internal/impl/codec_extension.go - protobuf - Git at Google

 // Copyright 2019 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 impl

 import (
 	"sync"
 	"sync/atomic"

 	"google.golang.org/protobuf/encoding/protowire"
 	"google.golang.org/protobuf/internal/errors"
 	"google.golang.org/protobuf/reflect/protoreflect"
 )

 type extensionFieldInfo struct {
 	wiretag             uint64
 	tagsize             int
 	unmarshalNeedsValue bool
 	funcs               valueCoderFuncs
 	validation          validationInfo
 }

 func getExtensionFieldInfo(xt protoreflect.ExtensionType) *extensionFieldInfo {
 	if xi, ok := xt.(*ExtensionInfo); ok {
 		xi.lazyInit()
 		return xi.info
 	}
 	// Ideally we'd cache the resulting *extensionFieldInfo so we don't have to
 	// recompute this metadata repeatedly. But without support for something like
 	// weak references, such a cache would pin temporary values (like dynamic
 	// extension types, constructed for the duration of a user request) to the
 	// heap forever, causing memory usage of the cache to grow unbounded.
 	// See discussion in https://github.com/golang/protobuf/issues/1521.
 	return makeExtensionFieldInfo(xt.TypeDescriptor())
 }

 func makeExtensionFieldInfo(xd protoreflect.ExtensionDescriptor) *extensionFieldInfo {
 	var wiretag uint64
 	if !xd.IsPacked() {
 		wiretag = protowire.EncodeTag(xd.Number(), wireTypes[xd.Kind()])
 	} else {
 		wiretag = protowire.EncodeTag(xd.Number(), protowire.BytesType)
 	}
 	e := &extensionFieldInfo{
 		wiretag: wiretag,
 		tagsize: protowire.SizeVarint(wiretag),
 		funcs:   encoderFuncsForValue(xd),
 	}
 	// Does the unmarshal function need a value passed to it?
 	// This is true for composite types, where we pass in a message, list, or map to fill in,
 	// and for enums, where we pass in a prototype value to specify the concrete enum type.
 	switch xd.Kind() {
 	case protoreflect.MessageKind, protoreflect.GroupKind, protoreflect.EnumKind:
 		e.unmarshalNeedsValue = true
 	default:
 		if xd.Cardinality() == protoreflect.Repeated {
 			e.unmarshalNeedsValue = true
 		}
 	}
 	return e
 }

 type lazyExtensionValue struct {
 	atomicOnce uint32 // atomically set if value is valid
 	mu         sync.Mutex
 	xi         *extensionFieldInfo
 	value      protoreflect.Value
 	b          []byte
 	fn         func() protoreflect.Value
 }

 type ExtensionField struct {
 	typ protoreflect.ExtensionType

 	// value is either the value of GetValue,
 	// or a *lazyExtensionValue that then returns the value of GetValue.
 	value protoreflect.Value
 	lazy  *lazyExtensionValue
 }

 func (f *ExtensionField) appendLazyBytes(xt protoreflect.ExtensionType, xi *extensionFieldInfo, num protowire.Number, wtyp protowire.Type, b []byte) {
 	if f.lazy == nil {
 		f.lazy = &lazyExtensionValue{xi: xi}
 	}
 	f.typ = xt
 	f.lazy.xi = xi
 	f.lazy.b = protowire.AppendTag(f.lazy.b, num, wtyp)
 	f.lazy.b = append(f.lazy.b, b...)
 }

 func (f *ExtensionField) canLazy(xt protoreflect.ExtensionType) bool {
 	if f.typ == nil {
 		return true
 	}
 	if f.typ == xt && f.lazy != nil && atomic.LoadUint32(&f.lazy.atomicOnce) == 0 {
 		return true
 	}
 	return false
 }

 func (f *ExtensionField) lazyInit() {
 	f.lazy.mu.Lock()
 	defer f.lazy.mu.Unlock()
 	if atomic.LoadUint32(&f.lazy.atomicOnce) == 1 {
 		return
 	}
 	if f.lazy.xi != nil {
 		b := f.lazy.b
 		val := f.typ.New()
 		for len(b) > 0 {
 			var tag uint64
 			if b[0] < 0x80 {
 				tag = uint64(b[0])
 				b = b[1:]
 			} else if len(b) >= 2 && b[1] < 128 {
 				tag = uint64(b[0]&0x7f) + uint64(b[1])<<7
 				b = b[2:]
 			} else {
 				var n int
 				tag, n = protowire.ConsumeVarint(b)
 				if n < 0 {
 					panic(errors.New("bad tag in lazy extension decoding"))
 				}
 				b = b[n:]
 			}
 			num := protowire.Number(tag >> 3)
 			wtyp := protowire.Type(tag & 7)
 			var out unmarshalOutput
 			var err error
 			val, out, err = f.lazy.xi.funcs.unmarshal(b, val, num, wtyp, lazyUnmarshalOptions)
 			if err != nil {
 				panic(errors.New("decode failure in lazy extension decoding: %v", err))
 			}
 			b = b[out.n:]
 		}
 		f.lazy.value = val
 	} else {
 		f.lazy.value = f.lazy.fn()
 	}
 	f.lazy.xi = nil
 	f.lazy.fn = nil
 	f.lazy.b = nil
 	atomic.StoreUint32(&f.lazy.atomicOnce, 1)
 }

 // Set sets the type and value of the extension field.
 // This must not be called concurrently.
 func (f *ExtensionField) Set(t protoreflect.ExtensionType, v protoreflect.Value) {
 	f.typ = t
 	f.value = v
 	f.lazy = nil
 }

 // SetLazy sets the type and a value that is to be lazily evaluated upon first use.
 // This must not be called concurrently.
 func (f *ExtensionField) SetLazy(t protoreflect.ExtensionType, fn func() protoreflect.Value) {
 	f.typ = t
 	f.lazy = &lazyExtensionValue{fn: fn}
 }

 // Value returns the value of the extension field.
 // This may be called concurrently.
 func (f *ExtensionField) Value() protoreflect.Value {
 	if f.lazy != nil {
 		if atomic.LoadUint32(&f.lazy.atomicOnce) == 0 {
 			f.lazyInit()
 		}
 		return f.lazy.value
 	}
 	return f.value
 }

 // Type returns the type of the extension field.
 // This may be called concurrently.
 func (f ExtensionField) Type() protoreflect.ExtensionType {
 	return f.typ
 }

 // IsSet returns whether the extension field is set.
 // This may be called concurrently.
 func (f ExtensionField) IsSet() bool {
 	return f.typ != nil
 }

 // IsLazy reports whether a field is lazily encoded.
 // It is exported for testing.
 func IsLazy(m protoreflect.Message, fd protoreflect.FieldDescriptor) bool {
 	var mi *MessageInfo
 	var p pointer
 	switch m := m.(type) {
 	case *messageState:
 		mi = m.messageInfo()
 		p = m.pointer()
 	case *messageReflectWrapper:
 		mi = m.messageInfo()
 		p = m.pointer()
 	default:
 		return false
 	}
 	xd, ok := fd.(protoreflect.ExtensionTypeDescriptor)
 	if !ok {
 		return false
 	}
 	xt := xd.Type()
 	ext := mi.extensionMap(p)
 	if ext == nil {
 		return false
 	}
 	f, ok := (*ext)[int32(fd.Number())]
 	if !ok {
 		return false
 	}
 	return f.typ == xt && f.lazy != nil && atomic.LoadUint32(&f.lazy.atomicOnce) == 0
 }
	// Copyright 2019 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 impl

	import (
	"sync"
	"sync/atomic"

	"google.golang.org/protobuf/encoding/protowire"
	"google.golang.org/protobuf/internal/errors"
	"google.golang.org/protobuf/reflect/protoreflect"
	)

	type extensionFieldInfo struct {
	wiretag uint64
	tagsize int
	unmarshalNeedsValue bool
	funcs valueCoderFuncs
	validation validationInfo
	}

	func getExtensionFieldInfo(xt protoreflect.ExtensionType) *extensionFieldInfo {
	if xi, ok := xt.(*ExtensionInfo); ok {
	xi.lazyInit()
	return xi.info
	}
	// Ideally we'd cache the resulting *extensionFieldInfo so we don't have to
	// recompute this metadata repeatedly. But without support for something like
	// weak references, such a cache would pin temporary values (like dynamic
	// extension types, constructed for the duration of a user request) to the
	// heap forever, causing memory usage of the cache to grow unbounded.
	// See discussion in https://github.com/golang/protobuf/issues/1521.
	return makeExtensionFieldInfo(xt.TypeDescriptor())
	}

	func makeExtensionFieldInfo(xd protoreflect.ExtensionDescriptor) *extensionFieldInfo {
	var wiretag uint64
	if !xd.IsPacked() {
	wiretag = protowire.EncodeTag(xd.Number(), wireTypes[xd.Kind()])
	} else {
	wiretag = protowire.EncodeTag(xd.Number(), protowire.BytesType)
	}
	e := &extensionFieldInfo{
	wiretag: wiretag,
	tagsize: protowire.SizeVarint(wiretag),
	funcs: encoderFuncsForValue(xd),
	}
	// Does the unmarshal function need a value passed to it?
	// This is true for composite types, where we pass in a message, list, or map to fill in,
	// and for enums, where we pass in a prototype value to specify the concrete enum type.
	switch xd.Kind() {
	case protoreflect.MessageKind, protoreflect.GroupKind, protoreflect.EnumKind:
	e.unmarshalNeedsValue = true
	default:
	if xd.Cardinality() == protoreflect.Repeated {
	e.unmarshalNeedsValue = true
	}
	}
	return e
	}

	type lazyExtensionValue struct {
	atomicOnce uint32 // atomically set if value is valid
	mu sync.Mutex
	xi *extensionFieldInfo
	value protoreflect.Value
	b []byte
	fn func() protoreflect.Value
	}

	type ExtensionField struct {
	typ protoreflect.ExtensionType

	// value is either the value of GetValue,
	// or a *lazyExtensionValue that then returns the value of GetValue.
	value protoreflect.Value
	lazy *lazyExtensionValue
	}

	func (f ExtensionField) appendLazyBytes(xt protoreflect.ExtensionType, xi extensionFieldInfo, num protowire.Number, wtyp protowire.Type, b []byte) {
	if f.lazy == nil {
	f.lazy = &lazyExtensionValue{xi: xi}
	}
	f.typ = xt
	f.lazy.xi = xi
	f.lazy.b = protowire.AppendTag(f.lazy.b, num, wtyp)
	f.lazy.b = append(f.lazy.b, b...)
	}

	func (f *ExtensionField) canLazy(xt protoreflect.ExtensionType) bool {
	if f.typ == nil {
	return true
	}
	if f.typ == xt && f.lazy != nil && atomic.LoadUint32(&f.lazy.atomicOnce) == 0 {
	return true
	}
	return false
	}

	func (f *ExtensionField) lazyInit() {
	f.lazy.mu.Lock()
	defer f.lazy.mu.Unlock()
	if atomic.LoadUint32(&f.lazy.atomicOnce) == 1 {
	return
	}
	if f.lazy.xi != nil {
	b := f.lazy.b
	val := f.typ.New()
	for len(b) > 0 {
	var tag uint64
	if b[0] < 0x80 {
	tag = uint64(b[0])
	b = b[1:]
	} else if len(b) >= 2 && b[1] < 128 {
	tag = uint64(b[0]&0x7f) + uint64(b[1])<<7
	b = b[2:]
	} else {
	var n int
	tag, n = protowire.ConsumeVarint(b)
	if n < 0 {
	panic(errors.New("bad tag in lazy extension decoding"))
	}
	b = b[n:]
	}
	num := protowire.Number(tag >> 3)
	wtyp := protowire.Type(tag & 7)
	var out unmarshalOutput
	var err error
	val, out, err = f.lazy.xi.funcs.unmarshal(b, val, num, wtyp, lazyUnmarshalOptions)
	if err != nil {
	panic(errors.New("decode failure in lazy extension decoding: %v", err))
	}
	b = b[out.n:]
	}
	f.lazy.value = val
	} else {
	f.lazy.value = f.lazy.fn()
	}
	f.lazy.xi = nil
	f.lazy.fn = nil
	f.lazy.b = nil
	atomic.StoreUint32(&f.lazy.atomicOnce, 1)
	}

	// Set sets the type and value of the extension field.
	// This must not be called concurrently.
	func (f *ExtensionField) Set(t protoreflect.ExtensionType, v protoreflect.Value) {
	f.typ = t
	f.value = v
	f.lazy = nil
	}

	// SetLazy sets the type and a value that is to be lazily evaluated upon first use.
	// This must not be called concurrently.
	func (f *ExtensionField) SetLazy(t protoreflect.ExtensionType, fn func() protoreflect.Value) {
	f.typ = t
	f.lazy = &lazyExtensionValue{fn: fn}
	}

	// Value returns the value of the extension field.
	// This may be called concurrently.
	func (f *ExtensionField) Value() protoreflect.Value {
	if f.lazy != nil {
	if atomic.LoadUint32(&f.lazy.atomicOnce) == 0 {
	f.lazyInit()
	}
	return f.lazy.value
	}
	return f.value
	}

	// Type returns the type of the extension field.
	// This may be called concurrently.
	func (f ExtensionField) Type() protoreflect.ExtensionType {
	return f.typ
	}

	// IsSet returns whether the extension field is set.
	// This may be called concurrently.
	func (f ExtensionField) IsSet() bool {
	return f.typ != nil
	}

	// IsLazy reports whether a field is lazily encoded.
	// It is exported for testing.
	func IsLazy(m protoreflect.Message, fd protoreflect.FieldDescriptor) bool {
	var mi *MessageInfo
	var p pointer
	switch m := m.(type) {
	case *messageState:
	mi = m.messageInfo()
	p = m.pointer()
	case *messageReflectWrapper:
	mi = m.messageInfo()
	p = m.pointer()
	default:
	return false
	}
	xd, ok := fd.(protoreflect.ExtensionTypeDescriptor)
	if !ok {
	return false
	}
	xt := xd.Type()
	ext := mi.extensionMap(p)
	if ext == nil {
	return false
	}
	f, ok := (*ext)[int32(fd.Number())]
	if !ok {
	return false
	}
	return f.typ == xt && f.lazy != nil && atomic.LoadUint32(&f.lazy.atomicOnce) == 0
	}