/* This file is part of solidity. solidity is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. solidity is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with solidity. If not, see . */ // SPDX-License-Identifier: GPL-3.0 /** * @author Christian * @date 2017 * Routines that generate Yul code related to ABI encoding, decoding and type conversions. */ #include #include #include #include #include #include using namespace std; using namespace solidity; using namespace solidity::util; using namespace solidity::frontend; string ABIFunctions::tupleEncoder( TypePointers const& _givenTypes, TypePointers const& _targetTypes, bool _encodeAsLibraryTypes, bool _reversed ) { solAssert(_givenTypes.size() == _targetTypes.size(), ""); EncodingOptions options; options.encodeAsLibraryTypes = _encodeAsLibraryTypes; options.encodeFunctionFromStack = true; options.padded = true; options.dynamicInplace = false; string functionName = string("abi_encode_tuple_"); for (auto const& t: _givenTypes) functionName += t->identifier() + "_"; functionName += "_to_"; for (auto const& t: _targetTypes) functionName += t->identifier() + "_"; functionName += options.toFunctionNameSuffix(); if (_reversed) functionName += "_reversed"; return createFunction(functionName, [&]() { // Note that the values are in reverse due to the difference in calling semantics. Whiskers templ(R"( function (headStart ) -> tail { tail := add(headStart, ) } )"); templ("functionName", functionName); size_t const headSize_ = headSize(_targetTypes); templ("headSize", to_string(headSize_)); string encodeElements; size_t headPos = 0; size_t stackPos = 0; for (size_t i = 0; i < _givenTypes.size(); ++i) { solAssert(_givenTypes[i], ""); solAssert(_targetTypes[i], ""); size_t sizeOnStack = _givenTypes[i]->sizeOnStack(); bool dynamic = _targetTypes[i]->isDynamicallyEncoded(); Whiskers elementTempl( dynamic ? string(R"( mstore(add(headStart, ), sub(tail, headStart)) tail := ( tail) )") : string(R"( ( add(headStart, )) )") ); string values = suffixedVariableNameList("value", stackPos, stackPos + sizeOnStack); elementTempl("values", values.empty() ? "" : values + ", "); elementTempl("pos", to_string(headPos)); elementTempl("abiEncode", abiEncodingFunction(*_givenTypes[i], *_targetTypes[i], options)); encodeElements += elementTempl.render(); headPos += _targetTypes[i]->calldataHeadSize(); stackPos += sizeOnStack; } solAssert(headPos == headSize_, ""); string valueParams = _reversed ? suffixedVariableNameList("value", stackPos, 0) : suffixedVariableNameList("value", 0, stackPos); templ("valueParams", valueParams.empty() ? "" : ", " + valueParams); templ("encodeElements", encodeElements); return templ.render(); }); } string ABIFunctions::tupleEncoderPacked( TypePointers const& _givenTypes, TypePointers const& _targetTypes, bool _reversed ) { EncodingOptions options; options.encodeAsLibraryTypes = false; options.encodeFunctionFromStack = true; options.padded = false; options.dynamicInplace = true; string functionName = string("abi_encode_tuple_packed_"); for (auto const& t: _givenTypes) functionName += t->identifier() + "_"; functionName += "_to_"; for (auto const& t: _targetTypes) functionName += t->identifier() + "_"; functionName += options.toFunctionNameSuffix(); if (_reversed) functionName += "_reversed"; return createFunction(functionName, [&]() { solAssert(!_givenTypes.empty(), ""); // Note that the values are in reverse due to the difference in calling semantics. Whiskers templ(R"( function (pos ) -> end { end := pos } )"); templ("functionName", functionName); string encodeElements; size_t stackPos = 0; for (size_t i = 0; i < _givenTypes.size(); ++i) { solAssert(_givenTypes[i], ""); solAssert(_targetTypes[i], ""); size_t sizeOnStack = _givenTypes[i]->sizeOnStack(); bool dynamic = _targetTypes[i]->isDynamicallyEncoded(); Whiskers elementTempl( dynamic ? string(R"( pos := ( pos) )") : string(R"( ( pos) pos := add(pos, ) )") ); string values = suffixedVariableNameList("value", stackPos, stackPos + sizeOnStack); elementTempl("values", values.empty() ? "" : values + ", "); if (!dynamic) elementTempl("calldataEncodedSize", to_string(_targetTypes[i]->calldataEncodedSize(false))); elementTempl("abiEncode", abiEncodingFunction(*_givenTypes[i], *_targetTypes[i], options)); encodeElements += elementTempl.render(); stackPos += sizeOnStack; } string valueParams = _reversed ? suffixedVariableNameList("value", stackPos, 0) : suffixedVariableNameList("value", 0, stackPos); templ("valueParams", valueParams.empty() ? "" : ", " + valueParams); templ("encodeElements", encodeElements); return templ.render(); }); } string ABIFunctions::tupleDecoder(TypePointers const& _types, bool _fromMemory) { string functionName = string("abi_decode_tuple_"); for (auto const& t: _types) functionName += t->identifier(); if (_fromMemory) functionName += "_fromMemory"; return createFunction(functionName, [&]() { TypePointers decodingTypes; for (auto const& t: _types) decodingTypes.emplace_back(t->decodingType()); Whiskers templ(R"( function (headStart, dataEnd) { if slt(sub(dataEnd, headStart), ) { } } )"); templ("functionName", functionName); templ("revertString", revertReasonIfDebug("ABI decoding: tuple data too short")); templ("minimumSize", to_string(headSize(decodingTypes))); string decodeElements; vector valueReturnParams; size_t headPos = 0; size_t stackPos = 0; for (size_t i = 0; i < _types.size(); ++i) { solAssert(_types[i], ""); solAssert(decodingTypes[i], ""); size_t sizeOnStack = _types[i]->sizeOnStack(); solAssert(sizeOnStack == decodingTypes[i]->sizeOnStack(), ""); solAssert(sizeOnStack > 0, ""); vector valueNamesLocal; for (size_t j = 0; j < sizeOnStack; j++) { valueNamesLocal.emplace_back("value" + to_string(stackPos)); valueReturnParams.emplace_back("value" + to_string(stackPos)); stackPos++; } Whiskers elementTempl(R"( { let offset := (add(headStart, )) if gt(offset, 0xffffffffffffffff) { } let offset := := (add(headStart, offset), dataEnd) } )"); elementTempl("dynamic", decodingTypes[i]->isDynamicallyEncoded()); // TODO add test elementTempl("revertString", revertReasonIfDebug("ABI decoding: invalid tuple offset")); elementTempl("load", _fromMemory ? "mload" : "calldataload"); elementTempl("values", boost::algorithm::join(valueNamesLocal, ", ")); elementTempl("pos", to_string(headPos)); elementTempl("abiDecode", abiDecodingFunction(*_types[i], _fromMemory, true)); decodeElements += elementTempl.render(); headPos += decodingTypes[i]->calldataHeadSize(); } templ("valueReturnParams", boost::algorithm::join(valueReturnParams, ", ")); templ("arrow", valueReturnParams.empty() ? "" : "->"); templ("decodeElements", decodeElements); return templ.render(); }); } string ABIFunctions::EncodingOptions::toFunctionNameSuffix() const { string suffix; if (!padded) suffix += "_nonPadded"; if (dynamicInplace) suffix += "_inplace"; if (encodeFunctionFromStack) suffix += "_fromStack"; if (encodeAsLibraryTypes) suffix += "_library"; return suffix; } string ABIFunctions::abiEncodingFunction( Type const& _from, Type const& _to, EncodingOptions const& _options ) { TypePointer toInterface = _to.fullEncodingType(_options.encodeAsLibraryTypes, true, false); solUnimplementedAssert(toInterface, "Encoding type \"" + _to.toString() + "\" not yet implemented."); Type const& to = *toInterface; if (_from.category() == Type::Category::StringLiteral) return abiEncodingFunctionStringLiteral(_from, to, _options); else if (auto toArray = dynamic_cast(&to)) { ArrayType const* fromArray = nullptr; switch (_from.category()) { case Type::Category::Array: fromArray = dynamic_cast(&_from); break; case Type::Category::ArraySlice: fromArray = &dynamic_cast(&_from)->arrayType(); solAssert( fromArray->dataStoredIn(DataLocation::CallData) && fromArray->isDynamicallySized() && !fromArray->baseType()->isDynamicallyEncoded(), "" ); break; default: solAssert(false, ""); break; } switch (fromArray->location()) { case DataLocation::CallData: if ( fromArray->isByteArray() || *fromArray->baseType() == *TypeProvider::uint256() || *fromArray->baseType() == FixedBytesType(32) ) return abiEncodingFunctionCalldataArrayWithoutCleanup(*fromArray, *toArray, _options); else return abiEncodingFunctionSimpleArray(*fromArray, *toArray, _options); case DataLocation::Memory: if (fromArray->isByteArray()) return abiEncodingFunctionMemoryByteArray(*fromArray, *toArray, _options); else return abiEncodingFunctionSimpleArray(*fromArray, *toArray, _options); case DataLocation::Storage: if (fromArray->baseType()->storageBytes() <= 16) return abiEncodingFunctionCompactStorageArray(*fromArray, *toArray, _options); else return abiEncodingFunctionSimpleArray(*fromArray, *toArray, _options); default: solAssert(false, ""); } } else if (auto const* toStruct = dynamic_cast(&to)) { StructType const* fromStruct = dynamic_cast(&_from); solAssert(fromStruct, ""); return abiEncodingFunctionStruct(*fromStruct, *toStruct, _options); } else if (_from.category() == Type::Category::Function) return abiEncodingFunctionFunctionType( dynamic_cast(_from), to, _options ); solAssert(_from.sizeOnStack() == 1, ""); solAssert(to.isValueType(), ""); solAssert(to.calldataEncodedSize() == 32, ""); string functionName = "abi_encode_" + _from.identifier() + "_to_" + to.identifier() + _options.toFunctionNameSuffix(); return createFunction(functionName, [&]() { solAssert(!to.isDynamicallyEncoded(), ""); Whiskers templ(R"( function (value, pos) { mstore(pos, ) } )"); templ("functionName", functionName); if (_from.dataStoredIn(DataLocation::Storage)) { // special case: convert storage reference type to value type - this is only // possible for library calls where we just forward the storage reference solAssert(_options.encodeAsLibraryTypes, ""); solAssert(_options.padded && !_options.dynamicInplace, "Non-padded / inplace encoding for library call requested."); solAssert(to == *TypeProvider::uint256(), ""); templ("cleanupConvert", "value"); } else { string cleanupConvert; if (_from == to) cleanupConvert = m_utils.cleanupFunction(_from) + "(value)"; else cleanupConvert = m_utils.conversionFunction(_from, to) + "(value)"; if (!_options.padded) cleanupConvert = m_utils.leftAlignFunction(to) + "(" + cleanupConvert + ")"; templ("cleanupConvert", cleanupConvert); } return templ.render(); }); } string ABIFunctions::abiEncodeAndReturnUpdatedPosFunction( Type const& _givenType, Type const& _targetType, ABIFunctions::EncodingOptions const& _options ) { string functionName = "abi_encodeUpdatedPos_" + _givenType.identifier() + "_to_" + _targetType.identifier() + _options.toFunctionNameSuffix(); return createFunction(functionName, [&]() { string values = suffixedVariableNameList("value", 0, numVariablesForType(_givenType, _options)); string encoder = abiEncodingFunction(_givenType, _targetType, _options); if (_targetType.isDynamicallyEncoded()) return Whiskers(R"( function (, pos) -> updatedPos { updatedPos := (, pos) } )") ("functionName", functionName) ("encode", encoder) ("values", values) .render(); else { unsigned encodedSize = _targetType.calldataEncodedSize(_options.padded); solAssert(encodedSize != 0, "Invalid encoded size."); return Whiskers(R"( function (, pos) -> updatedPos { (, pos) updatedPos := add(pos, ) } )") ("functionName", functionName) ("encode", encoder) ("encodedSize", toCompactHexWithPrefix(encodedSize)) ("values", values) .render(); } }); } string ABIFunctions::abiEncodingFunctionCalldataArrayWithoutCleanup( Type const& _from, Type const& _to, EncodingOptions const& _options ) { solAssert(_from.category() == Type::Category::Array, "Unknown dynamic type."); solAssert(_to.category() == Type::Category::Array, "Unknown dynamic type."); auto const& fromArrayType = dynamic_cast(_from); auto const& toArrayType = dynamic_cast(_to); solAssert(fromArrayType.location() == DataLocation::CallData, ""); solAssert( fromArrayType.isByteArray() || *fromArrayType.baseType() == *TypeProvider::uint256() || *fromArrayType.baseType() == FixedBytesType(32), "" ); solAssert(fromArrayType.calldataStride() == toArrayType.memoryStride(), ""); solAssert( *fromArrayType.copyForLocation(DataLocation::Memory, true) == *toArrayType.copyForLocation(DataLocation::Memory, true), "" ); string functionName = "abi_encode_" + _from.identifier() + "_to_" + _to.identifier() + _options.toFunctionNameSuffix(); return createFunction(functionName, [&]() { bool needsPadding = _options.padded && fromArrayType.isByteArray(); if (fromArrayType.isDynamicallySized()) { Whiskers templ(R"( // -> function (start, length, pos) -> end { pos := (pos, length) (start, pos, length) end := add(pos, ) } )"); templ("storeLength", arrayStoreLengthForEncodingFunction(toArrayType, _options)); templ("functionName", functionName); if (fromArrayType.isByteArray() || fromArrayType.calldataStride() == 1) templ("scaleLengthByStride", ""); else templ("scaleLengthByStride", Whiskers(R"( if gt(length, ) { } length := mul(length, ) )") ("stride", toCompactHexWithPrefix(fromArrayType.calldataStride())) ("maxLength", toCompactHexWithPrefix(u256(-1) / fromArrayType.calldataStride())) ("revertString", revertReasonIfDebug("ABI encoding: array data too long")) .render() // TODO add revert test ); templ("readableTypeNameFrom", _from.toString(true)); templ("readableTypeNameTo", _to.toString(true)); templ("copyFun", m_utils.copyToMemoryFunction(true)); templ("lengthPadded", needsPadding ? m_utils.roundUpFunction() + "(length)" : "length"); return templ.render(); } else { solAssert(fromArrayType.calldataStride() == 32, ""); Whiskers templ(R"( // -> function (start, pos) { (start, pos, ) } )"); templ("functionName", functionName); templ("readableTypeNameFrom", _from.toString(true)); templ("readableTypeNameTo", _to.toString(true)); templ("copyFun", m_utils.copyToMemoryFunction(true)); templ("byteLength", toCompactHexWithPrefix(fromArrayType.length() * fromArrayType.calldataStride())); return templ.render(); } }); } string ABIFunctions::abiEncodingFunctionSimpleArray( ArrayType const& _from, ArrayType const& _to, EncodingOptions const& _options ) { string functionName = "abi_encode_" + _from.identifier() + "_to_" + _to.identifier() + _options.toFunctionNameSuffix(); solAssert(_from.isDynamicallySized() == _to.isDynamicallySized(), ""); solAssert(_from.length() == _to.length(), ""); solAssert(!_from.isByteArray(), ""); if (_from.dataStoredIn(DataLocation::Storage)) solAssert(_from.baseType()->storageBytes() > 16, ""); return createFunction(functionName, [&]() { bool dynamic = _to.isDynamicallyEncoded(); bool dynamicBase = _to.baseType()->isDynamicallyEncoded(); bool const usesTail = dynamicBase && !_options.dynamicInplace; EncodingOptions subOptions(_options); subOptions.encodeFunctionFromStack = false; subOptions.padded = true; string elementValues = suffixedVariableNameList("elementValue", 0, numVariablesForType(*_from.baseType(), subOptions)); Whiskers templ( usesTail ? R"( // -> function (value, pos) { pos := (pos, length) let headStart := pos let tail := add(pos, mul(length, 0x20)) let baseRef := (value) let srcPtr := baseRef for { let i := 0 } lt(i, length) { i := add(i, 1) } { mstore(pos, sub(tail, headStart)) let := tail := (, tail) srcPtr := (srcPtr) pos := add(pos, 0x20) } pos := tail } )" : R"( // -> function (value, pos) { pos := (pos, length) let baseRef := (value) let srcPtr := baseRef for { let i := 0 } lt(i, length) { i := add(i, 1) } { let := pos := (, pos) srcPtr := (srcPtr) } } )" ); templ("functionName", functionName); templ("elementValues", elementValues); bool lengthAsArgument = _from.dataStoredIn(DataLocation::CallData) && _from.isDynamicallySized(); if (lengthAsArgument) { templ("maybeLength", " length,"); templ("declareLength", ""); } else { templ("maybeLength", ""); templ("declareLength", "let length := " + m_utils.arrayLengthFunction(_from) + "(value)"); } templ("readableTypeNameFrom", _from.toString(true)); templ("readableTypeNameTo", _to.toString(true)); templ("return", dynamic ? " -> end " : ""); templ("assignEnd", dynamic ? "end := pos" : ""); templ("storeLength", arrayStoreLengthForEncodingFunction(_to, _options)); templ("dataAreaFun", m_utils.arrayDataAreaFunction(_from)); templ("encodeToMemoryFun", abiEncodeAndReturnUpdatedPosFunction(*_from.baseType(), *_to.baseType(), subOptions)); switch (_from.location()) { case DataLocation::Memory: templ("arrayElementAccess", "mload(srcPtr)"); break; case DataLocation::Storage: if (_from.baseType()->isValueType()) templ("arrayElementAccess", m_utils.readFromStorage(*_from.baseType(), 0, false) + "(srcPtr)"); else templ("arrayElementAccess", "srcPtr"); break; case DataLocation::CallData: templ("arrayElementAccess", calldataAccessFunction(*_from.baseType()) + "(baseRef, srcPtr)"); break; default: solAssert(false, ""); } templ("nextArrayElement", m_utils.nextArrayElementFunction(_from)); return templ.render(); }); } string ABIFunctions::abiEncodingFunctionMemoryByteArray( ArrayType const& _from, ArrayType const& _to, EncodingOptions const& _options ) { string functionName = "abi_encode_" + _from.identifier() + "_to_" + _to.identifier() + _options.toFunctionNameSuffix(); solAssert(_from.isDynamicallySized() == _to.isDynamicallySized(), ""); solAssert(_from.length() == _to.length(), ""); solAssert(_from.dataStoredIn(DataLocation::Memory), ""); solAssert(_from.isByteArray(), ""); return createFunction(functionName, [&]() { solAssert(_to.isByteArray(), ""); Whiskers templ(R"( function (value, pos) -> end { let length := (value) pos := (pos, length) (add(value, 0x20), pos, length) end := add(pos, ) } )"); templ("functionName", functionName); templ("lengthFun", m_utils.arrayLengthFunction(_from)); templ("storeLength", arrayStoreLengthForEncodingFunction(_to, _options)); templ("copyFun", m_utils.copyToMemoryFunction(false)); templ("lengthPadded", _options.padded ? m_utils.roundUpFunction() + "(length)" : "length"); return templ.render(); }); } string ABIFunctions::abiEncodingFunctionCompactStorageArray( ArrayType const& _from, ArrayType const& _to, EncodingOptions const& _options ) { string functionName = "abi_encode_" + _from.identifier() + "_to_" + _to.identifier() + _options.toFunctionNameSuffix(); solAssert(_from.isDynamicallySized() == _to.isDynamicallySized(), ""); solAssert(_from.length() == _to.length(), ""); solAssert(_from.dataStoredIn(DataLocation::Storage), ""); return createFunction(functionName, [&]() { if (_from.isByteArray()) { solAssert(_to.isByteArray(), ""); Whiskers templ(R"( // -> function (value, pos) -> ret { let slotValue := sload(value) switch and(slotValue, 1) case 0 { // short byte array let length := and(div(slotValue, 2), 0x7f) pos := (pos, length) mstore(pos, and(slotValue, not(0xff))) ret := add(pos, ) } case 1 { // long byte array let length := div(slotValue, 2) pos := (pos, length) let dataPos := (value) let i := 0 for { } lt(i, length) { i := add(i, 0x20) } { mstore(add(pos, i), sload(dataPos)) dataPos := add(dataPos, 1) } ret := add(pos, ) } } )"); templ("functionName", functionName); templ("readableTypeNameFrom", _from.toString(true)); templ("readableTypeNameTo", _to.toString(true)); templ("storeLength", arrayStoreLengthForEncodingFunction(_to, _options)); templ("lengthPaddedShort", _options.padded ? "0x20" : "length"); templ("lengthPaddedLong", _options.padded ? "i" : "length"); templ("arrayDataSlot", m_utils.arrayDataAreaFunction(_from)); return templ.render(); } else { // Multiple items per slot solAssert(_from.baseType()->storageBytes() <= 16, ""); solAssert(!_from.baseType()->isDynamicallyEncoded(), ""); solAssert(!_to.baseType()->isDynamicallyEncoded(), ""); solAssert(_from.baseType()->isValueType(), ""); bool dynamic = _to.isDynamicallyEncoded(); size_t storageBytes = _from.baseType()->storageBytes(); size_t itemsPerSlot = 32 / storageBytes; solAssert(itemsPerSlot > 0, ""); // The number of elements we need to handle manually after the loop. size_t spill = static_cast(_from.length() % itemsPerSlot); Whiskers templ( R"( // -> function (value, pos) { let length := (value) pos := (pos, length) let originalPos := pos let srcPtr := (value) let itemCounter := 0 if { // Run the loop over all full slots for { } lt(add(itemCounter, sub(, 1)), length) { itemCounter := add(itemCounter, ) } { let data := sload(srcPtr) <#items> ((data), pos) pos := add(pos, ) srcPtr := add(srcPtr, 1) } } // Handle the last (not necessarily full) slot specially if { let data := sload(srcPtr) <#items> if { ((data), pos) pos := add(pos, ) itemCounter := add(itemCounter, 1) } } } )" ); templ("functionName", functionName); templ("readableTypeNameFrom", _from.toString(true)); templ("readableTypeNameTo", _to.toString(true)); templ("return", dynamic ? " -> end " : ""); templ("assignEnd", dynamic ? "end := pos" : ""); templ("lengthFun", m_utils.arrayLengthFunction(_from)); templ("storeLength", arrayStoreLengthForEncodingFunction(_to, _options)); templ("dataArea", m_utils.arrayDataAreaFunction(_from)); // We skip the loop for arrays that fit a single slot. if (_from.isDynamicallySized() || _from.length() >= itemsPerSlot) templ("useLoop", "1"); else templ("useLoop", "0"); if (_from.isDynamicallySized() || spill != 0) templ("useSpill", "1"); else templ("useSpill", "0"); templ("itemsPerSlot", to_string(itemsPerSlot)); templ("stride", toCompactHexWithPrefix(_to.calldataStride())); EncodingOptions subOptions(_options); subOptions.encodeFunctionFromStack = false; subOptions.padded = true; string encodeToMemoryFun = abiEncodingFunction( *_from.baseType(), *_to.baseType(), subOptions ); templ("encodeToMemoryFun", encodeToMemoryFun); std::vector> items(itemsPerSlot); for (size_t i = 0; i < itemsPerSlot; ++i) { if (_from.isDynamicallySized()) items[i]["inRange"] = "lt(itemCounter, length)"; else if (i < spill) items[i]["inRange"] = "1"; else items[i]["inRange"] = "0"; items[i]["extractFromSlot"] = m_utils.extractFromStorageValue(*_from.baseType(), i * storageBytes); } templ("items", items); return templ.render(); } }); } string ABIFunctions::abiEncodingFunctionStruct( StructType const& _from, StructType const& _to, EncodingOptions const& _options ) { string functionName = "abi_encode_" + _from.identifier() + "_to_" + _to.identifier() + _options.toFunctionNameSuffix(); solAssert(&_from.structDefinition() == &_to.structDefinition(), ""); return createFunction(functionName, [&]() { bool dynamic = _to.isDynamicallyEncoded(); Whiskers templ(R"( // -> function (value, pos) { let tail := add(pos, ) <#members> { // let := } } )"); templ("functionName", functionName); templ("readableTypeNameFrom", _from.toString(true)); templ("readableTypeNameTo", _to.toString(true)); templ("return", dynamic ? " -> end " : ""); if (dynamic && _options.dynamicInplace) templ("assignEnd", "end := pos"); else if (dynamic && !_options.dynamicInplace) templ("assignEnd", "end := tail"); else templ("assignEnd", ""); // to avoid multiple loads from the same slot for subsequent members templ("init", _from.dataStoredIn(DataLocation::Storage) ? "let slotValue := 0" : ""); u256 previousSlotOffset(-1); u256 encodingOffset = 0; vector> members; for (auto const& member: _to.members(nullptr)) { solAssert(member.type, ""); solAssert(!member.type->containsNestedMapping(), ""); TypePointer memberTypeTo = member.type->fullEncodingType(_options.encodeAsLibraryTypes, true, false); solUnimplementedAssert(memberTypeTo, "Encoding type \"" + member.type->toString() + "\" not yet implemented."); auto memberTypeFrom = _from.memberType(member.name); solAssert(memberTypeFrom, ""); bool dynamicMember = memberTypeTo->isDynamicallyEncoded(); if (dynamicMember) solAssert(dynamic, ""); members.emplace_back(); members.back()["preprocess"] = ""; switch (_from.location()) { case DataLocation::Storage: { solAssert(memberTypeFrom->isValueType() == memberTypeTo->isValueType(), ""); u256 storageSlotOffset; size_t intraSlotOffset; tie(storageSlotOffset, intraSlotOffset) = _from.storageOffsetsOfMember(member.name); if (memberTypeFrom->isValueType()) { if (storageSlotOffset != previousSlotOffset) { members.back()["preprocess"] = "slotValue := sload(add(value, " + toCompactHexWithPrefix(storageSlotOffset) + "))"; previousSlotOffset = storageSlotOffset; } members.back()["retrieveValue"] = m_utils.extractFromStorageValue(*memberTypeFrom, intraSlotOffset) + "(slotValue)"; } else { solAssert(memberTypeFrom->dataStoredIn(DataLocation::Storage), ""); solAssert(intraSlotOffset == 0, ""); members.back()["retrieveValue"] = "add(value, " + toCompactHexWithPrefix(storageSlotOffset) + ")"; } break; } case DataLocation::Memory: { string sourceOffset = toCompactHexWithPrefix(_from.memoryOffsetOfMember(member.name)); members.back()["retrieveValue"] = "mload(add(value, " + sourceOffset + "))"; break; } case DataLocation::CallData: { string sourceOffset = toCompactHexWithPrefix(_from.calldataOffsetOfMember(member.name)); members.back()["retrieveValue"] = calldataAccessFunction(*memberTypeFrom) + "(value, add(value, " + sourceOffset + "))"; break; } default: solAssert(false, ""); } EncodingOptions subOptions(_options); subOptions.encodeFunctionFromStack = false; // Like with arrays, struct members are always padded. subOptions.padded = true; string memberValues = suffixedVariableNameList("memberValue", 0, numVariablesForType(*memberTypeFrom, subOptions)); members.back()["memberValues"] = memberValues; string encode; if (_options.dynamicInplace) encode = Whiskers{"pos := (, pos)"} ("encode", abiEncodeAndReturnUpdatedPosFunction(*memberTypeFrom, *memberTypeTo, subOptions)) ("memberValues", memberValues) .render(); else { Whiskers encodeTempl( dynamicMember ? string(R"( mstore(add(pos, ), sub(tail, pos)) tail := (, tail) )") : "(, add(pos, ))" ); encodeTempl("memberValues", memberValues); encodeTempl("encodingOffset", toCompactHexWithPrefix(encodingOffset)); encodingOffset += memberTypeTo->calldataHeadSize(); encodeTempl("abiEncode", abiEncodingFunction(*memberTypeFrom, *memberTypeTo, subOptions)); encode = encodeTempl.render(); } members.back()["encode"] = encode; members.back()["memberName"] = member.name; } templ("members", members); if (_options.dynamicInplace) solAssert(encodingOffset == 0, "In-place encoding should enforce zero head size."); templ("headSize", toCompactHexWithPrefix(encodingOffset)); return templ.render(); }); } string ABIFunctions::abiEncodingFunctionStringLiteral( Type const& _from, Type const& _to, EncodingOptions const& _options ) { solAssert(_from.category() == Type::Category::StringLiteral, ""); string functionName = "abi_encode_" + _from.identifier() + "_to_" + _to.identifier() + _options.toFunctionNameSuffix(); return createFunction(functionName, [&]() { auto const& strType = dynamic_cast(_from); string const& value = strType.value(); solAssert(_from.sizeOnStack() == 0, ""); if (_to.isDynamicallySized()) { solAssert(_to.category() == Type::Category::Array, ""); Whiskers templ(R"( function (pos) -> end { pos := (pos, ) <#word> mstore(add(pos, ), ) end := add(pos, ) } )"); templ("functionName", functionName); // TODO this can make use of CODECOPY for large strings once we have that in Yul size_t words = (value.size() + 31) / 32; templ("length", to_string(value.size())); templ("storeLength", arrayStoreLengthForEncodingFunction(dynamic_cast(_to), _options)); if (_options.padded) templ("overallSize", to_string(words * 32)); else templ("overallSize", to_string(value.size())); vector> wordParams(words); for (size_t i = 0; i < words; ++i) { wordParams[i]["offset"] = to_string(i * 32); wordParams[i]["wordValue"] = formatAsStringOrNumber(value.substr(32 * i, 32)); } templ("word", wordParams); return templ.render(); } else { solAssert(_to.category() == Type::Category::FixedBytes, ""); solAssert(value.size() <= 32, ""); Whiskers templ(R"( function (pos) { mstore(pos, ) } )"); templ("functionName", functionName); templ("wordValue", formatAsStringOrNumber(value)); return templ.render(); } }); } string ABIFunctions::abiEncodingFunctionFunctionType( FunctionType const& _from, Type const& _to, EncodingOptions const& _options ) { solAssert(_from.kind() == FunctionType::Kind::External, ""); solAssert(_from == _to, ""); string functionName = "abi_encode_" + _from.identifier() + "_to_" + _to.identifier() + _options.toFunctionNameSuffix(); if (_options.encodeFunctionFromStack) return createFunction(functionName, [&]() { return Whiskers(R"( function (addr, function_id, pos) { mstore(pos, (addr, function_id)) } )") ("functionName", functionName) ("combineExtFun", m_utils.combineExternalFunctionIdFunction()) .render(); }); else return createFunction(functionName, [&]() { return Whiskers(R"( function (addr_and_function_id, pos) { mstore(pos, (addr_and_function_id)) } )") ("functionName", functionName) ("cleanExtFun", m_utils.cleanupFunction(_to)) .render(); }); } string ABIFunctions::abiDecodingFunction(Type const& _type, bool _fromMemory, bool _forUseOnStack) { // The decoding function has to perform bounds checks unless it decodes a value type. // Conversely, bounds checks have to be performed before the decoding function // of a value type is called. TypePointer decodingType = _type.decodingType(); solAssert(decodingType, ""); if (auto arrayType = dynamic_cast(decodingType)) { if (arrayType->dataStoredIn(DataLocation::CallData)) { solAssert(!_fromMemory, ""); return abiDecodingFunctionCalldataArray(*arrayType); } else return abiDecodingFunctionArray(*arrayType, _fromMemory); } else if (auto const* structType = dynamic_cast(decodingType)) { if (structType->dataStoredIn(DataLocation::CallData)) { solAssert(!_fromMemory, ""); return abiDecodingFunctionCalldataStruct(*structType); } else return abiDecodingFunctionStruct(*structType, _fromMemory); } else if (auto const* functionType = dynamic_cast(decodingType)) return abiDecodingFunctionFunctionType(*functionType, _fromMemory, _forUseOnStack); else return abiDecodingFunctionValueType(_type, _fromMemory); } string ABIFunctions::abiDecodingFunctionValueType(Type const& _type, bool _fromMemory) { TypePointer decodingType = _type.decodingType(); solAssert(decodingType, ""); solAssert(decodingType->sizeOnStack() == 1, ""); solAssert(decodingType->isValueType(), ""); solAssert(!decodingType->isDynamicallyEncoded(), ""); solAssert(decodingType->calldataEncodedSize() == 32, ""); string functionName = "abi_decode_" + _type.identifier() + (_fromMemory ? "_fromMemory" : ""); return createFunction(functionName, [&]() { Whiskers templ(R"( function (offset, end) -> value { value := (offset) (value) } )"); templ("functionName", functionName); templ("load", _fromMemory ? "mload" : "calldataload"); // Validation should use the type and not decodingType, because e.g. // the decoding type of an enum is a plain int. templ("validator", m_utils.validatorFunction(_type, true)); return templ.render(); }); } string ABIFunctions::abiDecodingFunctionArray(ArrayType const& _type, bool _fromMemory) { solAssert(_type.dataStoredIn(DataLocation::Memory), ""); string functionName = "abi_decode_" + _type.identifier() + (_fromMemory ? "_fromMemory" : ""); return createFunction(functionName, [&]() { string load = _fromMemory ? "mload" : "calldataload"; Whiskers templ( R"( // function (offset, end) -> array { if iszero(slt(add(offset, 0x1f), end)) { } let length := array := (, length, end) } )" ); // TODO add test templ("revertString", revertReasonIfDebug("ABI decoding: invalid calldata array offset")); templ("functionName", functionName); templ("readableTypeName", _type.toString(true)); templ("retrieveLength", _type.isDynamicallySized() ? (load + "(offset)") : toCompactHexWithPrefix(_type.length())); templ("offset", _type.isDynamicallySized() ? "add(offset, 0x20)" : "offset"); templ("abiDecodeAvailableLen", abiDecodingFunctionArrayAvailableLength(_type, _fromMemory)); return templ.render(); }); } string ABIFunctions::abiDecodingFunctionArrayAvailableLength(ArrayType const& _type, bool _fromMemory) { solAssert(_type.dataStoredIn(DataLocation::Memory), ""); if (_type.isByteArray()) return abiDecodingFunctionByteArrayAvailableLength(_type, _fromMemory); string functionName = "abi_decode_available_length_" + _type.identifier() + (_fromMemory ? "_fromMemory" : ""); return createFunction(functionName, [&]() { Whiskers templ(R"( // function (offset, length, end) -> array { array := ((length)) let dst := array let src := offset for { let i := 0 } lt(i, length) { i := add(i, 1) } { let elementPos := mstore(dst, (elementPos, end)) dst := add(dst, 0x20) src := add(src, ) } } )"); templ("functionName", functionName); templ("readableTypeName", _type.toString(true)); templ("allocate", m_utils.allocationFunction()); templ("allocationSize", m_utils.arrayAllocationSizeFunction(_type)); string calldataStride = toCompactHexWithPrefix(_type.calldataStride()); templ("stride", calldataStride); if (_type.isDynamicallySized()) templ("storeLength", "mstore(array, length) dst := add(array, 0x20)"); else templ("storeLength", ""); if (_type.baseType()->isDynamicallyEncoded()) { templ("staticBoundsCheck", ""); string load = _fromMemory ? "mload" : "calldataload"; templ("retrieveElementPos", "add(offset, " + load + "(src))"); } else { templ("staticBoundsCheck", "if gt(add(src, mul(length, " + calldataStride + ")), end) { " + revertReasonIfDebug("ABI decoding: invalid calldata array stride") + " }" ); templ("retrieveElementPos", "src"); } templ("decodingFun", abiDecodingFunction(*_type.baseType(), _fromMemory, false)); return templ.render(); }); } string ABIFunctions::abiDecodingFunctionCalldataArray(ArrayType const& _type) { solAssert(_type.dataStoredIn(DataLocation::CallData), ""); if (!_type.isDynamicallySized()) solAssert(_type.length() < u256("0xffffffffffffffff"), ""); solAssert(_type.calldataStride() > 0, ""); solAssert(_type.calldataStride() < u256("0xffffffffffffffff"), ""); string functionName = "abi_decode_" + _type.identifier(); return createFunction(functionName, [&]() { string templ; if (_type.isDynamicallySized()) templ = R"( // function (offset, end) -> arrayPos, length { if iszero(slt(add(offset, 0x1f), end)) { } length := calldataload(offset) if gt(length, 0xffffffffffffffff) { } arrayPos := add(offset, 0x20) if gt(add(arrayPos, mul(length, )), end) { } } )"; else templ = R"( // function (offset, end) -> arrayPos { arrayPos := offset if gt(add(arrayPos, mul(, )), end) { } } )"; Whiskers w{templ}; // TODO add test w("revertStringOffset", revertReasonIfDebug("ABI decoding: invalid calldata array offset")); w("revertStringLength", revertReasonIfDebug("ABI decoding: invalid calldata array length")); w("revertStringPos", revertReasonIfDebug("ABI decoding: invalid calldata array stride")); w("functionName", functionName); w("readableTypeName", _type.toString(true)); w("stride", toCompactHexWithPrefix(_type.calldataStride())); if (!_type.isDynamicallySized()) w("length", toCompactHexWithPrefix(_type.length())); return w.render(); }); } string ABIFunctions::abiDecodingFunctionByteArrayAvailableLength(ArrayType const& _type, bool _fromMemory) { solAssert(_type.dataStoredIn(DataLocation::Memory), ""); solAssert(_type.isByteArray(), ""); string functionName = "abi_decode_available_length_" + _type.identifier() + (_fromMemory ? "_fromMemory" : ""); return createFunction(functionName, [&]() { Whiskers templ(R"( function (src, length, end) -> array { array := ((length)) mstore(array, length) let dst := add(array, 0x20) if gt(add(src, length), end) { } (src, dst, length) } )"); templ("revertStringLength", revertReasonIfDebug("ABI decoding: invalid byte array length")); templ("functionName", functionName); templ("allocate", m_utils.allocationFunction()); templ("allocationSize", m_utils.arrayAllocationSizeFunction(_type)); templ("copyToMemFun", m_utils.copyToMemoryFunction(!_fromMemory)); return templ.render(); }); } string ABIFunctions::abiDecodingFunctionCalldataStruct(StructType const& _type) { solAssert(_type.dataStoredIn(DataLocation::CallData), ""); string functionName = "abi_decode_" + _type.identifier(); return createFunction(functionName, [&]() { Whiskers w{R"( // function (offset, end) -> value { if slt(sub(end, offset), ) { } value := offset } )"}; // TODO add test w("revertString", revertReasonIfDebug("ABI decoding: struct calldata too short")); w("functionName", functionName); w("readableTypeName", _type.toString(true)); w("minimumSize", to_string(_type.isDynamicallyEncoded() ? _type.calldataEncodedTailSize() : _type.calldataEncodedSize(true))); return w.render(); }); } string ABIFunctions::abiDecodingFunctionStruct(StructType const& _type, bool _fromMemory) { solAssert(!_type.dataStoredIn(DataLocation::CallData), ""); string functionName = "abi_decode_" + _type.identifier() + (_fromMemory ? "_fromMemory" : ""); return createFunction(functionName, [&]() { Whiskers templ(R"( // function (headStart, end) -> value { if slt(sub(end, headStart), ) { } value := () <#members> { // } } )"); // TODO add test templ("revertString", revertReasonIfDebug("ABI decoding: struct data too short")); templ("functionName", functionName); templ("readableTypeName", _type.toString(true)); templ("allocate", m_utils.allocationFunction()); solAssert(_type.memoryDataSize() < u256("0xffffffffffffffff"), ""); templ("memorySize", toCompactHexWithPrefix(_type.memoryDataSize())); size_t headPos = 0; vector> members; for (auto const& member: _type.members(nullptr)) { solAssert(member.type, ""); solAssert(!member.type->containsNestedMapping(), ""); auto decodingType = member.type->decodingType(); solAssert(decodingType, ""); Whiskers memberTempl(R"( let offset := (add(headStart, )) if gt(offset, 0xffffffffffffffff) { } let offset := mstore(add(value, ), (add(headStart, offset), end)) )"); memberTempl("dynamic", decodingType->isDynamicallyEncoded()); // TODO add test memberTempl("revertString", revertReasonIfDebug("ABI decoding: invalid struct offset")); memberTempl("load", _fromMemory ? "mload" : "calldataload"); memberTempl("pos", to_string(headPos)); memberTempl("memoryOffset", toCompactHexWithPrefix(_type.memoryOffsetOfMember(member.name))); memberTempl("abiDecode", abiDecodingFunction(*member.type, _fromMemory, false)); members.emplace_back(); members.back()["decode"] = memberTempl.render(); members.back()["memberName"] = member.name; headPos += decodingType->calldataHeadSize(); } templ("members", members); templ("minimumSize", toCompactHexWithPrefix(headPos)); return templ.render(); }); } string ABIFunctions::abiDecodingFunctionFunctionType(FunctionType const& _type, bool _fromMemory, bool _forUseOnStack) { solAssert(_type.kind() == FunctionType::Kind::External, ""); string functionName = "abi_decode_" + _type.identifier() + (_fromMemory ? "_fromMemory" : "") + (_forUseOnStack ? "_onStack" : ""); return createFunction(functionName, [&]() { if (_forUseOnStack) { return Whiskers(R"( function (offset, end) -> addr, function_selector { addr, function_selector := ((offset, end)) } )") ("functionName", functionName) ("decodeFun", abiDecodingFunctionFunctionType(_type, _fromMemory, false)) ("splitExtFun", m_utils.splitExternalFunctionIdFunction()) .render(); } else { return Whiskers(R"( function (offset, end) -> fun { fun := (offset) (fun) } )") ("functionName", functionName) ("load", _fromMemory ? "mload" : "calldataload") ("validateExtFun", m_utils.validatorFunction(_type, true)) .render(); } }); } string ABIFunctions::calldataAccessFunction(Type const& _type) { solAssert(_type.isValueType() || _type.dataStoredIn(DataLocation::CallData), ""); string functionName = "calldata_access_" + _type.identifier(); return createFunction(functionName, [&]() { if (_type.isDynamicallyEncoded()) { unsigned int tailSize = _type.calldataEncodedTailSize(); solAssert(tailSize > 1, ""); Whiskers w(R"( function (base_ref, ptr) -> { let rel_offset_of_tail := calldataload(ptr) if iszero(slt(rel_offset_of_tail, sub(sub(calldatasize(), base_ref), sub(, 1)))) { } value := add(rel_offset_of_tail, base_ref) } )"); if (_type.isDynamicallySized()) { auto const* arrayType = dynamic_cast(&_type); solAssert(!!arrayType, ""); w("handleLength", Whiskers(R"( length := calldataload(value) value := add(value, 0x20) if gt(length, 0xffffffffffffffff) { } if sgt(base_ref, sub(calldatasize(), mul(length, ))) { } )") ("calldataStride", toCompactHexWithPrefix(arrayType->calldataStride())) // TODO add test ("revertStringLength", revertReasonIfDebug("Invalid calldata access length")) // TODO add test ("revertStringStride", revertReasonIfDebug("Invalid calldata access stride")) .render()); w("return", "value, length"); } else { w("handleLength", ""); w("return", "value"); } w("neededLength", toCompactHexWithPrefix(tailSize)); w("functionName", functionName); w("revertStringOffset", revertReasonIfDebug("Invalid calldata access offset")); return w.render(); } else if (_type.isValueType()) { string decodingFunction; if (auto const* functionType = dynamic_cast(&_type)) decodingFunction = abiDecodingFunctionFunctionType(*functionType, false, false); else decodingFunction = abiDecodingFunctionValueType(_type, false); // Note that the second argument to the decoding function should be discarded after inlining. return Whiskers(R"( function (baseRef, ptr) -> value { value := (ptr, add(ptr, 32)) } )") ("functionName", functionName) ("decodingFunction", decodingFunction) .render(); } else { solAssert( _type.category() == Type::Category::Array || _type.category() == Type::Category::Struct, "" ); return Whiskers(R"( function (baseRef, ptr) -> value { value := ptr } )") ("functionName", functionName) .render(); } }); } string ABIFunctions::arrayStoreLengthForEncodingFunction(ArrayType const& _type, EncodingOptions const& _options) { string functionName = "array_storeLengthForEncoding_" + _type.identifier() + _options.toFunctionNameSuffix(); return createFunction(functionName, [&]() { if (_type.isDynamicallySized() && !_options.dynamicInplace) return Whiskers(R"( function (pos, length) -> updated_pos { mstore(pos, length) updated_pos := add(pos, 0x20) } )") ("functionName", functionName) .render(); else return Whiskers(R"( function (pos, length) -> updated_pos { updated_pos := pos } )") ("functionName", functionName) .render(); }); } string ABIFunctions::createFunction(string const& _name, function const& _creator) { return m_functionCollector.createFunction(_name, _creator); } size_t ABIFunctions::headSize(TypePointers const& _targetTypes) { size_t headSize = 0; for (auto const& t: _targetTypes) headSize += t->calldataHeadSize(); return headSize; } size_t ABIFunctions::numVariablesForType(Type const& _type, EncodingOptions const& _options) { if (_type.category() == Type::Category::Function && !_options.encodeFunctionFromStack) return 1; else return _type.sizeOnStack(); } std::string ABIFunctions::revertReasonIfDebug(std::string const& _message) { return YulUtilFunctions::revertReasonIfDebug(m_revertStrings, _message); }