vm

package
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Published: Dec 16, 2023 License: GPL-3.0 Imports: 19 Imported by: 0

Documentation

Overview

Package vm implements the Ethereum Virtual Machine.

The vm package implements one EVM, a byte code VM. The BC (Byte Code) VM loops over a set of bytes and executes them according to the set of rules defined in the Ethereum yellow paper.

Index

Constants

View Source
const (
	GasQuickStep   uint64 = 2
	GasFastestStep uint64 = 3
	GasFastStep    uint64 = 5
	GasMidStep     uint64 = 8
	GasSlowStep    uint64 = 10
	GasExtStep     uint64 = 20
)

Gas costs

View Source
const (
	DUP1 = 0x80 + iota
	DUP2
	DUP3
	DUP4
	DUP5
	DUP6
	DUP7
	DUP8
	DUP9
	DUP10
	DUP11
	DUP12
	DUP13
	DUP14
	DUP15
	DUP16
)

0x80 range - dups.

View Source
const (
	SWAP1 = 0x90 + iota
	SWAP2
	SWAP3
	SWAP4
	SWAP5
	SWAP6
	SWAP7
	SWAP8
	SWAP9
	SWAP10
	SWAP11
	SWAP12
	SWAP13
	SWAP14
	SWAP15
	SWAP16
)

0x90 range - swaps.

Variables

View Source
var (
	PrecompiledAddressesBerlin    []common.Address
	PrecompiledAddressesIstanbul  []common.Address
	PrecompiledAddressesByzantium []common.Address
	PrecompiledAddressesHomestead []common.Address
)
View Source
var (
	ErrOutOfGas                 = errors.New("out of gas")
	ErrCodeStoreOutOfGas        = errors.New("contract creation code storage out of gas")
	ErrDepth                    = errors.New("max call depth exceeded")
	ErrInsufficientBalance      = errors.New("insufficient balance for transfer")
	ErrContractAddressCollision = errors.New("contract address collision")
	ErrExecutionReverted        = errors.New("execution reverted")
	ErrMaxInitCodeSizeExceeded  = errors.New("max initcode size exceeded")
	ErrMaxCodeSizeExceeded      = errors.New("max code size exceeded")
	ErrInvalidJump              = errors.New("invalid jump destination")
	ErrWriteProtection          = errors.New("write protection")
	ErrReturnDataOutOfBounds    = errors.New("return data out of bounds")
	ErrGasUintOverflow          = errors.New("gas uint64 overflow")
	ErrInvalidCode              = errors.New("invalid code: must not begin with 0xef")
	ErrNonceUintOverflow        = errors.New("nonce uint64 overflow")
)

List evm execution errors

View Source
var PrecompiledContractsBLS = map[common.Address]PrecompiledContract{
	common.BytesToAddress([]byte{10}): &bls12381G1Add{},
	common.BytesToAddress([]byte{11}): &bls12381G1Mul{},
	common.BytesToAddress([]byte{12}): &bls12381G1MultiExp{},
	common.BytesToAddress([]byte{13}): &bls12381G2Add{},
	common.BytesToAddress([]byte{14}): &bls12381G2Mul{},
	common.BytesToAddress([]byte{15}): &bls12381G2MultiExp{},
	common.BytesToAddress([]byte{16}): &bls12381Pairing{},
	common.BytesToAddress([]byte{17}): &bls12381MapG1{},
	common.BytesToAddress([]byte{18}): &bls12381MapG2{},
}

PrecompiledContractsBLS contains the set of pre-compiled Ethereum contracts specified in EIP-2537. These are exported for testing purposes.

View Source
var PrecompiledContractsBerlin = map[common.Address]PrecompiledContract{
	common.BytesToAddress([]byte{1}): &ecrecover{},
	common.BytesToAddress([]byte{2}): &sha256hash{},
	common.BytesToAddress([]byte{3}): &ripemd160hash{},
	common.BytesToAddress([]byte{4}): &dataCopy{},
	common.BytesToAddress([]byte{5}): &bigModExp{eip2565: true},
	common.BytesToAddress([]byte{6}): &bn256AddIstanbul{},
	common.BytesToAddress([]byte{7}): &bn256ScalarMulIstanbul{},
	common.BytesToAddress([]byte{8}): &bn256PairingIstanbul{},
	common.BytesToAddress([]byte{9}): &blake2F{},
}

PrecompiledContractsBerlin contains the default set of pre-compiled Ethereum contracts used in the Berlin release.

View Source
var PrecompiledContractsByzantium = map[common.Address]PrecompiledContract{
	common.BytesToAddress([]byte{1}): &ecrecover{},
	common.BytesToAddress([]byte{2}): &sha256hash{},
	common.BytesToAddress([]byte{3}): &ripemd160hash{},
	common.BytesToAddress([]byte{4}): &dataCopy{},
	common.BytesToAddress([]byte{5}): &bigModExp{eip2565: false},
	common.BytesToAddress([]byte{6}): &bn256AddByzantium{},
	common.BytesToAddress([]byte{7}): &bn256ScalarMulByzantium{},
	common.BytesToAddress([]byte{8}): &bn256PairingByzantium{},
}

PrecompiledContractsByzantium contains the default set of pre-compiled Ethereum contracts used in the Byzantium release.

View Source
var PrecompiledContractsHomestead = map[common.Address]PrecompiledContract{
	common.BytesToAddress([]byte{1}): &ecrecover{},
	common.BytesToAddress([]byte{2}): &sha256hash{},
	common.BytesToAddress([]byte{3}): &ripemd160hash{},
	common.BytesToAddress([]byte{4}): &dataCopy{},
}

PrecompiledContractsHomestead contains the default set of pre-compiled Ethereum contracts used in the Frontier and Homestead releases.

View Source
var PrecompiledContractsIstanbul = map[common.Address]PrecompiledContract{
	common.BytesToAddress([]byte{1}): &ecrecover{},
	common.BytesToAddress([]byte{2}): &sha256hash{},
	common.BytesToAddress([]byte{3}): &ripemd160hash{},
	common.BytesToAddress([]byte{4}): &dataCopy{},
	common.BytesToAddress([]byte{5}): &bigModExp{eip2565: false},
	common.BytesToAddress([]byte{6}): &bn256AddIstanbul{},
	common.BytesToAddress([]byte{7}): &bn256ScalarMulIstanbul{},
	common.BytesToAddress([]byte{8}): &bn256PairingIstanbul{},
	common.BytesToAddress([]byte{9}): &blake2F{},
}

PrecompiledContractsIstanbul contains the default set of pre-compiled Ethereum contracts used in the Istanbul release.

Functions

func ActivateableEips

func ActivateableEips() []string

func ActivePrecompiles

func ActivePrecompiles(rules params.Rules) []common.Address

ActivePrecompiles returns the precompiles enabled with the current configuration.

func EnableEIP

func EnableEIP(eipNum int, jt *JumpTable) error

EnableEIP enables the given EIP on the config. This operation writes in-place, and callers need to ensure that the globally defined jump tables are not polluted.

func RunPrecompiledContract

func RunPrecompiledContract(p PrecompiledContract, input []byte, suppliedGas uint64) (ret []byte, remainingGas uint64, err error)

RunPrecompiledContract runs and evaluates the output of a precompiled contract. It returns - the returned bytes, - the _remaining_ gas, - any error that occurred

func ValidEip

func ValidEip(eipNum int) bool

Types

type AccountRef

type AccountRef common.Address

AccountRef implements ContractRef.

Account references are used during EVM initialisation and it's primary use is to fetch addresses. Removing this object proves difficult because of the cached jump destinations which are fetched from the parent contract (i.e. the caller), which is a ContractRef.

func (AccountRef) Address

func (ar AccountRef) Address() common.Address

Address casts AccountRef to a Address

type BlockContext

type BlockContext struct {
	// CanTransfer returns whether the account contains
	// sufficient ether to transfer the value
	CanTransfer CanTransferFunc
	// Transfer transfers ether from one account to the other
	Transfer TransferFunc
	// GetHash returns the hash corresponding to n
	GetHash GetHashFunc

	// Block information
	Coinbase    common.Address // Provides information for COINBASE
	GasLimit    uint64         // Provides information for GASLIMIT
	BlockNumber *big.Int       // Provides information for NUMBER
	Time        uint64         // Provides information for TIME
	Difficulty  *big.Int       // Provides information for DIFFICULTY
	BaseFee     *big.Int       // Provides information for BASEFEE
	Random      *common.Hash   // Provides information for PREVRANDAO
}

BlockContext provides the EVM with auxiliary information. Once provided it shouldn't be modified.

type CallContext

type CallContext interface {
	// Call calls another contract.
	Call(env *EVM, me ContractRef, addr common.Address, data []byte, gas, value *big.Int) ([]byte, error)
	// CallCode takes another contracts code and execute within our own context
	CallCode(env *EVM, me ContractRef, addr common.Address, data []byte, gas, value *big.Int) ([]byte, error)
	// DelegateCall is same as CallCode except sender and value is propagated from parent to child scope
	DelegateCall(env *EVM, me ContractRef, addr common.Address, data []byte, gas *big.Int) ([]byte, error)
	// Create creates a new contract
	Create(env *EVM, me ContractRef, data []byte, gas, value *big.Int) ([]byte, common.Address, error)
}

CallContext provides a basic interface for the EVM calling conventions. The EVM depends on this context being implemented for doing subcalls and initialising new EVM contracts.

type CanTransferFunc

type CanTransferFunc func(StateDB, common.Address, *big.Int) bool

CanTransferFunc is the signature of a transfer guard function

type Config

type Config struct {
	Tracer                  EVMLogger // Opcode logger
	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
}

Config are the configuration options for the Interpreter

type Contract

type Contract struct {
	// CallerAddress is the result of the caller which initialised this
	// contract. However when the "call method" is delegated this value
	// needs to be initialised to that of the caller's caller.
	CallerAddress common.Address

	Code     []byte
	CodeHash common.Hash
	CodeAddr *common.Address
	Input    []byte

	Gas uint64
	// contains filtered or unexported fields
}

Contract represents an ethereum contract in the state database. It contains the contract code, calling arguments. Contract implements ContractRef

func NewContract

func NewContract(caller ContractRef, object ContractRef, value *big.Int, gas uint64) *Contract

NewContract returns a new contract environment for the execution of EVM.

func (*Contract) Address

func (c *Contract) Address() common.Address

Address returns the contracts address

func (*Contract) AsDelegate

func (c *Contract) AsDelegate() *Contract

AsDelegate sets the contract to be a delegate call and returns the current contract (for chaining calls)

func (*Contract) Caller

func (c *Contract) Caller() common.Address

Caller returns the caller of the contract.

Caller will recursively call caller when the contract is a delegate call, including that of caller's caller.

func (*Contract) GetOp

func (c *Contract) GetOp(n uint64) OpCode

GetOp returns the n'th element in the contract's byte array

func (*Contract) SetCallCode

func (c *Contract) SetCallCode(addr *common.Address, hash common.Hash, code []byte)

SetCallCode sets the code of the contract and address of the backing data object

func (*Contract) SetCodeOptionalHash

func (c *Contract) SetCodeOptionalHash(addr *common.Address, codeAndHash *codeAndHash)

SetCodeOptionalHash can be used to provide code, but it's optional to provide hash. In case hash is not provided, the jumpdest analysis will not be saved to the parent context

func (*Contract) UseGas

func (c *Contract) UseGas(gas uint64) (ok bool)

UseGas attempts the use gas and subtracts it and returns true on success

func (*Contract) Value

func (c *Contract) Value() *big.Int

Value returns the contract's value (sent to it from it's caller)

type ContractRef

type ContractRef interface {
	Address() common.Address
}

ContractRef is a reference to the contract's backing object

type EVM

type EVM struct {
	// Context provides auxiliary blockchain related information
	Context BlockContext
	TxContext
	// StateDB gives access to the underlying state
	StateDB StateDB

	// virtual machine configuration options used to initialise the
	// evm.
	Config Config
	// contains filtered or unexported fields
}

EVM is the Ethereum Virtual Machine base object and provides the necessary tools to run a contract on the given state with the provided context. It should be noted that any error generated through any of the calls should be considered a revert-state-and-consume-all-gas operation, no checks on specific errors should ever be performed. The interpreter makes sure that any errors generated are to be considered faulty code.

The EVM should never be reused and is not thread safe.

func NewEVM

func NewEVM(blockCtx BlockContext, txCtx TxContext, statedb StateDB, chainConfig *params.ChainConfig, config Config) *EVM

NewEVM returns a new EVM. The returned EVM is not thread safe and should only ever be used *once*.

func (*EVM) Call

func (evm *EVM) Call(caller ContractRef, addr common.Address, input []byte, gas uint64, value *big.Int) (ret []byte, leftOverGas uint64, err error)

Call executes the contract associated with the addr with the given input as parameters. It also handles any necessary value transfer required and takes the necessary steps to create accounts and reverses the state in case of an execution error or failed value transfer.

func (*EVM) CallCode

func (evm *EVM) CallCode(caller ContractRef, addr common.Address, input []byte, gas uint64, value *big.Int) (ret []byte, leftOverGas uint64, err error)

CallCode executes the contract associated with the addr with the given input as parameters. It also handles any necessary value transfer required and takes the necessary steps to create accounts and reverses the state in case of an execution error or failed value transfer.

CallCode differs from Call in the sense that it executes the given address' code with the caller as context.

func (*EVM) Cancel

func (evm *EVM) Cancel()

Cancel cancels any running EVM operation. This may be called concurrently and it's safe to be called multiple times.

func (*EVM) Cancelled

func (evm *EVM) Cancelled() bool

Cancelled returns true if Cancel has been called

func (*EVM) ChainConfig

func (evm *EVM) ChainConfig() *params.ChainConfig

ChainConfig returns the environment's chain configuration

func (*EVM) Create

func (evm *EVM) Create(caller ContractRef, code []byte, gas uint64, value *big.Int) (ret []byte, contractAddr common.Address, leftOverGas uint64, err error)

Create creates a new contract using code as deployment code.

func (*EVM) Create2

func (evm *EVM) Create2(caller ContractRef, code []byte, gas uint64, endowment *big.Int, salt *uint256.Int) (ret []byte, contractAddr common.Address, leftOverGas uint64, err error)

Create2 creates a new contract using code as deployment code.

The different between Create2 with Create is Create2 uses keccak256(0xff ++ msg.sender ++ salt ++ keccak256(init_code))[12:] instead of the usual sender-and-nonce-hash as the address where the contract is initialized at.

func (*EVM) DelegateCall

func (evm *EVM) DelegateCall(caller ContractRef, addr common.Address, input []byte, gas uint64) (ret []byte, leftOverGas uint64, err error)

DelegateCall executes the contract associated with the addr with the given input as parameters. It reverses the state in case of an execution error.

DelegateCall differs from CallCode in the sense that it executes the given address' code with the caller as context and the caller is set to the caller of the caller.

func (*EVM) Interpreter

func (evm *EVM) Interpreter() *EVMInterpreter

Interpreter returns the current interpreter

func (*EVM) Reset

func (evm *EVM) Reset(txCtx TxContext, statedb StateDB)

Reset resets the EVM with a new transaction context.Reset This is not threadsafe and should only be done very cautiously.

func (*EVM) SetBlockContext

func (evm *EVM) SetBlockContext(blockCtx BlockContext)

SetBlockContext updates the block context of the EVM.

func (*EVM) StaticCall

func (evm *EVM) StaticCall(caller ContractRef, addr common.Address, input []byte, gas uint64) (ret []byte, leftOverGas uint64, err error)

StaticCall executes the contract associated with the addr with the given input as parameters while disallowing any modifications to the state during the call. Opcodes that attempt to perform such modifications will result in exceptions instead of performing the modifications.

type EVMInterpreter

type EVMInterpreter struct {
	// contains filtered or unexported fields
}

EVMInterpreter represents an EVM interpreter

func NewEVMInterpreter

func NewEVMInterpreter(evm *EVM) *EVMInterpreter

NewEVMInterpreter returns a new instance of the Interpreter.

func (*EVMInterpreter) Run

func (in *EVMInterpreter) Run(contract *Contract, input []byte, readOnly bool) (ret []byte, err error)

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.

type EVMLogger

type EVMLogger interface {
	// Transaction level
	CaptureTxStart(gasLimit uint64)
	CaptureTxEnd(restGas uint64)
	// Top call frame
	CaptureStart(env *EVM, from common.Address, to common.Address, create bool, input []byte, gas uint64, value *big.Int)
	CaptureEnd(output []byte, gasUsed uint64, err error)
	// Rest of call frames
	CaptureEnter(typ OpCode, from common.Address, to common.Address, input []byte, gas uint64, value *big.Int)
	CaptureExit(output []byte, gasUsed uint64, err error)
	// Opcode level
	CaptureState(pc uint64, op OpCode, gas, cost uint64, scope *ScopeContext, rData []byte, depth int, err error)
	CaptureFault(pc uint64, op OpCode, gas, cost uint64, scope *ScopeContext, depth int, err error)
}

EVMLogger is used to collect execution traces from an EVM transaction execution. CaptureState is called for each step of the VM with the current VM state. Note that reference types are actual VM data structures; make copies if you need to retain them beyond the current call.

type ErrInvalidOpCode

type ErrInvalidOpCode struct {
	// contains filtered or unexported fields
}

ErrInvalidOpCode wraps an evm error when an invalid opcode is encountered.

func (*ErrInvalidOpCode) Error

func (e *ErrInvalidOpCode) Error() string

type ErrStackOverflow

type ErrStackOverflow struct {
	// contains filtered or unexported fields
}

ErrStackOverflow wraps an evm error when the items on the stack exceeds the maximum allowance.

func (*ErrStackOverflow) Error

func (e *ErrStackOverflow) Error() string

type ErrStackUnderflow

type ErrStackUnderflow struct {
	// contains filtered or unexported fields
}

ErrStackUnderflow wraps an evm error when the items on the stack less than the minimal requirement.

func (*ErrStackUnderflow) Error

func (e *ErrStackUnderflow) Error() string

type GetHashFunc

type GetHashFunc func(uint64) common.Hash

GetHashFunc returns the n'th block hash in the blockchain and is used by the BLOCKHASH EVM op code.

type JumpTable

type JumpTable [256]*operation

JumpTable contains the EVM opcodes supported at a given fork.

func LookupInstructionSet

func LookupInstructionSet(rules params.Rules) (JumpTable, error)

LookupInstructionSet returns the instructionset for the fork configured by the rules.

type Memory

type Memory struct {
	// contains filtered or unexported fields
}

Memory implements a simple memory model for the ethereum virtual machine.

func NewMemory

func NewMemory() *Memory

NewMemory returns a new memory model.

func (*Memory) Data

func (m *Memory) Data() []byte

Data returns the backing slice

func (*Memory) GetCopy

func (m *Memory) GetCopy(offset, size int64) (cpy []byte)

GetCopy returns offset + size as a new slice

func (*Memory) GetPtr

func (m *Memory) GetPtr(offset, size int64) []byte

GetPtr returns the offset + size

func (*Memory) Len

func (m *Memory) Len() int

Len returns the length of the backing slice

func (*Memory) Resize

func (m *Memory) Resize(size uint64)

Resize resizes the memory to size

func (*Memory) Set

func (m *Memory) Set(offset, size uint64, value []byte)

Set sets offset + size to value

func (*Memory) Set32

func (m *Memory) Set32(offset uint64, val *uint256.Int)

Set32 sets the 32 bytes starting at offset to the value of val, left-padded with zeroes to 32 bytes.

type OpCode

type OpCode byte

OpCode is an EVM opcode

const (
	STOP       OpCode = 0x0
	ADD        OpCode = 0x1
	MUL        OpCode = 0x2
	SUB        OpCode = 0x3
	DIV        OpCode = 0x4
	SDIV       OpCode = 0x5
	MOD        OpCode = 0x6
	SMOD       OpCode = 0x7
	ADDMOD     OpCode = 0x8
	MULMOD     OpCode = 0x9
	EXP        OpCode = 0xa
	SIGNEXTEND OpCode = 0xb
)

0x0 range - arithmetic ops.

const (
	LT     OpCode = 0x10
	GT     OpCode = 0x11
	SLT    OpCode = 0x12
	SGT    OpCode = 0x13
	EQ     OpCode = 0x14
	ISZERO OpCode = 0x15
	AND    OpCode = 0x16
	OR     OpCode = 0x17
	XOR    OpCode = 0x18
	NOT    OpCode = 0x19
	BYTE   OpCode = 0x1a
	SHL    OpCode = 0x1b
	SHR    OpCode = 0x1c
	SAR    OpCode = 0x1d
)

0x10 range - comparison ops.

const (
	ADDRESS        OpCode = 0x30
	BALANCE        OpCode = 0x31
	ORIGIN         OpCode = 0x32
	CALLER         OpCode = 0x33
	CALLVALUE      OpCode = 0x34
	CALLDATALOAD   OpCode = 0x35
	CALLDATASIZE   OpCode = 0x36
	CALLDATACOPY   OpCode = 0x37
	CODESIZE       OpCode = 0x38
	CODECOPY       OpCode = 0x39
	GASPRICE       OpCode = 0x3a
	EXTCODESIZE    OpCode = 0x3b
	EXTCODECOPY    OpCode = 0x3c
	RETURNDATASIZE OpCode = 0x3d
	RETURNDATACOPY OpCode = 0x3e
	EXTCODEHASH    OpCode = 0x3f
)

0x30 range - closure state.

const (
	BLOCKHASH   OpCode = 0x40
	COINBASE    OpCode = 0x41
	TIMESTAMP   OpCode = 0x42
	NUMBER      OpCode = 0x43
	DIFFICULTY  OpCode = 0x44
	RANDOM      OpCode = 0x44 // Same as DIFFICULTY
	PREVRANDAO  OpCode = 0x44 // Same as DIFFICULTY
	GASLIMIT    OpCode = 0x45
	CHAINID     OpCode = 0x46
	SELFBALANCE OpCode = 0x47
	BASEFEE     OpCode = 0x48
)

0x40 range - block operations.

const (
	POP      OpCode = 0x50
	MLOAD    OpCode = 0x51
	MSTORE   OpCode = 0x52
	MSTORE8  OpCode = 0x53
	SLOAD    OpCode = 0x54
	SSTORE   OpCode = 0x55
	JUMP     OpCode = 0x56
	JUMPI    OpCode = 0x57
	PC       OpCode = 0x58
	MSIZE    OpCode = 0x59
	GAS      OpCode = 0x5a
	JUMPDEST OpCode = 0x5b
	PUSH0    OpCode = 0x5f
)

0x50 range - 'storage' and execution.

const (
	PUSH1 OpCode = 0x60 + iota
	PUSH2
	PUSH3
	PUSH4
	PUSH5
	PUSH6
	PUSH7
	PUSH8
	PUSH9
	PUSH10
	PUSH11
	PUSH12
	PUSH13
	PUSH14
	PUSH15
	PUSH16
	PUSH17
	PUSH18
	PUSH19
	PUSH20
	PUSH21
	PUSH22
	PUSH23
	PUSH24
	PUSH25
	PUSH26
	PUSH27
	PUSH28
	PUSH29
	PUSH30
	PUSH31
	PUSH32
)

0x60 range - pushes.

const (
	LOG0 OpCode = 0xa0 + iota
	LOG1
	LOG2
	LOG3
	LOG4
)

0xa0 range - logging ops.

const (
	TLOAD  OpCode = 0xb3
	TSTORE OpCode = 0xb4
)

0xb0 range.

const (
	CREATE       OpCode = 0xf0
	CALL         OpCode = 0xf1
	CALLCODE     OpCode = 0xf2
	RETURN       OpCode = 0xf3
	DELEGATECALL OpCode = 0xf4
	CREATE2      OpCode = 0xf5

	STATICCALL   OpCode = 0xfa
	REVERT       OpCode = 0xfd
	INVALID      OpCode = 0xfe
	SELFDESTRUCT OpCode = 0xff
)

0xf0 range - closures.

const (
	KECCAK256 OpCode = 0x20
)

0x20 range - crypto.

func StringToOp

func StringToOp(str string) OpCode

StringToOp finds the opcode whose name is stored in `str`.

func (OpCode) IsPush

func (op OpCode) IsPush() bool

IsPush specifies if an opcode is a PUSH opcode.

func (OpCode) String

func (op OpCode) String() string

type PrecompiledContract

type PrecompiledContract interface {
	RequiredGas(input []byte) uint64  // RequiredPrice calculates the contract gas use
	Run(input []byte) ([]byte, error) // Run runs the precompiled contract
}

PrecompiledContract is the basic interface for native Go contracts. The implementation requires a deterministic gas count based on the input size of the Run method of the contract.

type ScopeContext

type ScopeContext struct {
	Memory   *Memory
	Stack    *Stack
	Contract *Contract
}

ScopeContext contains the things that are per-call, such as stack and memory, but not transients like pc and gas

type Stack

type Stack struct {
	// contains filtered or unexported fields
}

Stack is an object for basic stack operations. Items popped to the stack are expected to be changed and modified. stack does not take care of adding newly initialised objects.

func (*Stack) Back

func (st *Stack) Back(n int) *uint256.Int

Back returns the n'th item in stack

func (*Stack) Data

func (st *Stack) Data() []uint256.Int

Data returns the underlying uint256.Int array.

type StateDB

type StateDB interface {
	CreateAccount(common.Address)

	SubBalance(common.Address, *big.Int)
	AddBalance(common.Address, *big.Int)
	GetBalance(common.Address) *big.Int

	GetNonce(common.Address) uint64
	SetNonce(common.Address, uint64)

	GetCodeHash(common.Address) common.Hash
	GetCode(common.Address) []byte
	SetCode(common.Address, []byte)
	GetCodeSize(common.Address) int

	AddRefund(uint64)
	SubRefund(uint64)
	GetRefund() uint64

	GetCommittedState(common.Address, common.Hash) common.Hash
	GetState(common.Address, common.Hash) common.Hash
	SetState(common.Address, common.Hash, common.Hash)

	GetTransientState(addr common.Address, key common.Hash) common.Hash
	SetTransientState(addr common.Address, key, value common.Hash)

	Suicide(common.Address) bool
	HasSuicided(common.Address) bool

	// Exist reports whether the given account exists in state.
	// Notably this should also return true for suicided accounts.
	Exist(common.Address) bool
	// Empty returns whether the given account is empty. Empty
	// is defined according to EIP161 (balance = nonce = code = 0).
	Empty(common.Address) bool

	AddressInAccessList(addr common.Address) bool
	SlotInAccessList(addr common.Address, slot common.Hash) (addressOk bool, slotOk bool)
	// AddAddressToAccessList adds the given address to the access list. This operation is safe to perform
	// even if the feature/fork is not active yet
	AddAddressToAccessList(addr common.Address)
	// AddSlotToAccessList adds the given (address,slot) to the access list. This operation is safe to perform
	// even if the feature/fork is not active yet
	AddSlotToAccessList(addr common.Address, slot common.Hash)
	Prepare(rules params.Rules, sender, coinbase common.Address, dest *common.Address, precompiles []common.Address, txAccesses types.AccessList)

	RevertToSnapshot(int)
	Snapshot() int

	AddLog(*types.Log)
	AddPreimage(common.Hash, []byte)
}

StateDB is an EVM database for full state querying.

type TransferFunc

type TransferFunc func(StateDB, common.Address, common.Address, *big.Int)

TransferFunc is the signature of a transfer function

type TxContext

type TxContext struct {
	// Message information
	Origin   common.Address // Provides information for ORIGIN
	GasPrice *big.Int       // Provides information for GASPRICE
}

TxContext provides the EVM with information about a transaction. All fields can change between transactions.

Directories

Path Synopsis
Package runtime provides a basic execution model for executing EVM code.
Package runtime provides a basic execution model for executing EVM code.

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