// Copyright 2017 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 vm import ( "errors" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/common/math" "github.com/ethereum/go-ethereum/params" ) // memoryGasCost calculates the quadratic gas for memory expansion. It does so // only for the memory region that is expanded, not the total memory. func memoryGasCost(mem *Memory, newMemSize uint64) (uint64, error) { if newMemSize == 0 { return 0, nil } // The maximum that will fit in a uint64 is max_word_count - 1. Anything above // that will result in an overflow. Additionally, a newMemSize which results in // a newMemSizeWords larger than 0xFFFFFFFF will cause the square operation to // overflow. The constant 0x1FFFFFFFE0 is the highest number that can be used // without overflowing the gas calculation. if newMemSize > 0x1FFFFFFFE0 { return 0, ErrGasUintOverflow } newMemSizeWords := toWordSize(newMemSize) newMemSize = newMemSizeWords * 32 if newMemSize > uint64(mem.Len()) { square := newMemSizeWords * newMemSizeWords linCoef := newMemSizeWords * params.MemoryGas quadCoef := square / params.QuadCoeffDiv newTotalFee := linCoef + quadCoef fee := newTotalFee - mem.lastGasCost mem.lastGasCost = newTotalFee return fee, nil } return 0, nil } // memoryCopierGas creates the gas functions for the following opcodes, and takes // the stack position of the operand which determines the size of the data to copy // as argument: // CALLDATACOPY (stack position 2) // CODECOPY (stack position 2) // MCOPY (stack position 2) // EXTCODECOPY (stack position 3) // RETURNDATACOPY (stack position 2) func memoryCopierGas(stackpos int) gasFunc { return func(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { // Gas for expanding the memory gas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } // And gas for copying data, charged per word at param.CopyGas words, overflow := stack.Back(stackpos).Uint64WithOverflow() if overflow { return GasCosts{}, ErrGasUintOverflow } if words, overflow = math.SafeMul(toWordSize(words), params.CopyGas); overflow { return GasCosts{}, ErrGasUintOverflow } if gas, overflow = math.SafeAdd(gas, words); overflow { return GasCosts{}, ErrGasUintOverflow } return GasCosts{RegularGas: gas}, nil } } var ( gasCallDataCopy = memoryCopierGas(2) gasCodeCopy = memoryCopierGas(2) gasMcopy = memoryCopierGas(2) gasExtCodeCopy = memoryCopierGas(3) gasReturnDataCopy = memoryCopierGas(2) ) func gasSStore(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { if evm.readOnly { return GasCosts{}, ErrWriteProtection } var ( y, x = stack.Back(1), stack.Back(0) current, original = evm.StateDB.GetStateAndCommittedState(contract.Address(), x.Bytes32()) ) // The legacy gas metering only takes into consideration the current state // Legacy rules should be applied if we are in Petersburg (removal of EIP-1283) // OR Constantinople is not active if evm.chainRules.IsPetersburg || !evm.chainRules.IsConstantinople { // This checks for 3 scenarios and calculates gas accordingly: // // 1. From a zero-value address to a non-zero value (NEW VALUE) // 2. From a non-zero value address to a zero-value address (DELETE) // 3. From a non-zero to a non-zero (CHANGE) switch { case current == (common.Hash{}) && y.Sign() != 0: // 0 => non 0 return GasCosts{RegularGas: params.SstoreSetGas}, nil case current != (common.Hash{}) && y.Sign() == 0: // non 0 => 0 evm.StateDB.AddRefund(params.SstoreRefundGas) return GasCosts{RegularGas: params.SstoreClearGas}, nil default: // non 0 => non 0 (or 0 => 0) return GasCosts{RegularGas: params.SstoreResetGas}, nil } } // The new gas metering is based on net gas costs (EIP-1283): // // (1.) If current value equals new value (this is a no-op), 200 gas is deducted. // (2.) If current value does not equal new value // (2.1.) If original value equals current value (this storage slot has not been changed by the current execution context) // (2.1.1.) If original value is 0, 20000 gas is deducted. // (2.1.2.) Otherwise, 5000 gas is deducted. If new value is 0, add 15000 gas to refund counter. // (2.2.) If original value does not equal current value (this storage slot is dirty), 200 gas is deducted. Apply both of the following clauses. // (2.2.1.) If original value is not 0 // (2.2.1.1.) If current value is 0 (also means that new value is not 0), remove 15000 gas from refund counter. We can prove that refund counter will never go below 0. // (2.2.1.2.) If new value is 0 (also means that current value is not 0), add 15000 gas to refund counter. // (2.2.2.) If original value equals new value (this storage slot is reset) // (2.2.2.1.) If original value is 0, add 19800 gas to refund counter. // (2.2.2.2.) Otherwise, add 4800 gas to refund counter. value := common.Hash(y.Bytes32()) if current == value { // noop (1) return GasCosts{RegularGas: params.NetSstoreNoopGas}, nil } if original == current { if original == (common.Hash{}) { // create slot (2.1.1) return GasCosts{RegularGas: params.NetSstoreInitGas}, nil } if value == (common.Hash{}) { // delete slot (2.1.2b) evm.StateDB.AddRefund(params.NetSstoreClearRefund) } return GasCosts{RegularGas: params.NetSstoreCleanGas}, nil // write existing slot (2.1.2) } if original != (common.Hash{}) { if current == (common.Hash{}) { // recreate slot (2.2.1.1) evm.StateDB.SubRefund(params.NetSstoreClearRefund) } else if value == (common.Hash{}) { // delete slot (2.2.1.2) evm.StateDB.AddRefund(params.NetSstoreClearRefund) } } if original == value { if original == (common.Hash{}) { // reset to original inexistent slot (2.2.2.1) evm.StateDB.AddRefund(params.NetSstoreResetClearRefund) } else { // reset to original existing slot (2.2.2.2) evm.StateDB.AddRefund(params.NetSstoreResetRefund) } } return GasCosts{RegularGas: params.NetSstoreDirtyGas}, nil } // Here come the EIP2200 rules: // // (0.) If *gasleft* is less than or equal to 2300, fail the current call. // (1.) If current value equals new value (this is a no-op), SLOAD_GAS is deducted. // (2.) If current value does not equal new value: // (2.1.) If original value equals current value (this storage slot has not been changed by the current execution context): // (2.1.1.) If original value is 0, SSTORE_SET_GAS (20K) gas is deducted. // (2.1.2.) Otherwise, SSTORE_RESET_GAS gas is deducted. If new value is 0, add SSTORE_CLEARS_SCHEDULE to refund counter. // (2.2.) If original value does not equal current value (this storage slot is dirty), SLOAD_GAS gas is deducted. Apply both of the following clauses: // (2.2.1.) If original value is not 0: // (2.2.1.1.) If current value is 0 (also means that new value is not 0), subtract SSTORE_CLEARS_SCHEDULE gas from refund counter. // (2.2.1.2.) If new value is 0 (also means that current value is not 0), add SSTORE_CLEARS_SCHEDULE gas to refund counter. // (2.2.2.) If original value equals new value (this storage slot is reset): // (2.2.2.1.) If original value is 0, add SSTORE_SET_GAS - SLOAD_GAS to refund counter. // (2.2.2.2.) Otherwise, add SSTORE_RESET_GAS - SLOAD_GAS gas to refund counter. func gasSStoreEIP2200(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { if evm.readOnly { return GasCosts{}, ErrWriteProtection } // If we fail the minimum gas availability invariant, fail (0) if contract.Gas.RegularGas <= params.SstoreSentryGasEIP2200 { return GasCosts{}, errors.New("not enough gas for reentrancy sentry") } // Gas sentry honoured, do the actual gas calculation based on the stored value var ( y, x = stack.Back(1), stack.Back(0) current, original = evm.StateDB.GetStateAndCommittedState(contract.Address(), x.Bytes32()) ) value := common.Hash(y.Bytes32()) if current == value { // noop (1) return GasCosts{RegularGas: params.SloadGasEIP2200}, nil } if original == current { if original == (common.Hash{}) { // create slot (2.1.1) return GasCosts{RegularGas: params.SstoreSetGasEIP2200}, nil } if value == (common.Hash{}) { // delete slot (2.1.2b) evm.StateDB.AddRefund(params.SstoreClearsScheduleRefundEIP2200) } return GasCosts{RegularGas: params.SstoreResetGasEIP2200}, nil // write existing slot (2.1.2) } if original != (common.Hash{}) { if current == (common.Hash{}) { // recreate slot (2.2.1.1) evm.StateDB.SubRefund(params.SstoreClearsScheduleRefundEIP2200) } else if value == (common.Hash{}) { // delete slot (2.2.1.2) evm.StateDB.AddRefund(params.SstoreClearsScheduleRefundEIP2200) } } if original == value { if original == (common.Hash{}) { // reset to original inexistent slot (2.2.2.1) evm.StateDB.AddRefund(params.SstoreSetGasEIP2200 - params.SloadGasEIP2200) } else { // reset to original existing slot (2.2.2.2) evm.StateDB.AddRefund(params.SstoreResetGasEIP2200 - params.SloadGasEIP2200) } } return GasCosts{RegularGas: params.SloadGasEIP2200}, nil // dirty update (2.2) } func makeGasLog(n uint64) gasFunc { return func(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { requestedSize, overflow := stack.Back(1).Uint64WithOverflow() if overflow { return GasCosts{}, ErrGasUintOverflow } gas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } if gas, overflow = math.SafeAdd(gas, params.LogGas); overflow { return GasCosts{}, ErrGasUintOverflow } if gas, overflow = math.SafeAdd(gas, n*params.LogTopicGas); overflow { return GasCosts{}, ErrGasUintOverflow } var memorySizeGas uint64 if memorySizeGas, overflow = math.SafeMul(requestedSize, params.LogDataGas); overflow { return GasCosts{}, ErrGasUintOverflow } if gas, overflow = math.SafeAdd(gas, memorySizeGas); overflow { return GasCosts{}, ErrGasUintOverflow } return GasCosts{RegularGas: gas}, nil } } func gasKeccak256(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { gas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } wordGas, overflow := stack.Back(1).Uint64WithOverflow() if overflow { return GasCosts{}, ErrGasUintOverflow } if wordGas, overflow = math.SafeMul(toWordSize(wordGas), params.Keccak256WordGas); overflow { return GasCosts{}, ErrGasUintOverflow } if gas, overflow = math.SafeAdd(gas, wordGas); overflow { return GasCosts{}, ErrGasUintOverflow } return GasCosts{RegularGas: gas}, nil } // pureMemoryGascost is used by several operations, which aside from their // static cost have a dynamic cost which is solely based on the memory // expansion func pureMemoryGascost(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { gas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } return GasCosts{RegularGas: gas}, nil } var ( gasReturn = pureMemoryGascost gasRevert = pureMemoryGascost gasMLoad = pureMemoryGascost gasMStore8 = pureMemoryGascost gasMStore = pureMemoryGascost gasCreate = pureMemoryGascost ) func gasCreate2(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { gas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } wordGas, overflow := stack.Back(2).Uint64WithOverflow() if overflow { return GasCosts{}, ErrGasUintOverflow } if wordGas, overflow = math.SafeMul(toWordSize(wordGas), params.Keccak256WordGas); overflow { return GasCosts{}, ErrGasUintOverflow } if gas, overflow = math.SafeAdd(gas, wordGas); overflow { return GasCosts{}, ErrGasUintOverflow } return GasCosts{RegularGas: gas}, nil } func gasCreateEip3860(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { gas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } size, overflow := stack.Back(2).Uint64WithOverflow() if overflow { return GasCosts{}, ErrGasUintOverflow } if err := CheckMaxInitCodeSize(&evm.chainRules, size); err != nil { return GasCosts{}, err } // Since size <= the protocol-defined maximum initcode size limit, these multiplication cannot overflow moreGas := params.InitCodeWordGas * ((size + 31) / 32) if gas, overflow = math.SafeAdd(gas, moreGas); overflow { return GasCosts{}, ErrGasUintOverflow } return GasCosts{RegularGas: gas}, nil } func gasCreate2Eip3860(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { gas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } size, overflow := stack.Back(2).Uint64WithOverflow() if overflow { return GasCosts{}, ErrGasUintOverflow } if err := CheckMaxInitCodeSize(&evm.chainRules, size); err != nil { return GasCosts{}, err } // Since size <= the protocol-defined maximum initcode size limit, these multiplication cannot overflow moreGas := (params.InitCodeWordGas + params.Keccak256WordGas) * ((size + 31) / 32) if gas, overflow = math.SafeAdd(gas, moreGas); overflow { return GasCosts{}, ErrGasUintOverflow } return GasCosts{RegularGas: gas}, nil } func gasExpFrontier(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { expByteLen := uint64((stack.data[stack.len()-2].BitLen() + 7) / 8) var ( gas = expByteLen * params.ExpByteFrontier // no overflow check required. Max is 256 * ExpByte gas overflow bool ) if gas, overflow = math.SafeAdd(gas, params.ExpGas); overflow { return GasCosts{}, ErrGasUintOverflow } return GasCosts{RegularGas: gas}, nil } func gasExpEIP158(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { expByteLen := uint64((stack.data[stack.len()-2].BitLen() + 7) / 8) var ( gas = expByteLen * params.ExpByteEIP158 // no overflow check required. Max is 256 * ExpByte gas overflow bool ) if gas, overflow = math.SafeAdd(gas, params.ExpGas); overflow { return GasCosts{}, ErrGasUintOverflow } return GasCosts{RegularGas: gas}, nil } func gasCallStateless(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { var ( gas uint64 transfersValue = !stack.Back(2).IsZero() ) if transfersValue { if evm.readOnly { return GasCosts{}, ErrWriteProtection } else if !evm.chainRules.IsEIP4762 { gas += params.CallValueTransferGas } } memoryGas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } var overflow bool if gas, overflow = math.SafeAdd(gas, memoryGas); overflow { return GasCosts{}, ErrGasUintOverflow } return GasCosts{RegularGas: gas}, nil } func gasCallStateful(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { var ( gas uint64 transfersValue = !stack.Back(2).IsZero() address = common.Address(stack.Back(1).Bytes20()) ) if evm.readOnly && transfersValue { return GasCosts{}, ErrWriteProtection } if evm.chainRules.IsEIP158 { if transfersValue && evm.StateDB.Empty(address) { gas += params.CallNewAccountGas } } else if !evm.StateDB.Exist(address) { gas += params.CallNewAccountGas } return GasCosts{RegularGas: gas}, nil } func gasCall(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { stateless, err := gasCallStateless(evm, contract, stack, mem, memorySize) if err != nil { return GasCosts{}, err } stateful, err := gasCallStateful(evm, contract, stack, mem, memorySize) if err != nil { return GasCosts{}, err } gas, overflow := math.SafeAdd(stateless.RegularGas, stateful.RegularGas) if overflow { return GasCosts{}, ErrGasUintOverflow } evm.callGasTemp, err = callGas(evm.chainRules.IsEIP150, contract.Gas.RegularGas, gas, stack.Back(0)) if err != nil { return GasCosts{}, err } if gas, overflow = math.SafeAdd(gas, evm.callGasTemp); overflow { return GasCosts{}, ErrGasUintOverflow } return GasCosts{RegularGas: gas}, nil } func gasCallCodeStateful(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { return GasCosts{}, nil } func gasCallCodeStateless(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { memoryGas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } var ( gas uint64 overflow bool transfersValue = !stack.Back(2).IsZero() ) if transfersValue { if !evm.chainRules.IsEIP4762 { gas += params.CallValueTransferGas } } if gas, overflow = math.SafeAdd(gas, memoryGas); overflow { return GasCosts{}, ErrGasUintOverflow } return GasCosts{RegularGas: gas}, nil } func gasCallCode(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { var overflow bool gas, err := gasCallCodeStateless(evm, contract, stack, mem, memorySize) if err != nil { return GasCosts{}, err } evm.callGasTemp, err = callGas(evm.chainRules.IsEIP150, contract.Gas.RegularGas, gas.RegularGas, stack.Back(0)) if err != nil { return GasCosts{}, err } if gas.RegularGas, overflow = math.SafeAdd(gas.RegularGas, evm.callGasTemp); overflow { return GasCosts{}, ErrGasUintOverflow } return gas, nil } func gasDelegateCall(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { var ( err error gas GasCosts ) gas, err = gasDelegateCallStateless(evm, contract, stack, mem, memorySize) if err != nil { return GasCosts{}, err } evm.callGasTemp, err = callGas(evm.chainRules.IsEIP150, contract.Gas.RegularGas, gas.RegularGas, stack.Back(0)) if err != nil { return GasCosts{}, err } var overflow bool if gas.RegularGas, overflow = math.SafeAdd(gas.RegularGas, evm.callGasTemp); overflow { return GasCosts{}, ErrGasUintOverflow } return gas, nil } func gasDelegateCallStateful(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { return GasCosts{}, nil } func gasDelegateCallStateless(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { gas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } return GasCosts{RegularGas: gas}, nil } func gasStaticCallStateless(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { gas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } return GasCosts{RegularGas: gas}, nil } func gasStaticCallStateful(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { return GasCosts{}, nil } func gasStaticCall(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { gas, err := gasStaticCallStateless(evm, contract, stack, mem, memorySize) if err != nil { return GasCosts{}, err } evm.callGasTemp, err = callGas(evm.chainRules.IsEIP150, contract.Gas.RegularGas, gas.RegularGas, stack.Back(0)) if err != nil { return GasCosts{}, err } var overflow bool if gas.RegularGas, overflow = math.SafeAdd(gas.RegularGas, evm.callGasTemp); overflow { return GasCosts{}, ErrGasUintOverflow } return gas, nil } func gasSelfdestruct(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { if evm.readOnly { return GasCosts{}, ErrWriteProtection } var gas uint64 // EIP150 homestead gas reprice fork: if evm.chainRules.IsEIP150 { gas = params.SelfdestructGasEIP150 var address = common.Address(stack.Back(0).Bytes20()) if gas > contract.Gas.RegularGas { return GasCosts{RegularGas: gas}, nil } if evm.chainRules.IsEIP158 { // if empty and transfers value if evm.StateDB.Empty(address) && evm.StateDB.GetBalance(contract.Address()).Sign() != 0 { gas += params.CreateBySelfdestructGas } } else if !evm.StateDB.Exist(address) { gas += params.CreateBySelfdestructGas } } if !evm.StateDB.HasSelfDestructed(contract.Address()) { evm.StateDB.AddRefund(params.SelfdestructRefundGas) } return GasCosts{RegularGas: gas}, nil } func gasCreateEip8037(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { gas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } size, overflow := stack.Back(2).Uint64WithOverflow() if overflow { return GasCosts{}, ErrGasUintOverflow } // Cap word gas at MaxInitCodeSizeAmsterdam to avoid overflow. // The actual init code size check happens in create() for graceful failure. wordSize := min(size, params.MaxInitCodeSizeAmsterdam) words := (wordSize + 31) / 32 // Account creation is a fixed state gas cost, not proportional to init code size. // Code storage state gas is charged separately in initNewContract. stateGas := params.AccountCreationSize * evm.Context.CostPerGasByte // CREATE uses InitCodeWordGas (EIP-3860); Keccak256WordGas is only for CREATE2. wordGas := params.InitCodeWordGas * words return GasCosts{RegularGas: gas + wordGas, StateGas: stateGas}, nil } func gasCreate2Eip8037(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { gas, err := memoryGasCost(mem, memorySize) if err != nil { return GasCosts{}, err } size, overflow := stack.Back(2).Uint64WithOverflow() if overflow { return GasCosts{}, ErrGasUintOverflow } // Cap word gas at MaxInitCodeSizeAmsterdam to avoid overflow. // The actual init code size check happens in create() for graceful failure. wordSize := min(size, params.MaxInitCodeSizeAmsterdam) words := (wordSize + 31) / 32 // Account creation is a fixed state gas cost, not proportional to init code size. // Code storage state gas is charged separately in initNewContract. stateGas := params.AccountCreationSize * evm.Context.CostPerGasByte // CREATE2 charges both InitCodeWordGas (EIP-3860) and Keccak256WordGas (for address hashing). wordGas := (params.InitCodeWordGas + params.Keccak256WordGas) * words return GasCosts{RegularGas: gas + wordGas, StateGas: stateGas}, nil } // gasCall8037 is the stateful gas calculator for CALL in Amsterdam (EIP-8037). // It only returns the state-dependent gas (account creation as state gas). // Memory gas, transfer gas, and callGas are handled by gasCallStateless and // makeCallVariantGasCall. func gasCall8037(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { var ( gas GasCosts transfersValue = !stack.Back(2).IsZero() address = common.Address(stack.Back(1).Bytes20()) ) if evm.chainRules.IsEIP158 { if transfersValue && evm.StateDB.Empty(address) { gas.StateGas += params.AccountCreationSize * evm.Context.CostPerGasByte } } else if !evm.StateDB.Exist(address) { gas.StateGas += params.AccountCreationSize * evm.Context.CostPerGasByte } return gas, nil } func gasSelfdestruct8037(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { if evm.readOnly { return GasCosts{}, ErrWriteProtection } var ( gas GasCosts address = common.Address(stack.peek().Bytes20()) ) if !evm.StateDB.AddressInAccessList(address) { // If the caller cannot afford the cost, this change will be rolled back evm.StateDB.AddAddressToAccessList(address) gas.RegularGas = params.ColdAccountAccessCostEIP2929 } // Check we have enough regular gas before we add the address to the BAL if contract.Gas.RegularGas < gas.RegularGas { return gas, nil } // if empty and transfers value if evm.StateDB.Empty(address) && evm.StateDB.GetBalance(contract.Address()).Sign() != 0 { gas.StateGas += params.AccountCreationSize * evm.Context.CostPerGasByte } return gas, nil } func gasSStore8037(evm *EVM, contract *Contract, stack *Stack, mem *Memory, memorySize uint64) (GasCosts, error) { if evm.readOnly { return GasCosts{}, ErrWriteProtection } // If we fail the minimum gas availability invariant, fail (0) if contract.Gas.RegularGas <= params.SstoreSentryGasEIP2200 { return GasCosts{}, errors.New("not enough gas for reentrancy sentry") } // Gas sentry honoured, do the actual gas calculation based on the stored value var ( y, x = stack.Back(1), stack.peek() slot = common.Hash(x.Bytes32()) current, original = evm.StateDB.GetStateAndCommittedState(contract.Address(), slot) cost GasCosts ) // Check slot presence in the access list if _, slotPresent := evm.StateDB.SlotInAccessList(contract.Address(), slot); !slotPresent { cost = GasCosts{RegularGas: params.ColdSloadCostEIP2929} // If the caller cannot afford the cost, this change will be rolled back evm.StateDB.AddSlotToAccessList(contract.Address(), slot) } value := common.Hash(y.Bytes32()) if current == value { // noop (1) // EIP 2200 original clause: // return params.SloadGasEIP2200, nil return GasCosts{RegularGas: cost.RegularGas + params.WarmStorageReadCostEIP2929}, nil // SLOAD_GAS } if original == current { if original == (common.Hash{}) { // create slot (2.1.1) // EIP-8037: Charge state gas first (before regular gas), matching the // spec's charge_state_gas → charge_gas ordering. This ensures that // state_gas_used is recorded even if the subsequent regular gas charge // fails with OOG. stateGas := GasCosts{StateGas: params.StorageCreationSize * evm.Context.CostPerGasByte} if contract.Gas.Underflow(stateGas) { return GasCosts{}, errors.New("out of gas for state gas") } contract.Gas.Sub(stateGas) return GasCosts{RegularGas: cost.RegularGas + params.SstoreResetGasEIP2200 - params.ColdSloadCostEIP2929}, nil } if value == (common.Hash{}) { // delete slot (2.1.2b) evm.StateDB.AddRefund(params.SstoreClearsScheduleRefundEIP3529) } // EIP-2200 original clause: // return params.SstoreResetGasEIP2200, nil // write existing slot (2.1.2) return GasCosts{RegularGas: cost.RegularGas + params.SstoreResetGasEIP2200 - params.ColdSloadCostEIP2929}, nil // write existing slot (2.1.2) } if original != (common.Hash{}) { if current == (common.Hash{}) { // recreate slot (2.2.1.1) evm.StateDB.SubRefund(params.SstoreClearsScheduleRefundEIP3529) } else if value == (common.Hash{}) { // delete slot (2.2.1.2) evm.StateDB.AddRefund(params.SstoreClearsScheduleRefundEIP3529) } } if original == value { if original == (common.Hash{}) { // reset to original inexistent slot (2.2.2.1) // EIP 2200 Original clause: //evm.StateDB.AddRefund(params.SstoreSetGasEIP2200 - params.SloadGasEIP2200) evm.StateDB.AddRefund(params.StorageCreationSize*evm.Context.CostPerGasByte + params.SstoreResetGasEIP2200 - params.ColdSloadCostEIP2929 - params.WarmStorageReadCostEIP2929) } else { // reset to original existing slot (2.2.2.2) // EIP 2200 Original clause: // evm.StateDB.AddRefund(params.SstoreResetGasEIP2200 - params.SloadGasEIP2200) // - SSTORE_RESET_GAS redefined as (5000 - COLD_SLOAD_COST) // - SLOAD_GAS redefined as WARM_STORAGE_READ_COST // Final: (5000 - COLD_SLOAD_COST) - WARM_STORAGE_READ_COST evm.StateDB.AddRefund((params.SstoreResetGasEIP2200 - params.ColdSloadCostEIP2929) - params.WarmStorageReadCostEIP2929) } } // EIP-2200 original clause: //return params.SloadGasEIP2200, nil // dirty update (2.2) return GasCosts{RegularGas: cost.RegularGas + params.WarmStorageReadCostEIP2929}, nil // dirty update (2.2) }