// Copyright 2021 The go-ethereum Authors // This file is part of the go-ethereum library. // // The go-ethereum library is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // The go-ethereum library 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 Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with the go-ethereum library. If not, see . package state import ( "maps" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/common/math" "github.com/ethereum/go-ethereum/params" "github.com/ethereum/go-ethereum/trie/utils" "github.com/holiman/uint256" ) // mode specifies how a tree location has been accessed // for the byte value: // * the first bit is set if the branch has been read // * the second bit is set if the branch has been edited type mode byte const ( AccessWitnessReadFlag = mode(1) AccessWitnessWriteFlag = mode(2) ) var zeroTreeIndex uint256.Int // AccessEvents lists the locations of the state that are being accessed // during the production of a block. type AccessEvents struct { branches map[branchAccessKey]mode chunks map[chunkAccessKey]mode pointCache *utils.PointCache } func NewAccessEvents(pointCache *utils.PointCache) *AccessEvents { return &AccessEvents{ branches: make(map[branchAccessKey]mode), chunks: make(map[chunkAccessKey]mode), pointCache: pointCache, } } // Merge is used to merge the access events that were generated during the // execution of a tx, with the accumulation of all access events that were // generated during the execution of all txs preceding this one in a block. func (ae *AccessEvents) Merge(other *AccessEvents) { for k := range other.branches { ae.branches[k] |= other.branches[k] } for k, chunk := range other.chunks { ae.chunks[k] |= chunk } } // Keys returns, predictably, the list of keys that were touched during the // buildup of the access witness. func (ae *AccessEvents) Keys() [][]byte { // TODO: consider if parallelizing this is worth it, probably depending on len(ae.chunks). keys := make([][]byte, 0, len(ae.chunks)) for chunk := range ae.chunks { basePoint := ae.pointCache.Get(chunk.addr[:]) key := utils.GetTreeKeyWithEvaluatedAddress(basePoint, &chunk.treeIndex, chunk.leafKey) keys = append(keys, key) } return keys } func (ae *AccessEvents) Copy() *AccessEvents { cpy := &AccessEvents{ branches: maps.Clone(ae.branches), chunks: maps.Clone(ae.chunks), pointCache: ae.pointCache, } return cpy } // AddAccount returns the gas to be charged for each of the currently cold // member fields of an account. func (ae *AccessEvents) AddAccount(addr common.Address, isWrite bool) uint64 { var gas uint64 gas += ae.touchAddressAndChargeGas(addr, zeroTreeIndex, utils.BasicDataLeafKey, isWrite) gas += ae.touchAddressAndChargeGas(addr, zeroTreeIndex, utils.CodeHashLeafKey, isWrite) return gas } // MessageCallGas returns the gas to be charged for each of the currently // cold member fields of an account, that need to be touched when making a message // call to that account. func (ae *AccessEvents) MessageCallGas(destination common.Address) uint64 { var gas uint64 gas += ae.touchAddressAndChargeGas(destination, zeroTreeIndex, utils.BasicDataLeafKey, false) return gas } // ValueTransferGas returns the gas to be charged for each of the currently // cold balance member fields of the caller and the callee accounts. func (ae *AccessEvents) ValueTransferGas(callerAddr, targetAddr common.Address) uint64 { var gas uint64 gas += ae.touchAddressAndChargeGas(callerAddr, zeroTreeIndex, utils.BasicDataLeafKey, true) gas += ae.touchAddressAndChargeGas(targetAddr, zeroTreeIndex, utils.BasicDataLeafKey, true) return gas } // ContractCreateCPreheck charges access costs before // a contract creation is initiated. It is just reads, because the // address collision is done before the transfer, and so no write // are guaranteed to happen at this point. func (ae *AccessEvents) ContractCreatePreCheckGas(addr common.Address) uint64 { var gas uint64 gas += ae.touchAddressAndChargeGas(addr, zeroTreeIndex, utils.BasicDataLeafKey, false) gas += ae.touchAddressAndChargeGas(addr, zeroTreeIndex, utils.CodeHashLeafKey, false) return gas } // ContractCreateInitGas returns the access gas costs for the initialization of // a contract creation. func (ae *AccessEvents) ContractCreateInitGas(addr common.Address) uint64 { var gas uint64 gas += ae.touchAddressAndChargeGas(addr, zeroTreeIndex, utils.BasicDataLeafKey, true) gas += ae.touchAddressAndChargeGas(addr, zeroTreeIndex, utils.CodeHashLeafKey, true) return gas } // AddTxOrigin adds the member fields of the sender account to the access event list, // so that cold accesses are not charged, since they are covered by the 21000 gas. func (ae *AccessEvents) AddTxOrigin(originAddr common.Address) { ae.touchAddressAndChargeGas(originAddr, zeroTreeIndex, utils.BasicDataLeafKey, true) ae.touchAddressAndChargeGas(originAddr, zeroTreeIndex, utils.CodeHashLeafKey, false) } // AddTxDestination adds the member fields of the sender account to the access event list, // so that cold accesses are not charged, since they are covered by the 21000 gas. func (ae *AccessEvents) AddTxDestination(addr common.Address, sendsValue bool) { ae.touchAddressAndChargeGas(addr, zeroTreeIndex, utils.BasicDataLeafKey, sendsValue) ae.touchAddressAndChargeGas(addr, zeroTreeIndex, utils.CodeHashLeafKey, false) } // SlotGas returns the amount of gas to be charged for a cold storage access. func (ae *AccessEvents) SlotGas(addr common.Address, slot common.Hash, isWrite bool) uint64 { treeIndex, subIndex := utils.StorageIndex(slot.Bytes()) return ae.touchAddressAndChargeGas(addr, *treeIndex, subIndex, isWrite) } // touchAddressAndChargeGas adds any missing access event to the access event list, and returns the cold // access cost to be charged, if need be. func (ae *AccessEvents) touchAddressAndChargeGas(addr common.Address, treeIndex uint256.Int, subIndex byte, isWrite bool) uint64 { stemRead, selectorRead, stemWrite, selectorWrite, selectorFill := ae.touchAddress(addr, treeIndex, subIndex, isWrite) var gas uint64 if stemRead { gas += params.WitnessBranchReadCost } if selectorRead { gas += params.WitnessChunkReadCost } if stemWrite { gas += params.WitnessBranchWriteCost } if selectorWrite { gas += params.WitnessChunkWriteCost } if selectorFill { gas += params.WitnessChunkFillCost } return gas } // touchAddress adds any missing access event to the access event list. func (ae *AccessEvents) touchAddress(addr common.Address, treeIndex uint256.Int, subIndex byte, isWrite bool) (bool, bool, bool, bool, bool) { branchKey := newBranchAccessKey(addr, treeIndex) chunkKey := newChunkAccessKey(branchKey, subIndex) // Read access. var branchRead, chunkRead bool if _, hasStem := ae.branches[branchKey]; !hasStem { branchRead = true ae.branches[branchKey] = AccessWitnessReadFlag } if _, hasSelector := ae.chunks[chunkKey]; !hasSelector { chunkRead = true ae.chunks[chunkKey] = AccessWitnessReadFlag } // Write access. var branchWrite, chunkWrite, chunkFill bool if isWrite { if (ae.branches[branchKey] & AccessWitnessWriteFlag) == 0 { branchWrite = true ae.branches[branchKey] |= AccessWitnessWriteFlag } chunkValue := ae.chunks[chunkKey] if (chunkValue & AccessWitnessWriteFlag) == 0 { chunkWrite = true ae.chunks[chunkKey] |= AccessWitnessWriteFlag } // TODO: charge chunk filling costs if the leaf was previously empty in the state } return branchRead, chunkRead, branchWrite, chunkWrite, chunkFill } type branchAccessKey struct { addr common.Address treeIndex uint256.Int } func newBranchAccessKey(addr common.Address, treeIndex uint256.Int) branchAccessKey { var sk branchAccessKey sk.addr = addr sk.treeIndex = treeIndex return sk } type chunkAccessKey struct { branchAccessKey leafKey byte } func newChunkAccessKey(branchKey branchAccessKey, leafKey byte) chunkAccessKey { var lk chunkAccessKey lk.branchAccessKey = branchKey lk.leafKey = leafKey return lk } // CodeChunksRangeGas is a helper function to touch every chunk in a code range and charge witness gas costs func (ae *AccessEvents) CodeChunksRangeGas(contractAddr common.Address, startPC, size uint64, codeLen uint64, isWrite bool) uint64 { // note that in the case where the copied code is outside the range of the // contract code but touches the last leaf with contract code in it, // we don't include the last leaf of code in the AccessWitness. The // reason that we do not need the last leaf is the account's code size // is already in the AccessWitness so a stateless verifier can see that // the code from the last leaf is not needed. if (codeLen == 0 && size == 0) || startPC > codeLen { return 0 } endPC := startPC + size if endPC > codeLen { endPC = codeLen } if endPC > 0 { endPC -= 1 // endPC is the last bytecode that will be touched. } var statelessGasCharged uint64 for chunkNumber := startPC / 31; chunkNumber <= endPC/31; chunkNumber++ { treeIndex := *uint256.NewInt((chunkNumber + 128) / 256) subIndex := byte((chunkNumber + 128) % 256) gas := ae.touchAddressAndChargeGas(contractAddr, treeIndex, subIndex, isWrite) var overflow bool statelessGasCharged, overflow = math.SafeAdd(statelessGasCharged, gas) if overflow { panic("overflow when adding gas") } } return statelessGasCharged } // BasicDataGas adds the account's basic data to the accessed data, and returns the // amount of gas that it costs. // Note that an access in write mode implies an access in read mode, whereas an // access in read mode does not imply an access in write mode. func (ae *AccessEvents) BasicDataGas(addr common.Address, isWrite bool) uint64 { return ae.touchAddressAndChargeGas(addr, zeroTreeIndex, utils.BasicDataLeafKey, isWrite) } // CodeHashGas adds the account's code hash to the accessed data, and returns the // amount of gas that it costs. // in write mode. If false, the charged gas corresponds to an access in read mode. // Note that an access in write mode implies an access in read mode, whereas an access in // read mode does not imply an access in write mode. func (ae *AccessEvents) CodeHashGas(addr common.Address, isWrite bool) uint64 { return ae.touchAddressAndChargeGas(addr, zeroTreeIndex, utils.CodeHashLeafKey, isWrite) }