mirror of
https://gitlab.com/pulsechaincom/erigon-pulse.git
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382 lines
13 KiB
Go
382 lines
13 KiB
Go
// Copyright 2014 The go-ethereum Authors
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// This file is part of the go-ethereum library.
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//
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// The go-ethereum library is free software: you can redistribute it and/or modify
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// it under the terms of the GNU Lesser General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// The go-ethereum library is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU Lesser General Public License for more details.
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//
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// You should have received a copy of the GNU Lesser General Public License
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// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
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package core
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import (
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"fmt"
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"math"
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"github.com/holiman/uint256"
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"github.com/ledgerwatch/erigon/common"
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cmath "github.com/ledgerwatch/erigon/common/math"
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"github.com/ledgerwatch/erigon/core/types"
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"github.com/ledgerwatch/erigon/core/vm"
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"github.com/ledgerwatch/erigon/params"
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)
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/*
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The State Transitioning Model
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A state transition is a change made when a transaction is applied to the current world state
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The state transitioning model does all the necessary work to work out a valid new state root.
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1) Nonce handling
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2) Pre pay gas
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3) Create a new state object if the recipient is \0*32
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4) Value transfer
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== If contract creation ==
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4a) Attempt to run transaction data
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4b) If valid, use result as code for the new state object
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== end ==
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5) Run Script section
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6) Derive new state root
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*/
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type StateTransition struct {
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gp *GasPool
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msg Message
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gas uint64
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gasPrice *uint256.Int
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gasFeeCap *uint256.Int
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tip *uint256.Int
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initialGas uint64
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value *uint256.Int
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data []byte
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state vm.IntraBlockState
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evm *vm.EVM
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//some pre-allocated intermediate variables
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sharedBuyGas *uint256.Int
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sharedBuyGasBalance *uint256.Int
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}
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// Message represents a message sent to a contract.
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type Message interface {
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From() common.Address
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To() *common.Address
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GasPrice() *uint256.Int
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FeeCap() *uint256.Int
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Tip() *uint256.Int
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Gas() uint64
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Value() *uint256.Int
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Nonce() uint64
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CheckNonce() bool
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Data() []byte
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AccessList() types.AccessList
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}
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// ExecutionResult includes all output after executing given evm
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// message no matter the execution itself is successful or not.
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type ExecutionResult struct {
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UsedGas uint64 // Total used gas but include the refunded gas
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Err error // Any error encountered during the execution(listed in core/vm/errors.go)
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ReturnData []byte // Returned data from evm(function result or data supplied with revert opcode)
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}
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// Unwrap returns the internal evm error which allows us for further
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// analysis outside.
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func (result *ExecutionResult) Unwrap() error {
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return result.Err
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}
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// Failed returns the indicator whether the execution is successful or not
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func (result *ExecutionResult) Failed() bool { return result.Err != nil }
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// Return is a helper function to help caller distinguish between revert reason
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// and function return. Return returns the data after execution if no error occurs.
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func (result *ExecutionResult) Return() []byte {
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if result.Err != nil {
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return nil
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}
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return common.CopyBytes(result.ReturnData)
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}
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// Revert returns the concrete revert reason if the execution is aborted by `REVERT`
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// opcode. Note the reason can be nil if no data supplied with revert opcode.
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func (result *ExecutionResult) Revert() []byte {
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if result.Err != vm.ErrExecutionReverted {
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return nil
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}
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return common.CopyBytes(result.ReturnData)
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}
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// IntrinsicGas computes the 'intrinsic gas' for a message with the given data.
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func IntrinsicGas(data []byte, accessList types.AccessList, isContractCreation bool, isHomestead, isEIP2028 bool) (uint64, error) {
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// Set the starting gas for the raw transaction
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var gas uint64
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if isContractCreation && isHomestead {
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gas = params.TxGasContractCreation
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} else {
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gas = params.TxGas
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}
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// Bump the required gas by the amount of transactional data
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if len(data) > 0 {
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// Zero and non-zero bytes are priced differently
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var nz uint64
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for _, byt := range data {
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if byt != 0 {
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nz++
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}
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}
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// Make sure we don't exceed uint64 for all data combinations
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nonZeroGas := params.TxDataNonZeroGasFrontier
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if isEIP2028 {
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nonZeroGas = params.TxDataNonZeroGasEIP2028
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}
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if (math.MaxUint64-gas)/nonZeroGas < nz {
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return 0, ErrGasUintOverflow
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}
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gas += nz * nonZeroGas
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z := uint64(len(data)) - nz
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if (math.MaxUint64-gas)/params.TxDataZeroGas < z {
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return 0, ErrGasUintOverflow
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}
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gas += z * params.TxDataZeroGas
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}
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if accessList != nil {
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gas += uint64(len(accessList)) * params.TxAccessListAddressGas
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gas += uint64(accessList.StorageKeys()) * params.TxAccessListStorageKeyGas
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}
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return gas, nil
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}
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// NewStateTransition initialises and returns a new state transition object.
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func NewStateTransition(evm *vm.EVM, msg Message, gp *GasPool) *StateTransition {
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return &StateTransition{
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gp: gp,
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evm: evm,
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msg: msg,
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gasPrice: msg.GasPrice(),
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gasFeeCap: msg.FeeCap(),
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tip: msg.Tip(),
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value: msg.Value(),
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data: msg.Data(),
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state: evm.IntraBlockState,
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sharedBuyGas: uint256.NewInt(0),
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sharedBuyGasBalance: uint256.NewInt(0),
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}
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}
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// ApplyMessage computes the new state by applying the given message
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// against the old state within the environment.
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//
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// ApplyMessage returns the bytes returned by any EVM execution (if it took place),
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// the gas used (which includes gas refunds) and an error if it failed. An error always
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// indicates a core error meaning that the message would always fail for that particular
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// state and would never be accepted within a block.
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// `refunds` is false when it is not required to apply gas refunds
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// `gasBailout` is true when it is not required to fail transaction if the balance is not enough to pay gas.
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// for trace_call to replicate OE/Pariry behaviour
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func ApplyMessage(evm *vm.EVM, msg Message, gp *GasPool, refunds bool, gasBailout bool) (*ExecutionResult, error) {
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return NewStateTransition(evm, msg, gp).TransitionDb(refunds, gasBailout)
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}
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// to returns the recipient of the message.
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func (st *StateTransition) to() common.Address {
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if st.msg == nil || st.msg.To() == nil /* contract creation */ {
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return common.Address{}
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}
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return *st.msg.To()
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}
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func (st *StateTransition) buyGas(gasBailout bool) error {
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mgval := st.sharedBuyGas
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mgval.SetUint64(st.msg.Gas())
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mgval = mgval.Mul(mgval, st.gasPrice)
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balanceCheck := mgval
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if st.gasFeeCap != nil {
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balanceCheck = st.sharedBuyGasBalance.SetUint64(st.msg.Gas())
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balanceCheck = balanceCheck.Mul(balanceCheck, st.gasFeeCap)
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}
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if have, want := st.state.GetBalance(st.msg.From()), balanceCheck; have.Cmp(want) < 0 {
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if !gasBailout {
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return fmt.Errorf("%w: address %v have %v want %v", ErrInsufficientFunds, st.msg.From().Hex(), have, want)
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}
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} else {
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st.state.SubBalance(st.msg.From(), mgval)
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}
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if err := st.gp.SubGas(st.msg.Gas()); err != nil {
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if !gasBailout {
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return err
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}
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}
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st.gas += st.msg.Gas()
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st.initialGas = st.msg.Gas()
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return nil
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}
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// DESCRIBED: docs/programmers_guide/guide.md#nonce
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func (st *StateTransition) preCheck(gasBailout bool) error {
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// Make sure this transaction's nonce is correct.
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if st.msg.CheckNonce() {
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stNonce := st.state.GetNonce(st.msg.From())
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if msgNonce := st.msg.Nonce(); stNonce < msgNonce {
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return fmt.Errorf("%w: address %v, tx: %d state: %d", ErrNonceTooHigh,
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st.msg.From().Hex(), msgNonce, stNonce)
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} else if stNonce > msgNonce {
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return fmt.Errorf("%w: address %v, tx: %d state: %d", ErrNonceTooLow,
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st.msg.From().Hex(), msgNonce, stNonce)
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}
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}
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// Make sure the transaction gasFeeCap is greater than the block's baseFee.
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if st.evm.ChainRules.IsLondon {
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// Skip the checks if gas fields are zero and baseFee was explicitly disabled (eth_call)
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if !st.evm.Config.NoBaseFee || st.gasFeeCap.BitLen() > 0 || st.tip.BitLen() > 0 {
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if l := st.gasFeeCap.BitLen(); l > 256 {
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return fmt.Errorf("%w: address %v, gasFeeCap bit length: %d", ErrFeeCapVeryHigh,
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st.msg.From().Hex(), l)
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}
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if l := st.tip.BitLen(); l > 256 {
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return fmt.Errorf("%w: address %v, tip bit length: %d", ErrTipVeryHigh,
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st.msg.From().Hex(), l)
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}
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if st.gasFeeCap.Cmp(st.tip) < 0 {
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return fmt.Errorf("%w: address %v, tip: %s, gasFeeCap: %s", ErrTipAboveFeeCap,
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st.msg.From().Hex(), st.gasFeeCap, st.tip)
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}
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if st.gasFeeCap.Cmp(st.evm.Context.BaseFee) < 0 {
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return fmt.Errorf("%w: address %v, gasFeeCap: %d baseFee: %d", ErrFeeCapTooLow,
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st.msg.From().Hex(), st.gasFeeCap.Uint64(), st.evm.Context.BaseFee.Uint64())
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}
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}
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}
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return st.buyGas(gasBailout)
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}
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// TransitionDb will transition the state by applying the current message and
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// returning the evm execution result with following fields.
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//
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// - used gas:
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// total gas used (including gas being refunded)
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// - returndata:
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// the returned data from evm
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// - concrete execution error:
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// various **EVM** error which aborts the execution,
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// e.g. ErrOutOfGas, ErrExecutionReverted
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//
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// However if any consensus issue encountered, return the error directly with
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// nil evm execution result.
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func (st *StateTransition) TransitionDb(refunds bool, gasBailout bool) (*ExecutionResult, error) {
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// First check this message satisfies all consensus rules before
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// applying the message. The rules include these clauses
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//
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// 1. the nonce of the message caller is correct
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// 2. caller has enough balance to cover transaction fee(gaslimit * gasprice)
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// 3. the amount of gas required is available in the block
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// 4. the purchased gas is enough to cover intrinsic usage
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// 5. there is no overflow when calculating intrinsic gas
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// 6. caller has enough balance to cover asset transfer for **topmost** call
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// Check clauses 1-3, buy gas if everything is correct
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if err := st.preCheck(gasBailout); err != nil {
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return nil, err
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}
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msg := st.msg
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sender := vm.AccountRef(msg.From())
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homestead := st.evm.ChainRules.IsHomestead
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istanbul := st.evm.ChainRules.IsIstanbul
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london := st.evm.ChainRules.IsLondon
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contractCreation := msg.To() == nil
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// Check clauses 4-5, subtract intrinsic gas if everything is correct
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gas, err := IntrinsicGas(st.data, st.msg.AccessList(), contractCreation, homestead, istanbul)
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if err != nil {
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return nil, err
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}
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if st.gas < gas {
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return nil, fmt.Errorf("%w: have %d, want %d", ErrIntrinsicGas, st.gas, gas)
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}
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st.gas -= gas
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// Check clause 6
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var bailout bool
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if !msg.Value().IsZero() && !st.evm.Context.CanTransfer(st.state, msg.From(), msg.Value()) {
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if gasBailout {
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bailout = true
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} else {
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return nil, fmt.Errorf("%w: address %v", ErrInsufficientFundsForTransfer, msg.From().Hex())
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}
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}
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// Set up the initial access list.
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if st.evm.ChainRules.IsBerlin {
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st.state.PrepareAccessList(msg.From(), msg.To(), st.evm.ActivePrecompiles(), msg.AccessList())
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}
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var (
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ret []byte
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vmerr error // vm errors do not effect consensus and are therefore not assigned to err
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)
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if contractCreation {
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// The reason why we don't increment nonce here is that we need the original
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// nonce to calculate the address of the contract that is being created
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// It does get incremented inside the `Create` call, after the computation
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// of the contract's address, but before the execution of the code.
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ret, _, st.gas, vmerr = st.evm.Create(sender, st.data, st.gas, st.value)
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} else {
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// Increment the nonce for the next transaction
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st.state.SetNonce(msg.From(), st.state.GetNonce(sender.Address())+1)
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ret, st.gas, vmerr = st.evm.Call(sender, st.to(), st.data, st.gas, st.value, bailout)
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}
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if refunds {
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if london {
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// After EIP-3529: refunds are capped to gasUsed / 5
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st.refundGas(params.RefundQuotientEIP3529)
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} else {
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// Before EIP-3529: refunds were capped to gasUsed / 2
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st.refundGas(params.RefundQuotient)
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}
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}
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effectiveTip := st.gasPrice
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if st.evm.ChainRules.IsLondon {
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effectiveTip = cmath.Min256(st.tip, new(uint256.Int).Sub(st.gasFeeCap, st.evm.Context.BaseFee))
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}
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st.state.AddBalance(st.evm.Context.Coinbase, new(uint256.Int).Mul(new(uint256.Int).SetUint64(st.gasUsed()), effectiveTip))
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return &ExecutionResult{
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UsedGas: st.gasUsed(),
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Err: vmerr,
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ReturnData: ret,
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}, nil
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}
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func (st *StateTransition) refundGas(refundQuotient uint64) {
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// Apply refund counter, capped to half of the used gas.
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refund := st.gasUsed() / refundQuotient
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if refund > st.state.GetRefund() {
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refund = st.state.GetRefund()
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}
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st.gas += refund
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// Return ETH for remaining gas, exchanged at the original rate.
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remaining := new(uint256.Int).Mul(new(uint256.Int).SetUint64(st.gas), st.gasPrice)
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st.state.AddBalance(st.msg.From(), remaining)
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// Also return remaining gas to the block gas counter so it is
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// available for the next transaction.
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st.gp.AddGas(st.gas)
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}
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// gasUsed returns the amount of gas used up by the state transition.
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func (st *StateTransition) gasUsed() uint64 {
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return st.initialGas - st.gas
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}
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