plugeth/rlp/encode.go
Felix Lange 552f5b2693 rlp: add functions for encoding
I'm reasonably confident that the encoding matches the output of
ethutil.Encode for values that it supports. Some of the tests have been
adpated from the Ethereum testing repository.

There are still TODOs in the code.
2015-01-15 11:00:19 +01:00

533 lines
14 KiB
Go

package rlp
import (
"fmt"
"io"
"math/big"
"reflect"
)
// TODO: put encbufs in a sync.Pool.
// Doing that requires zeroing the buffers after use.
// encReader will need to drop it's buffer when done.
var (
// Common encoded values.
// These are useful when implementing EncodeRLP.
EmptyString = []byte{0x80}
EmptyList = []byte{0xC0}
)
// Encoder is implemented by types that require custom
// encoding rules or want to encode private fields.
type Encoder interface {
// EncodeRLP should write the RLP encoding of its receiver to w.
// If the implementation is a pointer method, it may also be
// called for nil pointers.
//
// Implementations should generate valid RLP. The data written is
// not verified at the moment, but a future version might. It is
// recommended to write only a single value but writing multiple
// values or no value at all is also permitted.
EncodeRLP(io.Writer) error
}
// Encode writes the RLP encoding of val to w. Note that Encode may
// perform many small writes in some cases. Consider making w
// buffered.
//
// Encode uses the following type-dependent encoding rules:
//
// If the type implements the Encoder interface, Encode calls
// EncodeRLP. This is true even for nil pointers, please see the
// documentation for Encoder.
//
// To encode a pointer, the value being pointed to is encoded. For nil
// pointers, Encode will encode the zero value of the type. A nil
// pointer to a struct type always encodes as an empty RLP list.
//
// Struct values are encoded as an RLP list of all their encoded
// public fields. Recursive struct types are supported.
//
// To encode slices and arrays, the elements are encoded as an RLP
// list of the value's elements. Note that arrays and slices with
// element type uint8 or byte are always encoded as an RLP string.
//
// A Go string is encoded as an RLP string.
//
// An unsigned integer value is encoded as an RLP string. Zero always
// encodes as an empty RLP string. Encode also supports *big.Int.
//
// An interface value encodes as the value contained in the interface.
//
// Boolean values are not supported, nor are signed integers, floating
// point numbers, maps, channels and functions.
func Encode(w io.Writer, val interface{}) error {
if outer, ok := w.(*encbuf); ok {
// Encode was called by some type's EncodeRLP.
// Avoid copying by writing to the outer encbuf directly.
return outer.encode(val)
}
eb := newencbuf()
if err := eb.encode(val); err != nil {
return err
}
return eb.toWriter(w)
}
// EncodeBytes returns the RLP encoding of val.
// Please see the documentation of Encode for the encoding rules.
func EncodeToBytes(val interface{}) ([]byte, error) {
eb := newencbuf()
if err := eb.encode(val); err != nil {
return nil, err
}
return eb.toBytes(), nil
}
// EncodeReader returns a reader from which the RLP encoding of val
// can be read. The returned size is the total size of the encoded
// data.
//
// Please see the documentation of Encode for the encoding rules.
func EncodeToReader(val interface{}) (size int, r io.Reader, err error) {
eb := newencbuf()
if err := eb.encode(val); err != nil {
return 0, nil, err
}
return eb.size(), &encReader{buf: eb}, nil
}
type encbuf struct {
str []byte // string data, contains everything except list headers
lheads []*listhead // all list headers
lhsize int // sum of sizes of all encoded list headers
sizebuf []byte // 9-byte auxiliary buffer for uint encoding
}
type listhead struct {
offset int // index of this header in string data
size int // total size of encoded data (including list headers)
}
// encode writes head to the given buffer, which must be at least
// 9 bytes long. It returns the encoded bytes.
func (head *listhead) encode(buf []byte) []byte {
if head.size < 56 {
buf[0] = 0xC0 + byte(head.size)
return buf[:1]
} else {
sizesize := putint(buf[1:], uint64(head.size))
buf[0] = 0xF7 + byte(sizesize)
return buf[:sizesize+1]
}
}
func newencbuf() *encbuf {
return &encbuf{sizebuf: make([]byte, 9)}
}
// encbuf implements io.Writer so it can be passed it into EncodeRLP.
func (w *encbuf) Write(b []byte) (int, error) {
w.str = append(w.str, b...)
return len(b), nil
}
func (w *encbuf) encode(val interface{}) error {
rval := reflect.ValueOf(val)
ti, err := cachedTypeInfo(rval.Type())
if err != nil {
return err
}
return ti.writer(rval, w)
}
func (w *encbuf) encodeStringHeader(size int) {
if size < 56 {
w.str = append(w.str, 0x80+byte(size))
} else {
// TODO: encode to w.str directly
sizesize := putint(w.sizebuf[1:], uint64(size))
w.sizebuf[0] = 0xB7 + byte(sizesize)
w.str = append(w.str, w.sizebuf[:sizesize+1]...)
}
}
func (w *encbuf) encodeString(b []byte) {
w.encodeStringHeader(len(b))
w.str = append(w.str, b...)
}
func (w *encbuf) list() *listhead {
lh := &listhead{offset: len(w.str), size: w.lhsize}
w.lheads = append(w.lheads, lh)
return lh
}
func (w *encbuf) listEnd(lh *listhead) {
lh.size = w.size() - lh.offset - lh.size
if lh.size < 56 {
w.lhsize += 1 // length encoded into kind tag
} else {
w.lhsize += 1 + intsize(uint64(lh.size))
}
}
func (w *encbuf) size() int {
return len(w.str) + w.lhsize
}
func (w *encbuf) toBytes() []byte {
out := make([]byte, w.size())
strpos := 0
pos := 0
for _, head := range w.lheads {
// write string data before header
n := copy(out[pos:], w.str[strpos:head.offset])
pos += n
strpos += n
// write the header
enc := head.encode(out[pos:])
pos += len(enc)
}
// copy string data after the last list header
copy(out[pos:], w.str[strpos:])
return out
}
func (w *encbuf) toWriter(out io.Writer) (err error) {
strpos := 0
for _, head := range w.lheads {
// write string data before header
if head.offset-strpos > 0 {
n, err := out.Write(w.str[strpos:head.offset])
strpos += n
if err != nil {
return err
}
}
// write the header
enc := head.encode(w.sizebuf)
if _, err = out.Write(enc); err != nil {
return err
}
}
if strpos < len(w.str) {
// write string data after the last list header
_, err = out.Write(w.str[strpos:])
}
return err
}
// encReader is the io.Reader returned by EncodeToReader.
// It releases its encbuf at EOF.
type encReader struct {
buf *encbuf // the buffer we're reading from. this is nil when we're at EOF.
lhpos int // index of list header that we're reading
strpos int // current position in string buffer
piece []byte // next piece to be read
}
func (r *encReader) Read(b []byte) (n int, err error) {
for {
if r.piece = r.next(); r.piece == nil {
return n, io.EOF
}
nn := copy(b[n:], r.piece)
n += nn
if nn < len(r.piece) {
// piece didn't fit, see you next time.
r.piece = r.piece[nn:]
return n, nil
}
r.piece = nil
}
panic("not reached")
}
// next returns the next piece of data to be read.
// it returns nil at EOF.
func (r *encReader) next() []byte {
switch {
case r.piece != nil:
// There is still data available for reading.
return r.piece
case r.lhpos < len(r.buf.lheads):
// We're before the last list header.
head := r.buf.lheads[r.lhpos]
sizebefore := head.offset - r.strpos
if sizebefore > 0 {
// String data before header.
p := r.buf.str[r.strpos:head.offset]
r.strpos += sizebefore
return p
} else {
r.lhpos++
return head.encode(r.buf.sizebuf)
}
case r.strpos < len(r.buf.str):
// String data at the end, after all list headers.
p := r.buf.str[r.strpos:]
r.strpos = len(r.buf.str)
return p
default:
return nil
}
}
var (
encoderInterface = reflect.TypeOf(new(Encoder)).Elem()
emptyInterface = reflect.TypeOf(new(interface{})).Elem()
big0 = big.NewInt(0)
)
// makeWriter creates a writer function for the given type.
func makeWriter(typ reflect.Type) (writer, error) {
kind := typ.Kind()
switch {
case typ.Implements(encoderInterface):
return writeEncoder, nil
case kind != reflect.Ptr && reflect.PtrTo(typ).Implements(encoderInterface):
return writeEncoderNoPtr, nil
case typ == emptyInterface:
return writeInterface, nil
case typ.AssignableTo(reflect.PtrTo(bigInt)):
return writeBigIntPtr, nil
case typ.AssignableTo(bigInt):
return writeBigIntNoPtr, nil
case isUint(kind):
return writeUint, nil
case kind == reflect.String:
return writeString, nil
case kind == reflect.Slice && typ.Elem().Kind() == reflect.Uint8 && !typ.Elem().Implements(encoderInterface):
return writeBytes, nil
case kind == reflect.Slice || kind == reflect.Array:
return makeSliceWriter(typ)
case kind == reflect.Struct:
return makeStructWriter(typ)
case kind == reflect.Ptr:
return makePtrWriter(typ)
default:
return nil, fmt.Errorf("rlp: type %v is not RLP-serializable", typ)
}
}
func writeUint(val reflect.Value, w *encbuf) error {
i := val.Uint()
if i == 0 {
w.str = append(w.str, 0x80)
} else if i < 128 {
// fits single byte
w.str = append(w.str, byte(i))
} else {
// TODO: encode int to w.str directly
s := putint(w.sizebuf[1:], i)
w.sizebuf[0] = 0x80 + byte(s)
w.str = append(w.str, w.sizebuf[:s+1]...)
}
return nil
}
func writeBigIntPtr(val reflect.Value, w *encbuf) error {
return writeBigInt(val.Interface().(*big.Int), w)
}
func writeBigIntNoPtr(val reflect.Value, w *encbuf) error {
i := val.Interface().(big.Int)
return writeBigInt(&i, w)
}
func writeBigInt(i *big.Int, w *encbuf) error {
if cmp := i.Cmp(big0); cmp == -1 {
return fmt.Errorf("rlp: cannot encode negative *big.Int")
} else if cmp == 0 {
w.str = append(w.str, 0x80)
} else if bits := i.BitLen(); bits < 8 {
// fits single byte
w.str = append(w.str, byte(i.Uint64()))
} else {
w.encodeString(i.Bytes())
}
return nil
}
func writeBytes(val reflect.Value, w *encbuf) error {
w.encodeString(val.Bytes())
return nil
}
func writeString(val reflect.Value, w *encbuf) error {
s := val.String()
w.encodeStringHeader(len(s))
w.str = append(w.str, s...)
return nil
}
func writeEncoder(val reflect.Value, w *encbuf) error {
return val.Interface().(Encoder).EncodeRLP(w)
}
// writeEncoderNoPtr handles non-pointer values that implement Encoder
// with a pointer receiver.
func writeEncoderNoPtr(val reflect.Value, w *encbuf) error {
if !val.CanAddr() {
// We can't get the address. It would be possible make the
// value addressable by creating a shallow copy, but this
// creates other problems so we're not doing it (yet).
//
// package json simply doesn't call MarshalJSON for cases like
// this, but encodes the value as if it didn't implement the
// interface. We don't want to handle it that way.
return fmt.Errorf("rlp: game over: unadressable value of type %v, EncodeRLP is pointer method", val.Type())
}
return val.Addr().Interface().(Encoder).EncodeRLP(w)
}
func writeInterface(val reflect.Value, w *encbuf) error {
if val.IsNil() {
// Write empty list. This is consistent with the previous RLP
// encoder that we had and should therefore avoid any
// problems.
w.str = append(w.str, 0xC0)
return nil
}
eval := val.Elem()
ti, err := cachedTypeInfo(eval.Type())
if err != nil {
return err
}
return ti.writer(eval, w)
}
func makeSliceWriter(typ reflect.Type) (writer, error) {
etypeinfo, err := cachedTypeInfo1(typ.Elem())
if err != nil {
return nil, err
}
writer := func(val reflect.Value, w *encbuf) error {
lh := w.list()
vlen := val.Len()
for i := 0; i < vlen; i++ {
if err := etypeinfo.writer(val.Index(i), w); err != nil {
return err
}
}
w.listEnd(lh)
return nil
}
return writer, nil
}
func makeStructWriter(typ reflect.Type) (writer, error) {
fields, err := structFields(typ)
if err != nil {
return nil, err
}
writer := func(val reflect.Value, w *encbuf) error {
lh := w.list()
for _, f := range fields {
if err := f.info.writer(val.Field(f.index), w); err != nil {
return err
}
}
w.listEnd(lh)
return nil
}
return writer, nil
}
func makePtrWriter(typ reflect.Type) (writer, error) {
etypeinfo, err := cachedTypeInfo1(typ.Elem())
if err != nil {
return nil, err
}
zero := reflect.Zero(typ.Elem())
kind := typ.Elem().Kind()
writer := func(val reflect.Value, w *encbuf) error {
switch {
case !val.IsNil():
return etypeinfo.writer(val.Elem(), w)
case kind == reflect.Struct:
// encoding the zero value of a struct could trigger
// infinite recursion, avoid that.
w.listEnd(w.list())
return nil
default:
return etypeinfo.writer(zero, w)
}
}
return writer, err
}
// putint writes i to the beginning of b in with big endian byte
// order, using the least number of bytes needed to represent i.
func putint(b []byte, i uint64) (size int) {
switch {
case i < (1 << 8):
b[0] = byte(i)
return 1
case i < (1 << 16):
b[0] = byte(i >> 8)
b[1] = byte(i)
return 2
case i < (1 << 24):
b[0] = byte(i >> 16)
b[1] = byte(i >> 8)
b[2] = byte(i)
return 3
case i < (1 << 32):
b[0] = byte(i >> 24)
b[1] = byte(i >> 16)
b[2] = byte(i >> 8)
b[3] = byte(i)
return 4
case i < (1 << 40):
b[0] = byte(i >> 32)
b[1] = byte(i >> 24)
b[2] = byte(i >> 16)
b[3] = byte(i >> 8)
b[4] = byte(i)
return 5
case i < (1 << 48):
b[0] = byte(i >> 40)
b[1] = byte(i >> 32)
b[2] = byte(i >> 24)
b[3] = byte(i >> 16)
b[4] = byte(i >> 8)
b[5] = byte(i)
return 6
case i < (1 << 56):
b[0] = byte(i >> 48)
b[1] = byte(i >> 40)
b[2] = byte(i >> 32)
b[3] = byte(i >> 24)
b[4] = byte(i >> 16)
b[5] = byte(i >> 8)
b[6] = byte(i)
return 7
default:
b[0] = byte(i >> 56)
b[1] = byte(i >> 48)
b[2] = byte(i >> 40)
b[3] = byte(i >> 32)
b[4] = byte(i >> 24)
b[5] = byte(i >> 16)
b[6] = byte(i >> 8)
b[7] = byte(i)
return 8
}
}
// intsize computes the minimum number of bytes required to store i.
func intsize(i uint64) (size int) {
for size = 1; ; size++ {
if i >>= 8; i == 0 {
return size
}
}
panic("not reached")
}