gopls/internal/util/frob/frob.go - tools.git - Git at Google

 // Copyright 2023 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 // Package frob is a fast restricted object encoder/decoder in the
 // spirit of encoding/gob.
 //
 // As with gob, types that recursively contain functions, channels,
 // and unsafe.Pointers cannot be encoded, but frob has these
 // additional restrictions:
 //
 //   - Interface values are not supported; this avoids the need for
 //     the encoding to describe types.
 //
 //   - Types that recursively contain private struct fields are not
 //     permitted.
 //
 //   - The encoding is unspecified and subject to change, so the encoder
 //     and decoder must exactly agree on their implementation and on the
 //     definitions of the target types.
 //
 //   - Lengths (of arrays, slices, and maps) are currently assumed to
 //     fit in 32 bits.
 //
 //   - There is no error handling. All errors are reported by panicking.
 //
 //   - Values are serialized as trees, not graphs, so shared subgraphs
 //     are encoded repeatedly.
 //
 //   - No attempt is made to detect cyclic data structures.
 package frob

 import (
 	"encoding/binary"
 	"fmt"
 	"math"
 	"reflect"
 	"sync"
 )

 // A Codec[T] is an immutable encoder and decoder for values of type T.
 type Codec[T any] struct{ frob *frob }

 // CodecFor[T] returns a codec for values of type T.
 // It panics if type T is unsuitable.
 func CodecFor[T any]() Codec[T] {
 	frobsMu.Lock()
 	defer frobsMu.Unlock()
 	return Codec[T]{frobFor(reflect.TypeOf((*T)(nil)).Elem())}
 }

 func (codec Codec[T]) Encode(v T) []byte          { return codec.frob.Encode(v) }
 func (codec Codec[T]) Decode(data []byte, ptr *T) { codec.frob.Decode(data, ptr) }

 var (
 	frobsMu sync.Mutex
 	frobs   = make(map[reflect.Type]*frob)
 )

 // A frob is an encoder/decoder for a specific type.
 type frob struct {
 	t     reflect.Type
 	kind  reflect.Kind
 	elems []*frob // elem (array/slice/ptr), key+value (map), fields (struct)
 }

 // frobFor returns the frob for a particular type.
 // Precondition: caller holds frobsMu.
 func frobFor(t reflect.Type) *frob {
 	fr, ok := frobs[t]
 	if !ok {
 		fr = &frob{t: t, kind: t.Kind()}
 		frobs[t] = fr

 		switch fr.kind {
 		case reflect.Bool,
 			reflect.Int,
 			reflect.Int8,
 			reflect.Int16,
 			reflect.Int32,
 			reflect.Int64,
 			reflect.Uint,
 			reflect.Uint8,
 			reflect.Uint16,
 			reflect.Uint32,
 			reflect.Uint64,
 			reflect.Uintptr,
 			reflect.Float32,
 			reflect.Float64,
 			reflect.Complex64,
 			reflect.Complex128,
 			reflect.String:

 		case reflect.Array,
 			reflect.Slice,
 			reflect.Pointer:
 			fr.addElem(fr.t.Elem())

 		case reflect.Map:
 			fr.addElem(fr.t.Key())
 			fr.addElem(fr.t.Elem())

 		case reflect.Struct:
 			for i := 0; i < fr.t.NumField(); i++ {
 				field := fr.t.Field(i)
 				if field.PkgPath != "" {
 					panic(fmt.Sprintf("unexported field %v", field))
 				}
 				fr.addElem(field.Type)
 			}

 		default:
 			// chan, func, interface, unsafe.Pointer
 			panic(fmt.Sprintf("type %v is not supported by frob", fr.t))
 		}
 	}
 	return fr
 }

 func (fr *frob) addElem(t reflect.Type) {
 	fr.elems = append(fr.elems, frobFor(t))
 }

 const magic = "frob"

 func (fr *frob) Encode(v any) []byte {
 	rv := reflect.ValueOf(v)
 	if rv.Type() != fr.t {
 		panic(fmt.Sprintf("got %v, want %v", rv.Type(), fr.t))
 	}
 	w := &writer{}
 	w.bytes([]byte(magic))
 	fr.encode(w, rv)
 	if uint64(len(w.data))>>32 != 0 {
 		panic("too large") // includes all cases where len doesn't fit in 32 bits
 	}
 	return w.data
 }

 // encode appends the encoding of value v, whose type must be fr.t.
 func (fr *frob) encode(out *writer, v reflect.Value) {
 	switch fr.kind {
 	case reflect.Bool:
 		var b byte
 		if v.Bool() {
 			b = 1
 		}
 		out.uint8(b)
 	case reflect.Int:
 		out.uint64(uint64(v.Int()))
 	case reflect.Int8:
 		out.uint8(uint8(v.Int()))
 	case reflect.Int16:
 		out.uint16(uint16(v.Int()))
 	case reflect.Int32:
 		out.uint32(uint32(v.Int()))
 	case reflect.Int64:
 		out.uint64(uint64(v.Int()))
 	case reflect.Uint:
 		out.uint64(v.Uint())
 	case reflect.Uint8:
 		out.uint8(uint8(v.Uint()))
 	case reflect.Uint16:
 		out.uint16(uint16(v.Uint()))
 	case reflect.Uint32:
 		out.uint32(uint32(v.Uint()))
 	case reflect.Uint64:
 		out.uint64(v.Uint())
 	case reflect.Uintptr:
 		out.uint64(v.Uint())
 	case reflect.Float32:
 		out.uint32(math.Float32bits(float32(v.Float())))
 	case reflect.Float64:
 		out.uint64(math.Float64bits(v.Float()))
 	case reflect.Complex64:
 		z := complex64(v.Complex())
 		out.uint32(math.Float32bits(real(z)))
 		out.uint32(math.Float32bits(imag(z)))
 	case reflect.Complex128:
 		z := v.Complex()
 		out.uint64(math.Float64bits(real(z)))
 		out.uint64(math.Float64bits(imag(z)))

 	case reflect.Array:
 		len := v.Type().Len()
 		elem := fr.elems[0]
 		for i := 0; i < len; i++ {
 			elem.encode(out, v.Index(i))
 		}

 	case reflect.Slice:
 		len := v.Len()
 		out.uint32(uint32(len))
 		if len > 0 {
 			elem := fr.elems[0]
 			if elem.kind == reflect.Uint8 {
 				// []byte fast path
 				out.bytes(v.Bytes())
 			} else {
 				for i := 0; i < len; i++ {
 					elem.encode(out, v.Index(i))
 				}
 			}
 		}

 	case reflect.Map:
 		len := v.Len()
 		out.uint32(uint32(len))
 		if len > 0 {
 			kfrob, vfrob := fr.elems[0], fr.elems[1]
 			for iter := v.MapRange(); iter.Next(); {
 				kfrob.encode(out, iter.Key())
 				vfrob.encode(out, iter.Value())
 			}
 		}

 	case reflect.Pointer:
 		if v.IsNil() {
 			out.uint8(0)
 		} else {
 			out.uint8(1)
 			fr.elems[0].encode(out, v.Elem())
 		}

 	case reflect.String:
 		len := v.Len()
 		out.uint32(uint32(len))
 		if len > 0 {
 			out.data = append(out.data, v.String()...)
 		}

 	case reflect.Struct:
 		for i, elem := range fr.elems {
 			elem.encode(out, v.Field(i))
 		}

 	default:
 		panic(fr.t)
 	}
 }

 func (fr *frob) Decode(data []byte, ptr any) {
 	rv := reflect.ValueOf(ptr).Elem()
 	if rv.Type() != fr.t {
 		panic(fmt.Sprintf("got %v, want %v", rv.Type(), fr.t))
 	}
 	rd := &reader{data}
 	if string(rd.bytes(4)) != magic {
 		panic("not a frob-encoded message")
 	}
 	fr.decode(rd, rv)
 	if len(rd.data) > 0 {
 		panic("surplus bytes")
 	}
 }

 // decode reads from in, decodes a value, and sets addr to it.
 // addr must be a zero-initialized addressable variable of type fr.t.
 func (fr *frob) decode(in *reader, addr reflect.Value) {
 	switch fr.kind {
 	case reflect.Bool:
 		addr.SetBool(in.uint8() != 0)
 	case reflect.Int:
 		addr.SetInt(int64(in.uint64()))
 	case reflect.Int8:
 		addr.SetInt(int64(in.uint8()))
 	case reflect.Int16:
 		addr.SetInt(int64(in.uint16()))
 	case reflect.Int32:
 		addr.SetInt(int64(in.uint32()))
 	case reflect.Int64:
 		addr.SetInt(int64(in.uint64()))
 	case reflect.Uint:
 		addr.SetUint(in.uint64())
 	case reflect.Uint8:
 		addr.SetUint(uint64(in.uint8()))
 	case reflect.Uint16:
 		addr.SetUint(uint64(in.uint16()))
 	case reflect.Uint32:
 		addr.SetUint(uint64(in.uint32()))
 	case reflect.Uint64:
 		addr.SetUint(in.uint64())
 	case reflect.Uintptr:
 		addr.SetUint(in.uint64())
 	case reflect.Float32:
 		addr.SetFloat(float64(math.Float32frombits(in.uint32())))
 	case reflect.Float64:
 		addr.SetFloat(math.Float64frombits(in.uint64()))
 	case reflect.Complex64:
 		addr.SetComplex(complex128(complex(
 			math.Float32frombits(in.uint32()),
 			math.Float32frombits(in.uint32()),
 		)))
 	case reflect.Complex128:
 		addr.SetComplex(complex(
 			math.Float64frombits(in.uint64()),
 			math.Float64frombits(in.uint64()),
 		))

 	case reflect.Array:
 		len := fr.t.Len()
 		for i := 0; i < len; i++ {
 			fr.elems[0].decode(in, addr.Index(i))
 		}

 	case reflect.Slice:
 		len := int(in.uint32())
 		if len > 0 {
 			elem := fr.elems[0]
 			if elem.kind == reflect.Uint8 {
 				// []byte fast path
 				// (Not addr.SetBytes: we must make a copy.)
 				addr.Set(reflect.AppendSlice(addr, reflect.ValueOf(in.bytes(len))))
 			} else {
 				addr.Set(reflect.MakeSlice(fr.t, len, len))
 				for i := 0; i < len; i++ {
 					elem.decode(in, addr.Index(i))
 				}
 			}
 		}

 	case reflect.Map:
 		len := int(in.uint32())
 		if len > 0 {
 			m := reflect.MakeMapWithSize(fr.t, len)
 			addr.Set(m)
 			kfrob, vfrob := fr.elems[0], fr.elems[1]
 			k := reflect.New(kfrob.t).Elem()
 			v := reflect.New(vfrob.t).Elem()
 			kzero := reflect.Zero(kfrob.t)
 			vzero := reflect.Zero(vfrob.t)
 			for i := 0; i < len; i++ {
 				// TODO(adonovan): use SetZero from go1.20.
 				// k.SetZero()
 				// v.SetZero()
 				k.Set(kzero)
 				v.Set(vzero)
 				kfrob.decode(in, k)
 				vfrob.decode(in, v)
 				m.SetMapIndex(k, v)
 			}
 		}

 	case reflect.Pointer:
 		isNil := in.uint8() == 0
 		if !isNil {
 			ptr := reflect.New(fr.elems[0].t)
 			addr.Set(ptr)
 			fr.elems[0].decode(in, ptr.Elem())
 		}

 	case reflect.String:
 		len := int(in.uint32())
 		if len > 0 {
 			addr.SetString(string(in.bytes(len)))
 		}

 	case reflect.Struct:
 		for i, elem := range fr.elems {
 			elem.decode(in, addr.Field(i))
 		}

 	default:
 		panic(fr.t)
 	}
 }

 var le = binary.LittleEndian

 type reader struct{ data []byte }

 func (r *reader) uint8() uint8 {
 	v := r.data[0]
 	r.data = r.data[1:]
 	return v
 }

 func (r *reader) uint16() uint16 {
 	v := le.Uint16(r.data)
 	r.data = r.data[2:]
 	return v
 }

 func (r *reader) uint32() uint32 {
 	v := le.Uint32(r.data)
 	r.data = r.data[4:]
 	return v
 }

 func (r *reader) uint64() uint64 {
 	v := le.Uint64(r.data)
 	r.data = r.data[8:]
 	return v
 }

 func (r *reader) bytes(n int) []byte {
 	v := r.data[:n]
 	r.data = r.data[n:]
 	return v
 }

 type writer struct{ data []byte }

 func (w *writer) uint8(v uint8)   { w.data = append(w.data, v) }
 func (w *writer) uint16(v uint16) { w.data = le.AppendUint16(w.data, v) }
 func (w *writer) uint32(v uint32) { w.data = le.AppendUint32(w.data, v) }
 func (w *writer) uint64(v uint64) { w.data = le.AppendUint64(w.data, v) }
 func (w *writer) bytes(v []byte)  { w.data = append(w.data, v...) }
	// Copyright 2023 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	// Package frob is a fast restricted object encoder/decoder in the
	// spirit of encoding/gob.
	//
	// As with gob, types that recursively contain functions, channels,
	// and unsafe.Pointers cannot be encoded, but frob has these
	// additional restrictions:
	//
	// - Interface values are not supported; this avoids the need for
	// the encoding to describe types.
	//
	// - Types that recursively contain private struct fields are not
	// permitted.
	//
	// - The encoding is unspecified and subject to change, so the encoder
	// and decoder must exactly agree on their implementation and on the
	// definitions of the target types.
	//
	// - Lengths (of arrays, slices, and maps) are currently assumed to
	// fit in 32 bits.
	//
	// - There is no error handling. All errors are reported by panicking.
	//
	// - Values are serialized as trees, not graphs, so shared subgraphs
	// are encoded repeatedly.
	//
	// - No attempt is made to detect cyclic data structures.
	package frob

	import (
	"encoding/binary"
	"fmt"
	"math"
	"reflect"
	"sync"
	)

	// A Codec[T] is an immutable encoder and decoder for values of type T.
	type Codec[T any] struct{ frob *frob }

	// CodecFor[T] returns a codec for values of type T.
	// It panics if type T is unsuitable.
	func CodecFor[T any]() Codec[T] {
	frobsMu.Lock()
	defer frobsMu.Unlock()
	return Codec[T]{frobFor(reflect.TypeOf((*T)(nil)).Elem())}
	}

	func (codec Codec[T]) Encode(v T) []byte { return codec.frob.Encode(v) }
	func (codec Codec[T]) Decode(data []byte, ptr *T) { codec.frob.Decode(data, ptr) }

	var (
	frobsMu sync.Mutex
	frobs = make(map[reflect.Type]*frob)
	)

	// A frob is an encoder/decoder for a specific type.
	type frob struct {
	t reflect.Type
	kind reflect.Kind
	elems []*frob // elem (array/slice/ptr), key+value (map), fields (struct)
	}

	// frobFor returns the frob for a particular type.
	// Precondition: caller holds frobsMu.
	func frobFor(t reflect.Type) *frob {
	fr, ok := frobs[t]
	if !ok {
	fr = &frob{t: t, kind: t.Kind()}
	frobs[t] = fr

	switch fr.kind {
	case reflect.Bool,
	reflect.Int,
	reflect.Int8,
	reflect.Int16,
	reflect.Int32,
	reflect.Int64,
	reflect.Uint,
	reflect.Uint8,
	reflect.Uint16,
	reflect.Uint32,
	reflect.Uint64,
	reflect.Uintptr,
	reflect.Float32,
	reflect.Float64,
	reflect.Complex64,
	reflect.Complex128,
	reflect.String:

	case reflect.Array,
	reflect.Slice,
	reflect.Pointer:
	fr.addElem(fr.t.Elem())

	case reflect.Map:
	fr.addElem(fr.t.Key())
	fr.addElem(fr.t.Elem())

	case reflect.Struct:
	for i := 0; i < fr.t.NumField(); i++ {
	field := fr.t.Field(i)
	if field.PkgPath != "" {
	panic(fmt.Sprintf("unexported field %v", field))
	}
	fr.addElem(field.Type)
	}

	default:
	// chan, func, interface, unsafe.Pointer
	panic(fmt.Sprintf("type %v is not supported by frob", fr.t))
	}
	}
	return fr
	}

	func (fr *frob) addElem(t reflect.Type) {
	fr.elems = append(fr.elems, frobFor(t))
	}

	const magic = "frob"

	func (fr *frob) Encode(v any) []byte {
	rv := reflect.ValueOf(v)
	if rv.Type() != fr.t {
	panic(fmt.Sprintf("got %v, want %v", rv.Type(), fr.t))
	}
	w := &writer{}
	w.bytes([]byte(magic))
	fr.encode(w, rv)
	if uint64(len(w.data))>>32 != 0 {
	panic("too large") // includes all cases where len doesn't fit in 32 bits
	}
	return w.data
	}

	// encode appends the encoding of value v, whose type must be fr.t.
	func (fr frob) encode(out writer, v reflect.Value) {
	switch fr.kind {
	case reflect.Bool:
	var b byte
	if v.Bool() {
	b = 1
	}
	out.uint8(b)
	case reflect.Int:
	out.uint64(uint64(v.Int()))
	case reflect.Int8:
	out.uint8(uint8(v.Int()))
	case reflect.Int16:
	out.uint16(uint16(v.Int()))
	case reflect.Int32:
	out.uint32(uint32(v.Int()))
	case reflect.Int64:
	out.uint64(uint64(v.Int()))
	case reflect.Uint:
	out.uint64(v.Uint())
	case reflect.Uint8:
	out.uint8(uint8(v.Uint()))
	case reflect.Uint16:
	out.uint16(uint16(v.Uint()))
	case reflect.Uint32:
	out.uint32(uint32(v.Uint()))
	case reflect.Uint64:
	out.uint64(v.Uint())
	case reflect.Uintptr:
	out.uint64(v.Uint())
	case reflect.Float32:
	out.uint32(math.Float32bits(float32(v.Float())))
	case reflect.Float64:
	out.uint64(math.Float64bits(v.Float()))
	case reflect.Complex64:
	z := complex64(v.Complex())
	out.uint32(math.Float32bits(real(z)))
	out.uint32(math.Float32bits(imag(z)))
	case reflect.Complex128:
	z := v.Complex()
	out.uint64(math.Float64bits(real(z)))
	out.uint64(math.Float64bits(imag(z)))

	case reflect.Array:
	len := v.Type().Len()
	elem := fr.elems[0]
	for i := 0; i < len; i++ {
	elem.encode(out, v.Index(i))
	}

	case reflect.Slice:
	len := v.Len()
	out.uint32(uint32(len))
	if len > 0 {
	elem := fr.elems[0]
	if elem.kind == reflect.Uint8 {
	// []byte fast path
	out.bytes(v.Bytes())
	} else {
	for i := 0; i < len; i++ {
	elem.encode(out, v.Index(i))
	}
	}
	}

	case reflect.Map:
	len := v.Len()
	out.uint32(uint32(len))
	if len > 0 {
	kfrob, vfrob := fr.elems[0], fr.elems[1]
	for iter := v.MapRange(); iter.Next(); {
	kfrob.encode(out, iter.Key())
	vfrob.encode(out, iter.Value())
	}
	}

	case reflect.Pointer:
	if v.IsNil() {
	out.uint8(0)
	} else {
	out.uint8(1)
	fr.elems[0].encode(out, v.Elem())
	}

	case reflect.String:
	len := v.Len()
	out.uint32(uint32(len))
	if len > 0 {
	out.data = append(out.data, v.String()...)
	}

	case reflect.Struct:
	for i, elem := range fr.elems {
	elem.encode(out, v.Field(i))
	}

	default:
	panic(fr.t)
	}
	}

	func (fr *frob) Decode(data []byte, ptr any) {
	rv := reflect.ValueOf(ptr).Elem()
	if rv.Type() != fr.t {
	panic(fmt.Sprintf("got %v, want %v", rv.Type(), fr.t))
	}
	rd := &reader{data}
	if string(rd.bytes(4)) != magic {
	panic("not a frob-encoded message")
	}
	fr.decode(rd, rv)
	if len(rd.data) > 0 {
	panic("surplus bytes")
	}
	}

	// decode reads from in, decodes a value, and sets addr to it.
	// addr must be a zero-initialized addressable variable of type fr.t.
	func (fr frob) decode(in reader, addr reflect.Value) {
	switch fr.kind {
	case reflect.Bool:
	addr.SetBool(in.uint8() != 0)
	case reflect.Int:
	addr.SetInt(int64(in.uint64()))
	case reflect.Int8:
	addr.SetInt(int64(in.uint8()))
	case reflect.Int16:
	addr.SetInt(int64(in.uint16()))
	case reflect.Int32:
	addr.SetInt(int64(in.uint32()))
	case reflect.Int64:
	addr.SetInt(int64(in.uint64()))
	case reflect.Uint:
	addr.SetUint(in.uint64())
	case reflect.Uint8:
	addr.SetUint(uint64(in.uint8()))
	case reflect.Uint16:
	addr.SetUint(uint64(in.uint16()))
	case reflect.Uint32:
	addr.SetUint(uint64(in.uint32()))
	case reflect.Uint64:
	addr.SetUint(in.uint64())
	case reflect.Uintptr:
	addr.SetUint(in.uint64())
	case reflect.Float32:
	addr.SetFloat(float64(math.Float32frombits(in.uint32())))
	case reflect.Float64:
	addr.SetFloat(math.Float64frombits(in.uint64()))
	case reflect.Complex64:
	addr.SetComplex(complex128(complex(
	math.Float32frombits(in.uint32()),
	math.Float32frombits(in.uint32()),
	)))
	case reflect.Complex128:
	addr.SetComplex(complex(
	math.Float64frombits(in.uint64()),
	math.Float64frombits(in.uint64()),
	))

	case reflect.Array:
	len := fr.t.Len()
	for i := 0; i < len; i++ {
	fr.elems[0].decode(in, addr.Index(i))
	}

	case reflect.Slice:
	len := int(in.uint32())
	if len > 0 {
	elem := fr.elems[0]
	if elem.kind == reflect.Uint8 {
	// []byte fast path
	// (Not addr.SetBytes: we must make a copy.)
	addr.Set(reflect.AppendSlice(addr, reflect.ValueOf(in.bytes(len))))
	} else {
	addr.Set(reflect.MakeSlice(fr.t, len, len))
	for i := 0; i < len; i++ {
	elem.decode(in, addr.Index(i))
	}
	}
	}

	case reflect.Map:
	len := int(in.uint32())
	if len > 0 {
	m := reflect.MakeMapWithSize(fr.t, len)
	addr.Set(m)
	kfrob, vfrob := fr.elems[0], fr.elems[1]
	k := reflect.New(kfrob.t).Elem()
	v := reflect.New(vfrob.t).Elem()
	kzero := reflect.Zero(kfrob.t)
	vzero := reflect.Zero(vfrob.t)
	for i := 0; i < len; i++ {
	// TODO(adonovan): use SetZero from go1.20.
	// k.SetZero()
	// v.SetZero()
	k.Set(kzero)
	v.Set(vzero)
	kfrob.decode(in, k)
	vfrob.decode(in, v)
	m.SetMapIndex(k, v)
	}
	}

	case reflect.Pointer:
	isNil := in.uint8() == 0
	if !isNil {
	ptr := reflect.New(fr.elems[0].t)
	addr.Set(ptr)
	fr.elems[0].decode(in, ptr.Elem())
	}

	case reflect.String:
	len := int(in.uint32())
	if len > 0 {
	addr.SetString(string(in.bytes(len)))
	}

	case reflect.Struct:
	for i, elem := range fr.elems {
	elem.decode(in, addr.Field(i))
	}

	default:
	panic(fr.t)
	}
	}

	var le = binary.LittleEndian

	type reader struct{ data []byte }

	func (r *reader) uint8() uint8 {
	v := r.data[0]
	r.data = r.data[1:]
	return v
	}

	func (r *reader) uint16() uint16 {
	v := le.Uint16(r.data)
	r.data = r.data[2:]
	return v
	}

	func (r *reader) uint32() uint32 {
	v := le.Uint32(r.data)
	r.data = r.data[4:]
	return v
	}

	func (r *reader) uint64() uint64 {
	v := le.Uint64(r.data)
	r.data = r.data[8:]
	return v
	}

	func (r *reader) bytes(n int) []byte {
	v := r.data[:n]
	r.data = r.data[n:]
	return v
	}

	type writer struct{ data []byte }

	func (w *writer) uint8(v uint8) { w.data = append(w.data, v) }
	func (w *writer) uint16(v uint16) { w.data = le.AppendUint16(w.data, v) }
	func (w *writer) uint32(v uint32) { w.data = le.AppendUint32(w.data, v) }
	func (w *writer) uint64(v uint64) { w.data = le.AppendUint64(w.data, v) }
	func (w *writer) bytes(v []byte) { w.data = append(w.data, v...) }