mirror
/
go-ethereum
mirror of https://github.com/ethereum/go-ethereum
2
0
Fork 1
Code Issues Releases Wiki Activity
Official Go implementation of the Ethereum protocol
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
15427 Commits
50 Branches
243 Tags
1010 MiB
Tag: Branch: Tree: master
Branches Tags
${ item.name }
Create tag ${ searchTerm }
Create branch ${ searchTerm }
from 'master'
${ noResults }
go-ethereum/rlp/rlpgen/testdata/nil.out.txt

290 lines
6.0 KiB
Raw Permalink Normal View History Unescape

rlp/rlpgen: RLP encoder code generator (#24251) This change adds a code generator tool for creating EncodeRLP method implementations. The generated methods will behave identically to the reflect-based encoder, but run faster because there is no reflection overhead. Package rlp now provides the EncoderBuffer type for incremental encoding. This is used by generated code, but the new methods can also be useful for hand-written encoders. There is also experimental support for generating DecodeRLP, and some new methods have been added to the existing Stream type to support this. Creating decoders with rlpgen is not recommended at this time because the generated methods create very poor error reporting. More detail about package rlp changes: * rlp: externalize struct field processing / validation This adds a new package, rlp/internal/rlpstruct, in preparation for the RLP encoder generator. I think the struct field rules are subtle enough to warrant extracting this into their own package, even though it means that a bunch of adapter code is needed for converting to/from rlpstruct.Type. * rlp: add more decoder methods (for rlpgen) This adds new methods on rlp.Stream: - Uint64, Uint32, Uint16, Uint8, BigInt - ReadBytes for decoding into []byte - MoreDataInList - useful for optional list elements * rlp: expose encoder buffer (for rlpgen) This exposes the internal encoder buffer type for use in EncodeRLP implementations. The new EncoderBuffer type is a sort-of 'opaque handle' for a pointer to encBuffer. It is implemented this way to ensure the global encBuffer pool is handled correctly.
3 years ago
package test
import "github.com/ethereum/go-ethereum/rlp"
import "io"
func (obj *Test) EncodeRLP(_w io.Writer) error {
w := rlp.NewEncoderBuffer(_w)
_tmp0 := w.List()
if obj.Uint8 == nil {
w.Write([]byte{0x80})
} else {
w.WriteUint64(uint64((*obj.Uint8)))
}
if obj.Uint8List == nil {
w.Write([]byte{0xC0})
} else {
w.WriteUint64(uint64((*obj.Uint8List)))
}
if obj.Uint32 == nil {
w.Write([]byte{0x80})
} else {
w.WriteUint64(uint64((*obj.Uint32)))
}
if obj.Uint32List == nil {
w.Write([]byte{0xC0})
} else {
w.WriteUint64(uint64((*obj.Uint32List)))
}
if obj.Uint64 == nil {
w.Write([]byte{0x80})
} else {
w.WriteUint64((*obj.Uint64))
}
if obj.Uint64List == nil {
w.Write([]byte{0xC0})
} else {
w.WriteUint64((*obj.Uint64List))
}
if obj.String == nil {
w.Write([]byte{0x80})
} else {
w.WriteString((*obj.String))
}
if obj.StringList == nil {
w.Write([]byte{0xC0})
} else {
w.WriteString((*obj.StringList))
}
if obj.ByteArray == nil {
w.Write([]byte{0x80})
} else {
w.WriteBytes(obj.ByteArray[:])
}
if obj.ByteArrayList == nil {
w.Write([]byte{0xC0})
} else {
w.WriteBytes(obj.ByteArrayList[:])
}
if obj.ByteSlice == nil {
w.Write([]byte{0x80})
} else {
w.WriteBytes((*obj.ByteSlice))
}
if obj.ByteSliceList == nil {
w.Write([]byte{0xC0})
} else {
w.WriteBytes((*obj.ByteSliceList))
}
if obj.Struct == nil {
w.Write([]byte{0xC0})
} else {
_tmp1 := w.List()
w.WriteUint64(uint64(obj.Struct.A))
w.ListEnd(_tmp1)
}
if obj.StructString == nil {
w.Write([]byte{0x80})
} else {
_tmp2 := w.List()
w.WriteUint64(uint64(obj.StructString.A))
w.ListEnd(_tmp2)
}
w.ListEnd(_tmp0)
return w.Flush()
}
func (obj *Test) DecodeRLP(dec *rlp.Stream) error {
var _tmp0 Test
{
if _, err := dec.List(); err != nil {
return err
}
// Uint8:
var _tmp2 *byte
if _tmp3, _tmp4, err := dec.Kind(); err != nil {
return err
} else if _tmp4 != 0 || _tmp3 != rlp.String {
_tmp1, err := dec.Uint8()
if err != nil {
return err
}
_tmp2 = &_tmp1
}
_tmp0.Uint8 = _tmp2
// Uint8List:
var _tmp6 *byte
if _tmp7, _tmp8, err := dec.Kind(); err != nil {
return err
} else if _tmp8 != 0 || _tmp7 != rlp.List {
_tmp5, err := dec.Uint8()
if err != nil {
return err
}
_tmp6 = &_tmp5
}
_tmp0.Uint8List = _tmp6
// Uint32:
var _tmp10 *uint32
if _tmp11, _tmp12, err := dec.Kind(); err != nil {
return err
} else if _tmp12 != 0 || _tmp11 != rlp.String {
_tmp9, err := dec.Uint32()
if err != nil {
return err
}
_tmp10 = &_tmp9
}
_tmp0.Uint32 = _tmp10
// Uint32List:
var _tmp14 *uint32
if _tmp15, _tmp16, err := dec.Kind(); err != nil {
return err
} else if _tmp16 != 0 || _tmp15 != rlp.List {
_tmp13, err := dec.Uint32()
if err != nil {
return err
}
_tmp14 = &_tmp13
}
_tmp0.Uint32List = _tmp14
// Uint64:
var _tmp18 *uint64
if _tmp19, _tmp20, err := dec.Kind(); err != nil {
return err
} else if _tmp20 != 0 || _tmp19 != rlp.String {
_tmp17, err := dec.Uint64()
if err != nil {
return err
}
_tmp18 = &_tmp17
}
_tmp0.Uint64 = _tmp18
// Uint64List:
var _tmp22 *uint64
if _tmp23, _tmp24, err := dec.Kind(); err != nil {
return err
} else if _tmp24 != 0 || _tmp23 != rlp.List {
_tmp21, err := dec.Uint64()
if err != nil {
return err
}
_tmp22 = &_tmp21
}
_tmp0.Uint64List = _tmp22
// String:
var _tmp26 *string
if _tmp27, _tmp28, err := dec.Kind(); err != nil {
return err
} else if _tmp28 != 0 || _tmp27 != rlp.String {
_tmp25, err := dec.String()
if err != nil {
return err
}
_tmp26 = &_tmp25
}
_tmp0.String = _tmp26
// StringList:
var _tmp30 *string
if _tmp31, _tmp32, err := dec.Kind(); err != nil {
return err
} else if _tmp32 != 0 || _tmp31 != rlp.List {
_tmp29, err := dec.String()
if err != nil {
return err
}
_tmp30 = &_tmp29
}
_tmp0.StringList = _tmp30
// ByteArray:
var _tmp34 *[3]byte
if _tmp35, _tmp36, err := dec.Kind(); err != nil {
return err
} else if _tmp36 != 0 || _tmp35 != rlp.String {
var _tmp33 [3]byte
if err := dec.ReadBytes(_tmp33[:]); err != nil {
return err
}
_tmp34 = &_tmp33
}
_tmp0.ByteArray = _tmp34
// ByteArrayList:
var _tmp38 *[3]byte
if _tmp39, _tmp40, err := dec.Kind(); err != nil {
return err
} else if _tmp40 != 0 || _tmp39 != rlp.List {
var _tmp37 [3]byte
if err := dec.ReadBytes(_tmp37[:]); err != nil {
return err
}
_tmp38 = &_tmp37
}
_tmp0.ByteArrayList = _tmp38
// ByteSlice:
var _tmp42 *[]byte
if _tmp43, _tmp44, err := dec.Kind(); err != nil {
return err
} else if _tmp44 != 0 || _tmp43 != rlp.String {
_tmp41, err := dec.Bytes()
if err != nil {
return err
}
_tmp42 = &_tmp41
}
_tmp0.ByteSlice = _tmp42
// ByteSliceList:
var _tmp46 *[]byte
if _tmp47, _tmp48, err := dec.Kind(); err != nil {
return err
} else if _tmp48 != 0 || _tmp47 != rlp.List {
_tmp45, err := dec.Bytes()
if err != nil {
return err
}
_tmp46 = &_tmp45
}
_tmp0.ByteSliceList = _tmp46
// Struct:
var _tmp51 *Aux
if _tmp52, _tmp53, err := dec.Kind(); err != nil {
return err
} else if _tmp53 != 0 || _tmp52 != rlp.List {
var _tmp49 Aux
{
if _, err := dec.List(); err != nil {
return err
}
// A:
_tmp50, err := dec.Uint32()
if err != nil {
return err
}
_tmp49.A = _tmp50
if err := dec.ListEnd(); err != nil {
return err
}
}
_tmp51 = &_tmp49
}
_tmp0.Struct = _tmp51
// StructString:
var _tmp56 *Aux
if _tmp57, _tmp58, err := dec.Kind(); err != nil {
return err
} else if _tmp58 != 0 || _tmp57 != rlp.String {
var _tmp54 Aux
{
if _, err := dec.List(); err != nil {
return err
}
// A:
_tmp55, err := dec.Uint32()
if err != nil {
return err
}
_tmp54.A = _tmp55
if err := dec.ListEnd(); err != nil {
return err
}
}
_tmp56 = &_tmp54
}
_tmp0.StructString = _tmp56
if err := dec.ListEnd(); err != nil {
return err
}
}
*obj = _tmp0
return nil
}