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send.go
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send.go
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package seth
import (
"encoding/binary"
"encoding/json"
"fmt"
"math/big"
"strings"
)
// EtherType represents a type in the
// Ethereum Contract ABI type system
// https://github.com/ethereum/wiki/wiki/Ethereum-Contract-ABI
type EtherType interface {
// EncodeABI encodes this type using the
// canonical contract ABI encoding
EncodeABI(v []byte) []byte
internal() // cannot be implemented outside this library
}
// EtherSlice is an EtherType that represents
// a dynamically-sized list (e.g. []address or []uint in solidity)
type EtherSlice interface {
// The implementation of EtherSlice.EncodeABI should
// only concatenate the raw slice values to the input,
// and not the slice length prefix.
EtherType
// Len should return the number of elements in the slice
Len() int
}
// EncodeABI implements EtherType
func (a *Address) EncodeABI(v []byte) []byte {
var word [32]byte
copy(word[12:], a[:])
return append(v, word[:]...)
}
func (a *Address) internal() {}
// EncodeABI implements EtherType
func (i *Int) EncodeABI(v []byte) []byte {
var w [32]byte
bits := (*big.Int)(i).Bytes()
if len(bits) > 32 {
panic("ABI encoding: integer overflow")
}
copy(w[32-len(bits):], bits)
return append(v, w[:]...)
}
func (i *Int) internal() {}
func (d *Data) EncodeABI(v []byte) []byte {
if len(*d) > 32 {
panic("can't encode data with len greater than 32")
}
var w [32]byte
copy(w[:], *d)
return append(v, w[:]...)
}
func (d *Data) internal() {}
// EncodeABI implements EtherType.EncodeABI
func (b *Bytes) EncodeABI(v []byte) []byte {
return append(v, padright(*b)...)
}
// Len implements EtherSlice.Len
func (b *Bytes) Len() int { return len(*b) }
func (b *Bytes) internal() {}
func padint(i int, v []byte) []byte {
var w [32]byte
binary.BigEndian.PutUint64(w[32-8:], uint64(i))
return append(v, w[:]...)
}
func padright(b []byte) []byte {
p := make([]byte, (len(b)+31)&-32)
copy(p, b)
return p
}
// IntSlice is an implementation of EtherSlice
// for a list of integers
type IntSlice []Int
// EncodeABI implements EtherType.EncodeABI
func (i *IntSlice) EncodeABI(v []byte) []byte {
for j := range *i {
v = (*i)[j].EncodeABI(v)
}
return v
}
// Len implements EtherSlice.Len
func (i *IntSlice) Len() int { return len(*i) }
func (i *IntSlice) internal() {}
// AddrSlice is an implementation of EtherSlice
// for a list of addresses
type AddrSlice []Address
func (a *AddrSlice) EncodeABI(v []byte) []byte {
for j := range *a {
v = (*a)[j].EncodeABI(v)
}
return v
}
// Len implements EtherSlice.Len
func (a *AddrSlice) Len() int { return len(*a) }
func (a *AddrSlice) internal() {}
type DataSlice []Data
func (d *DataSlice) EncodeABI(v []byte) []byte {
for j := range *d {
v = (*d)[j].EncodeABI(v)
}
return v
}
func (d *DataSlice) Len() int { return len(*d) }
func (d *DataSlice) internal() {}
// CallOpts describes a transaction (contract call).
type CallOpts struct {
From *Address `json:"from,omitempty"` // Sender address
To *Address `json:"to,omitempty"` // Contract address
Gas *Int `json:"gas,omitempty"` // Gas offered for call
GasPrice *Int `json:"gasPrice,omitempty"` // GasPrice offered for gas
Value *Int `json:"value,omitempty"` // Value to send
Data Data `json:"data"` // Input to the call
Nonce *Uint64 `json:"nonce,omitempty"` // Nonce of the call
}
// Transaction returns a transaction structure representing this call.
func (o *CallOpts) Transaction() *Transaction {
tx := &Transaction{
From: o.From,
To: o.To,
Gas: Uint64(o.Gas.Uint64()),
GasPrice: *o.GasPrice,
Input: o.Data,
}
if o.Value != nil {
tx.Value = *o.Value
}
if o.Nonce != nil {
tx.Nonce = *o.Nonce
}
return tx
}
const illegal = " \t\n\b-+/~!@#$%^&*=|;:\"<>\\?"
// check that the given arguments correspond
// to the arguments given in the function signature 'f'
// where 'f' is of the form
// name(type0,type1,type2)
func typecheck(f string, args []EtherType) {
if strings.ContainsAny(f, illegal) {
panic("illegal characters in function signature string")
}
lparen := strings.IndexByte(f, '(')
if lparen == -1 {
panic(f + " has no left paren")
}
rparen := strings.IndexByte(f, ')')
if rparen != len(f)-1 {
panic(f + " has a bad right paren")
}
var argstrings []string
if strings.Contains(f[lparen+1:rparen], ",") {
argstrings = strings.Split(f[lparen+1:rparen], ",")
if len(argstrings) != len(args) {
panic(fmt.Sprintf("mismatched argument lists: %d args vs %d given", len(argstrings), len(args)))
}
}
for i := range argstrings {
switch argstrings[i] {
case "address":
if _, ok := args[i].(*Address); !ok {
panic("address argument not an address")
}
case "uint", "uint256", "int", "int256":
if _, ok := args[i].(*Int); !ok {
panic(argstrings[i] + " argument not an Int")
}
case "bytes32":
if _, ok := args[i].(*Data); !ok {
if _, ok = args[i].(*Int); !ok {
panic(argstrings[i] + "argument not an Int or Data")
}
}
default:
if strings.HasSuffix(argstrings[i], "[]") {
if _, ok := args[i].(EtherSlice); !ok {
panic("argument not a slice")
}
}
// TODO: more typechecking
}
}
}
// ABIEncode encodes a function and its arguments
func ABIEncode(fn string, args ...EtherType) []byte {
typecheck(fn, args)
buf := make([]byte, 4, 4+len(args)*32)
fhash := HashString(fn)
copy(buf[:4], fhash[:4])
var dyn []byte
dynoff := len(args) * 32
for _, a := range args {
if es, ok := a.(EtherSlice); ok {
buf = padint(dynoff+len(dyn), buf)
dyn = padint(es.Len(), dyn)
dyn = a.EncodeABI(dyn)
continue
}
buf = a.EncodeABI(buf)
}
return append(buf, dyn...)
}
// EncodeCall sets up c.Data so that it reflects
// the given function signature and argument list.
//
// EncodeCall does some rudimentary sanity checking on
// the provided arguments and panics if the function signature
// string or argument list is malformed. For instance,
// for a function signature of "transfer(address,uint256)",
// EncodeCall would panic if two arguments weren't provided,
// or if they weren't an *Address and *Int, respectively.
func (c *CallOpts) EncodeCall(fn string, args ...EtherType) {
c.Data = Data(ABIEncode(fn, args...))
}
// Call makes a transaction call using the given CallOpts.
func (c *Client) Call(opts *CallOpts) (tx Hash, err error) {
buf, _ := json.Marshal(opts)
err = c.Do("eth_sendTransaction", []json.RawMessage{buf}, &tx)
return
}
// RawCall makes a transaction call using the given CallOpts.
func (c *Client) RawCall(raw []byte) (tx Hash, err error) {
buf, _ := json.Marshal(Data(raw))
err = c.Do("eth_sendRawTransaction", []json.RawMessage{buf}, &tx)
return
}
// EstimateGas estimates the gas cost of mining this call into the blockchain.
func (c *Client) EstimateGas(opts *CallOpts) (gas Int, err error) {
buf, _ := json.Marshal(opts)
err = c.Do("eth_estimateGas", []json.RawMessage{buf, rawpending}, &gas)
return
}
// ConstCall executes an EVM call without mining a transaction into the blockchain.
// If 'pending' is true, the transaction is executed in the pending block; otherwise
// the call is executed in the latest block. 'out' should be a type that can be
// unmarshaled from the JSON representation of the return value of the function.
func (c *Client) ConstCall(opts *CallOpts, out interface{}, pending bool) error {
bs := Latest
if pending {
bs = Pending
}
return c.ConstCallAt(opts, out, bs)
}
// ConstCallAt executes a call in the given block.
func (c *Client) ConstCallAt(opts *CallOpts, out interface{}, block int64) error {
buf, _ := json.Marshal(opts)
args := []json.RawMessage{buf, itobs(block)}
return c.Do("eth_call", args, out)
}
// StorageAt reads contract storage from a contract at a particular 256-bit address.
func (c *Client) StorageAt(addr *Address, offset *Hash, block int64) (Hash, error) {
buf, _ := json.Marshal(addr)
buf2, _ := json.Marshal(offset)
var buf3 []byte
switch block {
case -2:
buf3 = rawpending
case -1:
buf3 = rawlatest
default:
buf3 = itox(block)
}
var out Hash
err := c.Do("eth_getStorageAt", []json.RawMessage{buf, buf2, buf3}, &out)
return out, err
}
// ABIDecoder is an encoding.TextUnmarshaler
// that can unpack a JSON-RPC response into
// its constituent solidity arugments.
type ABIDecoder []interface{}
// NewABIDecoder constructs an ABIDecoder whose implementation
// of encoding.TextUnmarshaler unpacks arguments into the provided
// arguments.
func NewABIDecoder(args ...interface{}) *ABIDecoder {
v := ABIDecoder(args)
return &v
}
// UnmarshalText implements encoding.TextUnmarshaler
func (d *ABIDecoder) UnmarshalText(v []byte) error {
var data Data
err := data.UnmarshalText(v)
if err != nil {
return err
}
return DecodeABI([]byte(data), (*d)...)
}
// DecodeABI decodes a solidity return value into its
// constituent arguments.
//
// NOTE: Not all values are supported. Currently,
// supported types are:
//
// - integers -> all Go integer types, plus big.Int and seth.Int
// - bool -> bool
// - string -> string
// - address -> seth.Address
// - uint256[] -> seth.IntSlice
// - address[] -> seth.AddrSlice
// - bytes32[] -> seth.DataSlice
// - bytes -> []byte or seth.Bytes
//
func DecodeABI(v []byte, args ...interface{}) error {
var spare big.Int
cur := v
offset := int64(0)
for i, v := range args {
if len(cur[offset:]) == 0 {
return fmt.Errorf("no argument returned at position %d", i)
}
buf := cur[offset:]
if len(buf) > 32 {
buf = buf[:32]
}
// easy cases that don't involve converting types
// or handling variable-length types
did := true
switch v := v.(type) {
case *Data:
if len(*v) < 32 {
*v = make([]byte, 32)
}
copy(*v, cur)
case *Address:
copy(v[:], cur[12:])
case *Int:
(*big.Int)(v).SetBytes(buf)
case *big.Int:
v.SetBytes(buf)
default:
did = false
}
if did {
offset += 32
continue
}
spare.SetBytes(buf)
switch v := v.(type) {
case *string:
doff := spare.Int64()
if doff < offset+32 || doff >= int64(len(cur)-32) {
return fmt.Errorf("bad string offset %d for data length returned (%d)", doff, len(cur))
}
spare.SetBytes(cur[doff : doff+32])
length := spare.Int64()
dpos := doff + 32
if dpos+length >= int64(len(cur)) {
return fmt.Errorf("bad string length %d for data length returned (%d)", length, len(cur))
}
*v = string(cur[dpos : dpos+length])
case *[]byte:
doff := spare.Int64()
if doff < offset+32 || doff >= int64(len(cur)-32) {
return fmt.Errorf("bad bytes offset %d for data length returned (%d)", doff, len(cur))
}
spare.SetBytes(cur[doff : doff+32])
length := spare.Int64()
dpos := doff + 32
if dpos+length > int64(len(cur)) {
return fmt.Errorf("bad bytes length %d for data length returned (%d)", length, len(cur))
}
*v = make([]byte, length)
copy(*v, cur[dpos:dpos+length])
case *Bytes:
doff := spare.Int64()
if doff < offset+32 || doff >= int64(len(cur)-32) {
return fmt.Errorf("bad bytes offset %d for data length returned (%d)", doff, len(cur))
}
spare.SetBytes(cur[doff : doff+32])
length := spare.Int64()
dpos := doff + 32
if dpos+length > int64(len(cur)) {
return fmt.Errorf("bad bytes length %d for data length returned (%d)", length, len(cur))
}
*v = make([]byte, length)
copy(*v, cur[dpos:dpos+length])
case *IntSlice:
doff := spare.Int64()
if doff < offset+32 || doff >= int64(len(cur)-32) {
return fmt.Errorf("bad slice offset %d for data length returned (%d)", doff, len(cur))
}
spare.SetBytes(cur[doff : doff+32])
length := spare.Int64()
dpos := doff + 32
if dpos+(length*32) > int64(len(cur)) {
return fmt.Errorf("bad slice offset %d for data length returned (%d)", doff, len(cur))
}
s := make([]Int, length)
for i := range s {
o := int(dpos) + i*32
(*big.Int)(&s[i]).SetBytes(cur[o : o+32])
}
*v = IntSlice(s)
case *AddrSlice:
doff := spare.Int64()
if doff < offset+32 || doff >= int64(len(cur)-32) {
return fmt.Errorf("bad slice offset %d for data length returned (%d)", doff, len(cur))
}
spare.SetBytes(cur[doff : doff+32])
length := spare.Int64()
dpos := doff + 32
if dpos+(length*32) > int64(len(cur)) {
return fmt.Errorf("bad slice offset %d for data length returned (%d)", doff, len(cur))
}
s := make([]Address, length)
for i := range s {
o := int(dpos) + i*32
copy(s[i][:], cur[o+12:o+32])
}
*v = AddrSlice(s)
case *DataSlice:
doff := spare.Int64()
if doff < offset+32 || doff >= int64(len(cur)-32) {
return fmt.Errorf("bad slice offset %d for data length returned (%d)", doff, len(cur))
}
spare.SetBytes(cur[doff : doff+32])
length := spare.Int64()
dpos := doff + 32
if dpos+(length*32) > int64(len(cur)) {
return fmt.Errorf("bad slice offset %d for data length returned (%d)", doff, len(cur))
}
s := make([]Data, length)
for i := range s {
o := int(dpos) + i*32
copy(s[i][:], cur[o+12:o+32])
}
*v = DataSlice(s)
case *bool:
*v = spare.Sign() != 0
case *uint8:
*v = uint8(spare.Uint64())
case *uint16:
*v = uint16(spare.Uint64())
case *uint32:
*v = uint32(spare.Uint64())
case *uint64:
*v = uint64(spare.Uint64())
case *int8:
*v = int8(spare.Int64())
case *int16:
*v = int16(spare.Int64())
case *int32:
*v = int32(spare.Int64())
case *int64:
*v = int64(spare.Int64())
case *int:
*v = int(spare.Int64())
case *uint:
*v = uint(spare.Uint64())
default:
return fmt.Errorf("unrecognized type %T", v)
}
offset += 32
}
return nil
}