/**
* @dev Internal view function to verify the signature of an order. An
* ERC-1271 fallback will be attempted if either the signature length
* is not 64 or 65 bytes or if the recovered signer does not match the
* supplied signer.
*
* @param signer The signer for the order.
* @param digest The digest to verify signature against.
* @param originalDigest The original digest to verify signature
* against.
* @param originalSignatureLength The original signature length.
* @param signature A signature from the signer indicating
* that the order has been approved.
*/
function _assertValidSignature(
address signer,
bytes32 digest,
bytes32 originalDigest,
uint256 originalSignatureLength,
bytes memory signature
) internal view {
// Declare value for ecrecover equality or 1271 call success status.
bool success;
// Utilize assembly to perform optimized signature verification check.
assembly {
// Ensure that first word of scratch space is empty.
mstore(0, 0)
// Get the length of the signature.
let signatureLength := mload(signature)
// Get the pointer to the value preceding the signature length.
// This will be used for temporary memory overrides - either the
// signature head for isValidSignature or the digest for ecrecover.
let wordBeforeSignaturePtr := sub(signature, OneWord)
// Cache the current value behind the signature to restore it later.
let cachedWordBeforeSignature := mload(wordBeforeSignaturePtr)
// Declare lenDiff + recoveredSigner scope to manage stack pressure.
{
// Take the difference between the max ECDSA signature length
// and the actual signature length. Overflow desired for any
// values > 65. If the diff is not 0 or 1, it is not a valid
// ECDSA signature - move on to EIP1271 check.
let lenDiff := sub(ECDSA_MaxLength, signatureLength)
// Declare variable for recovered signer.
let recoveredSigner
// If diff is 0 or 1, it may be an ECDSA signature.
// Try to recover signer.
if iszero(gt(lenDiff, 1)) {
// Read the signature `s` value.
let originalSignatureS := mload(
add(signature, ECDSA_signature_s_offset)
)
// Read the first byte of the word after `s`. If the
// signature is 65 bytes, this will be the real `v` value.
// If not, it will need to be modified - doing it this way
// saves an extra condition.
let v := byte(
0,
mload(add(signature, ECDSA_signature_v_offset))
)
// If lenDiff is 1, parse 64-byte signature as ECDSA.
if lenDiff {
// Extract yParity from highest bit of vs and add 27 to
// get v.
v := add(
shr(MaxUint8, originalSignatureS),
Signature_lower_v
)
// Extract canonical s from vs, all but the highest bit.
// Temporarily overwrite the original `s` value in the
// signature.
mstore(
add(signature, ECDSA_signature_s_offset),
and(
originalSignatureS,
EIP2098_allButHighestBitMask
)
)
}
// Temporarily overwrite the signature length with `v` to
// conform to the expected input for ecrecover.
mstore(signature, v)
// Temporarily overwrite the word before the length with
// `digest` to conform to the expected input for ecrecover.
mstore(wordBeforeSignaturePtr, digest)
// Attempt to recover the signer for the given signature. Do
// not check the call status as ecrecover will return a null
// address if the signature is invalid.
pop(
staticcall(
gas(),
Ecrecover_precompile, // Call ecrecover precompile.
wordBeforeSignaturePtr, // Use data memory location.
Ecrecover_args_size, // Size of digest, v, r, and s.
0, // Write result to scratch space.
OneWord // Provide size of returned result.
)
)
// Restore cached word before signature.
mstore(wordBeforeSignaturePtr, cachedWordBeforeSignature)
// Restore cached signature length.
mstore(signature, signatureLength)
// Restore cached signature `s` value.
mstore(
add(signature, ECDSA_signature_s_offset),
originalSignatureS
)
// Read the recovered signer from the buffer given as return
// space for ecrecover.
recoveredSigner := mload(0)
}
// Set success to true if the signature provided was a valid
// ECDSA signature and the signer is not the null address. Use
// gt instead of direct as success is used outside of assembly.
success := and(eq(signer, recoveredSigner), gt(signer, 0))
}
// If the signature was not verified with ecrecover, try EIP1271.
if iszero(success) {
// Reset the original signature length.
mstore(signature, originalSignatureLength)
// Temporarily overwrite the word before the signature length
// and use it as the head of the signature input to
// `isValidSignature`, which has a value of 64.
mstore(
wordBeforeSignaturePtr,
EIP1271_isValidSignature_signature_head_offset
)
// Get pointer to use for the selector of `isValidSignature`.
let selectorPtr := sub(
signature,
EIP1271_isValidSignature_selector_negativeOffset
)
// Cache the value currently stored at the selector pointer.
let cachedWordOverwrittenBySelector := mload(selectorPtr)
// Cache the value currently stored at the digest pointer.
let cachedWordOverwrittenByDigest := mload(
sub(
signature,
EIP1271_isValidSignature_digest_negativeOffset
)
)
// Write the selector first, since it overlaps the digest.
mstore(selectorPtr, EIP1271_isValidSignature_selector)
// Next, write the original digest.
mstore(
sub(
signature,
EIP1271_isValidSignature_digest_negativeOffset
),
originalDigest
)
// Call signer with `isValidSignature` to validate signature.
success := staticcall(
gas(),
signer,
selectorPtr,
add(
originalSignatureLength,
EIP1271_isValidSignature_calldata_baseLength
),
0,
OneWord
)
// Determine if the signature is valid on successful calls.
if success {
// If first word of scratch space does not contain EIP-1271
// signature selector, revert.
if iszero(eq(mload(0), EIP1271_isValidSignature_selector)) {
// Revert with bad 1271 signature if signer has code.
if extcodesize(signer) {
// Bad contract signature.
// Store left-padded selector with push4, mem[28:32]
mstore(0, BadContractSignature_error_selector)
// revert(abi.encodeWithSignature(
// "BadContractSignature()"
// ))
revert(
Error_selector_offset,
BadContractSignature_error_length
)
}
// Check if signature length was invalid.
if gt(sub(ECDSA_MaxLength, signatureLength), 1) {
// Revert with generic invalid signature error.
// Store left-padded selector with push4, mem[28:32]
mstore(0, InvalidSignature_error_selector)
// revert(abi.encodeWithSignature(
// "InvalidSignature()"
// ))
revert(
Error_selector_offset,
InvalidSignature_error_length
)
}
// Check if v was invalid.
if and(
eq(signatureLength, ECDSA_MaxLength),
iszero(
byte(
byte(
0,
mload(
add(
signature,
ECDSA_signature_v_offset
)
)
),
ECDSA_twentySeventhAndTwentyEighthBytesSet
)
)
) {
// Revert with invalid v value.
// Store left-padded selector with push4, mem[28:32]
mstore(0, BadSignatureV_error_selector)
mstore(
BadSignatureV_error_v_ptr,
byte(
0,
mload(
add(signature, ECDSA_signature_v_offset)
)
)
)
// revert(abi.encodeWithSignature(
// "BadSignatureV(uint8)", v
// ))
revert(
Error_selector_offset,
BadSignatureV_error_length
)
}
// Revert with generic invalid signer error message.
// Store left-padded selector with push4, mem[28:32]
mstore(0, InvalidSigner_error_selector)
// revert(abi.encodeWithSignature("InvalidSigner()"))
revert(
Error_selector_offset,
InvalidSigner_error_length
)
}
}
// Restore the cached values overwritten by selector, digest and
// signature head.
mstore(wordBeforeSignaturePtr, cachedWordBeforeSignature)
mstore(selectorPtr, cachedWordOverwrittenBySelector)
mstore(
sub(
signature,
EIP1271_isValidSignature_digest_negativeOffset
),
cachedWordOverwrittenByDigest
)
}
}
// If the call failed...
if (!success) {
// Revert and pass reason along if one was returned.
_revertWithReasonIfOneIsReturned();
// Otherwise, revert with error indicating bad contract signature.
assembly {
// Store left-padded selector with push4, mem[28:32] = selector
mstore(0, BadContractSignature_error_selector)
// revert(abi.encodeWithSignature("BadContractSignature()"))
revert(Error_selector_offset, BadContractSignature_error_length)
}
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
/*
* -------------------------- Disambiguation & Other Notes ---------------------
* - The term "head" is used as it is in the documentation for ABI encoding,
* but only in reference to dynamic types, i.e. it always refers to the
* offset or pointer to the body of a dynamic type. In calldata, the head
* is always an offset (relative to the parent object), while in memory,
* the head is always the pointer to the body. More information found here:
* https://docs.soliditylang.org/en/v0.8.17/abi-spec.html#argument-encoding
* - Note that the length of an array is separate from and precedes the
* head of the array.
*
* - The term "body" is used in place of the term "head" used in the ABI
* documentation. It refers to the start of the data for a dynamic type,
* e.g. the first word of a struct or the first word of the first element
* in an array.
*
* - The term "pointer" is used to describe the absolute position of a value
* and never an offset relative to another value.
* - The suffix "_ptr" refers to a memory pointer.
* - The suffix "_cdPtr" refers to a calldata pointer.
*
* - The term "offset" is used to describe the position of a value relative
* to some parent value. For example, OrderParameters_conduit_offset is the
* offset to the "conduit" value in the OrderParameters struct relative to
* the start of the body.
* - Note: Offsets are used to derive pointers.
*
* - Some structs have pointers defined for all of their fields in this file.
* Lines which are commented out are fields that are not used in the
* codebase but have been left in for readability.
*/
uint256 constant ThirtyOneBytes = 0x1f;
uint256 constant OneWord = 0x20;
uint256 constant TwoWords = 0x40;
uint256 constant ThreeWords = 0x60;
uint256 constant OneWordShift = 0x5;
uint256 constant TwoWordsShift = 0x6;
uint256 constant FreeMemoryPointerSlot = 0x40;
uint256 constant ZeroSlot = 0x60;
uint256 constant DefaultFreeMemoryPointer = 0x80;
uint256 constant Slot0x80 = 0x80;
uint256 constant Slot0xA0 = 0xa0;
uint256 constant Slot0xC0 = 0xc0;
uint256 constant Generic_error_selector_offset = 0x1c;
// abi.encodeWithSignature("transferFrom(address,address,uint256)")
uint256 constant ERC20_transferFrom_signature = (
0x23b872dd00000000000000000000000000000000000000000000000000000000
);
uint256 constant ERC20_transferFrom_sig_ptr = 0x0;
uint256 constant ERC20_transferFrom_from_ptr = 0x04;
uint256 constant ERC20_transferFrom_to_ptr = 0x24;
uint256 constant ERC20_transferFrom_amount_ptr = 0x44;
uint256 constant ERC20_transferFrom_length = 0x64; // 4 + 32 * 3 == 100
// abi.encodeWithSignature(
// "safeTransferFrom(address,address,uint256,uint256,bytes)"
// )
uint256 constant ERC1155_safeTransferFrom_signature = (
0xf242432a00000000000000000000000000000000000000000000000000000000
);
uint256 constant ERC1155_safeTransferFrom_sig_ptr = 0x0;
uint256 constant ERC1155_safeTransferFrom_from_ptr = 0x04;
uint256 constant ERC1155_safeTransferFrom_to_ptr = 0x24;
uint256 constant ERC1155_safeTransferFrom_id_ptr = 0x44;
uint256 constant ERC1155_safeTransferFrom_amount_ptr = 0x64;
uint256 constant ERC1155_safeTransferFrom_data_offset_ptr = 0x84;
uint256 constant ERC1155_safeTransferFrom_data_length_ptr = 0xa4;
uint256 constant ERC1155_safeTransferFrom_length = 0xc4; // 4 + 32 * 6 == 196
uint256 constant ERC1155_safeTransferFrom_data_length_offset = 0xa0;
// abi.encodeWithSignature(
// "safeBatchTransferFrom(address,address,uint256[],uint256[],bytes)"
// )
uint256 constant ERC1155_safeBatchTransferFrom_signature = (
0x2eb2c2d600000000000000000000000000000000000000000000000000000000
);
// bytes4 constant ERC1155_safeBatchTransferFrom_selector = bytes4(
// bytes32(ERC1155_safeBatchTransferFrom_signature)
// );
uint256 constant ERC721_transferFrom_signature = (
0x23b872dd00000000000000000000000000000000000000000000000000000000
);
uint256 constant ERC721_transferFrom_sig_ptr = 0x0;
uint256 constant ERC721_transferFrom_from_ptr = 0x04;
uint256 constant ERC721_transferFrom_to_ptr = 0x24;
uint256 constant ERC721_transferFrom_id_ptr = 0x44;
uint256 constant ERC721_transferFrom_length = 0x64; // 4 + 32 * 3 == 100
/*
* error NoContract(address account)
* - Defined in TokenTransferrerErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x00: account
* Revert buffer is memory[0x1c:0x40]
*/
uint256 constant NoContract_error_selector = 0x5f15d672;
uint256 constant NoContract_error_account_ptr = 0x20;
uint256 constant NoContract_error_length = 0x24;
/*
* error TokenTransferGenericFailure(
* address token,
* address from,
* address to,
* uint256 identifier,
* uint256 amount
* )
* - Defined in TokenTransferrerErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x20: token
* - 0x40: from
* - 0x60: to
* - 0x80: identifier
* - 0xa0: amount
* Revert buffer is memory[0x1c:0xc0]
*/
uint256 constant TokenTransferGenericFailure_error_selector = 0xf486bc87;
uint256 constant TokenTransferGenericFailure_error_token_ptr = 0x20;
uint256 constant TokenTransferGenericFailure_error_from_ptr = 0x40;
uint256 constant TokenTransferGenericFailure_error_to_ptr = 0x60;
uint256 constant TokenTransferGenericFailure_error_identifier_ptr = 0x80;
uint256 constant TokenTransferGenericFailure_err_identifier_ptr = 0x80;
uint256 constant TokenTransferGenericFailure_error_amount_ptr = 0xa0;
uint256 constant TokenTransferGenericFailure_error_length = 0xa4;
uint256 constant ExtraGasBuffer = 0x20;
uint256 constant CostPerWord = 0x3;
uint256 constant MemoryExpansionCoefficientShift = 0x9;
// Values are offset by 32 bytes in order to write the token to the beginning
// in the event of a revert
uint256 constant BatchTransfer1155Params_ptr = 0x24;
uint256 constant BatchTransfer1155Params_ids_head_ptr = 0x64;
uint256 constant BatchTransfer1155Params_amounts_head_ptr = 0x84;
uint256 constant BatchTransfer1155Params_data_head_ptr = 0xa4;
uint256 constant BatchTransfer1155Params_data_length_basePtr = 0xc4;
uint256 constant BatchTransfer1155Params_calldata_baseSize = 0xc4;
uint256 constant BatchTransfer1155Params_ids_length_ptr = 0xc4;
uint256 constant BatchTransfer1155Params_ids_length_offset = 0xa0;
// uint256 constant BatchTransfer1155Params_amounts_length_baseOffset = 0xc0;
// uint256 constant BatchTransfer1155Params_data_length_baseOffset = 0xe0;
uint256 constant ConduitBatch1155Transfer_usable_head_size = 0x80;
uint256 constant ConduitBatch1155Transfer_from_offset = 0x20;
uint256 constant ConduitBatch1155Transfer_ids_head_offset = 0x60;
// uint256 constant ConduitBatch1155Transfer_amounts_head_offset = 0x80;
uint256 constant ConduitBatch1155Transfer_ids_length_offset = 0xa0;
uint256 constant ConduitBatch1155Transfer_amounts_length_baseOffset = 0xc0;
// uint256 constant ConduitBatch1155Transfer_calldata_baseSize = 0xc0;
// Note: abbreviated version of above constant to adhere to line length limit.
uint256 constant ConduitBatchTransfer_amounts_head_offset = 0x80;
uint256 constant Invalid1155BatchTransferEncoding_ptr = 0x00;
uint256 constant Invalid1155BatchTransferEncoding_length = 0x04;
uint256 constant Invalid1155BatchTransferEncoding_selector = (
0xeba2084c00000000000000000000000000000000000000000000000000000000
);
uint256 constant ERC1155BatchTransferGenericFailure_error_signature = (
0xafc445e200000000000000000000000000000000000000000000000000000000
);
uint256 constant ERC1155BatchTransferGenericFailure_token_ptr = 0x04;
uint256 constant ERC1155BatchTransferGenericFailure_ids_offset = 0xc0;
/*
* error BadReturnValueFromERC20OnTransfer(
* address token, address from, address to, uint256 amount
* )
* - Defined in TokenTransferrerErrors.sol
* Memory layout:
* - 0x00: Left-padded selector (data begins at 0x1c)
* - 0x00: token
* - 0x20: from
* - 0x40: to
* - 0x60: amount
* Revert buffer is memory[0x1c:0xa0]
*/
uint256 constant BadReturnValueFromERC20OnTransfer_error_selector = 0x98891923;
uint256 constant BadReturnValueFromERC20OnTransfer_error_token_ptr = 0x20;
uint256 constant BadReturnValueFromERC20OnTransfer_error_from_ptr = 0x40;
uint256 constant BadReturnValueFromERC20OnTransfer_error_to_ptr = 0x60;
uint256 constant BadReturnValueFromERC20OnTransfer_error_amount_ptr = 0x80;
uint256 constant BadReturnValueFromERC20OnTransfer_error_length = 0x84;
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
/**
* @title TokenTransferrerErrors
*/
interface TokenTransferrerErrors {
/**
* @dev Revert with an error when an ERC721 transfer with amount other than
* one is attempted.
*
* @param amount The amount of the ERC721 tokens to transfer.
*/
error InvalidERC721TransferAmount(uint256 amount);
/**
* @dev Revert with an error when attempting to fulfill an order where an
* item has an amount of zero.
*/
error MissingItemAmount();
/**
* @dev Revert with an error when attempting to fulfill an order where an
* item has unused parameters. This includes both the token and the
* identifier parameters for native transfers as well as the identifier
* parameter for ERC20 transfers. Note that the conduit does not
* perform this check, leaving it up to the calling channel to enforce
* when desired.
*/
error UnusedItemParameters();
/**
* @dev Revert with an error when an ERC20, ERC721, or ERC1155 token
* transfer reverts.
*
* @param token The token for which the transfer was attempted.
* @param from The source of the attempted transfer.
* @param to The recipient of the attempted transfer.
* @param identifier The identifier for the attempted transfer.
* @param amount The amount for the attempted transfer.
*/
error TokenTransferGenericFailure(
address token,
address from,
address to,
uint256 identifier,
uint256 amount
);
/**
* @dev Revert with an error when a batch ERC1155 token transfer reverts.
*
* @param token The token for which the transfer was attempted.
* @param from The source of the attempted transfer.
* @param to The recipient of the attempted transfer.
* @param identifiers The identifiers for the attempted transfer.
* @param amounts The amounts for the attempted transfer.
*/
error ERC1155BatchTransferGenericFailure(
address token,
address from,
address to,
uint256[] identifiers,
uint256[] amounts
);
/**
* @dev Revert with an error when an ERC20 token transfer returns a falsey
* value.
*
* @param token The token for which the ERC20 transfer was attempted.
* @param from The source of the attempted ERC20 transfer.
* @param to The recipient of the attempted ERC20 transfer.
* @param amount The amount for the attempted ERC20 transfer.
*/
error BadReturnValueFromERC20OnTransfer(
address token,
address from,
address to,
uint256 amount
);
/**
* @dev Revert with an error when an account being called as an assumed
* contract does not have code and returns no data.
*
* @param account The account that should contain code.
*/
error NoContract(address account);
/**
* @dev Revert with an error when attempting to execute an 1155 batch
* transfer using calldata not produced by default ABI encoding or with
* different lengths for ids and amounts arrays.
*/
error Invalid1155BatchTransferEncoding();
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
OrderParameters
} from "seaport-types/src/lib/ConsiderationStructs.sol";
import { ConsiderationBase } from "./ConsiderationBase.sol";
import {
Create2AddressDerivation_length,
Create2AddressDerivation_ptr,
EIP_712_PREFIX,
EIP712_ConsiderationItem_size,
EIP712_DigestPayload_size,
EIP712_DomainSeparator_offset,
EIP712_OfferItem_size,
EIP712_Order_size,
EIP712_OrderHash_offset,
FreeMemoryPointerSlot,
information_conduitController_offset,
information_domainSeparator_offset,
information_length,
information_version_cd_offset,
information_version_offset,
information_versionLengthPtr,
information_versionWithLength,
MaskOverByteTwelve,
MaskOverLastTwentyBytes,
OneWord,
OneWordShift,
OrderParameters_consideration_head_offset,
OrderParameters_counter_offset,
OrderParameters_offer_head_offset,
TwoWords
} from "seaport-types/src/lib/ConsiderationConstants.sol";
/**
* @title GettersAndDerivers
* @author 0age
* @notice ConsiderationInternal contains pure and internal view functions
* related to getting or deriving various values.
*/
contract GettersAndDerivers is ConsiderationBase {
/**
* @dev Derive and set hashes, reference chainId, and associated domain
* separator during deployment.
*
* @param conduitController A contract that deploys conduits, or proxies
* that may optionally be used to transfer approved
* ERC20/721/1155 tokens.
*/
constructor(
address conduitController
) ConsiderationBase(conduitController) {}
/**
* @dev Internal view function to derive the order hash for a given order.
* Note that only the original consideration items are included in the
* order hash, as additional consideration items may be supplied by the
* caller.
*
* @param orderParameters The parameters of the order to hash.
* @param counter The counter of the order to hash.
*
* @return orderHash The hash.
*/
function _deriveOrderHash(
OrderParameters memory orderParameters,
uint256 counter
) internal view returns (bytes32 orderHash) {
// Get length of original consideration array and place it on the stack.
uint256 originalConsiderationLength = (
orderParameters.totalOriginalConsiderationItems
);
/*
* Memory layout for an array of structs (dynamic or not) is similar
* to ABI encoding of dynamic types, with a head segment followed by
* a data segment. The main difference is that the head of an element
* is a memory pointer rather than an offset.
*/
// Declare a variable for the derived hash of the offer array.
bytes32 offerHash;
// Read offer item EIP-712 typehash from runtime code & place on stack.
bytes32 typeHash = _OFFER_ITEM_TYPEHASH;
// Utilize assembly so that memory regions can be reused across hashes.
assembly {
// Retrieve the free memory pointer and place on the stack.
let hashArrPtr := mload(FreeMemoryPointerSlot)
// Get the pointer to the offers array.
let offerArrPtr := mload(
add(orderParameters, OrderParameters_offer_head_offset)
)
// Load the length.
let offerLength := mload(offerArrPtr)
// Set the pointer to the first offer's head.
offerArrPtr := add(offerArrPtr, OneWord)
// Iterate over the offer items.
for {
let i := 0
} lt(i, offerLength) {
i := add(i, 1)
} {
// Read the pointer to the offer data and subtract one word
// to get typeHash pointer.
let ptr := sub(mload(offerArrPtr), OneWord)
// Read the current value before the offer data.
let value := mload(ptr)
// Write the type hash to the previous word.
mstore(ptr, typeHash)
// Take the EIP712 hash and store it in the hash array.
mstore(hashArrPtr, keccak256(ptr, EIP712_OfferItem_size))
// Restore the previous word.
mstore(ptr, value)
// Increment the array pointers by one word.
offerArrPtr := add(offerArrPtr, OneWord)
hashArrPtr := add(hashArrPtr, OneWord)
}
// Derive the offer hash using the hashes of each item.
offerHash := keccak256(
mload(FreeMemoryPointerSlot),
shl(OneWordShift, offerLength)
)
}
// Declare a variable for the derived hash of the consideration array.
bytes32 considerationHash;
// Read consideration item typehash from runtime code & place on stack.
typeHash = _CONSIDERATION_ITEM_TYPEHASH;
// Utilize assembly so that memory regions can be reused across hashes.
assembly {
// Retrieve the free memory pointer and place on the stack.
let hashArrPtr := mload(FreeMemoryPointerSlot)
// Get the pointer to the consideration array.
let considerationArrPtr := add(
mload(
add(
orderParameters,
OrderParameters_consideration_head_offset
)
),
OneWord
)
// Iterate over the consideration items (not including tips).
for {
let i := 0
} lt(i, originalConsiderationLength) {
i := add(i, 1)
} {
// Read the pointer to the consideration data and subtract one
// word to get typeHash pointer.
let ptr := sub(mload(considerationArrPtr), OneWord)
// Read the current value before the consideration data.
let value := mload(ptr)
// Write the type hash to the previous word.
mstore(ptr, typeHash)
// Take the EIP712 hash and store it in the hash array.
mstore(
hashArrPtr,
keccak256(ptr, EIP712_ConsiderationItem_size)
)
// Restore the previous word.
mstore(ptr, value)
// Increment the array pointers by one word.
considerationArrPtr := add(considerationArrPtr, OneWord)
hashArrPtr := add(hashArrPtr, OneWord)
}
// Derive the consideration hash using the hashes of each item.
considerationHash := keccak256(
mload(FreeMemoryPointerSlot),
shl(OneWordShift, originalConsiderationLength)
)
}
// Read order item EIP-712 typehash from runtime code & place on stack.
typeHash = _ORDER_TYPEHASH;
// Utilize assembly to access derived hashes & other arguments directly.
assembly {
// Retrieve pointer to the region located just behind parameters.
let typeHashPtr := sub(orderParameters, OneWord)
// Store the value at that pointer location to restore later.
let previousValue := mload(typeHashPtr)
// Store the order item EIP-712 typehash at the typehash location.
mstore(typeHashPtr, typeHash)
// Retrieve the pointer for the offer array head.
let offerHeadPtr := add(
orderParameters,
OrderParameters_offer_head_offset
)
// Retrieve the data pointer referenced by the offer head.
let offerDataPtr := mload(offerHeadPtr)
// Store the offer hash at the retrieved memory location.
mstore(offerHeadPtr, offerHash)
// Retrieve the pointer for the consideration array head.
let considerationHeadPtr := add(
orderParameters,
OrderParameters_consideration_head_offset
)
// Retrieve the data pointer referenced by the consideration head.
let considerationDataPtr := mload(considerationHeadPtr)
// Store the consideration hash at the retrieved memory location.
mstore(considerationHeadPtr, considerationHash)
// Retrieve the pointer for the counter.
let counterPtr := add(
orderParameters,
OrderParameters_counter_offset
)
// Store the counter at the retrieved memory location.
mstore(counterPtr, counter)
// Derive the order hash using the full range of order parameters.
orderHash := keccak256(typeHashPtr, EIP712_Order_size)
// Restore the value previously held at typehash pointer location.
mstore(typeHashPtr, previousValue)
// Restore offer data pointer at the offer head pointer location.
mstore(offerHeadPtr, offerDataPtr)
// Restore consideration data pointer at the consideration head ptr.
mstore(considerationHeadPtr, considerationDataPtr)
// Restore consideration item length at the counter pointer.
mstore(counterPtr, originalConsiderationLength)
}
}
/**
* @dev Internal view function to derive the address of a given conduit
* using a corresponding conduit key.
*
* @param conduitKey A bytes32 value indicating what corresponding conduit,
* if any, to source token approvals from. This value is
* the "salt" parameter supplied by the deployer (i.e. the
* conduit controller) when deploying the given conduit.
*
* @return conduit The address of the conduit associated with the given
* conduit key.
*/
function _deriveConduit(
bytes32 conduitKey
) internal view returns (address conduit) {
// Read conduit controller address from runtime and place on the stack.
address conduitController = address(_CONDUIT_CONTROLLER);
// Read conduit creation code hash from runtime and place on the stack.
bytes32 conduitCreationCodeHash = _CONDUIT_CREATION_CODE_HASH;
// Leverage scratch space to perform an efficient hash.
assembly {
// Retrieve the free memory pointer; it will be replaced afterwards.
let freeMemoryPointer := mload(FreeMemoryPointerSlot)
// Place the control character and the conduit controller in scratch
// space; note that eleven bytes at the beginning are left unused.
mstore(0, or(MaskOverByteTwelve, conduitController))
// Place the conduit key in the next region of scratch space.
mstore(OneWord, conduitKey)
// Place conduit creation code hash in free memory pointer location.
mstore(TwoWords, conduitCreationCodeHash)
// Derive conduit by hashing and applying a mask over last 20 bytes.
conduit := and(
// Hash the relevant region.
keccak256(
// The region starts at memory pointer 11.
Create2AddressDerivation_ptr,
// The region is 85 bytes long (1 + 20 + 32 + 32).
Create2AddressDerivation_length
),
// The address equals the last twenty bytes of the hash.
MaskOverLastTwentyBytes
)
// Restore the free memory pointer.
mstore(FreeMemoryPointerSlot, freeMemoryPointer)
}
}
/**
* @dev Internal view function to get the EIP-712 domain separator. If the
* chainId matches the chainId set on deployment, the cached domain
* separator will be returned; otherwise, it will be derived from
* scratch.
*
* @return The domain separator.
*/
function _domainSeparator() internal view returns (bytes32) {
return
block.chainid == _CHAIN_ID
? _DOMAIN_SEPARATOR
: _deriveDomainSeparator();
}
/**
* @dev Internal view function to retrieve configuration information for
* this contract.
*
* @return The contract version.
* @return The domain separator for this contract.
* @return The conduit Controller set for this contract.
*/
function _information()
internal
view
returns (
string memory /* version */,
bytes32 /* domainSeparator */,
address /* conduitController */
)
{
// Derive the domain separator.
bytes32 domainSeparator = _domainSeparator();
// Declare variable as immutables cannot be accessed within assembly.
address conduitController = address(_CONDUIT_CONTROLLER);
// Return the version, domain separator, and conduit controller.
assembly {
mstore(information_version_offset, information_version_cd_offset)
mstore(information_domainSeparator_offset, domainSeparator)
mstore(information_conduitController_offset, conduitController)
mstore(information_versionLengthPtr, information_versionWithLength)
return(information_version_offset, information_length)
}
}
/**
* @dev Internal pure function to efficiently derive an digest to sign for
* an order in accordance with EIP-712.
*
* @param domainSeparator The domain separator.
* @param orderHash The order hash.
*
* @return value The hash.
*/
function _deriveEIP712Digest(
bytes32 domainSeparator,
bytes32 orderHash
) internal pure returns (bytes32 value) {
// Leverage scratch space to perform an efficient hash.
assembly {
// Place the EIP-712 prefix at the start of scratch space.
mstore(0, EIP_712_PREFIX)
// Place the domain separator in the next region of scratch space.
mstore(EIP712_DomainSeparator_offset, domainSeparator)
// Place the order hash in scratch space, spilling into the first
// two bytes of the free memory pointer — this should never be set
// as memory cannot be expanded to that size, and will be zeroed out
// after the hash is performed.
mstore(EIP712_OrderHash_offset, orderHash)
// Hash the relevant region (65 bytes).
value := keccak256(0, EIP712_DigestPayload_size)
// Clear out the dirtied bits in the memory pointer.
mstore(EIP712_OrderHash_offset, 0)
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
ConsiderationEventsAndErrors
} from "seaport-types/src/interfaces/ConsiderationEventsAndErrors.sol";
import { ReentrancyGuard } from "./ReentrancyGuard.sol";
import {
Counter_blockhash_shift,
OneWord,
TwoWords
} from "seaport-types/src/lib/ConsiderationConstants.sol";
/**
* @title CounterManager
* @author 0age
* @notice CounterManager contains a storage mapping and related functionality
* for retrieving and incrementing a per-offerer counter.
*/
contract CounterManager is ConsiderationEventsAndErrors, ReentrancyGuard {
// Only orders signed using an offerer's current counter are fulfillable.
mapping(address => uint256) private _counters;
/**
* @dev Internal function to cancel all orders from a given offerer in bulk
* by incrementing a counter by a large, quasi-random interval. Note
* that only the offerer may increment the counter. Note that the
* counter is incremented by a large, quasi-random interval, which
* makes it infeasible to "activate" signed orders by incrementing the
* counter. This activation functionality can be achieved instead with
* restricted orders or contract orders.
*
* @return newCounter The new counter.
*/
function _incrementCounter() internal returns (uint256 newCounter) {
// Ensure that the reentrancy guard is not currently set.
_assertNonReentrant();
// Utilize assembly to access counters storage mapping directly. Skip
// overflow check as counter cannot be incremented that far.
assembly {
// Use second half of previous block hash as a quasi-random number.
let quasiRandomNumber := shr(
Counter_blockhash_shift,
blockhash(sub(number(), 1))
)
// Write the caller to scratch space.
mstore(0, caller())
// Write the storage slot for _counters to scratch space.
mstore(OneWord, _counters.slot)
// Derive the storage pointer for the counter value.
let storagePointer := keccak256(0, TwoWords)
// Derive new counter value using random number and original value.
newCounter := add(quasiRandomNumber, sload(storagePointer))
// Store the updated counter value.
sstore(storagePointer, newCounter)
}
// Emit an event containing the new counter.
emit CounterIncremented(newCounter, msg.sender);
}
/**
* @dev Internal view function to retrieve the current counter for a given
* offerer.
*
* @param offerer The offerer in question.
*
* @return currentCounter The current counter.
*/
function _getCounter(
address offerer
) internal view returns (uint256 currentCounter) {
// Return the counter for the supplied offerer.
currentCounter = _counters[offerer];
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
/**
* @title SignatureVerificationErrors
* @author 0age
* @notice SignatureVerificationErrors contains all errors related to signature
* verification.
*/
interface SignatureVerificationErrors {
/**
* @dev Revert with an error when a signature that does not contain a v
* value of 27 or 28 has been supplied.
*
* @param v The invalid v value.
*/
error BadSignatureV(uint8 v);
/**
* @dev Revert with an error when the signer recovered by the supplied
* signature does not match the offerer or an allowed EIP-1271 signer
* as specified by the offerer in the event they are a contract.
*/
error InvalidSigner();
/**
* @dev Revert with an error when a signer cannot be recovered from the
* supplied signature.
*/
error InvalidSignature();
/**
* @dev Revert with an error when an EIP-1271 call to an account fails.
*/
error BadContractSignature();
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
ConduitControllerInterface
} from "seaport-types/src/interfaces/ConduitControllerInterface.sol";
import {
ConsiderationEventsAndErrors
} from "seaport-types/src/interfaces/ConsiderationEventsAndErrors.sol";
import {
BulkOrder_Typehash_Height_One,
BulkOrder_Typehash_Height_Two,
BulkOrder_Typehash_Height_Three,
BulkOrder_Typehash_Height_Four,
BulkOrder_Typehash_Height_Five,
BulkOrder_Typehash_Height_Six,
BulkOrder_Typehash_Height_Seven,
BulkOrder_Typehash_Height_Eight,
BulkOrder_Typehash_Height_Nine,
BulkOrder_Typehash_Height_Ten,
BulkOrder_Typehash_Height_Eleven,
BulkOrder_Typehash_Height_Twelve,
BulkOrder_Typehash_Height_Thirteen,
BulkOrder_Typehash_Height_Fourteen,
BulkOrder_Typehash_Height_Fifteen,
BulkOrder_Typehash_Height_Sixteen,
BulkOrder_Typehash_Height_Seventeen,
BulkOrder_Typehash_Height_Eighteen,
BulkOrder_Typehash_Height_Nineteen,
BulkOrder_Typehash_Height_Twenty,
BulkOrder_Typehash_Height_TwentyOne,
BulkOrder_Typehash_Height_TwentyTwo,
BulkOrder_Typehash_Height_TwentyThree,
BulkOrder_Typehash_Height_TwentyFour,
EIP712_domainData_chainId_offset,
EIP712_domainData_nameHash_offset,
EIP712_domainData_size,
EIP712_domainData_verifyingContract_offset,
EIP712_domainData_versionHash_offset,
FreeMemoryPointerSlot,
NameLengthPtr,
NameWithLength,
OneWord,
Slot0x80,
ThreeWords,
ZeroSlot
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import { ConsiderationDecoder } from "./ConsiderationDecoder.sol";
import { ConsiderationEncoder } from "./ConsiderationEncoder.sol";
/**
* @title ConsiderationBase
* @author 0age
* @notice ConsiderationBase contains immutable constants and constructor logic.
*/
contract ConsiderationBase is
ConsiderationDecoder,
ConsiderationEncoder,
ConsiderationEventsAndErrors
{
// Precompute hashes, original chainId, and domain separator on deployment.
bytes32 internal immutable _NAME_HASH;
bytes32 internal immutable _VERSION_HASH;
bytes32 internal immutable _EIP_712_DOMAIN_TYPEHASH;
bytes32 internal immutable _OFFER_ITEM_TYPEHASH;
bytes32 internal immutable _CONSIDERATION_ITEM_TYPEHASH;
bytes32 internal immutable _ORDER_TYPEHASH;
uint256 internal immutable _CHAIN_ID;
bytes32 internal immutable _DOMAIN_SEPARATOR;
// Allow for interaction with the conduit controller.
ConduitControllerInterface internal immutable _CONDUIT_CONTROLLER;
// Cache the conduit creation code hash used by the conduit controller.
bytes32 internal immutable _CONDUIT_CREATION_CODE_HASH;
/**
* @dev Derive and set hashes, reference chainId, and associated domain
* separator during deployment.
*
* @param conduitController A contract that deploys conduits, or proxies
* that may optionally be used to transfer approved
* ERC20/721/1155 tokens.
*/
constructor(address conduitController) {
// Derive name and version hashes alongside required EIP-712 typehashes.
(
_NAME_HASH,
_VERSION_HASH,
_EIP_712_DOMAIN_TYPEHASH,
_OFFER_ITEM_TYPEHASH,
_CONSIDERATION_ITEM_TYPEHASH,
_ORDER_TYPEHASH
) = _deriveTypehashes();
// Store the current chainId and derive the current domain separator.
_CHAIN_ID = block.chainid;
_DOMAIN_SEPARATOR = _deriveDomainSeparator();
// Set the supplied conduit controller.
_CONDUIT_CONTROLLER = ConduitControllerInterface(conduitController);
// Retrieve the conduit creation code hash from the supplied controller.
(_CONDUIT_CREATION_CODE_HASH, ) = (
_CONDUIT_CONTROLLER.getConduitCodeHashes()
);
}
/**
* @dev Internal view function to derive the EIP-712 domain separator.
*
* @return domainSeparator The derived domain separator.
*/
function _deriveDomainSeparator()
internal
view
returns (bytes32 domainSeparator)
{
bytes32 typehash = _EIP_712_DOMAIN_TYPEHASH;
bytes32 nameHash = _NAME_HASH;
bytes32 versionHash = _VERSION_HASH;
// Leverage scratch space and other memory to perform an efficient hash.
assembly {
// Retrieve the free memory pointer; it will be replaced afterwards.
let freeMemoryPointer := mload(FreeMemoryPointerSlot)
// Retrieve value at 0x80; it will also be replaced afterwards.
let slot0x80 := mload(Slot0x80)
// Place typehash, name hash, and version hash at start of memory.
mstore(0, typehash)
mstore(EIP712_domainData_nameHash_offset, nameHash)
mstore(EIP712_domainData_versionHash_offset, versionHash)
// Place chainId in the next memory location.
mstore(EIP712_domainData_chainId_offset, chainid())
// Place the address of this contract in the next memory location.
mstore(EIP712_domainData_verifyingContract_offset, address())
// Hash relevant region of memory to derive the domain separator.
domainSeparator := keccak256(0, EIP712_domainData_size)
// Restore the free memory pointer.
mstore(FreeMemoryPointerSlot, freeMemoryPointer)
// Restore the zero slot to zero.
mstore(ZeroSlot, 0)
// Restore the value at 0x80.
mstore(Slot0x80, slot0x80)
}
}
/**
* @dev Internal pure function to retrieve the default name of this
* contract and return.
*
* @return The name of this contract.
*/
function _name() internal pure virtual returns (string memory) {
// Return the name of the contract.
assembly {
// First element is the offset for the returned string. Offset the
// value in memory by one word so that the free memory pointer will
// be overwritten by the next write.
mstore(OneWord, OneWord)
// Name is right padded, so it touches the length which is left
// padded. This enables writing both values at once. The free memory
// pointer will be overwritten in the process.
mstore(NameLengthPtr, NameWithLength)
// Standard ABI encoding pads returned data to the nearest word. Use
// the already empty zero slot memory region for this purpose and
// return the final name string, offset by the original single word.
return(OneWord, ThreeWords)
}
}
/**
* @dev Internal pure function to retrieve the default name of this contract
* as a string that can be used internally.
*
* @return The name of this contract.
*/
function _nameString() internal pure virtual returns (string memory) {
// Return the name of the contract.
return "Consideration";
}
/**
* @dev Internal pure function to derive required EIP-712 typehashes and
* other hashes during contract creation.
*
* @return nameHash The hash of the name of the contract.
* @return versionHash The hash of the version string of the
* contract.
* @return eip712DomainTypehash The primary EIP-712 domain typehash.
* @return offerItemTypehash The EIP-712 typehash for OfferItem
* types.
* @return considerationItemTypehash The EIP-712 typehash for
* ConsiderationItem types.
* @return orderTypehash The EIP-712 typehash for Order types.
*/
function _deriveTypehashes()
internal
pure
returns (
bytes32 nameHash,
bytes32 versionHash,
bytes32 eip712DomainTypehash,
bytes32 offerItemTypehash,
bytes32 considerationItemTypehash,
bytes32 orderTypehash
)
{
// Derive hash of the name of the contract.
nameHash = keccak256(bytes(_nameString()));
// Derive hash of the version string of the contract.
versionHash = keccak256(bytes("1.6"));
// Construct the OfferItem type string.
bytes memory offerItemTypeString = bytes(
"OfferItem("
"uint8 itemType,"
"address token,"
"uint256 identifierOrCriteria,"
"uint256 startAmount,"
"uint256 endAmount"
")"
);
// Construct the ConsiderationItem type string.
bytes memory considerationItemTypeString = bytes(
"ConsiderationItem("
"uint8 itemType,"
"address token,"
"uint256 identifierOrCriteria,"
"uint256 startAmount,"
"uint256 endAmount,"
"address recipient"
")"
);
// Construct the OrderComponents type string, not including the above.
bytes memory orderComponentsPartialTypeString = bytes(
"OrderComponents("
"address offerer,"
"address zone,"
"OfferItem[] offer,"
"ConsiderationItem[] consideration,"
"uint8 orderType,"
"uint256 startTime,"
"uint256 endTime,"
"bytes32 zoneHash,"
"uint256 salt,"
"bytes32 conduitKey,"
"uint256 counter"
")"
);
// Construct the primary EIP-712 domain type string.
eip712DomainTypehash = keccak256(
bytes(
"EIP712Domain("
"string name,"
"string version,"
"uint256 chainId,"
"address verifyingContract"
")"
)
);
// Derive the OfferItem type hash using the corresponding type string.
offerItemTypehash = keccak256(offerItemTypeString);
// Derive ConsiderationItem type hash using corresponding type string.
considerationItemTypehash = keccak256(considerationItemTypeString);
bytes memory orderTypeString = bytes.concat(
orderComponentsPartialTypeString,
considerationItemTypeString,
offerItemTypeString
);
// Derive OrderItem type hash via combination of relevant type strings.
orderTypehash = keccak256(orderTypeString);
}
/**
* @dev Internal pure function to look up one of twenty-four potential bulk
* order typehash constants based on the height of the bulk order tree.
* Note that values between one and twenty-four are supported, which is
* enforced by _isValidBulkOrderSize.
*
* @param _treeHeight The height of the bulk order tree. The value must be
* between one and twenty-four.
*
* @return _typeHash The EIP-712 typehash for the bulk order type with the
* given height.
*/
function _lookupBulkOrderTypehash(
uint256 _treeHeight
) internal pure returns (bytes32 _typeHash) {
// Utilize assembly to efficiently retrieve correct bulk order typehash.
assembly {
// Use a Yul function to enable use of the `leave` keyword
// to stop searching once the appropriate type hash is found.
function lookupTypeHash(treeHeight) -> typeHash {
// Handle tree heights one through eight.
if lt(treeHeight, 9) {
// Handle tree heights one through four.
if lt(treeHeight, 5) {
// Handle tree heights one and two.
if lt(treeHeight, 3) {
// Utilize branchless logic to determine typehash.
typeHash := ternary(
eq(treeHeight, 1),
BulkOrder_Typehash_Height_One,
BulkOrder_Typehash_Height_Two
)
// Exit the function once typehash has been located.
leave
}
// Handle height three and four via branchless logic.
typeHash := ternary(
eq(treeHeight, 3),
BulkOrder_Typehash_Height_Three,
BulkOrder_Typehash_Height_Four
)
// Exit the function once typehash has been located.
leave
}
// Handle tree height five and six.
if lt(treeHeight, 7) {
// Utilize branchless logic to determine typehash.
typeHash := ternary(
eq(treeHeight, 5),
BulkOrder_Typehash_Height_Five,
BulkOrder_Typehash_Height_Six
)
// Exit the function once typehash has been located.
leave
}
// Handle height seven and eight via branchless logic.
typeHash := ternary(
eq(treeHeight, 7),
BulkOrder_Typehash_Height_Seven,
BulkOrder_Typehash_Height_Eight
)
// Exit the function once typehash has been located.
leave
}
// Handle tree height nine through sixteen.
if lt(treeHeight, 17) {
// Handle tree height nine through twelve.
if lt(treeHeight, 13) {
// Handle tree height nine and ten.
if lt(treeHeight, 11) {
// Utilize branchless logic to determine typehash.
typeHash := ternary(
eq(treeHeight, 9),
BulkOrder_Typehash_Height_Nine,
BulkOrder_Typehash_Height_Ten
)
// Exit the function once typehash has been located.
leave
}
// Handle height eleven and twelve via branchless logic.
typeHash := ternary(
eq(treeHeight, 11),
BulkOrder_Typehash_Height_Eleven,
BulkOrder_Typehash_Height_Twelve
)
// Exit the function once typehash has been located.
leave
}
// Handle tree height thirteen and fourteen.
if lt(treeHeight, 15) {
// Utilize branchless logic to determine typehash.
typeHash := ternary(
eq(treeHeight, 13),
BulkOrder_Typehash_Height_Thirteen,
BulkOrder_Typehash_Height_Fourteen
)
// Exit the function once typehash has been located.
leave
}
// Handle height fifteen and sixteen via branchless logic.
typeHash := ternary(
eq(treeHeight, 15),
BulkOrder_Typehash_Height_Fifteen,
BulkOrder_Typehash_Height_Sixteen
)
// Exit the function once typehash has been located.
leave
}
// Handle tree height seventeen through twenty.
if lt(treeHeight, 21) {
// Handle tree height seventeen and eighteen.
if lt(treeHeight, 19) {
// Utilize branchless logic to determine typehash.
typeHash := ternary(
eq(treeHeight, 17),
BulkOrder_Typehash_Height_Seventeen,
BulkOrder_Typehash_Height_Eighteen
)
// Exit the function once typehash has been located.
leave
}
// Handle height nineteen and twenty via branchless logic.
typeHash := ternary(
eq(treeHeight, 19),
BulkOrder_Typehash_Height_Nineteen,
BulkOrder_Typehash_Height_Twenty
)
// Exit the function once typehash has been located.
leave
}
// Handle tree height twenty-one and twenty-two.
if lt(treeHeight, 23) {
// Utilize branchless logic to determine typehash.
typeHash := ternary(
eq(treeHeight, 21),
BulkOrder_Typehash_Height_TwentyOne,
BulkOrder_Typehash_Height_TwentyTwo
)
// Exit the function once typehash has been located.
leave
}
// Handle height twenty-three & twenty-four w/ branchless logic.
typeHash := ternary(
eq(treeHeight, 23),
BulkOrder_Typehash_Height_TwentyThree,
BulkOrder_Typehash_Height_TwentyFour
)
// Exit the function once typehash has been located.
leave
}
// Implement ternary conditional using branchless logic.
function ternary(cond, ifTrue, ifFalse) -> c {
c := xor(ifFalse, mul(cond, xor(ifFalse, ifTrue)))
}
// Look up the typehash using the supplied tree height.
_typeHash := lookupTypeHash(_treeHeight)
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
import {
OrderParameters,
ReceivedItem,
SpentItem
} from "../lib/ConsiderationStructs.sol";
/**
* @title ConsiderationEventsAndErrors
* @author 0age
* @notice ConsiderationEventsAndErrors contains all events and errors.
*/
interface ConsiderationEventsAndErrors {
/**
* @dev Emit an event whenever an order is successfully fulfilled.
*
* @param orderHash The hash of the fulfilled order.
* @param offerer The offerer of the fulfilled order.
* @param zone The zone of the fulfilled order.
* @param recipient The recipient of each spent item on the fulfilled
* order, or the null address if there is no specific
* fulfiller (i.e. the order is part of a group of
* orders). Defaults to the caller unless explicitly
* specified otherwise by the fulfiller.
* @param offer The offer items spent as part of the order.
* @param consideration The consideration items received as part of the
* order along with the recipients of each item.
*/
event OrderFulfilled(
bytes32 orderHash,
address indexed offerer,
address indexed zone,
address recipient,
SpentItem[] offer,
ReceivedItem[] consideration
);
/**
* @dev Emit an event whenever an order is successfully cancelled.
*
* @param orderHash The hash of the cancelled order.
* @param offerer The offerer of the cancelled order.
* @param zone The zone of the cancelled order.
*/
event OrderCancelled(
bytes32 orderHash,
address indexed offerer,
address indexed zone
);
/**
* @dev Emit an event whenever an order is explicitly validated. Note that
* this event will not be emitted on partial fills even though they do
* validate the order as part of partial fulfillment.
*
* @param orderHash The hash of the validated order.
* @param orderParameters The parameters of the validated order.
*/
event OrderValidated(bytes32 orderHash, OrderParameters orderParameters);
/**
* @dev Emit an event whenever one or more orders are matched using either
* matchOrders or matchAdvancedOrders.
*
* @param orderHashes The order hashes of the matched orders.
*/
event OrdersMatched(bytes32[] orderHashes);
/**
* @dev Emit an event whenever a counter for a given offerer is incremented.
*
* @param newCounter The new counter for the offerer.
* @param offerer The offerer in question.
*/
event CounterIncremented(uint256 newCounter, address indexed offerer);
/**
* @dev Revert with an error when attempting to fill an order that has
* already been fully filled.
*
* @param orderHash The order hash on which a fill was attempted.
*/
error OrderAlreadyFilled(bytes32 orderHash);
/**
* @dev Revert with an error when attempting to fill an order outside the
* specified start time and end time.
*
* @param startTime The time at which the order becomes active.
* @param endTime The time at which the order becomes inactive.
*/
error InvalidTime(uint256 startTime, uint256 endTime);
/**
* @dev Revert with an error when attempting to fill an order referencing an
* invalid conduit (i.e. one that has not been deployed).
*/
error InvalidConduit(bytes32 conduitKey, address conduit);
/**
* @dev Revert with an error when an order is supplied for fulfillment with
* a consideration array that is shorter than the original array.
*/
error MissingOriginalConsiderationItems();
/**
* @dev Revert with an error when an order is validated and the length of
* the consideration array is not equal to the supplied total original
* consideration items value. This error is also thrown when contract
* orders supply a total original consideration items value that does
* not match the supplied consideration array length.
*/
error ConsiderationLengthNotEqualToTotalOriginal();
/**
* @dev Revert with an error when a call to a conduit fails with revert data
* that is too expensive to return.
*/
error InvalidCallToConduit(address conduit);
/**
* @dev Revert with an error if a consideration amount has not been fully
* zeroed out after applying all fulfillments.
*
* @param orderIndex The index of the order with the consideration
* item with a shortfall.
* @param considerationIndex The index of the consideration item on the
* order.
* @param shortfallAmount The unfulfilled consideration amount.
*/
error ConsiderationNotMet(
uint256 orderIndex,
uint256 considerationIndex,
uint256 shortfallAmount
);
/**
* @dev Revert with an error when insufficient native tokens are supplied as
* part of msg.value when fulfilling orders.
*/
error InsufficientNativeTokensSupplied();
/**
* @dev Revert with an error when a native token transfer reverts.
*/
error NativeTokenTransferGenericFailure(address account, uint256 amount);
/**
* @dev Revert with an error when a partial fill is attempted on an order
* that does not specify partial fill support in its order type.
*/
error PartialFillsNotEnabledForOrder();
/**
* @dev Revert with an error when attempting to fill an order that has been
* cancelled.
*
* @param orderHash The hash of the cancelled order.
*/
error OrderIsCancelled(bytes32 orderHash);
/**
* @dev Revert with an error when attempting to fill a basic order that has
* been partially filled.
*
* @param orderHash The hash of the partially used order.
*/
error OrderPartiallyFilled(bytes32 orderHash);
/**
* @dev Revert with an error when attempting to cancel an order as a caller
* other than the indicated offerer or zone or when attempting to
* cancel a contract order.
*/
error CannotCancelOrder();
/**
* @dev Revert with an error when supplying a fraction with a value of zero
* for the numerator or denominator, or one where the numerator exceeds
* the denominator.
*/
error BadFraction();
/**
* @dev Revert with an error when a caller attempts to supply callvalue to a
* non-payable basic order route or does not supply any callvalue to a
* payable basic order route.
*/
error InvalidMsgValue(uint256 value);
/**
* @dev Revert with an error when attempting to fill a basic order using
* calldata not produced by default ABI encoding.
*/
error InvalidBasicOrderParameterEncoding();
/**
* @dev Revert with an error when attempting to fulfill any number of
* available orders when none are fulfillable.
*/
error NoSpecifiedOrdersAvailable();
/**
* @dev Revert with an error when attempting to fulfill an order with an
* offer for a native token outside of matching orders.
*/
error InvalidNativeOfferItem();
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
ReentrancyErrors
} from "seaport-types/src/interfaces/ReentrancyErrors.sol";
import { LowLevelHelpers } from "./LowLevelHelpers.sol";
import {
_revertInvalidMsgValue,
_revertNoReentrantCalls
} from "seaport-types/src/lib/ConsiderationErrors.sol";
import {
_ENTERED_AND_ACCEPTING_NATIVE_TOKENS_SSTORE,
_ENTERED_SSTORE,
_NOT_ENTERED_SSTORE,
_ENTERED_AND_ACCEPTING_NATIVE_TOKENS_TSTORE,
_ENTERED_TSTORE,
_NOT_ENTERED_TSTORE,
_TSTORE_ENABLED_SSTORE,
_REENTRANCY_GUARD_SLOT,
_TLOAD_TEST_PAYLOAD,
_TLOAD_TEST_PAYLOAD_OFFSET,
_TLOAD_TEST_PAYLOAD_LENGTH
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
InvalidMsgValue_error_selector,
InvalidMsgValue_error_length,
InvalidMsgValue_error_value_ptr,
NoReentrantCalls_error_selector,
NoReentrantCalls_error_length,
Error_selector_offset
} from "seaport-types/src/lib/ConsiderationErrorConstants.sol";
/**
* @title ReentrancyGuard
* @author 0age
* @notice ReentrancyGuard contains a storage variable (or a transient storage
* variable in EVM environments that support it once activated) and
* related functionality for protecting against reentrancy.
*/
contract ReentrancyGuard is ReentrancyErrors, LowLevelHelpers {
// Declare an immutable variable to store the initial TSTORE support status.
bool private immutable _tstoreInitialSupport;
// Declare an immutable variable to store the tstore test contract address.
address private immutable _tloadTestContract;
/**
* @dev Initialize the reentrancy guard during deployment. This involves
* attempting to deploy a contract that utilizes TLOAD as part of the
* contract construction bytecode, and configuring initial support for
* using TSTORE in place of SSTORE for the reentrancy lock based on the
* result.
*/
constructor() {
// Deploy the contract testing TLOAD support and store the address.
address tloadTestContract = _prepareTloadTest();
// Ensure the deployment was successful.
if (tloadTestContract == address(0)) {
revert TloadTestContractDeploymentFailed();
}
// Determine if TSTORE is supported.
bool tstoreInitialSupport = _testTload(tloadTestContract);
// Store the result as an immutable.
_tstoreInitialSupport = tstoreInitialSupport;
// Set the address of the deployed TLOAD test contract as an immutable.
_tloadTestContract = tloadTestContract;
// If not using TSTORE (where _NOT_ENTERED_TSTORE = 0), set initial
// sentinel value (where _NOT_ENTERED_SSTORE = 1).
if (!tstoreInitialSupport) {
// Initialize storage for the reentrancy guard in a cleared state.
assembly {
sstore(_REENTRANCY_GUARD_SLOT, _NOT_ENTERED_SSTORE)
}
}
}
/**
* @dev External function to activate TSTORE usage for the reentrancy guard.
* Does not need to be called if TSTORE is supported from deployment,
* and only needs to be called once. Reverts if TSTORE has already been
* activated, if the opcode is not available, or if the reentrancy
* guard is currently set.
*/
function __activateTstore() external {
// Determine if TSTORE can potentially be activated. If it has already
// been activated, or if the reentrancy guard is currently set, then
// it cannot be activated.
bool tstoreActivatable;
assembly {
tstoreActivatable := eq(
sload(_REENTRANCY_GUARD_SLOT),
_NOT_ENTERED_SSTORE
)
}
// Revert if TSTORE is already activated or not activatable.
if (_tstoreInitialSupport || !tstoreActivatable) {
revert TStoreAlreadyActivated();
}
// Determine if TSTORE can be activated and revert if not.
if (!_testTload(_tloadTestContract)) {
revert TStoreNotSupported();
}
// Mark TSTORE as activated.
assembly {
sstore(_REENTRANCY_GUARD_SLOT, _TSTORE_ENABLED_SSTORE)
}
}
/**
* @dev Internal function to ensure that a sentinel value for the reentrancy
* guard is not currently set and, if not, to set a sentinel value for
* the reentrancy guard based on whether or not native tokens may be
* received during execution or not.
*
* @param acceptNativeTokens A boolean indicating whether native tokens may
* be received during execution or not.
*/
function _setReentrancyGuard(bool acceptNativeTokens) internal {
// Place immutable variable on the stack access within inline assembly.
bool tstoreInitialSupport = _tstoreInitialSupport;
// Utilize assembly to set the reentrancy guard based on tstore support.
assembly {
// "Loop" over three possible cases for setting the reentrancy guard
// based on tstore support and state, exiting once the respective
// state has been identified and a corresponding guard has been set.
for {} 1 {} {
// 1: handle case where tstore is supported from the start.
if tstoreInitialSupport {
// Ensure that the reentrancy guard is not already set.
if tload(_REENTRANCY_GUARD_SLOT) {
// Store left-padded selector with push4,
// mem[28:32] = selector
mstore(0, NoReentrantCalls_error_selector)
// revert(abi.encodeWithSignature("NoReentrantCalls()"))
revert(
Error_selector_offset,
NoReentrantCalls_error_length
)
}
// Set the reentrancy guard. A value of 1 indicates that
// native tokens may not be accepted during execution,
// whereas a value of 2 indicates that they will be accepted
// (returning any remaining native tokens to the caller).
tstore(
_REENTRANCY_GUARD_SLOT,
add(_ENTERED_TSTORE, acceptNativeTokens)
)
// Exit the loop.
break
}
// Retrieve the reentrancy guard sentinel value.
let reentrancyGuard := sload(_REENTRANCY_GUARD_SLOT)
// 2: handle tstore support that was activated post-deployment.
if iszero(reentrancyGuard) {
// Ensure that the reentrancy guard is not already set.
if tload(_REENTRANCY_GUARD_SLOT) {
// Store left-padded selector with push4,
// mem[28:32] = selector
mstore(0, NoReentrantCalls_error_selector)
// revert(abi.encodeWithSignature("NoReentrantCalls()"))
revert(
Error_selector_offset,
NoReentrantCalls_error_length
)
}
// Set the reentrancy guard. A value of 1 indicates that
// native tokens may not be accepted during execution,
// whereas a value of 2 indicates that they will be accepted
// (returning any remaining native tokens to the caller).
tstore(
_REENTRANCY_GUARD_SLOT,
add(_ENTERED_TSTORE, acceptNativeTokens)
)
// Exit the loop.
break
}
// 3: handle case where tstore support has not been activated.
// Ensure that the reentrancy guard is not already set.
if iszero(eq(reentrancyGuard, _NOT_ENTERED_SSTORE)) {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, NoReentrantCalls_error_selector)
// revert(abi.encodeWithSignature("NoReentrantCalls()"))
revert(Error_selector_offset, NoReentrantCalls_error_length)
}
// Set the reentrancy guard. A value of 2 indicates that native
// tokens may not be accepted during execution, whereas a value
// of 3 indicates that they will be accepted (with any remaining
// native tokens returned to the caller).
sstore(
_REENTRANCY_GUARD_SLOT,
add(_ENTERED_SSTORE, acceptNativeTokens)
)
// Exit the loop.
break
}
}
}
/**
* @dev Internal function to unset the reentrancy guard sentinel value.
*/
function _clearReentrancyGuard() internal {
// Place immutable variable on the stack access within inline assembly.
bool tstoreInitialSupport = _tstoreInitialSupport;
// Utilize assembly to clear reentrancy guard based on tstore support.
assembly {
// "Loop" over three possible cases for clearing reentrancy guard
// based on tstore support and state, exiting once the respective
// state has been identified and corresponding guard cleared.
for {} 1 {} {
// 1: handle case where tstore is supported from the start.
if tstoreInitialSupport {
// Clear the reentrancy guard.
tstore(_REENTRANCY_GUARD_SLOT, _NOT_ENTERED_TSTORE)
// Exit the loop.
break
}
// Retrieve the reentrancy guard sentinel value.
let reentrancyGuard := sload(_REENTRANCY_GUARD_SLOT)
// 2: handle tstore support that was activated post-deployment.
if iszero(reentrancyGuard) {
// Clear the reentrancy guard.
tstore(_REENTRANCY_GUARD_SLOT, _NOT_ENTERED_TSTORE)
// Exit the loop.
break
}
// 3: handle case where tstore support has not been activated.
// Clear the reentrancy guard.
sstore(_REENTRANCY_GUARD_SLOT, _NOT_ENTERED_SSTORE)
// Exit the loop.
break
}
}
}
/**
* @dev Internal view function to ensure that a sentinel value for the
* reentrancy guard is not currently set.
*/
function _assertNonReentrant() internal view {
// Place immutable variable on the stack access within inline assembly.
bool tstoreInitialSupport = _tstoreInitialSupport;
// Utilize assembly to check reentrancy guard based on tstore support.
assembly {
// 1: handle case where tstore is supported from the start.
if tstoreInitialSupport {
// Ensure that the reentrancy guard is not currently set.
if tload(_REENTRANCY_GUARD_SLOT) {
// Store left-padded selector with push4,
// mem[28:32] = selector
mstore(0, NoReentrantCalls_error_selector)
// revert(abi.encodeWithSignature("NoReentrantCalls()"))
revert(Error_selector_offset, NoReentrantCalls_error_length)
}
}
// Handle cases where tstore is not initially supported.
if iszero(tstoreInitialSupport) {
// Retrieve the reentrancy guard sentinel value.
let reentrancyGuard := sload(_REENTRANCY_GUARD_SLOT)
// 2: handle tstore support that was activated post-deployment.
if iszero(reentrancyGuard) {
// Ensure that the reentrancy guard is not currently set.
if tload(_REENTRANCY_GUARD_SLOT) {
// Store left-padded selector with push4,
// mem[28:32] = selector
mstore(0, NoReentrantCalls_error_selector)
// revert(abi.encodeWithSignature("NoReentrantCalls()"))
revert(
Error_selector_offset,
NoReentrantCalls_error_length
)
}
}
// 3: handle case where tstore support has not been activated.
// Ensure that the reentrancy guard is not currently set.
if gt(reentrancyGuard, _NOT_ENTERED_SSTORE) {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, NoReentrantCalls_error_selector)
// revert(abi.encodeWithSignature("NoReentrantCalls()"))
revert(Error_selector_offset, NoReentrantCalls_error_length)
}
}
}
}
/**
* @dev Internal view function to ensure that the sentinel value indicating
* native tokens may be received during execution is currently set.
*/
function _assertAcceptingNativeTokens() internal view {
// Place immutable variable on the stack access within inline assembly.
bool tstoreInitialSupport = _tstoreInitialSupport;
// Utilize assembly to check reentrancy guard based on tstore support.
assembly {
// 1: handle case where tstore is supported from the start.
if tstoreInitialSupport {
// Ensure reentrancy guard is set to accept native tokens.
if iszero(
eq(
tload(_REENTRANCY_GUARD_SLOT),
_ENTERED_AND_ACCEPTING_NATIVE_TOKENS_TSTORE
)
) {
// Store left-padded selector with push4,
// mem[28:32] = selector
mstore(0, InvalidMsgValue_error_selector)
// Store argument.
mstore(InvalidMsgValue_error_value_ptr, callvalue())
// revert(abi.encodeWithSignature(
// "InvalidMsgValue(uint256)", value)
// )
revert(Error_selector_offset, InvalidMsgValue_error_length)
}
}
// Handle cases where tstore is not initially supported.
if iszero(tstoreInitialSupport) {
// Retrieve the reentrancy guard sentinel value.
let reentrancyGuard := sload(_REENTRANCY_GUARD_SLOT)
// 2: handle tstore support that was activated post-deployment.
if iszero(reentrancyGuard) {
// Ensure reentrancy guard is set to accept native tokens.
if iszero(
eq(
tload(_REENTRANCY_GUARD_SLOT),
_ENTERED_AND_ACCEPTING_NATIVE_TOKENS_TSTORE
)
) {
// Store left-padded selector with push4,
// mem[28:32] = selector
mstore(0, InvalidMsgValue_error_selector)
// Store argument.
mstore(InvalidMsgValue_error_value_ptr, callvalue())
// revert(abi.encodeWithSignature(
// "InvalidMsgValue(uint256)", value)
// )
revert(
Error_selector_offset,
InvalidMsgValue_error_length
)
}
}
// 3: handle case where tstore support has not been activated.
// Ensure reentrancy guard is set to accepting native tokens.
if and(
iszero(iszero(reentrancyGuard)),
iszero(
eq(
reentrancyGuard,
_ENTERED_AND_ACCEPTING_NATIVE_TOKENS_SSTORE
)
)
) {
// Store left-padded selector with push4 (reduces bytecode),
// mem[28:32] = selector
mstore(0, InvalidMsgValue_error_selector)
// Store argument.
mstore(InvalidMsgValue_error_value_ptr, callvalue())
// revert(abi.encodeWithSignature(
// "InvalidMsgValue(uint256)", value)
// )
revert(Error_selector_offset, InvalidMsgValue_error_length)
}
}
}
}
/**
* @dev Private function to deploy a test contract that utilizes TLOAD as
* part of its fallback logic.
*/
function _prepareTloadTest() private returns (address contractAddress) {
// Utilize assembly to deploy a contract testing TLOAD support.
assembly {
// Write the contract deployment code payload to scratch space.
mstore(0, _TLOAD_TEST_PAYLOAD)
// Deploy the contract.
contractAddress := create(
0,
_TLOAD_TEST_PAYLOAD_OFFSET,
_TLOAD_TEST_PAYLOAD_LENGTH
)
}
}
/**
* @dev Private view function to determine if TSTORE/TLOAD are supported by
* the current EVM implementation by attempting to call the test
* contract, which utilizes TLOAD as part of its fallback logic.
*/
function _testTload(
address tloadTestContract
) private view returns (bool ok) {
// Call the test contract, which will perform a TLOAD test. If the call
// does not revert, then TLOAD/TSTORE is supported. Do not forward all
// available gas, as all forwarded gas will be consumed on revert.
(ok, ) = tloadTestContract.staticcall{ gas: gasleft() / 10 }("");
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
/**
* @title ConduitControllerInterface
* @author 0age
* @notice ConduitControllerInterface contains all external function interfaces,
* structs, events, and errors for the conduit controller.
*/
interface ConduitControllerInterface {
/**
* @dev Track the conduit key, current owner, new potential owner, and open
* channels for each deployed conduit.
*/
struct ConduitProperties {
bytes32 key;
address owner;
address potentialOwner;
address[] channels;
mapping(address => uint256) channelIndexesPlusOne;
}
/**
* @dev Emit an event whenever a new conduit is created.
*
* @param conduit The newly created conduit.
* @param conduitKey The conduit key used to create the new conduit.
*/
event NewConduit(address conduit, bytes32 conduitKey);
/**
* @dev Emit an event whenever conduit ownership is transferred.
*
* @param conduit The conduit for which ownership has been
* transferred.
* @param previousOwner The previous owner of the conduit.
* @param newOwner The new owner of the conduit.
*/
event OwnershipTransferred(
address indexed conduit,
address indexed previousOwner,
address indexed newOwner
);
/**
* @dev Emit an event whenever a conduit owner registers a new potential
* owner for that conduit.
*
* @param newPotentialOwner The new potential owner of the conduit.
*/
event PotentialOwnerUpdated(address indexed newPotentialOwner);
/**
* @dev Revert with an error when attempting to create a new conduit using a
* conduit key where the first twenty bytes of the key do not match the
* address of the caller.
*/
error InvalidCreator();
/**
* @dev Revert with an error when attempting to create a new conduit when no
* initial owner address is supplied.
*/
error InvalidInitialOwner();
/**
* @dev Revert with an error when attempting to set a new potential owner
* that is already set.
*/
error NewPotentialOwnerAlreadySet(
address conduit,
address newPotentialOwner
);
/**
* @dev Revert with an error when attempting to cancel ownership transfer
* when no new potential owner is currently set.
*/
error NoPotentialOwnerCurrentlySet(address conduit);
/**
* @dev Revert with an error when attempting to interact with a conduit that
* does not yet exist.
*/
error NoConduit();
/**
* @dev Revert with an error when attempting to create a conduit that
* already exists.
*/
error ConduitAlreadyExists(address conduit);
/**
* @dev Revert with an error when attempting to update channels or transfer
* ownership of a conduit when the caller is not the owner of the
* conduit in question.
*/
error CallerIsNotOwner(address conduit);
/**
* @dev Revert with an error when attempting to register a new potential
* owner and supplying the null address.
*/
error NewPotentialOwnerIsZeroAddress(address conduit);
/**
* @dev Revert with an error when attempting to claim ownership of a conduit
* with a caller that is not the current potential owner for the
* conduit in question.
*/
error CallerIsNotNewPotentialOwner(address conduit);
/**
* @dev Revert with an error when attempting to retrieve a channel using an
* index that is out of range.
*/
error ChannelOutOfRange(address conduit);
/**
* @notice Deploy a new conduit using a supplied conduit key and assigning
* an initial owner for the deployed conduit. Note that the first
* twenty bytes of the supplied conduit key must match the caller
* and that a new conduit cannot be created if one has already been
* deployed using the same conduit key.
*
* @param conduitKey The conduit key used to deploy the conduit. Note that
* the first twenty bytes of the conduit key must match
* the caller of this contract.
* @param initialOwner The initial owner to set for the new conduit.
*
* @return conduit The address of the newly deployed conduit.
*/
function createConduit(
bytes32 conduitKey,
address initialOwner
) external returns (address conduit);
/**
* @notice Open or close a channel on a given conduit, thereby allowing the
* specified account to execute transfers against that conduit.
* Extreme care must be taken when updating channels, as malicious
* or vulnerable channels can transfer any ERC20, ERC721 and ERC1155
* tokens where the token holder has granted the conduit approval.
* Only the owner of the conduit in question may call this function.
*
* @param conduit The conduit for which to open or close the channel.
* @param channel The channel to open or close on the conduit.
* @param isOpen A boolean indicating whether to open or close the channel.
*/
function updateChannel(
address conduit,
address channel,
bool isOpen
) external;
/**
* @notice Initiate conduit ownership transfer by assigning a new potential
* owner for the given conduit. Once set, the new potential owner
* may call `acceptOwnership` to claim ownership of the conduit.
* Only the owner of the conduit in question may call this function.
*
* @param conduit The conduit for which to initiate ownership transfer.
* @param newPotentialOwner The new potential owner of the conduit.
*/
function transferOwnership(
address conduit,
address newPotentialOwner
) external;
/**
* @notice Clear the currently set potential owner, if any, from a conduit.
* Only the owner of the conduit in question may call this function.
*
* @param conduit The conduit for which to cancel ownership transfer.
*/
function cancelOwnershipTransfer(address conduit) external;
/**
* @notice Accept ownership of a supplied conduit. Only accounts that the
* current owner has set as the new potential owner may call this
* function.
*
* @param conduit The conduit for which to accept ownership.
*/
function acceptOwnership(address conduit) external;
/**
* @notice Retrieve the current owner of a deployed conduit.
*
* @param conduit The conduit for which to retrieve the associated owner.
*
* @return owner The owner of the supplied conduit.
*/
function ownerOf(address conduit) external view returns (address owner);
/**
* @notice Retrieve the conduit key for a deployed conduit via reverse
* lookup.
*
* @param conduit The conduit for which to retrieve the associated conduit
* key.
*
* @return conduitKey The conduit key used to deploy the supplied conduit.
*/
function getKey(address conduit) external view returns (bytes32 conduitKey);
/**
* @notice Derive the conduit associated with a given conduit key and
* determine whether that conduit exists (i.e. whether it has been
* deployed).
*
* @param conduitKey The conduit key used to derive the conduit.
*
* @return conduit The derived address of the conduit.
* @return exists A boolean indicating whether the derived conduit has been
* deployed or not.
*/
function getConduit(
bytes32 conduitKey
) external view returns (address conduit, bool exists);
/**
* @notice Retrieve the potential owner, if any, for a given conduit. The
* current owner may set a new potential owner via
* `transferOwnership` and that owner may then accept ownership of
* the conduit in question via `acceptOwnership`.
*
* @param conduit The conduit for which to retrieve the potential owner.
*
* @return potentialOwner The potential owner, if any, for the conduit.
*/
function getPotentialOwner(
address conduit
) external view returns (address potentialOwner);
/**
* @notice Retrieve the status (either open or closed) of a given channel on
* a conduit.
*
* @param conduit The conduit for which to retrieve the channel status.
* @param channel The channel for which to retrieve the status.
*
* @return isOpen The status of the channel on the given conduit.
*/
function getChannelStatus(
address conduit,
address channel
) external view returns (bool isOpen);
/**
* @notice Retrieve the total number of open channels for a given conduit.
*
* @param conduit The conduit for which to retrieve the total channel count.
*
* @return totalChannels The total number of open channels for the conduit.
*/
function getTotalChannels(
address conduit
) external view returns (uint256 totalChannels);
/**
* @notice Retrieve an open channel at a specific index for a given conduit.
* Note that the index of a channel can change as a result of other
* channels being closed on the conduit.
*
* @param conduit The conduit for which to retrieve the open channel.
* @param channelIndex The index of the channel in question.
*
* @return channel The open channel, if any, at the specified channel index.
*/
function getChannel(
address conduit,
uint256 channelIndex
) external view returns (address channel);
/**
* @notice Retrieve all open channels for a given conduit. Note that calling
* this function for a conduit with many channels will revert with
* an out-of-gas error.
*
* @param conduit The conduit for which to retrieve open channels.
*
* @return channels An array of open channels on the given conduit.
*/
function getChannels(
address conduit
) external view returns (address[] memory channels);
/**
* @dev Retrieve the conduit creation code and runtime code hashes.
*/
function getConduitCodeHashes()
external
view
returns (bytes32 creationCodeHash, bytes32 runtimeCodeHash);
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.24;
import {
AdvancedOrder,
ConsiderationItem,
CriteriaResolver,
Fulfillment,
FulfillmentComponent,
OfferItem,
Order,
OrderParameters,
ReceivedItem
} from "seaport-types/src/lib/ConsiderationStructs.sol";
import {
AdvancedOrder_denominator_offset,
AdvancedOrder_extraData_offset,
AdvancedOrder_fixed_segment_0,
AdvancedOrder_head_size,
AdvancedOrder_numerator_offset,
AdvancedOrder_signature_offset,
AdvancedOrderPlusOrderParameters_head_size,
Common_amount_offset,
Common_endAmount_offset,
Common_identifier_offset,
Common_token_offset,
ConsiderationItem_recipient_offset,
ConsiderationItem_size_with_head_pointer,
ConsiderationItem_size,
CriteriaResolver_criteriaProof_offset,
CriteriaResolver_fixed_segment_0,
CriteriaResolver_head_size,
ThreeWords,
FreeMemoryPointerSlot,
Fulfillment_considerationComponents_offset,
Fulfillment_head_size,
FulfillmentComponent_mem_tail_size_shift,
FulfillmentComponent_mem_tail_size,
generateOrder_maximum_returned_array_length,
OfferItem_size_with_head_pointer,
OfferItem_size,
OneWord,
OneWordShift,
OnlyFullWordMask,
Order_head_size,
Order_signature_offset,
OrderComponents_OrderParameters_common_head_size,
OrderParameters_consideration_head_offset,
OrderParameters_head_size,
OrderParameters_offer_head_offset,
OrderParameters_totalOriginalConsiderationItems_offset,
ReceivedItem_recipient_offset,
ReceivedItem_size,
ReceivedItem_size_excluding_recipient,
SpentItem_size_shift,
SpentItem_size,
ThirtyOneBytes,
TwoWords
} from "seaport-types/src/lib/ConsiderationConstants.sol";
import {
CalldataPointer,
malloc,
MemoryPointer,
OffsetOrLengthMask
} from "seaport-types/src/helpers/PointerLibraries.sol";
contract ConsiderationDecoder {
/**
* @dev Takes a bytes array from calldata and copies it into memory.
*
* @param cdPtrLength A calldata pointer to the start of the bytes array in
* calldata which contains the length of the array.
*
* @return mPtrLength A memory pointer to the start of the bytes array in
* memory which contains the length of the array.
*/
function _decodeBytes(
CalldataPointer cdPtrLength
) internal pure returns (MemoryPointer mPtrLength) {
assembly {
// Get the current free memory pointer.
mPtrLength := mload(FreeMemoryPointerSlot)
// Derive the size of the bytes array, rounding up to nearest word
// and adding a word for the length field. Note: masking
// `calldataload(cdPtrLength)` is redundant here.
let size := add(
and(
add(calldataload(cdPtrLength), ThirtyOneBytes),
OnlyFullWordMask
),
OneWord
)
// Copy bytes from calldata into memory based on pointers and size.
calldatacopy(mPtrLength, cdPtrLength, size)
// Store the masked value in memory. Note: the value of `size` is at
// least 32, meaning the calldatacopy above will at least write to
// `[mPtrLength, mPtrLength + 32)`.
mstore(
mPtrLength,
and(calldataload(cdPtrLength), OffsetOrLengthMask)
)
// Update free memory pointer based on the size of the bytes array.
mstore(FreeMemoryPointerSlot, add(mPtrLength, size))
}
}
/**
* @dev Takes an offer array from calldata and copies it into memory.
*
* @param cdPtrLength A calldata pointer to the start of the offer array
* in calldata which contains the length of the array.
*
* @return mPtrLength A memory pointer to the start of the offer array in
* memory which contains the length of the array.
*/
function _decodeOffer(
CalldataPointer cdPtrLength
) internal pure returns (MemoryPointer mPtrLength) {
assembly {
// Retrieve length of array, masking to prevent potential overflow.
let arrLength := and(calldataload(cdPtrLength), OffsetOrLengthMask)
// Get the current free memory pointer.
mPtrLength := mload(FreeMemoryPointerSlot)
// Write the array length to memory.
mstore(mPtrLength, arrLength)
// Derive the head by adding one word to the length pointer.
let mPtrHead := add(mPtrLength, OneWord)
// Derive the tail by adding one word per element (note that structs
// are written to memory with an offset per struct element).
let mPtrTail := add(mPtrHead, shl(OneWordShift, arrLength))
// Track the next tail, beginning with the initial tail value.
let mPtrTailNext := mPtrTail
// Copy all offer array data into memory at the tail pointer.
calldatacopy(
mPtrTail,
add(cdPtrLength, OneWord),
mul(arrLength, OfferItem_size)
)
// Track the next head pointer, starting with initial head value.
let mPtrHeadNext := mPtrHead
// Iterate over each head pointer until it reaches the tail.
for {
} lt(mPtrHeadNext, mPtrTail) {
} {
// Write the next tail pointer to next head pointer in memory.
mstore(mPtrHeadNext, mPtrTailNext)
// Increment the next head pointer by one word.
mPtrHeadNext := add(mPtrHeadNext, OneWord)
// Increment the next tail pointer by the size of an offer item.
mPtrTailNext := add(mPtrTailNext, OfferItem_size)
}
// Update free memory pointer to allocate memory up to end of tail.
mstore(FreeMemoryPointerSlot, mPtrTailNext)
}
}
/**
* @dev Takes a consideration array from calldata and copies it into memory.
*
* @param cdPtrLength A calldata pointer to the start of the consideration
* array in calldata which contains the length of the
* array.
*
* @return mPtrLength A memory pointer to the start of the consideration
* array in memory which contains the length of the
* array.
*/
function _decodeConsideration(
CalldataPointer cdPtrLength
) internal pure returns (MemoryPointer mPtrLength) {
assembly {
// Retrieve length of array, masking to prevent potential overflow.
let arrLength := and(calldataload(cdPtrLength), OffsetOrLengthMask)
// Get the current free memory pointer.
mPtrLength := mload(FreeMemoryPointerSlot)
// Write the array length to memory.
mstore(mPtrLength, arrLength)
// Derive the head by adding one word to the length pointer.
let mPtrHead := add(mPtrLength, OneWord)
// Derive the tail by adding one word per element (note that structs
// are written to memory with an offset per struct element).
let mPtrTail := add(mPtrHead, shl(OneWordShift, arrLength))
// Track the next tail, beginning with the initial tail value.
let mPtrTailNext := mPtrTail
// Copy all consideration array data into memory at tail pointer.
calldatacopy(
mPtrTail,
add(cdPtrLength, OneWord),
mul(arrLength, ConsiderationItem_size)
)
// Track the next head pointer, starting with initial head value.
let mPtrHeadNext := mPtrHead
// Iterate over each head pointer until it reaches the tail.
for {
} lt(mPtrHeadNext, mPtrTail) {
} {
// Write the next tail pointer to next head pointer in memory.
mstore(mPtrHeadNext, mPtrTailNext)
// Increment the next head pointer by one word.
mPtrHeadNext := add(mPtrHeadNext, OneWord)
// Increment next tail pointer by size of a consideration item.
mPtrTailNext := add(mPtrTailNext, ConsiderationItem_size)
}
// Update free memory pointer to allocate memory up to end of tail.
mstore(FreeMemoryPointerSlot, mPtrTailNext)
}
}
/**
* @dev Takes a calldata pointer and memory pointer and copies a referenced
* OrderParameters struct and associated offer and consideration data
* to memory.
*
* @param cdPtr A calldata pointer for the OrderParameters struct.
* @param mPtr A memory pointer to the OrderParameters struct head.
*/
function _decodeOrderParametersTo(
CalldataPointer cdPtr,
MemoryPointer mPtr
) internal pure {
// Copy the full OrderParameters head from calldata to memory.
cdPtr.copy(mPtr, OrderParameters_head_size);
// Resolve the offer calldata offset, use that to decode and copy offer
// from calldata, and write resultant memory offset to head in memory.
mPtr.offset(OrderParameters_offer_head_offset).write(
_decodeOffer(cdPtr.pptrOffset(OrderParameters_offer_head_offset))
);
// Resolve consideration calldata offset, use that to copy consideration
// from calldata, and write resultant memory offset to head in memory.
mPtr.offset(OrderParameters_consideration_head_offset).write(
_decodeConsideration(
cdPtr.pptrOffset(OrderParameters_consideration_head_offset)
)
);
}
/**
* @dev Takes a calldata pointer to an OrderParameters struct and copies the
* decoded struct to memory.
*
* @param cdPtr A calldata pointer for the OrderParameters struct.
*
* @return mPtr A memory pointer to the OrderParameters struct head.
*/
function _decodeOrderParameters(
CalldataPointer cdPtr
) internal pure returns (MemoryPointer mPtr) {
// Allocate required memory for the OrderParameters head (offer and
// consideration are allocated independently).
mPtr = malloc(OrderParameters_head_size);
// Decode and copy the order parameters to the newly allocated memory.
_decodeOrderParametersTo(cdPtr, mPtr);
}
/**
* @dev Takes a calldata pointer to an Order struct and copies the decoded
* struct to memory.
*
* @param cdPtr A calldata pointer for the Order struct.
*
* @return mPtr A memory pointer to the Order struct head.
*/
function _decodeOrder(
CalldataPointer cdPtr
) internal pure returns (MemoryPointer mPtr) {
// Allocate required memory for the Order head (OrderParameters and
// signature are allocated independently).
mPtr = malloc(Order_head_size);
// Resolve OrderParameters calldata offset, use it to decode and copy
// from calldata, and write resultant memory offset to head in memory.
mPtr.write(_decodeOrderParameters(cdPtr.pptr()));
// Resolve signature calldata offset, use that to decode and copy from
// calldata, and write resultant memory offset to head in memory.
mPtr.offset(Order_signature_offset).write(
_decodeBytes(cdPtr.pptrOffset(Order_signature_offset))
);
}
/**
* @dev Takes a calldata pointer to an AdvancedOrder struct and copies the
* decoded struct to memory.
*
* @param cdPtr A calldata pointer for the AdvancedOrder struct.
*
* @return mPtr A memory pointer to the AdvancedOrder struct head.
*/
function _decodeAdvancedOrder(
CalldataPointer cdPtr
) internal pure returns (MemoryPointer mPtr) {
// Allocate memory for AdvancedOrder head and OrderParameters head.
mPtr = malloc(AdvancedOrderPlusOrderParameters_head_size);
// Use numerator + denominator calldata offset to decode and copy
// from calldata and write resultant memory offset to head in memory.
cdPtr.offset(AdvancedOrder_numerator_offset).copy(
mPtr.offset(AdvancedOrder_numerator_offset),
AdvancedOrder_fixed_segment_0
);
// Get pointer to memory immediately after advanced order.
MemoryPointer mPtrParameters = mPtr.offset(AdvancedOrder_head_size);
// Write pptr for advanced order parameters to memory.
mPtr.write(mPtrParameters);
// Resolve OrderParameters calldata pointer & write to allocated region.
_decodeOrderParametersTo(cdPtr.pptr(), mPtrParameters);
// Resolve signature calldata offset, use that to decode and copy from
// calldata, and write resultant memory offset to head in memory.
mPtr.offset(AdvancedOrder_signature_offset).write(
_decodeBytes(cdPtr.pptrOffset(AdvancedOrder_signature_offset))
);
// Resolve extraData calldata offset, use that to decode and copy from
// calldata, and write resultant memory offset to head in memory.
mPtr.offset(AdvancedOrder_extraData_offset).write(
_decodeBytes(cdPtr.pptrOffset(AdvancedOrder_extraData_offset))
);
}
/**
* @dev Allocates a single word of empty bytes in memory and returns the
* pointer to that memory region.
*
* @return mPtr The memory pointer to the new empty word in memory.
*/
function _getEmptyBytesOrArray()
internal
pure
returns (MemoryPointer mPtr)
{
mPtr = malloc(OneWord);
mPtr.write(0);
}
/**
* @dev Takes a calldata pointer to an Order struct and copies the decoded
* struct to memory as an AdvancedOrder.
*
* @param cdPtr A calldata pointer for the Order struct.
*
* @return mPtr A memory pointer to the AdvancedOrder struct head.
*/
function _decodeOrderAsAdvancedOrder(
CalldataPointer cdPtr
) internal pure returns (MemoryPointer mPtr) {
// Allocate memory for AdvancedOrder head and OrderParameters head.
mPtr = malloc(AdvancedOrderPlusOrderParameters_head_size);
// Get pointer to memory immediately after advanced order.
MemoryPointer mPtrParameters = mPtr.offset(AdvancedOrder_head_size);
// Write pptr for advanced order parameters.
mPtr.write(mPtrParameters);
// Resolve OrderParameters calldata pointer & write to allocated region.
_decodeOrderParametersTo(cdPtr.pptr(), mPtrParameters);
// Write default Order numerator and denominator values (i.e. 1/1).
mPtr.offset(AdvancedOrder_numerator_offset).write(1);
mPtr.offset(AdvancedOrder_denominator_offset).write(1);
// Resolve signature calldata offset, use that to decode and copy from
// calldata, and write resultant memory offset to head in memory.
mPtr.offset(AdvancedOrder_signature_offset).write(
_decodeBytes(cdPtr.pptrOffset(Order_signature_offset))
);
// Resolve extraData calldata offset, use that to decode and copy from
// calldata, and write resultant memory offset to head in memory.
mPtr.offset(AdvancedOrder_extraData_offset).write(
_getEmptyBytesOrArray()
);
}
/**
* @dev Takes a calldata pointer to an array of Order structs and copies the
* decoded array to memory as an array of AdvancedOrder structs.
*
* @param cdPtrLength A calldata pointer to the start of the orders array in
* calldata which contains the length of the array.
*
* @return mPtrLength A memory pointer to the start of the array of advanced
* orders in memory which contains length of the array.
*/
function _decodeOrdersAsAdvancedOrders(
CalldataPointer cdPtrLength
) internal pure returns (MemoryPointer mPtrLength) {
// Retrieve length of array, masking to prevent potential overflow.
uint256 arrLength = cdPtrLength.readMaskedUint256();
unchecked {
// Derive offset to the tail based on one word per array element.
uint256 tailOffset = arrLength << OneWordShift;
// Add one additional word for the length and allocate memory.
mPtrLength = malloc(tailOffset + OneWord);
// Write the length of the array to memory.
mPtrLength.write(arrLength);
// Advance to first memory & calldata pointers (e.g. after length).
MemoryPointer mPtrHead = mPtrLength.next();
CalldataPointer cdPtrHead = cdPtrLength.next();
// Iterate over each pointer, word by word, until tail is reached.
for (uint256 offset = 0; offset < tailOffset; offset += OneWord) {
// Resolve Order calldata offset, use it to decode and copy from
// calldata, and write resultant AdvancedOrder offset to memory.
mPtrHead.offset(offset).write(
_decodeOrderAsAdvancedOrder(cdPtrHead.pptrOffset(offset))
);
}
}
}
/**
* @dev Takes a calldata pointer to a criteria proof, or an array bytes32
* types, and copies the decoded proof to memory.
*
* @param cdPtrLength A calldata pointer to the start of the criteria proof
* in calldata which contains the length of the array.
*
* @return mPtrLength A memory pointer to the start of the criteria proof
* in memory which contains length of the array.
*/
function _decodeCriteriaProof(
CalldataPointer cdPtrLength
) internal pure returns (MemoryPointer mPtrLength) {
// Retrieve length of array, masking to prevent potential overflow.
uint256 arrLength = cdPtrLength.readMaskedUint256();
unchecked {
// Derive array size based on one word per array element and length.
uint256 arrSize = (arrLength + 1) << OneWordShift;
// Allocate memory equal to the array size.
mPtrLength = malloc(arrSize);
// Copy the array from calldata into memory.
cdPtrLength.copy(mPtrLength, arrSize);
}
}
/**
* @dev Takes a calldata pointer to a CriteriaResolver struct and copies the
* decoded struct to memory.
*
* @param cdPtr A calldata pointer for the CriteriaResolver struct.
*
* @return mPtr A memory pointer to the CriteriaResolver struct head.
*/
function _decodeCriteriaResolver(
CalldataPointer cdPtr
) internal pure returns (MemoryPointer mPtr) {
// Allocate required memory for the CriteriaResolver head (the criteria
// proof bytes32 array is allocated independently).
mPtr = malloc(CriteriaResolver_head_size);
// Decode and copy order index, side, index, and identifier from
// calldata and write resultant memory offset to head in memory.
cdPtr.copy(mPtr, CriteriaResolver_fixed_segment_0);
// Resolve criteria proof calldata offset, use it to decode and copy
// from calldata, and write resultant memory offset to head in memory.
mPtr.offset(CriteriaResolver_criteriaProof_offset).write(
_decodeCriteriaProof(
cdPtr.pptrOffset(CriteriaResolver_criteriaProof_offset)
)
);
}
/**
* @dev Takes an array of criteria resolvers from calldata and copies it
* into memory.
*
* @param cdPtrLength A calldata pointer to the start of the criteria
* resolver array in calldata which contains the length
* of the array.
*
* @return mPtrLength A memory pointer to the start of the criteria resolver
* array in memory which contains the length of the
* array.
*/
function _decodeCriteriaResolvers(
CalldataPointer cdPtrLength
) internal pure returns (MemoryPointer mPtrLength) {
// Retrieve length of array, masking to prevent potential overflow.
uint256 arrLength = cdPtrLength.readMaskedUint256();
unchecked {
// Derive offset to the tail based on one word per array element.
uint256 tailOffset = arrLength << OneWordShift;
// Add one additional word for the length and allocate memory.
mPtrLength = malloc(tailOffset + OneWord);
// Write the length of the array to memory.
mPtrLength.write(arrLength);
// Advance to first memory & calldata pointers (e.g. after length).
MemoryPointer mPtrHead = mPtrLength.next();
CalldataPointer cdPtrHead = cdPtrLength.next();
// Iterate over each pointer, word by word, until tail is reached.
for (uint256 offset = 0; offset < tailOffset; offset += OneWord) {
// Resolve CriteriaResolver calldata offset, use it to decode
// and copy from calldata, and write resultant memory offset.
mPtrHead.offset(offset).write(
_decodeCriteriaResolver(cdPtrHead.pptrOffset(offset))
);
}
}
}
/**
* @dev Takes an array of orders from calldata and copies it into memory.
*
* @param cdPtrLength A calldata pointer to the start of the orders array in
* calldata which contains the length of the array.
*
* @return mPtrLength A memory pointer to the start of the orders array
* in memory which contains the length of the array.
*/
function _decodeOrders(
CalldataPointer cdPtrLength
) internal pure returns (MemoryPointer mPtrLength) {
// Retrieve length of array, masking to prevent potential overflow.
uint256 arrLength = cdPtrLength.readMaskedUint256();
unchecked {
// Derive offset to the tail based on one word per array element.
uint256 tailOffset = arrLength << OneWordShift;
// Add one additional word for the length and allocate memory.
mPtrLength = malloc(tailOffset + OneWord);
// Write the length of the array to memory.
mPtrLength.write(arrLength);
// Advance to first memory & calldata pointers (e.g. after length).
MemoryPointer mPtrHead = mPtrLength.next();
CalldataPointer cdPtrHead = cdPtrLength.next();
// Iterate over each pointer, word by word, until tail is reached.
for (uint256 offset = 0; offset < tailOffset; offset += OneWord) {
// Resolve Order calldata offset, use it to decode and copy
// from calldata, and write resultant memory offset.
mPtrHead.offset(offset).write(
_decodeOrder(cdPtrHead.pptrOffset(offset))
);
}
}
}
/**
* @dev Takes an array of fulfillment components from calldata and copies it
* into memory.
*
* @param cdPtrLength A calldata pointer to the start of the fulfillment
* components array in calldata which contains the length
* of the array.
*
* @return mPtrLength A memory pointer to the start of the fulfillment
* components array in memory which contains the length
* of the array.
*/
function _decodeFulfillmentComponents(
CalldataPointer cdPtrLength
) internal pure returns (MemoryPointer mPtrLength) {
assembly {
let arrLength := and(calldataload(cdPtrLength), OffsetOrLengthMask)
// Get the current free memory pointer.
mPtrLength := mload(FreeMemoryPointerSlot)
mstore(mPtrLength, arrLength)
let mPtrHead := add(mPtrLength, OneWord)
let mPtrTail := add(mPtrHead, shl(OneWordShift, arrLength))
let mPtrTailNext := mPtrTail
calldatacopy(
mPtrTail,
add(cdPtrLength, OneWord),
shl(FulfillmentComponent_mem_tail_size_shift, arrLength)
)
let mPtrHeadNext := mPtrHead
for {
} lt(mPtrHeadNext, mPtrTail) {
} {
mstore(mPtrHeadNext, mPtrTailNext)
mPtrHeadNext := add(mPtrHeadNext, OneWord)
mPtrTailNext := add(
mPtrTailNext,
FulfillmentComponent_mem_tail_size
)
}
// Update the free memory pointer.
mstore(FreeMemoryPointerSlot, mPtrTailNext)
}
}
/**
* @dev Takes a nested array of fulfillment components from calldata and
* copies it into memory.
*
* @param cdPtrLength A calldata pointer to the start of the nested
* fulfillment components array in calldata which
* contains the length of the array.
*
* @return mPtrLength A memory pointer to the start of the nested
* fulfillment components array in memory which
* contains the length of the array.
*/
function _decodeNestedFulfillmentComponents(
CalldataPointer cdPtrLength
) internal pure returns (MemoryPointer mPtrLength) {
// Retrieve length of array, masking to prevent potential overflow.
uint256 arrLength = cdPtrLength.readMaskedUint256();
unchecked {
// Derive offset to the tail based on one word per array element.
uint256 tailOffset = arrLength << OneWordShift;
// Add one additional word for the length and allocate memory.
mPtrLength = malloc(tailOffset + OneWord);
// Write the length of the array to memory.
mPtrLength.write(arrLength);
// Advance to first memory & calldata pointers (e.g. after length).
MemoryPointer mPtrHead = mPtrLength.next();
CalldataPointer cdPtrHead = cdPtrLength.next();
// Iterate over each pointer, word by word, until tail is reached.
for (uint256 offset = 0; offset < tailOffset; offset += OneWord) {
// Resolve FulfillmentComponents array calldata offset, use it
// to decode and copy from calldata, and write memory offset.
mPtrHead.offset(offset).write(
_decodeFulfillmentComponents(cdPtrHead.pptrOffset(offset))
);
}
}
}
/**
* @dev Takes an array of advanced orders from calldata and copies it into
* memory.
*
* @param cdPtrLength A calldata pointer to the start of the advanced orders
* array in calldata which contains the length of the
* array.
*
* @return mPtrLength A memory pointer to the start of the advanced orders
* array in memory which contains the length of the
* array.
*/
function _decodeAdvancedOrders(
CalldataPointer cdPtrLength
) internal pure returns (MemoryPointer mPtrLength) {
// Retrieve length of array, masking to prevent potential overflow.
uint256 arrLength = cdPtrLength.readMaskedUint256();
unchecked {
// Derive offset to the tail based on one word per array element.
uint256 tailOffset = arrLength << OneWordShift;
// Add one additional word for the length and allocate memory.
mPtrLength = malloc(tailOffset + OneWord);
// Write the length of the array to memory.
mPtrLength.write(arrLength);
// Advance to first memory & calldata pointers (e.g. after length).
MemoryPointer mPtrHead = mPtrLength.next();
CalldataPointer cdPtrHead = cdPtrLength.next();
// Iterate over each pointer, word by word, until tail is reached.
for (uint256 offset = 0; offset < tailOffset; offset += OneWord) {
// Resolve AdvancedOrder calldata offset, use it to decode and
// copy from calldata, and write resultant memory offset.
mPtrHead.offset(offset).write(
_decodeAdvancedOrder(cdPtrHead.pptrOffset(offset))
);
}
}
}
/**
* @dev Takes a calldata pointer to a Fulfillment struct and copies the
* decoded struct to memory.
*
* @param cdPtr A calldata pointer for the Fulfillment struct.
*
* @return mPtr A memory pointer to the Fulfillment struct head.
*/
function _decodeFulfillment(
CalldataPointer cdPtr
) internal pure returns (MemoryPointer mPtr) {
// Allocate required memory for the Fulfillment head (the fulfillment
// components arrays are allocated independently).
mPtr = malloc(Fulfillment_head_size);
// Resolve offerComponents calldata offset, use it to decode and copy
// from calldata, and write resultant memory offset to head in memory.
mPtr.write(_decodeFulfillmentComponents(cdPtr.pptr()));
// Resolve considerationComponents calldata offset, use it to decode and
// copy from calldata, and write resultant memory offset to memory head.
mPtr.offset(Fulfillment_considerationComponents_offset).write(
_decodeFulfillmentComponents(
cdPtr.pptrOffset(Fulfillment_considerationComponents_offset)
)
);
}
/**
* @dev Takes an array of fulfillments from calldata and copies it into
* memory.
*
* @param cdPtrLength A calldata pointer to the start of the fulfillments
* array in calldata which contains the length of the
* array.
*
* @return mPtrLength A memory pointer to the start of the fulfillments
* array in memory which contains the length of the
* array.
*/
function _decodeFulfillments(
CalldataPointer cdPtrLength
) internal pure returns (MemoryPointer mPtrLength) {
// Retrieve length of array, masking to prevent potential overflow.
uint256 arrLength = cdPtrLength.readMaskedUint256();
unchecked {
// Derive offset to the tail based on one word per array element.
uint256 tailOffset = arrLength << OneWordShift;
// Add one additional word for the length and allocate memory.
mPtrLength = malloc(tailOffset + OneWord);
// Write the length of the array to memory.
mPtrLength.write(arrLength);
// Advance to first memory & calldata pointers (e.g. after length).
MemoryPointer mPtrHead = mPtrLength.next();
CalldataPointer cdPtrHead = cdPtrLength.next();
// Iterate over each pointer, word by word, until tail is reached.
for (uint256 offset = 0; offset < tailOffset; offset += OneWord) {
// Resolve Fulfillment calldata offset, use it to decode and
// copy from calldata, and write resultant memory offset.
mPtrHead.offset(offset).write(
_decodeFulfillment(cdPtrHead.pptrOffset(offset))
);
}
}
}
/**
* @dev Takes a calldata pointer to an OrderComponents struct and copies the
* decoded struct to memory as an OrderParameters struct (with the
* totalOriginalConsiderationItems value set equal to the length of the
* supplied consideration array).
*
* @param cdPtr A calldata pointer for the OrderComponents struct.
*
* @return mPtr A memory pointer to the OrderParameters struct head.
*/
function _decodeOrderComponentsAsOrderParameters(
CalldataPointer cdPtr
) internal pure returns (MemoryPointer mPtr) {
// Allocate memory for the OrderParameters head.
mPtr = malloc(OrderParameters_head_size);
// Copy the full OrderComponents head from calldata to memory.
cdPtr.copy(mPtr, OrderComponents_OrderParameters_common_head_size);
// Resolve the offer calldata offset, use that to decode and copy offer
// from calldata, and write resultant memory offset to head in memory.
mPtr.offset(OrderParameters_offer_head_offset).write(
_decodeOffer(cdPtr.pptrOffset(OrderParameters_offer_head_offset))
);
// Resolve consideration calldata offset, use that to copy consideration
// from calldata, and write resultant memory offset to head in memory.
MemoryPointer consideration = _decodeConsideration(
cdPtr.pptrOffset(OrderParameters_consideration_head_offset)
);
mPtr.offset(OrderParameters_consideration_head_offset).write(
consideration
);
// Write masked consideration length to totalOriginalConsiderationItems.
mPtr
.offset(OrderParameters_totalOriginalConsiderationItems_offset)
.write(consideration.readUint256());
}
/**
* @dev Decodes the returndata from a call to generateOrder, or returns
* empty arrays and a boolean signifying that the returndata does not
* adhere to a valid encoding scheme if it cannot be decoded. Note
* that this function expects that original offer and consideration
* item arrays have been modified and repurposed to resemble spent
* and received item arrays; specifically, the recipient should be
* in the endAmount location on consideration items and the derived
* amount should be in the startAmount location for both item types.
*
* @return invalidEncoding A boolean signifying whether the returndata has
* an invalid encoding.
* @return offer The decoded offer array.
* @return consideration The decoded consideration array.
*/
function _decodeGenerateOrderReturndata(
MemoryPointer originalOffer,
MemoryPointer originalConsideration
)
internal
pure
returns (
uint256 invalidEncoding,
MemoryPointer offer,
MemoryPointer consideration
)
{
assembly {
// Check that returndatasize is at least three words:
// 1. offerOffset
// 2. considerationOffset
// 3. offerLength & considerationLength might occupy just one word
// if offerOffset & considerationOffset would point to the same
// offset and the arrays have length 0.
invalidEncoding := lt(returndatasize(), ThreeWords)
let offsetOffer
let offsetConsideration
let offerLength
let considerationLength
// Proceed if enough returndata is present to continue evaluation.
if iszero(invalidEncoding) {
// Copy first two words of returndata (the offsets to offer and
// consideration array lengths) to scratch space.
returndatacopy(0, 0, TwoWords)
offsetOffer := mload(0)
offsetConsideration := mload(OneWord)
// If valid length, check that offsets word boundaries are
// within returndata.
let invalidOfferOffset := gt(
add(offsetOffer, OneWord),
returndatasize()
)
let invalidConsiderationOffset := gt(
add(offsetConsideration, OneWord),
returndatasize()
)
// Only proceed if length (and thus encoding) is valid so far.
invalidEncoding := or(
invalidOfferOffset,
invalidConsiderationOffset
)
if iszero(invalidEncoding) {
// Copy length of offer array to scratch space.
returndatacopy(0, offsetOffer, OneWord)
offerLength := mload(0)
// Copy length of consideration array to scratch space.
returndatacopy(OneWord, offsetConsideration, OneWord)
considerationLength := mload(OneWord)
{
// Derive end offsets for offer & consideration arrays.
let offerEndOffset := add(
add(offsetOffer, OneWord),
shl(SpentItem_size_shift, offerLength)
)
let considerationEndOffset := add(
add(offsetConsideration, OneWord),
mul(ReceivedItem_size, considerationLength)
)
// Don't continue if either offer or consideration
// length exceeds 65535 or if returndatasize is less
// than the end offsets.
invalidEncoding := or(
gt(
or(offerLength, considerationLength),
generateOrder_maximum_returned_array_length
),
or(
lt(returndatasize(), offerEndOffset),
lt(returndatasize(), considerationEndOffset)
)
)
// Set first word of scratch space to 0 so length of
// offer/consideration are set to 0 on invalid encoding.
mstore(0, 0)
}
}
}
if iszero(invalidEncoding) {
let invalidSpentItems, invalidReceivedItems
offer, invalidSpentItems := copySpentItemsAsOfferItems(
originalOffer,
add(offsetOffer, OneWord),
offerLength
)
consideration, invalidReceivedItems :=
copyReceivedItemsAsConsiderationItems(
originalConsideration,
add(offsetConsideration, OneWord),
considerationLength
)
invalidEncoding := or(invalidSpentItems, invalidReceivedItems)
}
function copySpentItemsAsOfferItems(
mPtrLengthOriginal,
rdPtrHeadSpentItems,
length
) -> mPtrLength, invalidSpentItems {
// Retrieve the current free memory pointer.
mPtrLength := mload(FreeMemoryPointerSlot)
// Cache the original offer array length
let originalOfferLength := mload(mPtrLengthOriginal)
// Allocate memory for the new array.
mstore(
FreeMemoryPointerSlot,
add(
mPtrLength,
add(
OneWord,
mul(length, OfferItem_size_with_head_pointer)
)
)
)
// Write the length of the array to the start of free memory.
mstore(mPtrLength, length)
// Use offset from length to minimize stack depth.
let headOffsetFromLength := OneWord
let headSizeWithLength := shl(OneWordShift, add(1, length))
let mPtrTailNext := add(mPtrLength, headSizeWithLength)
let mPtrTailOriginalNext := add(
mPtrLengthOriginal,
shl(OneWordShift, add(1, originalOfferLength))
)
let headSizeToCompareWithLength := shl(
OneWordShift,
add(1, min(length, originalOfferLength))
)
// Iterate over each new element with a corresponding original
// item. For each original offer item, check that:
// - There is a corresponding new spent item.
// - The original and new items match with compareItems.
// - The new offer item amount >= original amount.
invalidSpentItems := gt(originalOfferLength, length)
for {
} lt(headOffsetFromLength, headSizeToCompareWithLength) {
} {
// Write the memory pointer to the accompanying head offset.
mstore(add(mPtrLength, headOffsetFromLength), mPtrTailNext)
// Copy itemType, token, identifier and amount.
returndatacopy(
mPtrTailNext,
rdPtrHeadSpentItems,
SpentItem_size
)
let newAmount := mload(
add(mPtrTailNext, Common_amount_offset)
)
// Copy amount to endAmount.
mstore(
add(mPtrTailNext, Common_endAmount_offset),
newAmount
)
let originalAmount := mload(
add(mPtrTailOriginalNext, Common_amount_offset)
)
invalidSpentItems := or(
invalidSpentItems,
or(
compareItems(mPtrTailOriginalNext, mPtrTailNext),
gt(originalAmount, newAmount)
)
)
// Update read pointer, next tail pointer for new and
// original, and head offset.
rdPtrHeadSpentItems := add(
rdPtrHeadSpentItems,
SpentItem_size
)
mPtrTailNext := add(mPtrTailNext, OfferItem_size)
mPtrTailOriginalNext := add(
mPtrTailOriginalNext,
OfferItem_size
)
headOffsetFromLength := add(headOffsetFromLength, OneWord)
}
// Iterate over each element without corresponding original item
for {
} lt(headOffsetFromLength, headSizeWithLength) {
} {
// Write the memory pointer to the accompanying head offset.
mstore(add(mPtrLength, headOffsetFromLength), mPtrTailNext)
// Copy itemType, token, identifier and amount.
returndatacopy(
mPtrTailNext,
rdPtrHeadSpentItems,
SpentItem_size
)
// Copy amount to endAmount.
mstore(
add(mPtrTailNext, Common_endAmount_offset),
mload(add(mPtrTailNext, Common_amount_offset))
)
// Update read pointer, next tail pointer, and head offset.
rdPtrHeadSpentItems := add(
rdPtrHeadSpentItems,
SpentItem_size
)
mPtrTailNext := add(mPtrTailNext, OfferItem_size)
headOffsetFromLength := add(headOffsetFromLength, OneWord)
}
}
function copyReceivedItemsAsConsiderationItems(
mPtrLengthOriginal,
rdPtrHeadReceivedItems,
length
) -> mPtrLength, invalidReceivedItems {
// Retrieve the current free memory pointer.
mPtrLength := mload(FreeMemoryPointerSlot)
// Cache the original consideration array length
let originalConsiderationLength := mload(mPtrLengthOriginal)
// Ensure returned array length does not exceed original length.
invalidReceivedItems := gt(length, originalConsiderationLength)
// Derive the length of the new array in memory, capped by the
// original consideration array length.
let newLength := min(length, originalConsiderationLength)
// Allocate memory for the array. Note that memory does not need
// to be allocated for new elements without a corresponding
// original item as the new array will be invalid if its length
// exceeds the original array length.
mstore(
FreeMemoryPointerSlot,
add(
mPtrLength,
add(
OneWord,
mul(
newLength,
ConsiderationItem_size_with_head_pointer
)
)
)
)
// Write the length of the array to the start of free memory.
mstore(mPtrLength, newLength)
// Use offset from length to minimize stack depth.
let headOffsetFromLength := OneWord
let mPtrTailNext := add(
mPtrLength,
shl(OneWordShift, add(1, newLength))
)
let mPtrTailOriginalNext := add(
mPtrLengthOriginal,
shl(OneWordShift, add(1, originalConsiderationLength))
)
let headSizeToCompareWithLength := shl(
OneWordShift,
add(1, newLength)
)
// Iterate over each new element with a corresponding original
// item. For each new received item, check that:
// - The new & original items match according to compareItems.
// - The new consideration item amount <= the original amount.
// - The items have the same recipient if original != null.
for {
} lt(headOffsetFromLength, headSizeToCompareWithLength) {
} {
// Write the memory pointer to the accompanying head offset.
mstore(add(mPtrLength, headOffsetFromLength), mPtrTailNext)
// Copy itemType, token, identifier, amount and recipient.
returndatacopy(
mPtrTailNext,
rdPtrHeadReceivedItems,
ReceivedItem_size
)
// Copy amount to consideration item's recipient offset.
returndatacopy(
add(mPtrTailNext, ConsiderationItem_recipient_offset),
add(rdPtrHeadReceivedItems, Common_amount_offset),
OneWord
)
// Retrieve both the new and original item amounts.
let newAmount := mload(
add(mPtrTailNext, Common_amount_offset)
)
let originalAmount := mload(
add(mPtrTailOriginalNext, Common_amount_offset)
)
// Compare items' item type, token, and identifier, ensure
// they have the same recipient and that the new amount is
// less than or equal to the original amount. The original
// recipient must already be present at the ReceivedItem
// recipient offset rather than at the initial
// ConsiderationItem recipient offset.
invalidReceivedItems := or(
invalidReceivedItems,
or(
compareItems(mPtrTailOriginalNext, mPtrTailNext),
or(
gt(newAmount, originalAmount),
checkRecipients(
mload(
add(
mPtrTailOriginalNext,
ReceivedItem_recipient_offset
)
),
mload(
add(
mPtrTailNext,
ReceivedItem_recipient_offset
)
)
)
)
)
)
// Update read pointer, next tail pointer, and head offset.
rdPtrHeadReceivedItems := add(
rdPtrHeadReceivedItems,
ReceivedItem_size
)
mPtrTailNext := add(mPtrTailNext, ConsiderationItem_size)
mPtrTailOriginalNext := add(
mPtrTailOriginalNext,
ConsiderationItem_size
)
headOffsetFromLength := add(headOffsetFromLength, OneWord)
}
// Note: skip copying new elements without a corresponding
// original item as the new array will be invalid if its length
// exceeds the original array length.
}
/**
* @dev Yul function to check the compatibility of two offer or
* consideration items for contract orders. Note that the
* itemType and identifier are reset in cases where criteria is
* equal to 0 (collection-wide or "wildcard" items), which
* means that a contract offerer has full latitude to choose
* any identifier it wants mid-flight, in contrast to the usual
* behavior, where the fulfiller can pick which identifier to
* receive by providing a CriteriaResolver.
*
* @param originalItem The original offer or consideration item.
* @param newItem The new offer or consideration item.
*
* @return isInvalid Error buffer indicating whether or not the
* items are incompatible.
*/
function compareItems(originalItem, newItem) -> isInvalid {
let itemType := mload(originalItem)
let identifier := mload(
add(originalItem, Common_identifier_offset)
)
// Use returned identifier for criteria-based items with a
// criteria value of 0 (collection-wide or "wildcard" items).
if and(gt(itemType, 3), iszero(identifier)) {
// Replace item type with non-criteria equivalent.
itemType := sub(itemType, 2)
// Replace identifier with the returned identifier.
identifier := mload(add(newItem, Common_identifier_offset))
}
isInvalid := iszero(
and(
// originalItem.token == newItem.token &&
// originalItem.itemType == newItem.itemType
and(
eq(
mload(add(originalItem, Common_token_offset)),
mload(add(newItem, Common_token_offset))
),
eq(itemType, mload(newItem))
),
// originalItem.identifier == newItem.identifier
eq(
identifier,
mload(add(newItem, Common_identifier_offset))
)
)
)
}
/**
* @dev Internal pure function to check the compatibility of two
* recipients on consideration items for contract orders. This
* check is skipped if no recipient is originally supplied.
*
* @param originalRecipient The original consideration item
* recipient.
* @param newRecipient The new consideration item recipient.
*
* @return isInvalid Error buffer indicating whether or not the
* two recipients are incompatible.
*/
function checkRecipients(originalRecipient, newRecipient)
-> isInvalid
{
isInvalid := iszero(
or(
iszero(originalRecipient),
eq(newRecipient, originalRecipient)
)
)
}
function min(a, b) -> c {
c := add(b, mul(lt(a, b), sub(a, b)))
}
}
}
/**
* @dev Converts a function returning _decodeGenerateOrderReturndata types
* into a function returning offer and consideration types.
*
* @param inFn The input function, taking no arguments and returning an
* error buffer, spent item array, and received item array.
*
* @return outFn The output function, taking no arguments and returning an
* error buffer, offer array, and consideration array.
*/
function _convertGetGeneratedOrderResult(
function(MemoryPointer, MemoryPointer)
internal
pure
returns (uint256, MemoryPointer, MemoryPointer) inFn
)
internal
pure
returns (
function(OfferItem[] memory, ConsiderationItem[] memory)
internal
pure
returns (
uint256,
OfferItem[] memory,
ConsiderationItem[] memory
) outFn
)
{
assembly {
outFn := inFn
}
}
/**
* @dev Converts a function taking ReceivedItem, address, bytes32, and bytes
* types (e.g. the _transfer function) into a function taking
* OfferItem, address, bytes32, and bytes types.
*
* @param inFn The input function, taking ReceivedItem, address, bytes32,
* and bytes types (e.g. the _transfer function).
*
* @return outFn The output function, taking OfferItem, address, bytes32,
* and bytes types.
*/
function _toOfferItemInput(
function(ReceivedItem memory, address, bytes32, bytes memory)
internal inFn
)
internal
pure
returns (
function(OfferItem memory, address, bytes32, bytes memory)
internal outFn
)
{
assembly {
outFn := inFn
}
}
/**
* @dev Converts a function taking ReceivedItem, address, bytes32, and bytes
* types (e.g. the _transfer function) into a function taking
* ConsiderationItem, address, bytes32, and bytes types.
*
* @param inFn The input function, taking ReceivedItem, address, bytes32,
* and bytes types (e.g. the _transfer function).
*
* @return outFn The output function, taking ConsiderationItem, address,
* bytes32, and bytes types.
*/
function _toConsiderationItemInput(
function(ReceivedItem memory, address, bytes32, bytes memory)
internal inFn
)
internal
pure
returns (
function(ConsiderationItem memory, address, bytes32, bytes memory)
internal outFn
)
{
assembly {
outFn := inFn
}
}
/**
* @dev Converts a function taking a calldata pointer and returning a memory
* pointer into a function taking that calldata pointer and returning
* a bytes type.
*
* @param inFn The input function, taking an arbitrary calldata pointer and
* returning an arbitrary memory pointer.
*
* @return outFn The output function, taking an arbitrary calldata pointer
* and returning a bytes type.
*/
function _toBytesReturnType(
function(CalldataPointer) internal pure returns (MemoryPointer) inFn
)
internal
pure
returns (
function(CalldataPointer) internal pure returns (bytes memory) outFn
)
{
assembly {
outFn := inFn
}
}
/**
* @dev Converts a function taking a calldata pointer and returning a memory
* pointer into a function taking that calldata pointer and returning
* an OrderParameters type.
*
* @param inFn The input function, taking an arbitrary calldata pointer and
* returning an arbitrary memory pointer.
*
* @return outFn The output function, taking an arbitrary calldata pointer
* and returning an OrderParameters type.
*/
function _toOrderParametersReturnType(
function(CalldataPointer) internal pure returns (MemoryPointer) inFn
)
internal
pure
returns (
function(CalldataPointer)
internal
pure
returns (OrderParameters memory) outFn
)
{
assembly {
outFn := inFn
}
}
/**
* @dev Converts a function taking a calldata pointer and returning a memory
* pointer into a function taking that calldata pointer and returning
* an AdvancedOrder type.
*
* @param inFn The input function, taking an arbitrary calldata pointer and
* returning an arbitrary memory pointer.
*
* @return outFn The output function, taking an arbitrary calldata pointer
* and returning an AdvancedOrder type.
*/
function _toAdvancedOrderReturnType(
function(CalldataPointer) internal pure returns (MemoryPointer) inFn
)
internal
pure
returns (
function(CalldataPointer)
internal
pure
returns (AdvancedOrder memory) outFn
)
{
assembly {
outFn := inFn
}
}
/**
* @dev Converts a function taking a calldata pointer and returning a memory
* pointer into a function taking that calldata pointer and returning
* a dynamic array of CriteriaResolver types.
*
* @param inFn The input function, taking an arbitrary calldata pointer and
* returning an arbitrary memory pointer.
*
* @return outFn The output function, taking an arbitrary calldata pointer
* and returning a dynamic array of CriteriaResolver types.
*/
function _toCriteriaResolversReturnType(
function(CalldataPointer) internal pure returns (MemoryPointer) inFn
)
internal
pure
returns (
function(CalldataPointer)
internal
pure
returns (CriteriaResolver[] memory) outFn
)
{
assembly {
outFn := inFn
}
}
/**
* @dev Converts a function taking a calldata pointer and returning a memory
* pointer into a function taking that calldata pointer and returning
* a dynamic array of Order types.
*
* @param inFn The input function, taking an arbitrary calldata pointer and
* returning an arbitrary memory pointer.
*
* @return outFn The output function, taking an arbitrary calldata pointer
* and returning a dynamic array of Order types.
*/
function _toOrdersReturnType(
function(CalldataPointer) internal pure returns (MemoryPointer) inFn
)
internal
pure
returns (
function(CalldataPointer)
internal
pure
returns (Order[] memory) outFn
)
{
assembly {
outFn := inFn
}
}
/**
* @dev Converts a function taking a calldata pointer and returning a memory
* pointer into a function taking that calldata pointer and returning
* a nested dynamic array of dynamic arrays of FulfillmentComponent
* types.
*
* @param inFn The input function, taking an arbitrary calldata pointer and
* returning an arbitrary memory pointer.
*
* @return outFn The output function, taking an arbitrary calldata pointer
* and returning a nested dynamic array of dynamic arrays of
* FulfillmentComponent types.
*/
function _toNestedFulfillmentComponentsReturnType(
function(CalldataPointer) internal pure returns (MemoryPointer) inFn
)
internal
pure
returns (
function(CalldataPointer)
internal
pure
returns (FulfillmentComponent[][] memory) outFn
)
{
assembly {
outFn := inFn
}
}
/**
* @dev Converts a function taking a calldata pointer and returning a memory
* pointer into a function taking that calldata pointer and returning
* a dynamic array of AdvancedOrder types.
*
* @param inFn The input function, taking an arbitrary calldata pointer and
* returning an arbitrary memory pointer.
*
* @return outFn The output function, taking an arbitrary calldata pointer
* and returning a dynamic array of AdvancedOrder types.
*/
function _toAdvancedOrdersReturnType(
function(CalldataPointer) internal pure returns (MemoryPointer) inFn
)
internal
pure
returns (
function(CalldataPointer)
internal
pure
returns (AdvancedOrder[] memory) outFn
)
{
assembly {
outFn := inFn
}
}
/**
* @dev Converts a function taking a calldata pointer and returning a memory
* pointer into a function taking that calldata pointer and returning
* a dynamic array of Fulfillment types.
*
* @param inFn The input function, taking an arbitrary calldata pointer and
* returning an arbitrary memory pointer.
*
* @return outFn The output function, taking an arbitrary calldata pointer
* and returning a dynamic array of Fulfillment types.
*/
function _toFulfillmentsReturnType(
function(CalldataPointer) internal pure returns (MemoryPointer) inFn
)
internal
pure
returns (
function(CalldataPointer)
internal
pure
returns (Fulfillment[] memory) outFn
)
{
assembly {
outFn := inFn
}
}
/**
* @dev Caches the endAmount in an offer item and replaces it with
* a given recipient so that its memory may be reused as a temporary
* ReceivedItem.
*
* @param offerItem The offer item.
* @param recipient The recipient.
*
* @return originalEndAmount The original end amount.
*/
function _replaceEndAmountWithRecipient(
OfferItem memory offerItem,
address recipient
) internal pure returns (uint256 originalEndAmount) {
assembly {
// Derive the pointer to the end amount on the offer item.
let endAmountPtr := add(offerItem, ReceivedItem_recipient_offset)
// Retrieve the value of the end amount on the offer item.
originalEndAmount := mload(endAmountPtr)
// Write recipient to received item at the offer end amount pointer.
mstore(endAmountPtr, recipient)
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.13;
/**
* @title ReentrancyErrors
* @author 0age
* @notice ReentrancyErrors contains errors related to reentrancy.
*/
interface ReentrancyErrors {
/**
* @dev Revert with an error when a caller attempts to reenter a protected
* function.
*/
error NoReentrantCalls();
/**
* @dev Revert with an error when attempting to activate the TSTORE opcode
* when it is already active.
*/
error TStoreAlreadyActivated();
/**
* @dev Revert with an error when attempting to activate the TSTORE opcode
* in an EVM environment that does not support it.
*/
error TStoreNotSupported();
/**
* @dev Revert with an error when deployment of the contract for testing
* TSTORE support fails.
*/
error TloadTestContractDeploymentFailed();
}
File 2 of 4: TheModZ
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
import "@openzeppelin/contracts/token/ERC721/ERC721.sol";
import "@openzeppelin/contracts/utils/cryptography/ECDSA.sol";
import "@openzeppelin/contracts/access/Ownable.sol";
contract TheModZ is ERC721, Ownable {
using ECDSA for bytes32;
// base configuration
uint constant public MAX_SUPPLY = 5555;
uint constant public PRICE = 0.05 ether;
string public baseURI;
uint public reservedSupply;
uint public maxMintsPerTransaction;
uint public mintingStartTimestamp;
// presale
uint public presaleStartTimestamp;
uint public presalePerWalletLimit;
address public authorizedSigner;
mapping(address => uint) public mintedOnPresale;
uint public totalSupply;
constructor() ERC721("The ModZ", "MODZ") {
presaleStartTimestamp = 1634763600;
mintingStartTimestamp = 1635109200;
}
// Setters region
function setBaseURI(string memory _baseURIArg) external onlyOwner {
baseURI = _baseURIArg;
}
function setReservedSupply(uint _reservedSupply) external onlyOwner {
reservedSupply = _reservedSupply;
}
function setMaxMintsPerTransaction(uint _maxMintsPerTransaction) external onlyOwner {
maxMintsPerTransaction = _maxMintsPerTransaction;
}
function setMintingStartTimestamp(uint _mintingStartTimestamp) external onlyOwner {
mintingStartTimestamp = _mintingStartTimestamp;
}
function setPresaleStartTimestamp(uint _presaleStartTimestamp) external onlyOwner {
presaleStartTimestamp = _presaleStartTimestamp;
}
function setPresalePerWalletLimit(uint _presalePerWalletLimit) external onlyOwner {
presalePerWalletLimit = _presalePerWalletLimit;
}
function setAuthorizedSigner(address _authorizedSigner) external onlyOwner {
authorizedSigner = _authorizedSigner;
}
function configure(
uint _reservedSupply,
uint _maxMintsPerTransaction,
uint _mintingStartTimestamp,
uint _presaleStartTimestamp,
uint _presalePerWalletLimit,
address _authorizedSigner
) external onlyOwner {
reservedSupply = _reservedSupply;
maxMintsPerTransaction = _maxMintsPerTransaction;
mintingStartTimestamp = _mintingStartTimestamp;
presaleStartTimestamp = _presaleStartTimestamp;
presalePerWalletLimit = _presalePerWalletLimit;
authorizedSigner = _authorizedSigner;
}
// endregion
// region
function _baseURI() internal view override returns (string memory) {
return baseURI;
}
//endregion
//
function hashTransaction(address minter) private pure returns (bytes32) {
bytes32 argsHash = keccak256(abi.encodePacked(minter));
return keccak256(abi.encodePacked("\\x19Ethereum Signed Message:\
32", argsHash));
}
function recoverSignerAddress(address minter, bytes memory signature) private pure returns (address) {
bytes32 hash = hashTransaction(minter);
return hash.recover(signature);
}
// Mint and Claim functions
modifier maxSupplyCheck(uint amount) {
require(totalSupply + reservedSupply + amount <= MAX_SUPPLY, "Tokens supply reached limit");
_;
}
function presale(uint amount, bytes memory signature) external payable {
require(block.timestamp >= presaleStartTimestamp, "Presale is not available");
require(amount * PRICE == msg.value, "Wrong ethers value");
require(mintedOnPresale[msg.sender] + amount <= presalePerWalletLimit, "Max mints per wallet constraint violation");
require(recoverSignerAddress(msg.sender, signature) == authorizedSigner, "You have not access to presale");
mintedOnPresale[msg.sender] += amount;
mintNFTs(msg.sender, amount);
}
function mint(uint amount) external payable {
require(block.timestamp >= mintingStartTimestamp, "Minting is not available");
require(amount * PRICE == msg.value, "Wrong ethers value");
require(amount <= maxMintsPerTransaction, "Max mints per transaction constraint violation");
mintNFTs(msg.sender, amount);
}
function mintNFTs(address to, uint amount) internal maxSupplyCheck(amount) {
uint fromToken = totalSupply + 1;
totalSupply += amount;
for (uint i = 0; i < amount; i++) {
_mint(to, fromToken + i);
}
}
//endregion
function airdrop(address[] memory addresses, uint[] memory amounts) external onlyOwner {
for (uint i = 0; i < addresses.length; i++) {
mintNFTs(addresses[i], amounts[i]);
}
}
function withdraw() external onlyOwner {
uint balance = address(this).balance;
uint share1 = 15 * balance / 100;
uint share2 = 5 * balance / 100;
payable(0x897B7cf41d1D7C22bc4F44C0C61dC53F63a4149E).transfer(share1);
payable(0xc0Ad7a7686A12a6E75e2A03F4985FaFF1A761388).transfer(share2);
payable(0xDF747Ffb322215491cC839efC5E7fe47Bf878643).transfer(balance - share1 - share2);
}
}// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
/**
* @dev Interface of the ERC165 standard, as defined in the
* https://eips.ethereum.org/EIPS/eip-165[EIP].
*
* Implementers can declare support of contract interfaces, which can then be
* queried by others ({ERC165Checker}).
*
* For an implementation, see {ERC165}.
*/
interface IERC165 {
/**
* @dev Returns true if this contract implements the interface defined by
* `interfaceId`. See the corresponding
* https://eips.ethereum.org/EIPS/eip-165#how-interfaces-are-identified[EIP section]
* to learn more about how these ids are created.
*
* This function call must use less than 30 000 gas.
*/
function supportsInterface(bytes4 interfaceId) external view returns (bool);
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
import "./IERC165.sol";
/**
* @dev Implementation of the {IERC165} interface.
*
* Contracts that want to implement ERC165 should inherit from this contract and override {supportsInterface} to check
* for the additional interface id that will be supported. For example:
*
* ```solidity
* function supportsInterface(bytes4 interfaceId) public view virtual override returns (bool) {
* return interfaceId == type(MyInterface).interfaceId || super.supportsInterface(interfaceId);
* }
* ```
*
* Alternatively, {ERC165Storage} provides an easier to use but more expensive implementation.
*/
abstract contract ERC165 is IERC165 {
/**
* @dev See {IERC165-supportsInterface}.
*/
function supportsInterface(bytes4 interfaceId) public view virtual override returns (bool) {
return interfaceId == type(IERC165).interfaceId;
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
/**
* @dev Elliptic Curve Digital Signature Algorithm (ECDSA) operations.
*
* These functions can be used to verify that a message was signed by the holder
* of the private keys of a given address.
*/
library ECDSA {
enum RecoverError {
NoError,
InvalidSignature,
InvalidSignatureLength,
InvalidSignatureS,
InvalidSignatureV
}
function _throwError(RecoverError error) private pure {
if (error == RecoverError.NoError) {
return; // no error: do nothing
} else if (error == RecoverError.InvalidSignature) {
revert("ECDSA: invalid signature");
} else if (error == RecoverError.InvalidSignatureLength) {
revert("ECDSA: invalid signature length");
} else if (error == RecoverError.InvalidSignatureS) {
revert("ECDSA: invalid signature 's' value");
} else if (error == RecoverError.InvalidSignatureV) {
revert("ECDSA: invalid signature 'v' value");
}
}
/**
* @dev Returns the address that signed a hashed message (`hash`) with
* `signature` or error string. This address can then be used for verification purposes.
*
* The `ecrecover` EVM opcode allows for malleable (non-unique) signatures:
* this function rejects them by requiring the `s` value to be in the lower
* half order, and the `v` value to be either 27 or 28.
*
* IMPORTANT: `hash` _must_ be the result of a hash operation for the
* verification to be secure: it is possible to craft signatures that
* recover to arbitrary addresses for non-hashed data. A safe way to ensure
* this is by receiving a hash of the original message (which may otherwise
* be too long), and then calling {toEthSignedMessageHash} on it.
*
* Documentation for signature generation:
* - with https://web3js.readthedocs.io/en/v1.3.4/web3-eth-accounts.html#sign[Web3.js]
* - with https://docs.ethers.io/v5/api/signer/#Signer-signMessage[ethers]
*
* _Available since v4.3._
*/
function tryRecover(bytes32 hash, bytes memory signature) internal pure returns (address, RecoverError) {
// Check the signature length
// - case 65: r,s,v signature (standard)
// - case 64: r,vs signature (cf https://eips.ethereum.org/EIPS/eip-2098) _Available since v4.1._
if (signature.length == 65) {
bytes32 r;
bytes32 s;
uint8 v;
// ecrecover takes the signature parameters, and the only way to get them
// currently is to use assembly.
assembly {
r := mload(add(signature, 0x20))
s := mload(add(signature, 0x40))
v := byte(0, mload(add(signature, 0x60)))
}
return tryRecover(hash, v, r, s);
} else if (signature.length == 64) {
bytes32 r;
bytes32 vs;
// ecrecover takes the signature parameters, and the only way to get them
// currently is to use assembly.
assembly {
r := mload(add(signature, 0x20))
vs := mload(add(signature, 0x40))
}
return tryRecover(hash, r, vs);
} else {
return (address(0), RecoverError.InvalidSignatureLength);
}
}
/**
* @dev Returns the address that signed a hashed message (`hash`) with
* `signature`. This address can then be used for verification purposes.
*
* The `ecrecover` EVM opcode allows for malleable (non-unique) signatures:
* this function rejects them by requiring the `s` value to be in the lower
* half order, and the `v` value to be either 27 or 28.
*
* IMPORTANT: `hash` _must_ be the result of a hash operation for the
* verification to be secure: it is possible to craft signatures that
* recover to arbitrary addresses for non-hashed data. A safe way to ensure
* this is by receiving a hash of the original message (which may otherwise
* be too long), and then calling {toEthSignedMessageHash} on it.
*/
function recover(bytes32 hash, bytes memory signature) internal pure returns (address) {
(address recovered, RecoverError error) = tryRecover(hash, signature);
_throwError(error);
return recovered;
}
/**
* @dev Overload of {ECDSA-tryRecover} that receives the `r` and `vs` short-signature fields separately.
*
* See https://eips.ethereum.org/EIPS/eip-2098[EIP-2098 short signatures]
*
* _Available since v4.3._
*/
function tryRecover(
bytes32 hash,
bytes32 r,
bytes32 vs
) internal pure returns (address, RecoverError) {
bytes32 s;
uint8 v;
assembly {
s := and(vs, 0x7fffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff)
v := add(shr(255, vs), 27)
}
return tryRecover(hash, v, r, s);
}
/**
* @dev Overload of {ECDSA-recover} that receives the `r and `vs` short-signature fields separately.
*
* _Available since v4.2._
*/
function recover(
bytes32 hash,
bytes32 r,
bytes32 vs
) internal pure returns (address) {
(address recovered, RecoverError error) = tryRecover(hash, r, vs);
_throwError(error);
return recovered;
}
/**
* @dev Overload of {ECDSA-tryRecover} that receives the `v`,
* `r` and `s` signature fields separately.
*
* _Available since v4.3._
*/
function tryRecover(
bytes32 hash,
uint8 v,
bytes32 r,
bytes32 s
) internal pure returns (address, RecoverError) {
// EIP-2 still allows signature malleability for ecrecover(). Remove this possibility and make the signature
// unique. Appendix F in the Ethereum Yellow paper (https://ethereum.github.io/yellowpaper/paper.pdf), defines
// the valid range for s in (301): 0 < s < secp256k1n ÷ 2 + 1, and for v in (302): v ∈ {27, 28}. Most
// signatures from current libraries generate a unique signature with an s-value in the lower half order.
//
// If your library generates malleable signatures, such as s-values in the upper range, calculate a new s-value
// with 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141 - s1 and flip v from 27 to 28 or
// vice versa. If your library also generates signatures with 0/1 for v instead 27/28, add 27 to v to accept
// these malleable signatures as well.
if (uint256(s) > 0x7FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF5D576E7357A4501DDFE92F46681B20A0) {
return (address(0), RecoverError.InvalidSignatureS);
}
if (v != 27 && v != 28) {
return (address(0), RecoverError.InvalidSignatureV);
}
// If the signature is valid (and not malleable), return the signer address
address signer = ecrecover(hash, v, r, s);
if (signer == address(0)) {
return (address(0), RecoverError.InvalidSignature);
}
return (signer, RecoverError.NoError);
}
/**
* @dev Overload of {ECDSA-recover} that receives the `v`,
* `r` and `s` signature fields separately.
*/
function recover(
bytes32 hash,
uint8 v,
bytes32 r,
bytes32 s
) internal pure returns (address) {
(address recovered, RecoverError error) = tryRecover(hash, v, r, s);
_throwError(error);
return recovered;
}
/**
* @dev Returns an Ethereum Signed Message, created from a `hash`. This
* produces hash corresponding to the one signed with the
* https://eth.wiki/json-rpc/API#eth_sign[`eth_sign`]
* JSON-RPC method as part of EIP-191.
*
* See {recover}.
*/
function toEthSignedMessageHash(bytes32 hash) internal pure returns (bytes32) {
// 32 is the length in bytes of hash,
// enforced by the type signature above
return keccak256(abi.encodePacked("\\x19Ethereum Signed Message:\
32", hash));
}
/**
* @dev Returns an Ethereum Signed Typed Data, created from a
* `domainSeparator` and a `structHash`. This produces hash corresponding
* to the one signed with the
* https://eips.ethereum.org/EIPS/eip-712[`eth_signTypedData`]
* JSON-RPC method as part of EIP-712.
*
* See {recover}.
*/
function toTypedDataHash(bytes32 domainSeparator, bytes32 structHash) internal pure returns (bytes32) {
return keccak256(abi.encodePacked("\\x19\\x01", domainSeparator, structHash));
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
/**
* @dev String operations.
*/
library Strings {
bytes16 private constant _HEX_SYMBOLS = "0123456789abcdef";
/**
* @dev Converts a `uint256` to its ASCII `string` decimal representation.
*/
function toString(uint256 value) internal pure returns (string memory) {
// Inspired by OraclizeAPI's implementation - MIT licence
// https://github.com/oraclize/ethereum-api/blob/b42146b063c7d6ee1358846c198246239e9360e8/oraclizeAPI_0.4.25.sol
if (value == 0) {
return "0";
}
uint256 temp = value;
uint256 digits;
while (temp != 0) {
digits++;
temp /= 10;
}
bytes memory buffer = new bytes(digits);
while (value != 0) {
digits -= 1;
buffer[digits] = bytes1(uint8(48 + uint256(value % 10)));
value /= 10;
}
return string(buffer);
}
/**
* @dev Converts a `uint256` to its ASCII `string` hexadecimal representation.
*/
function toHexString(uint256 value) internal pure returns (string memory) {
if (value == 0) {
return "0x00";
}
uint256 temp = value;
uint256 length = 0;
while (temp != 0) {
length++;
temp >>= 8;
}
return toHexString(value, length);
}
/**
* @dev Converts a `uint256` to its ASCII `string` hexadecimal representation with fixed length.
*/
function toHexString(uint256 value, uint256 length) internal pure returns (string memory) {
bytes memory buffer = new bytes(2 * length + 2);
buffer[0] = "0";
buffer[1] = "x";
for (uint256 i = 2 * length + 1; i > 1; --i) {
buffer[i] = _HEX_SYMBOLS[value & 0xf];
value >>= 4;
}
require(value == 0, "Strings: hex length insufficient");
return string(buffer);
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
/**
* @dev Provides information about the current execution context, including the
* sender of the transaction and its data. While these are generally available
* via msg.sender and msg.data, they should not be accessed in such a direct
* manner, since when dealing with meta-transactions the account sending and
* paying for execution may not be the actual sender (as far as an application
* is concerned).
*
* This contract is only required for intermediate, library-like contracts.
*/
abstract contract Context {
function _msgSender() internal view virtual returns (address) {
return msg.sender;
}
function _msgData() internal view virtual returns (bytes calldata) {
return msg.data;
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
/**
* @dev Collection of functions related to the address type
*/
library Address {
/**
* @dev Returns true if `account` is a contract.
*
* [IMPORTANT]
* ====
* It is unsafe to assume that an address for which this function returns
* false is an externally-owned account (EOA) and not a contract.
*
* Among others, `isContract` will return false for the following
* types of addresses:
*
* - an externally-owned account
* - a contract in construction
* - an address where a contract will be created
* - an address where a contract lived, but was destroyed
* ====
*/
function isContract(address account) internal view returns (bool) {
// This method relies on extcodesize, which returns 0 for contracts in
// construction, since the code is only stored at the end of the
// constructor execution.
uint256 size;
assembly {
size := extcodesize(account)
}
return size > 0;
}
/**
* @dev Replacement for Solidity's `transfer`: sends `amount` wei to
* `recipient`, forwarding all available gas and reverting on errors.
*
* https://eips.ethereum.org/EIPS/eip-1884[EIP1884] increases the gas cost
* of certain opcodes, possibly making contracts go over the 2300 gas limit
* imposed by `transfer`, making them unable to receive funds via
* `transfer`. {sendValue} removes this limitation.
*
* https://diligence.consensys.net/posts/2019/09/stop-using-soliditys-transfer-now/[Learn more].
*
* IMPORTANT: because control is transferred to `recipient`, care must be
* taken to not create reentrancy vulnerabilities. Consider using
* {ReentrancyGuard} or the
* https://solidity.readthedocs.io/en/v0.5.11/security-considerations.html#use-the-checks-effects-interactions-pattern[checks-effects-interactions pattern].
*/
function sendValue(address payable recipient, uint256 amount) internal {
require(address(this).balance >= amount, "Address: insufficient balance");
(bool success, ) = recipient.call{value: amount}("");
require(success, "Address: unable to send value, recipient may have reverted");
}
/**
* @dev Performs a Solidity function call using a low level `call`. A
* plain `call` is an unsafe replacement for a function call: use this
* function instead.
*
* If `target` reverts with a revert reason, it is bubbled up by this
* function (like regular Solidity function calls).
*
* Returns the raw returned data. To convert to the expected return value,
* use https://solidity.readthedocs.io/en/latest/units-and-global-variables.html?highlight=abi.decode#abi-encoding-and-decoding-functions[`abi.decode`].
*
* Requirements:
*
* - `target` must be a contract.
* - calling `target` with `data` must not revert.
*
* _Available since v3.1._
*/
function functionCall(address target, bytes memory data) internal returns (bytes memory) {
return functionCall(target, data, "Address: low-level call failed");
}
/**
* @dev Same as {xref-Address-functionCall-address-bytes-}[`functionCall`], but with
* `errorMessage` as a fallback revert reason when `target` reverts.
*
* _Available since v3.1._
*/
function functionCall(
address target,
bytes memory data,
string memory errorMessage
) internal returns (bytes memory) {
return functionCallWithValue(target, data, 0, errorMessage);
}
/**
* @dev Same as {xref-Address-functionCall-address-bytes-}[`functionCall`],
* but also transferring `value` wei to `target`.
*
* Requirements:
*
* - the calling contract must have an ETH balance of at least `value`.
* - the called Solidity function must be `payable`.
*
* _Available since v3.1._
*/
function functionCallWithValue(
address target,
bytes memory data,
uint256 value
) internal returns (bytes memory) {
return functionCallWithValue(target, data, value, "Address: low-level call with value failed");
}
/**
* @dev Same as {xref-Address-functionCallWithValue-address-bytes-uint256-}[`functionCallWithValue`], but
* with `errorMessage` as a fallback revert reason when `target` reverts.
*
* _Available since v3.1._
*/
function functionCallWithValue(
address target,
bytes memory data,
uint256 value,
string memory errorMessage
) internal returns (bytes memory) {
require(address(this).balance >= value, "Address: insufficient balance for call");
require(isContract(target), "Address: call to non-contract");
(bool success, bytes memory returndata) = target.call{value: value}(data);
return verifyCallResult(success, returndata, errorMessage);
}
/**
* @dev Same as {xref-Address-functionCall-address-bytes-}[`functionCall`],
* but performing a static call.
*
* _Available since v3.3._
*/
function functionStaticCall(address target, bytes memory data) internal view returns (bytes memory) {
return functionStaticCall(target, data, "Address: low-level static call failed");
}
/**
* @dev Same as {xref-Address-functionCall-address-bytes-string-}[`functionCall`],
* but performing a static call.
*
* _Available since v3.3._
*/
function functionStaticCall(
address target,
bytes memory data,
string memory errorMessage
) internal view returns (bytes memory) {
require(isContract(target), "Address: static call to non-contract");
(bool success, bytes memory returndata) = target.staticcall(data);
return verifyCallResult(success, returndata, errorMessage);
}
/**
* @dev Same as {xref-Address-functionCall-address-bytes-}[`functionCall`],
* but performing a delegate call.
*
* _Available since v3.4._
*/
function functionDelegateCall(address target, bytes memory data) internal returns (bytes memory) {
return functionDelegateCall(target, data, "Address: low-level delegate call failed");
}
/**
* @dev Same as {xref-Address-functionCall-address-bytes-string-}[`functionCall`],
* but performing a delegate call.
*
* _Available since v3.4._
*/
function functionDelegateCall(
address target,
bytes memory data,
string memory errorMessage
) internal returns (bytes memory) {
require(isContract(target), "Address: delegate call to non-contract");
(bool success, bytes memory returndata) = target.delegatecall(data);
return verifyCallResult(success, returndata, errorMessage);
}
/**
* @dev Tool to verifies that a low level call was successful, and revert if it wasn't, either by bubbling the
* revert reason using the provided one.
*
* _Available since v4.3._
*/
function verifyCallResult(
bool success,
bytes memory returndata,
string memory errorMessage
) internal pure returns (bytes memory) {
if (success) {
return returndata;
} else {
// Look for revert reason and bubble it up if present
if (returndata.length > 0) {
// The easiest way to bubble the revert reason is using memory via assembly
assembly {
let returndata_size := mload(returndata)
revert(add(32, returndata), returndata_size)
}
} else {
revert(errorMessage);
}
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
import "../IERC721.sol";
/**
* @title ERC-721 Non-Fungible Token Standard, optional metadata extension
* @dev See https://eips.ethereum.org/EIPS/eip-721
*/
interface IERC721Metadata is IERC721 {
/**
* @dev Returns the token collection name.
*/
function name() external view returns (string memory);
/**
* @dev Returns the token collection symbol.
*/
function symbol() external view returns (string memory);
/**
* @dev Returns the Uniform Resource Identifier (URI) for `tokenId` token.
*/
function tokenURI(uint256 tokenId) external view returns (string memory);
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
/**
* @title ERC721 token receiver interface
* @dev Interface for any contract that wants to support safeTransfers
* from ERC721 asset contracts.
*/
interface IERC721Receiver {
/**
* @dev Whenever an {IERC721} `tokenId` token is transferred to this contract via {IERC721-safeTransferFrom}
* by `operator` from `from`, this function is called.
*
* It must return its Solidity selector to confirm the token transfer.
* If any other value is returned or the interface is not implemented by the recipient, the transfer will be reverted.
*
* The selector can be obtained in Solidity with `IERC721.onERC721Received.selector`.
*/
function onERC721Received(
address operator,
address from,
uint256 tokenId,
bytes calldata data
) external returns (bytes4);
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
import "../../utils/introspection/IERC165.sol";
/**
* @dev Required interface of an ERC721 compliant contract.
*/
interface IERC721 is IERC165 {
/**
* @dev Emitted when `tokenId` token is transferred from `from` to `to`.
*/
event Transfer(address indexed from, address indexed to, uint256 indexed tokenId);
/**
* @dev Emitted when `owner` enables `approved` to manage the `tokenId` token.
*/
event Approval(address indexed owner, address indexed approved, uint256 indexed tokenId);
/**
* @dev Emitted when `owner` enables or disables (`approved`) `operator` to manage all of its assets.
*/
event ApprovalForAll(address indexed owner, address indexed operator, bool approved);
/**
* @dev Returns the number of tokens in ``owner``'s account.
*/
function balanceOf(address owner) external view returns (uint256 balance);
/**
* @dev Returns the owner of the `tokenId` token.
*
* Requirements:
*
* - `tokenId` must exist.
*/
function ownerOf(uint256 tokenId) external view returns (address owner);
/**
* @dev Safely transfers `tokenId` token from `from` to `to`, checking first that contract recipients
* are aware of the ERC721 protocol to prevent tokens from being forever locked.
*
* Requirements:
*
* - `from` cannot be the zero address.
* - `to` cannot be the zero address.
* - `tokenId` token must exist and be owned by `from`.
* - If the caller is not `from`, it must be have been allowed to move this token by either {approve} or {setApprovalForAll}.
* - If `to` refers to a smart contract, it must implement {IERC721Receiver-onERC721Received}, which is called upon a safe transfer.
*
* Emits a {Transfer} event.
*/
function safeTransferFrom(
address from,
address to,
uint256 tokenId
) external;
/**
* @dev Transfers `tokenId` token from `from` to `to`.
*
* WARNING: Usage of this method is discouraged, use {safeTransferFrom} whenever possible.
*
* Requirements:
*
* - `from` cannot be the zero address.
* - `to` cannot be the zero address.
* - `tokenId` token must be owned by `from`.
* - If the caller is not `from`, it must be approved to move this token by either {approve} or {setApprovalForAll}.
*
* Emits a {Transfer} event.
*/
function transferFrom(
address from,
address to,
uint256 tokenId
) external;
/**
* @dev Gives permission to `to` to transfer `tokenId` token to another account.
* The approval is cleared when the token is transferred.
*
* Only a single account can be approved at a time, so approving the zero address clears previous approvals.
*
* Requirements:
*
* - The caller must own the token or be an approved operator.
* - `tokenId` must exist.
*
* Emits an {Approval} event.
*/
function approve(address to, uint256 tokenId) external;
/**
* @dev Returns the account approved for `tokenId` token.
*
* Requirements:
*
* - `tokenId` must exist.
*/
function getApproved(uint256 tokenId) external view returns (address operator);
/**
* @dev Approve or remove `operator` as an operator for the caller.
* Operators can call {transferFrom} or {safeTransferFrom} for any token owned by the caller.
*
* Requirements:
*
* - The `operator` cannot be the caller.
*
* Emits an {ApprovalForAll} event.
*/
function setApprovalForAll(address operator, bool _approved) external;
/**
* @dev Returns if the `operator` is allowed to manage all of the assets of `owner`.
*
* See {setApprovalForAll}
*/
function isApprovedForAll(address owner, address operator) external view returns (bool);
/**
* @dev Safely transfers `tokenId` token from `from` to `to`.
*
* Requirements:
*
* - `from` cannot be the zero address.
* - `to` cannot be the zero address.
* - `tokenId` token must exist and be owned by `from`.
* - If the caller is not `from`, it must be approved to move this token by either {approve} or {setApprovalForAll}.
* - If `to` refers to a smart contract, it must implement {IERC721Receiver-onERC721Received}, which is called upon a safe transfer.
*
* Emits a {Transfer} event.
*/
function safeTransferFrom(
address from,
address to,
uint256 tokenId,
bytes calldata data
) external;
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
import "./IERC721.sol";
import "./IERC721Receiver.sol";
import "./extensions/IERC721Metadata.sol";
import "../../utils/Address.sol";
import "../../utils/Context.sol";
import "../../utils/Strings.sol";
import "../../utils/introspection/ERC165.sol";
/**
* @dev Implementation of https://eips.ethereum.org/EIPS/eip-721[ERC721] Non-Fungible Token Standard, including
* the Metadata extension, but not including the Enumerable extension, which is available separately as
* {ERC721Enumerable}.
*/
contract ERC721 is Context, ERC165, IERC721, IERC721Metadata {
using Address for address;
using Strings for uint256;
// Token name
string private _name;
// Token symbol
string private _symbol;
// Mapping from token ID to owner address
mapping(uint256 => address) private _owners;
// Mapping owner address to token count
mapping(address => uint256) private _balances;
// Mapping from token ID to approved address
mapping(uint256 => address) private _tokenApprovals;
// Mapping from owner to operator approvals
mapping(address => mapping(address => bool)) private _operatorApprovals;
/**
* @dev Initializes the contract by setting a `name` and a `symbol` to the token collection.
*/
constructor(string memory name_, string memory symbol_) {
_name = name_;
_symbol = symbol_;
}
/**
* @dev See {IERC165-supportsInterface}.
*/
function supportsInterface(bytes4 interfaceId) public view virtual override(ERC165, IERC165) returns (bool) {
return
interfaceId == type(IERC721).interfaceId ||
interfaceId == type(IERC721Metadata).interfaceId ||
super.supportsInterface(interfaceId);
}
/**
* @dev See {IERC721-balanceOf}.
*/
function balanceOf(address owner) public view virtual override returns (uint256) {
require(owner != address(0), "ERC721: balance query for the zero address");
return _balances[owner];
}
/**
* @dev See {IERC721-ownerOf}.
*/
function ownerOf(uint256 tokenId) public view virtual override returns (address) {
address owner = _owners[tokenId];
require(owner != address(0), "ERC721: owner query for nonexistent token");
return owner;
}
/**
* @dev See {IERC721Metadata-name}.
*/
function name() public view virtual override returns (string memory) {
return _name;
}
/**
* @dev See {IERC721Metadata-symbol}.
*/
function symbol() public view virtual override returns (string memory) {
return _symbol;
}
/**
* @dev See {IERC721Metadata-tokenURI}.
*/
function tokenURI(uint256 tokenId) public view virtual override returns (string memory) {
require(_exists(tokenId), "ERC721Metadata: URI query for nonexistent token");
string memory baseURI = _baseURI();
return bytes(baseURI).length > 0 ? string(abi.encodePacked(baseURI, tokenId.toString())) : "";
}
/**
* @dev Base URI for computing {tokenURI}. If set, the resulting URI for each
* token will be the concatenation of the `baseURI` and the `tokenId`. Empty
* by default, can be overriden in child contracts.
*/
function _baseURI() internal view virtual returns (string memory) {
return "";
}
/**
* @dev See {IERC721-approve}.
*/
function approve(address to, uint256 tokenId) public virtual override {
address owner = ERC721.ownerOf(tokenId);
require(to != owner, "ERC721: approval to current owner");
require(
_msgSender() == owner || isApprovedForAll(owner, _msgSender()),
"ERC721: approve caller is not owner nor approved for all"
);
_approve(to, tokenId);
}
/**
* @dev See {IERC721-getApproved}.
*/
function getApproved(uint256 tokenId) public view virtual override returns (address) {
require(_exists(tokenId), "ERC721: approved query for nonexistent token");
return _tokenApprovals[tokenId];
}
/**
* @dev See {IERC721-setApprovalForAll}.
*/
function setApprovalForAll(address operator, bool approved) public virtual override {
require(operator != _msgSender(), "ERC721: approve to caller");
_operatorApprovals[_msgSender()][operator] = approved;
emit ApprovalForAll(_msgSender(), operator, approved);
}
/**
* @dev See {IERC721-isApprovedForAll}.
*/
function isApprovedForAll(address owner, address operator) public view virtual override returns (bool) {
return _operatorApprovals[owner][operator];
}
/**
* @dev See {IERC721-transferFrom}.
*/
function transferFrom(
address from,
address to,
uint256 tokenId
) public virtual override {
//solhint-disable-next-line max-line-length
require(_isApprovedOrOwner(_msgSender(), tokenId), "ERC721: transfer caller is not owner nor approved");
_transfer(from, to, tokenId);
}
/**
* @dev See {IERC721-safeTransferFrom}.
*/
function safeTransferFrom(
address from,
address to,
uint256 tokenId
) public virtual override {
safeTransferFrom(from, to, tokenId, "");
}
/**
* @dev See {IERC721-safeTransferFrom}.
*/
function safeTransferFrom(
address from,
address to,
uint256 tokenId,
bytes memory _data
) public virtual override {
require(_isApprovedOrOwner(_msgSender(), tokenId), "ERC721: transfer caller is not owner nor approved");
_safeTransfer(from, to, tokenId, _data);
}
/**
* @dev Safely transfers `tokenId` token from `from` to `to`, checking first that contract recipients
* are aware of the ERC721 protocol to prevent tokens from being forever locked.
*
* `_data` is additional data, it has no specified format and it is sent in call to `to`.
*
* This internal function is equivalent to {safeTransferFrom}, and can be used to e.g.
* implement alternative mechanisms to perform token transfer, such as signature-based.
*
* Requirements:
*
* - `from` cannot be the zero address.
* - `to` cannot be the zero address.
* - `tokenId` token must exist and be owned by `from`.
* - If `to` refers to a smart contract, it must implement {IERC721Receiver-onERC721Received}, which is called upon a safe transfer.
*
* Emits a {Transfer} event.
*/
function _safeTransfer(
address from,
address to,
uint256 tokenId,
bytes memory _data
) internal virtual {
_transfer(from, to, tokenId);
require(_checkOnERC721Received(from, to, tokenId, _data), "ERC721: transfer to non ERC721Receiver implementer");
}
/**
* @dev Returns whether `tokenId` exists.
*
* Tokens can be managed by their owner or approved accounts via {approve} or {setApprovalForAll}.
*
* Tokens start existing when they are minted (`_mint`),
* and stop existing when they are burned (`_burn`).
*/
function _exists(uint256 tokenId) internal view virtual returns (bool) {
return _owners[tokenId] != address(0);
}
/**
* @dev Returns whether `spender` is allowed to manage `tokenId`.
*
* Requirements:
*
* - `tokenId` must exist.
*/
function _isApprovedOrOwner(address spender, uint256 tokenId) internal view virtual returns (bool) {
require(_exists(tokenId), "ERC721: operator query for nonexistent token");
address owner = ERC721.ownerOf(tokenId);
return (spender == owner || getApproved(tokenId) == spender || isApprovedForAll(owner, spender));
}
/**
* @dev Safely mints `tokenId` and transfers it to `to`.
*
* Requirements:
*
* - `tokenId` must not exist.
* - If `to` refers to a smart contract, it must implement {IERC721Receiver-onERC721Received}, which is called upon a safe transfer.
*
* Emits a {Transfer} event.
*/
function _safeMint(address to, uint256 tokenId) internal virtual {
_safeMint(to, tokenId, "");
}
/**
* @dev Same as {xref-ERC721-_safeMint-address-uint256-}[`_safeMint`], with an additional `data` parameter which is
* forwarded in {IERC721Receiver-onERC721Received} to contract recipients.
*/
function _safeMint(
address to,
uint256 tokenId,
bytes memory _data
) internal virtual {
_mint(to, tokenId);
require(
_checkOnERC721Received(address(0), to, tokenId, _data),
"ERC721: transfer to non ERC721Receiver implementer"
);
}
/**
* @dev Mints `tokenId` and transfers it to `to`.
*
* WARNING: Usage of this method is discouraged, use {_safeMint} whenever possible
*
* Requirements:
*
* - `tokenId` must not exist.
* - `to` cannot be the zero address.
*
* Emits a {Transfer} event.
*/
function _mint(address to, uint256 tokenId) internal virtual {
require(to != address(0), "ERC721: mint to the zero address");
require(!_exists(tokenId), "ERC721: token already minted");
_beforeTokenTransfer(address(0), to, tokenId);
_balances[to] += 1;
_owners[tokenId] = to;
emit Transfer(address(0), to, tokenId);
}
/**
* @dev Destroys `tokenId`.
* The approval is cleared when the token is burned.
*
* Requirements:
*
* - `tokenId` must exist.
*
* Emits a {Transfer} event.
*/
function _burn(uint256 tokenId) internal virtual {
address owner = ERC721.ownerOf(tokenId);
_beforeTokenTransfer(owner, address(0), tokenId);
// Clear approvals
_approve(address(0), tokenId);
_balances[owner] -= 1;
delete _owners[tokenId];
emit Transfer(owner, address(0), tokenId);
}
/**
* @dev Transfers `tokenId` from `from` to `to`.
* As opposed to {transferFrom}, this imposes no restrictions on msg.sender.
*
* Requirements:
*
* - `to` cannot be the zero address.
* - `tokenId` token must be owned by `from`.
*
* Emits a {Transfer} event.
*/
function _transfer(
address from,
address to,
uint256 tokenId
) internal virtual {
require(ERC721.ownerOf(tokenId) == from, "ERC721: transfer of token that is not own");
require(to != address(0), "ERC721: transfer to the zero address");
_beforeTokenTransfer(from, to, tokenId);
// Clear approvals from the previous owner
_approve(address(0), tokenId);
_balances[from] -= 1;
_balances[to] += 1;
_owners[tokenId] = to;
emit Transfer(from, to, tokenId);
}
/**
* @dev Approve `to` to operate on `tokenId`
*
* Emits a {Approval} event.
*/
function _approve(address to, uint256 tokenId) internal virtual {
_tokenApprovals[tokenId] = to;
emit Approval(ERC721.ownerOf(tokenId), to, tokenId);
}
/**
* @dev Internal function to invoke {IERC721Receiver-onERC721Received} on a target address.
* The call is not executed if the target address is not a contract.
*
* @param from address representing the previous owner of the given token ID
* @param to target address that will receive the tokens
* @param tokenId uint256 ID of the token to be transferred
* @param _data bytes optional data to send along with the call
* @return bool whether the call correctly returned the expected magic value
*/
function _checkOnERC721Received(
address from,
address to,
uint256 tokenId,
bytes memory _data
) private returns (bool) {
if (to.isContract()) {
try IERC721Receiver(to).onERC721Received(_msgSender(), from, tokenId, _data) returns (bytes4 retval) {
return retval == IERC721Receiver.onERC721Received.selector;
} catch (bytes memory reason) {
if (reason.length == 0) {
revert("ERC721: transfer to non ERC721Receiver implementer");
} else {
assembly {
revert(add(32, reason), mload(reason))
}
}
}
} else {
return true;
}
}
/**
* @dev Hook that is called before any token transfer. This includes minting
* and burning.
*
* Calling conditions:
*
* - When `from` and `to` are both non-zero, ``from``'s `tokenId` will be
* transferred to `to`.
* - When `from` is zero, `tokenId` will be minted for `to`.
* - When `to` is zero, ``from``'s `tokenId` will be burned.
* - `from` and `to` are never both zero.
*
* To learn more about hooks, head to xref:ROOT:extending-contracts.adoc#using-hooks[Using Hooks].
*/
function _beforeTokenTransfer(
address from,
address to,
uint256 tokenId
) internal virtual {}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
import "../utils/Context.sol";
/**
* @dev Contract module which provides a basic access control mechanism, where
* there is an account (an owner) that can be granted exclusive access to
* specific functions.
*
* By default, the owner account will be the one that deploys the contract. This
* can later be changed with {transferOwnership}.
*
* This module is used through inheritance. It will make available the modifier
* `onlyOwner`, which can be applied to your functions to restrict their use to
* the owner.
*/
abstract contract Ownable is Context {
address private _owner;
event OwnershipTransferred(address indexed previousOwner, address indexed newOwner);
/**
* @dev Initializes the contract setting the deployer as the initial owner.
*/
constructor() {
_setOwner(_msgSender());
}
/**
* @dev Returns the address of the current owner.
*/
function owner() public view virtual returns (address) {
return _owner;
}
/**
* @dev Throws if called by any account other than the owner.
*/
modifier onlyOwner() {
require(owner() == _msgSender(), "Ownable: caller is not the owner");
_;
}
/**
* @dev Leaves the contract without owner. It will not be possible to call
* `onlyOwner` functions anymore. Can only be called by the current owner.
*
* NOTE: Renouncing ownership will leave the contract without an owner,
* thereby removing any functionality that is only available to the owner.
*/
function renounceOwnership() public virtual onlyOwner {
_setOwner(address(0));
}
/**
* @dev Transfers ownership of the contract to a new account (`newOwner`).
* Can only be called by the current owner.
*/
function transferOwnership(address newOwner) public virtual onlyOwner {
require(newOwner != address(0), "Ownable: new owner is the zero address");
_setOwner(newOwner);
}
function _setOwner(address newOwner) private {
address oldOwner = _owner;
_owner = newOwner;
emit OwnershipTransferred(oldOwner, newOwner);
}
}
File 3 of 4: Conduit
// SPDX-License-Identifier: MIT
pragma solidity >=0.8.7;
import { ConduitInterface } from "../interfaces/ConduitInterface.sol";
import { ConduitItemType } from "./lib/ConduitEnums.sol";
import { TokenTransferrer } from "../lib/TokenTransferrer.sol";
// prettier-ignore
import {
ConduitTransfer,
ConduitBatch1155Transfer
} from "./lib/ConduitStructs.sol";
import "./lib/ConduitConstants.sol";
/**
* @title Conduit
* @author 0age
* @notice This contract serves as an originator for "proxied" transfers. Each
* conduit is deployed and controlled by a "conduit controller" that can
* add and remove "channels" or contracts that can instruct the conduit
* to transfer approved ERC20/721/1155 tokens. *IMPORTANT NOTE: each
* conduit has an owner that can arbitrarily add or remove channels, and
* a malicious or negligent owner can add a channel that allows for any
* approved ERC20/721/1155 tokens to be taken immediately — be extremely
* cautious with what conduits you give token approvals to!*
*/
contract Conduit is ConduitInterface, TokenTransferrer {
// Set deployer as an immutable controller that can update channel statuses.
address private immutable _controller;
// Track the status of each channel.
mapping(address => bool) private _channels;
/**
* @notice Ensure that the caller is currently registered as an open channel
* on the conduit.
*/
modifier onlyOpenChannel() {
// Utilize assembly to access channel storage mapping directly.
assembly {
// Write the caller to scratch space.
mstore(ChannelKey_channel_ptr, caller())
// Write the storage slot for _channels to scratch space.
mstore(ChannelKey_slot_ptr, _channels.slot)
// Derive the position in storage of _channels[msg.sender]
// and check if the stored value is zero.
if iszero(
sload(keccak256(ChannelKey_channel_ptr, ChannelKey_length))
) {
// The caller is not an open channel; revert with
// ChannelClosed(caller). First, set error signature in memory.
mstore(ChannelClosed_error_ptr, ChannelClosed_error_signature)
// Next, set the caller as the argument.
mstore(ChannelClosed_channel_ptr, caller())
// Finally, revert, returning full custom error with argument.
revert(ChannelClosed_error_ptr, ChannelClosed_error_length)
}
}
// Continue with function execution.
_;
}
/**
* @notice In the constructor, set the deployer as the controller.
*/
constructor() {
// Set the deployer as the controller.
_controller = msg.sender;
}
/**
* @notice Execute a sequence of ERC20/721/1155 transfers. Only a caller
* with an open channel can call this function. Note that channels
* are expected to implement reentrancy protection if desired, and
* that cross-channel reentrancy may be possible if the conduit has
* multiple open channels at once. Also note that channels are
* expected to implement checks against transferring any zero-amount
* items if that constraint is desired.
*
* @param transfers The ERC20/721/1155 transfers to perform.
*
* @return magicValue A magic value indicating that the transfers were
* performed successfully.
*/
function execute(ConduitTransfer[] calldata transfers)
external
override
onlyOpenChannel
returns (bytes4 magicValue)
{
// Retrieve the total number of transfers and place on the stack.
uint256 totalStandardTransfers = transfers.length;
// Iterate over each transfer.
for (uint256 i = 0; i < totalStandardTransfers; ) {
// Retrieve the transfer in question and perform the transfer.
_transfer(transfers[i]);
// Skip overflow check as for loop is indexed starting at zero.
unchecked {
++i;
}
}
// Return a magic value indicating that the transfers were performed.
magicValue = this.execute.selector;
}
/**
* @notice Execute a sequence of batch 1155 item transfers. Only a caller
* with an open channel can call this function. Note that channels
* are expected to implement reentrancy protection if desired, and
* that cross-channel reentrancy may be possible if the conduit has
* multiple open channels at once. Also note that channels are
* expected to implement checks against transferring any zero-amount
* items if that constraint is desired.
*
* @param batchTransfers The 1155 batch item transfers to perform.
*
* @return magicValue A magic value indicating that the item transfers were
* performed successfully.
*/
function executeBatch1155(
ConduitBatch1155Transfer[] calldata batchTransfers
) external override onlyOpenChannel returns (bytes4 magicValue) {
// Perform 1155 batch transfers. Note that memory should be considered
// entirely corrupted from this point forward.
_performERC1155BatchTransfers(batchTransfers);
// Return a magic value indicating that the transfers were performed.
magicValue = this.executeBatch1155.selector;
}
/**
* @notice Execute a sequence of transfers, both single ERC20/721/1155 item
* transfers as well as batch 1155 item transfers. Only a caller
* with an open channel can call this function. Note that channels
* are expected to implement reentrancy protection if desired, and
* that cross-channel reentrancy may be possible if the conduit has
* multiple open channels at once. Also note that channels are
* expected to implement checks against transferring any zero-amount
* items if that constraint is desired.
*
* @param standardTransfers The ERC20/721/1155 item transfers to perform.
* @param batchTransfers The 1155 batch item transfers to perform.
*
* @return magicValue A magic value indicating that the item transfers were
* performed successfully.
*/
function executeWithBatch1155(
ConduitTransfer[] calldata standardTransfers,
ConduitBatch1155Transfer[] calldata batchTransfers
) external override onlyOpenChannel returns (bytes4 magicValue) {
// Retrieve the total number of transfers and place on the stack.
uint256 totalStandardTransfers = standardTransfers.length;
// Iterate over each standard transfer.
for (uint256 i = 0; i < totalStandardTransfers; ) {
// Retrieve the transfer in question and perform the transfer.
_transfer(standardTransfers[i]);
// Skip overflow check as for loop is indexed starting at zero.
unchecked {
++i;
}
}
// Perform 1155 batch transfers. Note that memory should be considered
// entirely corrupted from this point forward aside from the free memory
// pointer having the default value.
_performERC1155BatchTransfers(batchTransfers);
// Return a magic value indicating that the transfers were performed.
magicValue = this.executeWithBatch1155.selector;
}
/**
* @notice Open or close a given channel. Only callable by the controller.
*
* @param channel The channel to open or close.
* @param isOpen The status of the channel (either open or closed).
*/
function updateChannel(address channel, bool isOpen) external override {
// Ensure that the caller is the controller of this contract.
if (msg.sender != _controller) {
revert InvalidController();
}
// Ensure that the channel does not already have the indicated status.
if (_channels[channel] == isOpen) {
revert ChannelStatusAlreadySet(channel, isOpen);
}
// Update the status of the channel.
_channels[channel] = isOpen;
// Emit a corresponding event.
emit ChannelUpdated(channel, isOpen);
}
/**
* @dev Internal function to transfer a given ERC20/721/1155 item. Note that
* channels are expected to implement checks against transferring any
* zero-amount items if that constraint is desired.
*
* @param item The ERC20/721/1155 item to transfer.
*/
function _transfer(ConduitTransfer calldata item) internal {
// Determine the transfer method based on the respective item type.
if (item.itemType == ConduitItemType.ERC20) {
// Transfer ERC20 token. Note that item.identifier is ignored and
// therefore ERC20 transfer items are potentially malleable — this
// check should be performed by the calling channel if a constraint
// on item malleability is desired.
_performERC20Transfer(item.token, item.from, item.to, item.amount);
} else if (item.itemType == ConduitItemType.ERC721) {
// Ensure that exactly one 721 item is being transferred.
if (item.amount != 1) {
revert InvalidERC721TransferAmount();
}
// Transfer ERC721 token.
_performERC721Transfer(
item.token,
item.from,
item.to,
item.identifier
);
} else if (item.itemType == ConduitItemType.ERC1155) {
// Transfer ERC1155 token.
_performERC1155Transfer(
item.token,
item.from,
item.to,
item.identifier,
item.amount
);
} else {
// Throw with an error.
revert InvalidItemType();
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity >=0.8.7;
// prettier-ignore
import {
ConduitTransfer,
ConduitBatch1155Transfer
} from "../conduit/lib/ConduitStructs.sol";
/**
* @title ConduitInterface
* @author 0age
* @notice ConduitInterface contains all external function interfaces, events,
* and errors for conduit contracts.
*/
interface ConduitInterface {
/**
* @dev Revert with an error when attempting to execute transfers using a
* caller that does not have an open channel.
*/
error ChannelClosed(address channel);
/**
* @dev Revert with an error when attempting to update a channel to the
* current status of that channel.
*/
error ChannelStatusAlreadySet(address channel, bool isOpen);
/**
* @dev Revert with an error when attempting to execute a transfer for an
* item that does not have an ERC20/721/1155 item type.
*/
error InvalidItemType();
/**
* @dev Revert with an error when attempting to update the status of a
* channel from a caller that is not the conduit controller.
*/
error InvalidController();
/**
* @dev Emit an event whenever a channel is opened or closed.
*
* @param channel The channel that has been updated.
* @param open A boolean indicating whether the conduit is open or not.
*/
event ChannelUpdated(address indexed channel, bool open);
/**
* @notice Execute a sequence of ERC20/721/1155 transfers. Only a caller
* with an open channel can call this function.
*
* @param transfers The ERC20/721/1155 transfers to perform.
*
* @return magicValue A magic value indicating that the transfers were
* performed successfully.
*/
function execute(ConduitTransfer[] calldata transfers)
external
returns (bytes4 magicValue);
/**
* @notice Execute a sequence of batch 1155 transfers. Only a caller with an
* open channel can call this function.
*
* @param batch1155Transfers The 1155 batch transfers to perform.
*
* @return magicValue A magic value indicating that the transfers were
* performed successfully.
*/
function executeBatch1155(
ConduitBatch1155Transfer[] calldata batch1155Transfers
) external returns (bytes4 magicValue);
/**
* @notice Execute a sequence of transfers, both single and batch 1155. Only
* a caller with an open channel can call this function.
*
* @param standardTransfers The ERC20/721/1155 transfers to perform.
* @param batch1155Transfers The 1155 batch transfers to perform.
*
* @return magicValue A magic value indicating that the transfers were
* performed successfully.
*/
function executeWithBatch1155(
ConduitTransfer[] calldata standardTransfers,
ConduitBatch1155Transfer[] calldata batch1155Transfers
) external returns (bytes4 magicValue);
/**
* @notice Open or close a given channel. Only callable by the controller.
*
* @param channel The channel to open or close.
* @param isOpen The status of the channel (either open or closed).
*/
function updateChannel(address channel, bool isOpen) external;
}
// SPDX-License-Identifier: MIT
pragma solidity >=0.8.7;
enum ConduitItemType {
NATIVE, // unused
ERC20,
ERC721,
ERC1155
}
// SPDX-License-Identifier: MIT
pragma solidity >=0.8.7;
import "./TokenTransferrerConstants.sol";
// prettier-ignore
import {
TokenTransferrerErrors
} from "../interfaces/TokenTransferrerErrors.sol";
import { ConduitBatch1155Transfer } from "../conduit/lib/ConduitStructs.sol";
/**
* @title TokenTransferrer
* @author 0age
* @custom:coauthor d1ll0n
* @custom:coauthor transmissions11
* @notice TokenTransferrer is a library for performing optimized ERC20, ERC721,
* ERC1155, and batch ERC1155 transfers, used by both Seaport as well as
* by conduits deployed by the ConduitController. Use great caution when
* considering these functions for use in other codebases, as there are
* significant side effects and edge cases that need to be thoroughly
* understood and carefully addressed.
*/
contract TokenTransferrer is TokenTransferrerErrors {
/**
* @dev Internal function to transfer ERC20 tokens from a given originator
* to a given recipient. Sufficient approvals must be set on the
* contract performing the transfer.
*
* @param token The ERC20 token to transfer.
* @param from The originator of the transfer.
* @param to The recipient of the transfer.
* @param amount The amount to transfer.
*/
function _performERC20Transfer(
address token,
address from,
address to,
uint256 amount
) internal {
// Utilize assembly to perform an optimized ERC20 token transfer.
assembly {
// The free memory pointer memory slot will be used when populating
// call data for the transfer; read the value and restore it later.
let memPointer := mload(FreeMemoryPointerSlot)
// Write call data into memory, starting with function selector.
mstore(ERC20_transferFrom_sig_ptr, ERC20_transferFrom_signature)
mstore(ERC20_transferFrom_from_ptr, from)
mstore(ERC20_transferFrom_to_ptr, to)
mstore(ERC20_transferFrom_amount_ptr, amount)
// Make call & copy up to 32 bytes of return data to scratch space.
// Scratch space does not need to be cleared ahead of time, as the
// subsequent check will ensure that either at least a full word of
// return data is received (in which case it will be overwritten) or
// that no data is received (in which case scratch space will be
// ignored) on a successful call to the given token.
let callStatus := call(
gas(),
token,
0,
ERC20_transferFrom_sig_ptr,
ERC20_transferFrom_length,
0,
OneWord
)
// Determine whether transfer was successful using status & result.
let success := and(
// Set success to whether the call reverted, if not check it
// either returned exactly 1 (can't just be non-zero data), or
// had no return data.
or(
and(eq(mload(0), 1), gt(returndatasize(), 31)),
iszero(returndatasize())
),
callStatus
)
// Handle cases where either the transfer failed or no data was
// returned. Group these, as most transfers will succeed with data.
// Equivalent to `or(iszero(success), iszero(returndatasize()))`
// but after it's inverted for JUMPI this expression is cheaper.
if iszero(and(success, iszero(iszero(returndatasize())))) {
// If the token has no code or the transfer failed: Equivalent
// to `or(iszero(success), iszero(extcodesize(token)))` but
// after it's inverted for JUMPI this expression is cheaper.
if iszero(and(iszero(iszero(extcodesize(token))), success)) {
// If the transfer failed:
if iszero(success) {
// If it was due to a revert:
if iszero(callStatus) {
// If it returned a message, bubble it up as long as
// sufficient gas remains to do so:
if returndatasize() {
// Ensure that sufficient gas is available to
// copy returndata while expanding memory where
// necessary. Start by computing the word size
// of returndata and allocated memory. Round up
// to the nearest full word.
let returnDataWords := div(
add(returndatasize(), AlmostOneWord),
OneWord
)
// Note: use the free memory pointer in place of
// msize() to work around a Yul warning that
// prevents accessing msize directly when the IR
// pipeline is activated.
let msizeWords := div(memPointer, OneWord)
// Next, compute the cost of the returndatacopy.
let cost := mul(CostPerWord, returnDataWords)
// Then, compute cost of new memory allocation.
if gt(returnDataWords, msizeWords) {
cost := add(
cost,
add(
mul(
sub(
returnDataWords,
msizeWords
),
CostPerWord
),
div(
sub(
mul(
returnDataWords,
returnDataWords
),
mul(msizeWords, msizeWords)
),
MemoryExpansionCoefficient
)
)
)
}
// Finally, add a small constant and compare to
// gas remaining; bubble up the revert data if
// enough gas is still available.
if lt(add(cost, ExtraGasBuffer), gas()) {
// Copy returndata to memory; overwrite
// existing memory.
returndatacopy(0, 0, returndatasize())
// Revert, specifying memory region with
// copied returndata.
revert(0, returndatasize())
}
}
// Otherwise revert with a generic error message.
mstore(
TokenTransferGenericFailure_error_sig_ptr,
TokenTransferGenericFailure_error_signature
)
mstore(
TokenTransferGenericFailure_error_token_ptr,
token
)
mstore(
TokenTransferGenericFailure_error_from_ptr,
from
)
mstore(TokenTransferGenericFailure_error_to_ptr, to)
mstore(TokenTransferGenericFailure_error_id_ptr, 0)
mstore(
TokenTransferGenericFailure_error_amount_ptr,
amount
)
revert(
TokenTransferGenericFailure_error_sig_ptr,
TokenTransferGenericFailure_error_length
)
}
// Otherwise revert with a message about the token
// returning false or non-compliant return values.
mstore(
BadReturnValueFromERC20OnTransfer_error_sig_ptr,
BadReturnValueFromERC20OnTransfer_error_signature
)
mstore(
BadReturnValueFromERC20OnTransfer_error_token_ptr,
token
)
mstore(
BadReturnValueFromERC20OnTransfer_error_from_ptr,
from
)
mstore(
BadReturnValueFromERC20OnTransfer_error_to_ptr,
to
)
mstore(
BadReturnValueFromERC20OnTransfer_error_amount_ptr,
amount
)
revert(
BadReturnValueFromERC20OnTransfer_error_sig_ptr,
BadReturnValueFromERC20OnTransfer_error_length
)
}
// Otherwise, revert with error about token not having code:
mstore(NoContract_error_sig_ptr, NoContract_error_signature)
mstore(NoContract_error_token_ptr, token)
revert(NoContract_error_sig_ptr, NoContract_error_length)
}
// Otherwise, the token just returned no data despite the call
// having succeeded; no need to optimize for this as it's not
// technically ERC20 compliant.
}
// Restore the original free memory pointer.
mstore(FreeMemoryPointerSlot, memPointer)
// Restore the zero slot to zero.
mstore(ZeroSlot, 0)
}
}
/**
* @dev Internal function to transfer an ERC721 token from a given
* originator to a given recipient. Sufficient approvals must be set on
* the contract performing the transfer. Note that this function does
* not check whether the receiver can accept the ERC721 token (i.e. it
* does not use `safeTransferFrom`).
*
* @param token The ERC721 token to transfer.
* @param from The originator of the transfer.
* @param to The recipient of the transfer.
* @param identifier The tokenId to transfer.
*/
function _performERC721Transfer(
address token,
address from,
address to,
uint256 identifier
) internal {
// Utilize assembly to perform an optimized ERC721 token transfer.
assembly {
// If the token has no code, revert.
if iszero(extcodesize(token)) {
mstore(NoContract_error_sig_ptr, NoContract_error_signature)
mstore(NoContract_error_token_ptr, token)
revert(NoContract_error_sig_ptr, NoContract_error_length)
}
// The free memory pointer memory slot will be used when populating
// call data for the transfer; read the value and restore it later.
let memPointer := mload(FreeMemoryPointerSlot)
// Write call data to memory starting with function selector.
mstore(ERC721_transferFrom_sig_ptr, ERC721_transferFrom_signature)
mstore(ERC721_transferFrom_from_ptr, from)
mstore(ERC721_transferFrom_to_ptr, to)
mstore(ERC721_transferFrom_id_ptr, identifier)
// Perform the call, ignoring return data.
let success := call(
gas(),
token,
0,
ERC721_transferFrom_sig_ptr,
ERC721_transferFrom_length,
0,
0
)
// If the transfer reverted:
if iszero(success) {
// If it returned a message, bubble it up as long as sufficient
// gas remains to do so:
if returndatasize() {
// Ensure that sufficient gas is available to copy
// returndata while expanding memory where necessary. Start
// by computing word size of returndata & allocated memory.
// Round up to the nearest full word.
let returnDataWords := div(
add(returndatasize(), AlmostOneWord),
OneWord
)
// Note: use the free memory pointer in place of msize() to
// work around a Yul warning that prevents accessing msize
// directly when the IR pipeline is activated.
let msizeWords := div(memPointer, OneWord)
// Next, compute the cost of the returndatacopy.
let cost := mul(CostPerWord, returnDataWords)
// Then, compute cost of new memory allocation.
if gt(returnDataWords, msizeWords) {
cost := add(
cost,
add(
mul(
sub(returnDataWords, msizeWords),
CostPerWord
),
div(
sub(
mul(returnDataWords, returnDataWords),
mul(msizeWords, msizeWords)
),
MemoryExpansionCoefficient
)
)
)
}
// Finally, add a small constant and compare to gas
// remaining; bubble up the revert data if enough gas is
// still available.
if lt(add(cost, ExtraGasBuffer), gas()) {
// Copy returndata to memory; overwrite existing memory.
returndatacopy(0, 0, returndatasize())
// Revert, giving memory region with copied returndata.
revert(0, returndatasize())
}
}
// Otherwise revert with a generic error message.
mstore(
TokenTransferGenericFailure_error_sig_ptr,
TokenTransferGenericFailure_error_signature
)
mstore(TokenTransferGenericFailure_error_token_ptr, token)
mstore(TokenTransferGenericFailure_error_from_ptr, from)
mstore(TokenTransferGenericFailure_error_to_ptr, to)
mstore(TokenTransferGenericFailure_error_id_ptr, identifier)
mstore(TokenTransferGenericFailure_error_amount_ptr, 1)
revert(
TokenTransferGenericFailure_error_sig_ptr,
TokenTransferGenericFailure_error_length
)
}
// Restore the original free memory pointer.
mstore(FreeMemoryPointerSlot, memPointer)
// Restore the zero slot to zero.
mstore(ZeroSlot, 0)
}
}
/**
* @dev Internal function to transfer ERC1155 tokens from a given
* originator to a given recipient. Sufficient approvals must be set on
* the contract performing the transfer and contract recipients must
* implement the ERC1155TokenReceiver interface to indicate that they
* are willing to accept the transfer.
*
* @param token The ERC1155 token to transfer.
* @param from The originator of the transfer.
* @param to The recipient of the transfer.
* @param identifier The id to transfer.
* @param amount The amount to transfer.
*/
function _performERC1155Transfer(
address token,
address from,
address to,
uint256 identifier,
uint256 amount
) internal {
// Utilize assembly to perform an optimized ERC1155 token transfer.
assembly {
// If the token has no code, revert.
if iszero(extcodesize(token)) {
mstore(NoContract_error_sig_ptr, NoContract_error_signature)
mstore(NoContract_error_token_ptr, token)
revert(NoContract_error_sig_ptr, NoContract_error_length)
}
// The following memory slots will be used when populating call data
// for the transfer; read the values and restore them later.
let memPointer := mload(FreeMemoryPointerSlot)
let slot0x80 := mload(Slot0x80)
let slot0xA0 := mload(Slot0xA0)
let slot0xC0 := mload(Slot0xC0)
// Write call data into memory, beginning with function selector.
mstore(
ERC1155_safeTransferFrom_sig_ptr,
ERC1155_safeTransferFrom_signature
)
mstore(ERC1155_safeTransferFrom_from_ptr, from)
mstore(ERC1155_safeTransferFrom_to_ptr, to)
mstore(ERC1155_safeTransferFrom_id_ptr, identifier)
mstore(ERC1155_safeTransferFrom_amount_ptr, amount)
mstore(
ERC1155_safeTransferFrom_data_offset_ptr,
ERC1155_safeTransferFrom_data_length_offset
)
mstore(ERC1155_safeTransferFrom_data_length_ptr, 0)
// Perform the call, ignoring return data.
let success := call(
gas(),
token,
0,
ERC1155_safeTransferFrom_sig_ptr,
ERC1155_safeTransferFrom_length,
0,
0
)
// If the transfer reverted:
if iszero(success) {
// If it returned a message, bubble it up as long as sufficient
// gas remains to do so:
if returndatasize() {
// Ensure that sufficient gas is available to copy
// returndata while expanding memory where necessary. Start
// by computing word size of returndata & allocated memory.
// Round up to the nearest full word.
let returnDataWords := div(
add(returndatasize(), AlmostOneWord),
OneWord
)
// Note: use the free memory pointer in place of msize() to
// work around a Yul warning that prevents accessing msize
// directly when the IR pipeline is activated.
let msizeWords := div(memPointer, OneWord)
// Next, compute the cost of the returndatacopy.
let cost := mul(CostPerWord, returnDataWords)
// Then, compute cost of new memory allocation.
if gt(returnDataWords, msizeWords) {
cost := add(
cost,
add(
mul(
sub(returnDataWords, msizeWords),
CostPerWord
),
div(
sub(
mul(returnDataWords, returnDataWords),
mul(msizeWords, msizeWords)
),
MemoryExpansionCoefficient
)
)
)
}
// Finally, add a small constant and compare to gas
// remaining; bubble up the revert data if enough gas is
// still available.
if lt(add(cost, ExtraGasBuffer), gas()) {
// Copy returndata to memory; overwrite existing memory.
returndatacopy(0, 0, returndatasize())
// Revert, giving memory region with copied returndata.
revert(0, returndatasize())
}
}
// Otherwise revert with a generic error message.
mstore(
TokenTransferGenericFailure_error_sig_ptr,
TokenTransferGenericFailure_error_signature
)
mstore(TokenTransferGenericFailure_error_token_ptr, token)
mstore(TokenTransferGenericFailure_error_from_ptr, from)
mstore(TokenTransferGenericFailure_error_to_ptr, to)
mstore(TokenTransferGenericFailure_error_id_ptr, identifier)
mstore(TokenTransferGenericFailure_error_amount_ptr, amount)
revert(
TokenTransferGenericFailure_error_sig_ptr,
TokenTransferGenericFailure_error_length
)
}
mstore(Slot0x80, slot0x80) // Restore slot 0x80.
mstore(Slot0xA0, slot0xA0) // Restore slot 0xA0.
mstore(Slot0xC0, slot0xC0) // Restore slot 0xC0.
// Restore the original free memory pointer.
mstore(FreeMemoryPointerSlot, memPointer)
// Restore the zero slot to zero.
mstore(ZeroSlot, 0)
}
}
/**
* @dev Internal function to transfer ERC1155 tokens from a given
* originator to a given recipient. Sufficient approvals must be set on
* the contract performing the transfer and contract recipients must
* implement the ERC1155TokenReceiver interface to indicate that they
* are willing to accept the transfer. NOTE: this function is not
* memory-safe; it will overwrite existing memory, restore the free
* memory pointer to the default value, and overwrite the zero slot.
* This function should only be called once memory is no longer
* required and when uninitialized arrays are not utilized, and memory
* should be considered fully corrupted (aside from the existence of a
* default-value free memory pointer) after calling this function.
*
* @param batchTransfers The group of 1155 batch transfers to perform.
*/
function _performERC1155BatchTransfers(
ConduitBatch1155Transfer[] calldata batchTransfers
) internal {
// Utilize assembly to perform optimized batch 1155 transfers.
assembly {
let len := batchTransfers.length
// Pointer to first head in the array, which is offset to the struct
// at each index. This gets incremented after each loop to avoid
// multiplying by 32 to get the offset for each element.
let nextElementHeadPtr := batchTransfers.offset
// Pointer to beginning of the head of the array. This is the
// reference position each offset references. It's held static to
// let each loop calculate the data position for an element.
let arrayHeadPtr := nextElementHeadPtr
// Write the function selector, which will be reused for each call:
// safeBatchTransferFrom(address,address,uint256[],uint256[],bytes)
mstore(
ConduitBatch1155Transfer_from_offset,
ERC1155_safeBatchTransferFrom_signature
)
// Iterate over each batch transfer.
for {
let i := 0
} lt(i, len) {
i := add(i, 1)
} {
// Read the offset to the beginning of the element and add
// it to pointer to the beginning of the array head to get
// the absolute position of the element in calldata.
let elementPtr := add(
arrayHeadPtr,
calldataload(nextElementHeadPtr)
)
// Retrieve the token from calldata.
let token := calldataload(elementPtr)
// If the token has no code, revert.
if iszero(extcodesize(token)) {
mstore(NoContract_error_sig_ptr, NoContract_error_signature)
mstore(NoContract_error_token_ptr, token)
revert(NoContract_error_sig_ptr, NoContract_error_length)
}
// Get the total number of supplied ids.
let idsLength := calldataload(
add(elementPtr, ConduitBatch1155Transfer_ids_length_offset)
)
// Determine the expected offset for the amounts array.
let expectedAmountsOffset := add(
ConduitBatch1155Transfer_amounts_length_baseOffset,
mul(idsLength, OneWord)
)
// Validate struct encoding.
let invalidEncoding := iszero(
and(
// ids.length == amounts.length
eq(
idsLength,
calldataload(add(elementPtr, expectedAmountsOffset))
),
and(
// ids_offset == 0xa0
eq(
calldataload(
add(
elementPtr,
ConduitBatch1155Transfer_ids_head_offset
)
),
ConduitBatch1155Transfer_ids_length_offset
),
// amounts_offset == 0xc0 + ids.length*32
eq(
calldataload(
add(
elementPtr,
ConduitBatchTransfer_amounts_head_offset
)
),
expectedAmountsOffset
)
)
)
)
// Revert with an error if the encoding is not valid.
if invalidEncoding {
mstore(
Invalid1155BatchTransferEncoding_ptr,
Invalid1155BatchTransferEncoding_selector
)
revert(
Invalid1155BatchTransferEncoding_ptr,
Invalid1155BatchTransferEncoding_length
)
}
// Update the offset position for the next loop
nextElementHeadPtr := add(nextElementHeadPtr, OneWord)
// Copy the first section of calldata (before dynamic values).
calldatacopy(
BatchTransfer1155Params_ptr,
add(elementPtr, ConduitBatch1155Transfer_from_offset),
ConduitBatch1155Transfer_usable_head_size
)
// Determine size of calldata required for ids and amounts. Note
// that the size includes both lengths as well as the data.
let idsAndAmountsSize := add(TwoWords, mul(idsLength, TwoWords))
// Update the offset for the data array in memory.
mstore(
BatchTransfer1155Params_data_head_ptr,
add(
BatchTransfer1155Params_ids_length_offset,
idsAndAmountsSize
)
)
// Set the length of the data array in memory to zero.
mstore(
add(
BatchTransfer1155Params_data_length_basePtr,
idsAndAmountsSize
),
0
)
// Determine the total calldata size for the call to transfer.
let transferDataSize := add(
BatchTransfer1155Params_calldata_baseSize,
idsAndAmountsSize
)
// Copy second section of calldata (including dynamic values).
calldatacopy(
BatchTransfer1155Params_ids_length_ptr,
add(elementPtr, ConduitBatch1155Transfer_ids_length_offset),
idsAndAmountsSize
)
// Perform the call to transfer 1155 tokens.
let success := call(
gas(),
token,
0,
ConduitBatch1155Transfer_from_offset, // Data portion start.
transferDataSize, // Location of the length of callData.
0,
0
)
// If the transfer reverted:
if iszero(success) {
// If it returned a message, bubble it up as long as
// sufficient gas remains to do so:
if returndatasize() {
// Ensure that sufficient gas is available to copy
// returndata while expanding memory where necessary.
// Start by computing word size of returndata and
// allocated memory. Round up to the nearest full word.
let returnDataWords := div(
add(returndatasize(), AlmostOneWord),
OneWord
)
// Note: use transferDataSize in place of msize() to
// work around a Yul warning that prevents accessing
// msize directly when the IR pipeline is activated.
// The free memory pointer is not used here because
// this function does almost all memory management
// manually and does not update it, and transferDataSize
// should be the largest memory value used (unless a
// previous batch was larger).
let msizeWords := div(transferDataSize, OneWord)
// Next, compute the cost of the returndatacopy.
let cost := mul(CostPerWord, returnDataWords)
// Then, compute cost of new memory allocation.
if gt(returnDataWords, msizeWords) {
cost := add(
cost,
add(
mul(
sub(returnDataWords, msizeWords),
CostPerWord
),
div(
sub(
mul(
returnDataWords,
returnDataWords
),
mul(msizeWords, msizeWords)
),
MemoryExpansionCoefficient
)
)
)
}
// Finally, add a small constant and compare to gas
// remaining; bubble up the revert data if enough gas is
// still available.
if lt(add(cost, ExtraGasBuffer), gas()) {
// Copy returndata to memory; overwrite existing.
returndatacopy(0, 0, returndatasize())
// Revert with memory region containing returndata.
revert(0, returndatasize())
}
}
// Set the error signature.
mstore(
0,
ERC1155BatchTransferGenericFailure_error_signature
)
// Write the token.
mstore(ERC1155BatchTransferGenericFailure_token_ptr, token)
// Increase the offset to ids by 32.
mstore(
BatchTransfer1155Params_ids_head_ptr,
ERC1155BatchTransferGenericFailure_ids_offset
)
// Increase the offset to amounts by 32.
mstore(
BatchTransfer1155Params_amounts_head_ptr,
add(
OneWord,
mload(BatchTransfer1155Params_amounts_head_ptr)
)
)
// Return modified region. The total size stays the same as
// `token` uses the same number of bytes as `data.length`.
revert(0, transferDataSize)
}
}
// Reset the free memory pointer to the default value; memory must
// be assumed to be dirtied and not reused from this point forward.
// Also note that the zero slot is not reset to zero, meaning empty
// arrays cannot be safely created or utilized until it is restored.
mstore(FreeMemoryPointerSlot, DefaultFreeMemoryPointer)
}
}
}
// SPDX-License-Identifier: MIT
pragma solidity >=0.8.7;
import { ConduitItemType } from "./ConduitEnums.sol";
struct ConduitTransfer {
ConduitItemType itemType;
address token;
address from;
address to;
uint256 identifier;
uint256 amount;
}
struct ConduitBatch1155Transfer {
address token;
address from;
address to;
uint256[] ids;
uint256[] amounts;
}
// SPDX-License-Identifier: MIT
pragma solidity >=0.8.7;
// error ChannelClosed(address channel)
uint256 constant ChannelClosed_error_signature = (
0x93daadf200000000000000000000000000000000000000000000000000000000
);
uint256 constant ChannelClosed_error_ptr = 0x00;
uint256 constant ChannelClosed_channel_ptr = 0x4;
uint256 constant ChannelClosed_error_length = 0x24;
// For the mapping:
// mapping(address => bool) channels
// The position in storage for a particular account is:
// keccak256(abi.encode(account, channels.slot))
uint256 constant ChannelKey_channel_ptr = 0x00;
uint256 constant ChannelKey_slot_ptr = 0x20;
uint256 constant ChannelKey_length = 0x40;
// SPDX-License-Identifier: MIT
pragma solidity >=0.8.7;
/*
* -------------------------- Disambiguation & Other Notes ---------------------
* - The term "head" is used as it is in the documentation for ABI encoding,
* but only in reference to dynamic types, i.e. it always refers to the
* offset or pointer to the body of a dynamic type. In calldata, the head
* is always an offset (relative to the parent object), while in memory,
* the head is always the pointer to the body. More information found here:
* https://docs.soliditylang.org/en/v0.8.14/abi-spec.html#argument-encoding
* - Note that the length of an array is separate from and precedes the
* head of the array.
*
* - The term "body" is used in place of the term "head" used in the ABI
* documentation. It refers to the start of the data for a dynamic type,
* e.g. the first word of a struct or the first word of the first element
* in an array.
*
* - The term "pointer" is used to describe the absolute position of a value
* and never an offset relative to another value.
* - The suffix "_ptr" refers to a memory pointer.
* - The suffix "_cdPtr" refers to a calldata pointer.
*
* - The term "offset" is used to describe the position of a value relative
* to some parent value. For example, OrderParameters_conduit_offset is the
* offset to the "conduit" value in the OrderParameters struct relative to
* the start of the body.
* - Note: Offsets are used to derive pointers.
*
* - Some structs have pointers defined for all of their fields in this file.
* Lines which are commented out are fields that are not used in the
* codebase but have been left in for readability.
*/
uint256 constant AlmostOneWord = 0x1f;
uint256 constant OneWord = 0x20;
uint256 constant TwoWords = 0x40;
uint256 constant ThreeWords = 0x60;
uint256 constant FreeMemoryPointerSlot = 0x40;
uint256 constant ZeroSlot = 0x60;
uint256 constant DefaultFreeMemoryPointer = 0x80;
uint256 constant Slot0x80 = 0x80;
uint256 constant Slot0xA0 = 0xa0;
uint256 constant Slot0xC0 = 0xc0;
// abi.encodeWithSignature("transferFrom(address,address,uint256)")
uint256 constant ERC20_transferFrom_signature = (
0x23b872dd00000000000000000000000000000000000000000000000000000000
);
uint256 constant ERC20_transferFrom_sig_ptr = 0x0;
uint256 constant ERC20_transferFrom_from_ptr = 0x04;
uint256 constant ERC20_transferFrom_to_ptr = 0x24;
uint256 constant ERC20_transferFrom_amount_ptr = 0x44;
uint256 constant ERC20_transferFrom_length = 0x64; // 4 + 32 * 3 == 100
// abi.encodeWithSignature(
// "safeTransferFrom(address,address,uint256,uint256,bytes)"
// )
uint256 constant ERC1155_safeTransferFrom_signature = (
0xf242432a00000000000000000000000000000000000000000000000000000000
);
uint256 constant ERC1155_safeTransferFrom_sig_ptr = 0x0;
uint256 constant ERC1155_safeTransferFrom_from_ptr = 0x04;
uint256 constant ERC1155_safeTransferFrom_to_ptr = 0x24;
uint256 constant ERC1155_safeTransferFrom_id_ptr = 0x44;
uint256 constant ERC1155_safeTransferFrom_amount_ptr = 0x64;
uint256 constant ERC1155_safeTransferFrom_data_offset_ptr = 0x84;
uint256 constant ERC1155_safeTransferFrom_data_length_ptr = 0xa4;
uint256 constant ERC1155_safeTransferFrom_length = 0xc4; // 4 + 32 * 6 == 196
uint256 constant ERC1155_safeTransferFrom_data_length_offset = 0xa0;
// abi.encodeWithSignature(
// "safeBatchTransferFrom(address,address,uint256[],uint256[],bytes)"
// )
uint256 constant ERC1155_safeBatchTransferFrom_signature = (
0x2eb2c2d600000000000000000000000000000000000000000000000000000000
);
bytes4 constant ERC1155_safeBatchTransferFrom_selector = bytes4(
bytes32(ERC1155_safeBatchTransferFrom_signature)
);
uint256 constant ERC721_transferFrom_signature = ERC20_transferFrom_signature;
uint256 constant ERC721_transferFrom_sig_ptr = 0x0;
uint256 constant ERC721_transferFrom_from_ptr = 0x04;
uint256 constant ERC721_transferFrom_to_ptr = 0x24;
uint256 constant ERC721_transferFrom_id_ptr = 0x44;
uint256 constant ERC721_transferFrom_length = 0x64; // 4 + 32 * 3 == 100
// abi.encodeWithSignature("NoContract(address)")
uint256 constant NoContract_error_signature = (
0x5f15d67200000000000000000000000000000000000000000000000000000000
);
uint256 constant NoContract_error_sig_ptr = 0x0;
uint256 constant NoContract_error_token_ptr = 0x4;
uint256 constant NoContract_error_length = 0x24; // 4 + 32 == 36
// abi.encodeWithSignature(
// "TokenTransferGenericFailure(address,address,address,uint256,uint256)"
// )
uint256 constant TokenTransferGenericFailure_error_signature = (
0xf486bc8700000000000000000000000000000000000000000000000000000000
);
uint256 constant TokenTransferGenericFailure_error_sig_ptr = 0x0;
uint256 constant TokenTransferGenericFailure_error_token_ptr = 0x4;
uint256 constant TokenTransferGenericFailure_error_from_ptr = 0x24;
uint256 constant TokenTransferGenericFailure_error_to_ptr = 0x44;
uint256 constant TokenTransferGenericFailure_error_id_ptr = 0x64;
uint256 constant TokenTransferGenericFailure_error_amount_ptr = 0x84;
// 4 + 32 * 5 == 164
uint256 constant TokenTransferGenericFailure_error_length = 0xa4;
// abi.encodeWithSignature(
// "BadReturnValueFromERC20OnTransfer(address,address,address,uint256)"
// )
uint256 constant BadReturnValueFromERC20OnTransfer_error_signature = (
0x9889192300000000000000000000000000000000000000000000000000000000
);
uint256 constant BadReturnValueFromERC20OnTransfer_error_sig_ptr = 0x0;
uint256 constant BadReturnValueFromERC20OnTransfer_error_token_ptr = 0x4;
uint256 constant BadReturnValueFromERC20OnTransfer_error_from_ptr = 0x24;
uint256 constant BadReturnValueFromERC20OnTransfer_error_to_ptr = 0x44;
uint256 constant BadReturnValueFromERC20OnTransfer_error_amount_ptr = 0x64;
// 4 + 32 * 4 == 132
uint256 constant BadReturnValueFromERC20OnTransfer_error_length = 0x84;
uint256 constant ExtraGasBuffer = 0x20;
uint256 constant CostPerWord = 3;
uint256 constant MemoryExpansionCoefficient = 0x200;
// Values are offset by 32 bytes in order to write the token to the beginning
// in the event of a revert
uint256 constant BatchTransfer1155Params_ptr = 0x24;
uint256 constant BatchTransfer1155Params_ids_head_ptr = 0x64;
uint256 constant BatchTransfer1155Params_amounts_head_ptr = 0x84;
uint256 constant BatchTransfer1155Params_data_head_ptr = 0xa4;
uint256 constant BatchTransfer1155Params_data_length_basePtr = 0xc4;
uint256 constant BatchTransfer1155Params_calldata_baseSize = 0xc4;
uint256 constant BatchTransfer1155Params_ids_length_ptr = 0xc4;
uint256 constant BatchTransfer1155Params_ids_length_offset = 0xa0;
uint256 constant BatchTransfer1155Params_amounts_length_baseOffset = 0xc0;
uint256 constant BatchTransfer1155Params_data_length_baseOffset = 0xe0;
uint256 constant ConduitBatch1155Transfer_usable_head_size = 0x80;
uint256 constant ConduitBatch1155Transfer_from_offset = 0x20;
uint256 constant ConduitBatch1155Transfer_ids_head_offset = 0x60;
uint256 constant ConduitBatch1155Transfer_amounts_head_offset = 0x80;
uint256 constant ConduitBatch1155Transfer_ids_length_offset = 0xa0;
uint256 constant ConduitBatch1155Transfer_amounts_length_baseOffset = 0xc0;
uint256 constant ConduitBatch1155Transfer_calldata_baseSize = 0xc0;
// Note: abbreviated version of above constant to adhere to line length limit.
uint256 constant ConduitBatchTransfer_amounts_head_offset = 0x80;
uint256 constant Invalid1155BatchTransferEncoding_ptr = 0x00;
uint256 constant Invalid1155BatchTransferEncoding_length = 0x04;
uint256 constant Invalid1155BatchTransferEncoding_selector = (
0xeba2084c00000000000000000000000000000000000000000000000000000000
);
uint256 constant ERC1155BatchTransferGenericFailure_error_signature = (
0xafc445e200000000000000000000000000000000000000000000000000000000
);
uint256 constant ERC1155BatchTransferGenericFailure_token_ptr = 0x04;
uint256 constant ERC1155BatchTransferGenericFailure_ids_offset = 0xc0;
// SPDX-License-Identifier: MIT
pragma solidity >=0.8.7;
/**
* @title TokenTransferrerErrors
*/
interface TokenTransferrerErrors {
/**
* @dev Revert with an error when an ERC721 transfer with amount other than
* one is attempted.
*/
error InvalidERC721TransferAmount();
/**
* @dev Revert with an error when attempting to fulfill an order where an
* item has an amount of zero.
*/
error MissingItemAmount();
/**
* @dev Revert with an error when attempting to fulfill an order where an
* item has unused parameters. This includes both the token and the
* identifier parameters for native transfers as well as the identifier
* parameter for ERC20 transfers. Note that the conduit does not
* perform this check, leaving it up to the calling channel to enforce
* when desired.
*/
error UnusedItemParameters();
/**
* @dev Revert with an error when an ERC20, ERC721, or ERC1155 token
* transfer reverts.
*
* @param token The token for which the transfer was attempted.
* @param from The source of the attempted transfer.
* @param to The recipient of the attempted transfer.
* @param identifier The identifier for the attempted transfer.
* @param amount The amount for the attempted transfer.
*/
error TokenTransferGenericFailure(
address token,
address from,
address to,
uint256 identifier,
uint256 amount
);
/**
* @dev Revert with an error when a batch ERC1155 token transfer reverts.
*
* @param token The token for which the transfer was attempted.
* @param from The source of the attempted transfer.
* @param to The recipient of the attempted transfer.
* @param identifiers The identifiers for the attempted transfer.
* @param amounts The amounts for the attempted transfer.
*/
error ERC1155BatchTransferGenericFailure(
address token,
address from,
address to,
uint256[] identifiers,
uint256[] amounts
);
/**
* @dev Revert with an error when an ERC20 token transfer returns a falsey
* value.
*
* @param token The token for which the ERC20 transfer was attempted.
* @param from The source of the attempted ERC20 transfer.
* @param to The recipient of the attempted ERC20 transfer.
* @param amount The amount for the attempted ERC20 transfer.
*/
error BadReturnValueFromERC20OnTransfer(
address token,
address from,
address to,
uint256 amount
);
/**
* @dev Revert with an error when an account being called as an assumed
* contract does not have code and returns no data.
*
* @param account The account that should contain code.
*/
error NoContract(address account);
/**
* @dev Revert with an error when attempting to execute an 1155 batch
* transfer using calldata not produced by default ABI encoding or with
* different lengths for ids and amounts arrays.
*/
error Invalid1155BatchTransferEncoding();
}
File 4 of 4: PayableProxy
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.7;
import { PayableProxyInterface } from "../interfaces/PayableProxyInterface.sol";
interface IUpgradeBeacon {
/**
* @notice An external view function that returns the implementation.
*
* @return The address of the implementation.
*/
function implementation() external view returns (address);
}
/**
* @title PayableProxy
* @author OpenSea Protocol Team
* @notice PayableProxy is a beacon proxy which will immediately return if
* called with callvalue. Otherwise, it will delegatecall the beacon
* implementation.
*/
contract PayableProxy is PayableProxyInterface {
// Address of the beacon.
address private immutable _beacon;
constructor(address beacon) payable {
// Ensure the origin is an approved deployer.
require(
(tx.origin == address(0x939C8d89EBC11fA45e576215E2353673AD0bA18A) ||
tx.origin ==
address(0xe80a65eB7a3018DedA407e621Ef5fb5B416678CA) ||
tx.origin ==
address(0x86D26897267711ea4b173C8C124a0A73612001da) ||
tx.origin ==
address(0x3B52ad533687Ce908bA0485ac177C5fb42972962)),
"Deployment must originate from an approved deployer."
);
// Set the initial beacon.
_beacon = beacon;
}
function initialize(address ownerToSet) external {
// Ensure the origin is an approved deployer.
require(
(tx.origin == address(0x939C8d89EBC11fA45e576215E2353673AD0bA18A) ||
tx.origin ==
address(0xe80a65eB7a3018DedA407e621Ef5fb5B416678CA) ||
tx.origin ==
address(0x86D26897267711ea4b173C8C124a0A73612001da) ||
tx.origin ==
address(0x3B52ad533687Ce908bA0485ac177C5fb42972962)),
"Initialize must originate from an approved deployer."
);
// Get the implementation address from the provided beacon.
address implementation = IUpgradeBeacon(_beacon).implementation();
// Create the initializationCalldata from the provided parameters.
bytes memory initializationCalldata = abi.encodeWithSignature(
"initialize(address)",
ownerToSet
);
// Delegatecall into the implementation, supplying initialization
// calldata.
(bool ok, ) = implementation.delegatecall(initializationCalldata);
// Revert and include revert data if delegatecall to implementation
// reverts.
if (!ok) {
assembly {
returndatacopy(0, 0, returndatasize())
revert(0, returndatasize())
}
}
}
/**
* @dev Fallback function that delegates calls to the address returned by
* `_implementation()`. Will run if no other function in the contract
* matches the call data.
*/
fallback() external payable override {
_fallback();
}
/**
* @dev Internal fallback function that delegates calls to the address
* returned by `_implementation()`. Will run if no other function
* in the contract matches the call data.
*/
function _fallback() internal {
// Delegate if call value is zero.
if (msg.value == 0) {
_delegate(_implementation());
}
}
/**
* @dev Delegates the current call to `implementation`.
*
* This function does not return to its internal call site, it will
* return directly to the external caller.
*/
function _delegate(address implementation) internal virtual {
assembly {
// Copy msg.data. We take full control of memory in this
// inline assembly block because it will not return to
// Solidity code. We overwrite the Solidity scratch pad
// at memory position 0.
calldatacopy(0, 0, calldatasize())
// Call the implementation.
// out and outsize are 0 because we don't know the size yet.
let result := delegatecall(
gas(),
implementation,
0,
calldatasize(),
0,
0
)
// Copy the returned data.
returndatacopy(0, 0, returndatasize())
switch result
// delegatecall returns 0 on error.
case 0 {
revert(0, returndatasize())
}
default {
return(0, returndatasize())
}
}
}
/**
* @dev This function returns the address to which the fallback function
* should delegate.
*/
function _implementation() internal view returns (address) {
return IUpgradeBeacon(_beacon).implementation();
}
}
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.7;
/**
* @title PayableProxyInterface
* @author OpenSea Protocol Team
* @notice PayableProxyInterface contains all external function interfaces
* for the payable proxy.
*/
interface PayableProxyInterface {
/**
* @dev Fallback function that delegates calls to the address returned by
* `_implementation()`. Will run if no other function in the contract
* matches the call data.
*/
fallback() external payable;
}