// Copyright 2014 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 ( "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/common/math" "github.com/ethereum/go-ethereum/core/tracing" "github.com/ethereum/go-ethereum/crypto" "github.com/ethereum/go-ethereum/log" "github.com/holiman/uint256" ) // Config are the configuration options for the Interpreter type Config struct { Tracer *tracing.Hooks NoBaseFee bool // Forces the EIP-1559 baseFee to 0 (needed for 0 price calls) EnablePreimageRecording bool // Enables recording of SHA3/keccak preimages ExtraEips []int // Additional EIPS that are to be enabled } // ScopeContext contains the things that are per-call, such as stack and memory, // but not transients like pc and gas type ScopeContext struct { Memory *Memory Stack *Stack Contract *Contract } // MemoryData returns the underlying memory slice. Callers must not modify the contents // of the returned data. func (ctx *ScopeContext) MemoryData() []byte { if ctx.Memory == nil { return nil } return ctx.Memory.Data() } // MemoryData returns the stack data. Callers must not modify the contents // of the returned data. func (ctx *ScopeContext) StackData() []uint256.Int { if ctx.Stack == nil { return nil } return ctx.Stack.Data() } // Caller returns the current caller. func (ctx *ScopeContext) Caller() common.Address { return ctx.Contract.Caller() } // Address returns the address where this scope of execution is taking place. func (ctx *ScopeContext) Address() common.Address { return ctx.Contract.Address() } // CallValue returns the value supplied with this call. func (ctx *ScopeContext) CallValue() *uint256.Int { return ctx.Contract.Value() } // CallInput returns the input/calldata with this call. Callers must not modify // the contents of the returned data. func (ctx *ScopeContext) CallInput() []byte { return ctx.Contract.Input } // EVMInterpreter represents an EVM interpreter type EVMInterpreter struct { evm *EVM table *JumpTable hasher crypto.KeccakState // Keccak256 hasher instance shared across opcodes hasherBuf common.Hash // Keccak256 hasher result array shared across opcodes readOnly bool // Whether to throw on stateful modifications returnData []byte // Last CALL's return data for subsequent reuse } // NewEVMInterpreter returns a new instance of the Interpreter. func NewEVMInterpreter(evm *EVM) *EVMInterpreter { // If jump table was not initialised we set the default one. var table *JumpTable switch { case evm.chainRules.IsCancun: table = &cancunInstructionSet case evm.chainRules.IsShanghai: table = &shanghaiInstructionSet case evm.chainRules.IsMerge: table = &mergeInstructionSet case evm.chainRules.IsLondon: table = &londonInstructionSet case evm.chainRules.IsBerlin: table = &berlinInstructionSet case evm.chainRules.IsIstanbul: table = &istanbulInstructionSet case evm.chainRules.IsConstantinople: table = &constantinopleInstructionSet case evm.chainRules.IsByzantium: table = &byzantiumInstructionSet case evm.chainRules.IsEIP158: table = &spuriousDragonInstructionSet case evm.chainRules.IsEIP150: table = &tangerineWhistleInstructionSet case evm.chainRules.IsHomestead: table = &homesteadInstructionSet default: table = &frontierInstructionSet } var extraEips []int if len(evm.Config.ExtraEips) > 0 { // Deep-copy jumptable to prevent modification of opcodes in other tables table = copyJumpTable(table) } for _, eip := range evm.Config.ExtraEips { if err := EnableEIP(eip, table); err != nil { // Disable it, so caller can check if it's activated or not log.Error("EIP activation failed", "eip", eip, "error", err) } else { extraEips = append(extraEips, eip) } } evm.Config.ExtraEips = extraEips return &EVMInterpreter{evm: evm, table: table} } // Run loops and evaluates the contract's code with the given input data and returns // the return byte-slice and an error if one occurred. // // It's important to note that any errors returned by the interpreter should be // considered a revert-and-consume-all-gas operation except for // ErrExecutionReverted which means revert-and-keep-gas-left. func (in *EVMInterpreter) Run(contract *Contract, input []byte, readOnly bool) (ret []byte, err error) { // Increment the call depth which is restricted to 1024 in.evm.depth++ defer func() { in.evm.depth-- }() // Make sure the readOnly is only set if we aren't in readOnly yet. // This also makes sure that the readOnly flag isn't removed for child calls. if readOnly && !in.readOnly { in.readOnly = true defer func() { in.readOnly = false }() } // Reset the previous call's return data. It's unimportant to preserve the old buffer // as every returning call will return new data anyway. in.returnData = nil // Don't bother with the execution if there's no code. if len(contract.Code) == 0 { return nil, nil } var ( op OpCode // current opcode mem = NewMemory() // bound memory stack = newstack() // local stack callContext = &ScopeContext{ Memory: mem, Stack: stack, Contract: contract, } // For optimisation reason we're using uint64 as the program counter. // It's theoretically possible to go above 2^64. The YP defines the PC // to be uint256. Practically much less so feasible. pc = uint64(0) // program counter cost uint64 // copies used by tracer pcCopy uint64 // needed for the deferred EVMLogger gasCopy uint64 // for EVMLogger to log gas remaining before execution logged bool // deferred EVMLogger should ignore already logged steps res []byte // result of the opcode execution function debug = in.evm.Config.Tracer != nil ) // Don't move this deferred function, it's placed before the OnOpcode-deferred method, // so that it gets executed _after_: the OnOpcode needs the stacks before // they are returned to the pools defer func() { returnStack(stack) }() contract.Input = input if debug { defer func() { // this deferred method handles exit-with-error if err == nil { return } if !logged && in.evm.Config.Tracer.OnOpcode != nil { in.evm.Config.Tracer.OnOpcode(pcCopy, byte(op), gasCopy, cost, callContext, in.returnData, in.evm.depth, VMErrorFromErr(err)) } if logged && in.evm.Config.Tracer.OnFault != nil { in.evm.Config.Tracer.OnFault(pcCopy, byte(op), gasCopy, cost, callContext, in.evm.depth, VMErrorFromErr(err)) } }() } // The Interpreter main run loop (contextual). This loop runs until either an // explicit STOP, RETURN or SELFDESTRUCT is executed, an error occurred during // the execution of one of the operations or until the done flag is set by the // parent context. for { if debug { // Capture pre-execution values for tracing. logged, pcCopy, gasCopy = false, pc, contract.Gas } // Get the operation from the jump table and validate the stack to ensure there are // enough stack items available to perform the operation. op = contract.GetOp(pc) operation := in.table[op] cost = operation.constantGas // For tracing // Validate stack if sLen := stack.len(); sLen < operation.minStack { return nil, &ErrStackUnderflow{stackLen: sLen, required: operation.minStack} } else if sLen > operation.maxStack { return nil, &ErrStackOverflow{stackLen: sLen, limit: operation.maxStack} } if !contract.UseGas(cost, in.evm.Config.Tracer, tracing.GasChangeIgnored) { return nil, ErrOutOfGas } if operation.dynamicGas != nil { // All ops with a dynamic memory usage also has a dynamic gas cost. var memorySize uint64 // calculate the new memory size and expand the memory to fit // the operation // Memory check needs to be done prior to evaluating the dynamic gas portion, // to detect calculation overflows if operation.memorySize != nil { memSize, overflow := operation.memorySize(stack) if overflow { return nil, ErrGasUintOverflow } // memory is expanded in words of 32 bytes. Gas // is also calculated in words. if memorySize, overflow = math.SafeMul(toWordSize(memSize), 32); overflow { return nil, ErrGasUintOverflow } } // Consume the gas and return an error if not enough gas is available. // cost is explicitly set so that the capture state defer method can get the proper cost var dynamicCost uint64 dynamicCost, err = operation.dynamicGas(in.evm, contract, stack, mem, memorySize) cost += dynamicCost // for tracing if err != nil || !contract.UseGas(dynamicCost, in.evm.Config.Tracer, tracing.GasChangeIgnored) { return nil, ErrOutOfGas } // Do tracing before memory expansion if debug { if in.evm.Config.Tracer.OnGasChange != nil { in.evm.Config.Tracer.OnGasChange(gasCopy, gasCopy-cost, tracing.GasChangeCallOpCode) } if in.evm.Config.Tracer.OnOpcode != nil { in.evm.Config.Tracer.OnOpcode(pc, byte(op), gasCopy, cost, callContext, in.returnData, in.evm.depth, VMErrorFromErr(err)) logged = true } } if memorySize > 0 { mem.Resize(memorySize) } } else if debug { if in.evm.Config.Tracer.OnGasChange != nil { in.evm.Config.Tracer.OnGasChange(gasCopy, gasCopy-cost, tracing.GasChangeCallOpCode) } if in.evm.Config.Tracer.OnOpcode != nil { in.evm.Config.Tracer.OnOpcode(pc, byte(op), gasCopy, cost, callContext, in.returnData, in.evm.depth, VMErrorFromErr(err)) logged = true } } // execute the operation res, err = operation.execute(&pc, in, callContext) if err != nil { break } pc++ } if err == errStopToken { err = nil // clear stop token error } return res, err }