vendor/github.com/gogo/protobuf/proto/pointer_reflect.go - voltha-openolt-adapter - Gitiles

 // Go support for Protocol Buffers - Google's data interchange format
 //
 // Copyright 2012 The Go Authors.  All rights reserved.
 // https://github.com/golang/protobuf
 //
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 // notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 // copyright notice, this list of conditions and the following disclaimer
 // in the documentation and/or other materials provided with the
 // distribution.
 //     * Neither the name of Google Inc. nor the names of its
 // contributors may be used to endorse or promote products derived from
 // this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 // +build purego appengine js

 // This file contains an implementation of proto field accesses using package reflect.
 // It is slower than the code in pointer_unsafe.go but it avoids package unsafe and can
 // be used on App Engine.

 package proto

 import (
 	"reflect"
 	"sync"
 )

 const unsafeAllowed = false

 // A field identifies a field in a struct, accessible from a pointer.
 // In this implementation, a field is identified by the sequence of field indices
 // passed to reflect's FieldByIndex.
 type field []int

 // toField returns a field equivalent to the given reflect field.
 func toField(f *reflect.StructField) field {
 	return f.Index
 }

 // invalidField is an invalid field identifier.
 var invalidField = field(nil)

 // zeroField is a noop when calling pointer.offset.
 var zeroField = field([]int{})

 // IsValid reports whether the field identifier is valid.
 func (f field) IsValid() bool { return f != nil }

 // The pointer type is for the table-driven decoder.
 // The implementation here uses a reflect.Value of pointer type to
 // create a generic pointer. In pointer_unsafe.go we use unsafe
 // instead of reflect to implement the same (but faster) interface.
 type pointer struct {
 	v reflect.Value
 }

 // toPointer converts an interface of pointer type to a pointer
 // that points to the same target.
 func toPointer(i *Message) pointer {
 	return pointer{v: reflect.ValueOf(*i)}
 }

 // toAddrPointer converts an interface to a pointer that points to
 // the interface data.
 func toAddrPointer(i *interface{}, isptr bool) pointer {
 	v := reflect.ValueOf(*i)
 	u := reflect.New(v.Type())
 	u.Elem().Set(v)
 	return pointer{v: u}
 }

 // valToPointer converts v to a pointer.  v must be of pointer type.
 func valToPointer(v reflect.Value) pointer {
 	return pointer{v: v}
 }

 // offset converts from a pointer to a structure to a pointer to
 // one of its fields.
 func (p pointer) offset(f field) pointer {
 	return pointer{v: p.v.Elem().FieldByIndex(f).Addr()}
 }

 func (p pointer) isNil() bool {
 	return p.v.IsNil()
 }

 // grow updates the slice s in place to make it one element longer.
 // s must be addressable.
 // Returns the (addressable) new element.
 func grow(s reflect.Value) reflect.Value {
 	n, m := s.Len(), s.Cap()
 	if n < m {
 		s.SetLen(n + 1)
 	} else {
 		s.Set(reflect.Append(s, reflect.Zero(s.Type().Elem())))
 	}
 	return s.Index(n)
 }

 func (p pointer) toInt64() *int64 {
 	return p.v.Interface().(*int64)
 }
 func (p pointer) toInt64Ptr() **int64 {
 	return p.v.Interface().(**int64)
 }
 func (p pointer) toInt64Slice() *[]int64 {
 	return p.v.Interface().(*[]int64)
 }

 var int32ptr = reflect.TypeOf((*int32)(nil))

 func (p pointer) toInt32() *int32 {
 	return p.v.Convert(int32ptr).Interface().(*int32)
 }

 // The toInt32Ptr/Slice methods don't work because of enums.
 // Instead, we must use set/get methods for the int32ptr/slice case.
 /*
 	func (p pointer) toInt32Ptr() **int32 {
 		return p.v.Interface().(**int32)
 }
 	func (p pointer) toInt32Slice() *[]int32 {
 		return p.v.Interface().(*[]int32)
 }
 */
 func (p pointer) getInt32Ptr() *int32 {
 	if p.v.Type().Elem().Elem() == reflect.TypeOf(int32(0)) {
 		// raw int32 type
 		return p.v.Elem().Interface().(*int32)
 	}
 	// an enum
 	return p.v.Elem().Convert(int32PtrType).Interface().(*int32)
 }
 func (p pointer) setInt32Ptr(v int32) {
 	// Allocate value in a *int32. Possibly convert that to a *enum.
 	// Then assign it to a **int32 or **enum.
 	// Note: we can convert *int32 to *enum, but we can't convert
 	// **int32 to **enum!
 	p.v.Elem().Set(reflect.ValueOf(&v).Convert(p.v.Type().Elem()))
 }

 // getInt32Slice copies []int32 from p as a new slice.
 // This behavior differs from the implementation in pointer_unsafe.go.
 func (p pointer) getInt32Slice() []int32 {
 	if p.v.Type().Elem().Elem() == reflect.TypeOf(int32(0)) {
 		// raw int32 type
 		return p.v.Elem().Interface().([]int32)
 	}
 	// an enum
 	// Allocate a []int32, then assign []enum's values into it.
 	// Note: we can't convert []enum to []int32.
 	slice := p.v.Elem()
 	s := make([]int32, slice.Len())
 	for i := 0; i < slice.Len(); i++ {
 		s[i] = int32(slice.Index(i).Int())
 	}
 	return s
 }

 // setInt32Slice copies []int32 into p as a new slice.
 // This behavior differs from the implementation in pointer_unsafe.go.
 func (p pointer) setInt32Slice(v []int32) {
 	if p.v.Type().Elem().Elem() == reflect.TypeOf(int32(0)) {
 		// raw int32 type
 		p.v.Elem().Set(reflect.ValueOf(v))
 		return
 	}
 	// an enum
 	// Allocate a []enum, then assign []int32's values into it.
 	// Note: we can't convert []enum to []int32.
 	slice := reflect.MakeSlice(p.v.Type().Elem(), len(v), cap(v))
 	for i, x := range v {
 		slice.Index(i).SetInt(int64(x))
 	}
 	p.v.Elem().Set(slice)
 }
 func (p pointer) appendInt32Slice(v int32) {
 	grow(p.v.Elem()).SetInt(int64(v))
 }

 func (p pointer) toUint64() *uint64 {
 	return p.v.Interface().(*uint64)
 }
 func (p pointer) toUint64Ptr() **uint64 {
 	return p.v.Interface().(**uint64)
 }
 func (p pointer) toUint64Slice() *[]uint64 {
 	return p.v.Interface().(*[]uint64)
 }
 func (p pointer) toUint32() *uint32 {
 	return p.v.Interface().(*uint32)
 }
 func (p pointer) toUint32Ptr() **uint32 {
 	return p.v.Interface().(**uint32)
 }
 func (p pointer) toUint32Slice() *[]uint32 {
 	return p.v.Interface().(*[]uint32)
 }
 func (p pointer) toBool() *bool {
 	return p.v.Interface().(*bool)
 }
 func (p pointer) toBoolPtr() **bool {
 	return p.v.Interface().(**bool)
 }
 func (p pointer) toBoolSlice() *[]bool {
 	return p.v.Interface().(*[]bool)
 }
 func (p pointer) toFloat64() *float64 {
 	return p.v.Interface().(*float64)
 }
 func (p pointer) toFloat64Ptr() **float64 {
 	return p.v.Interface().(**float64)
 }
 func (p pointer) toFloat64Slice() *[]float64 {
 	return p.v.Interface().(*[]float64)
 }
 func (p pointer) toFloat32() *float32 {
 	return p.v.Interface().(*float32)
 }
 func (p pointer) toFloat32Ptr() **float32 {
 	return p.v.Interface().(**float32)
 }
 func (p pointer) toFloat32Slice() *[]float32 {
 	return p.v.Interface().(*[]float32)
 }
 func (p pointer) toString() *string {
 	return p.v.Interface().(*string)
 }
 func (p pointer) toStringPtr() **string {
 	return p.v.Interface().(**string)
 }
 func (p pointer) toStringSlice() *[]string {
 	return p.v.Interface().(*[]string)
 }
 func (p pointer) toBytes() *[]byte {
 	return p.v.Interface().(*[]byte)
 }
 func (p pointer) toBytesSlice() *[][]byte {
 	return p.v.Interface().(*[][]byte)
 }
 func (p pointer) toExtensions() *XXX_InternalExtensions {
 	return p.v.Interface().(*XXX_InternalExtensions)
 }
 func (p pointer) toOldExtensions() *map[int32]Extension {
 	return p.v.Interface().(*map[int32]Extension)
 }
 func (p pointer) getPointer() pointer {
 	return pointer{v: p.v.Elem()}
 }
 func (p pointer) setPointer(q pointer) {
 	p.v.Elem().Set(q.v)
 }
 func (p pointer) appendPointer(q pointer) {
 	grow(p.v.Elem()).Set(q.v)
 }

 // getPointerSlice copies []*T from p as a new []pointer.
 // This behavior differs from the implementation in pointer_unsafe.go.
 func (p pointer) getPointerSlice() []pointer {
 	if p.v.IsNil() {
 		return nil
 	}
 	n := p.v.Elem().Len()
 	s := make([]pointer, n)
 	for i := 0; i < n; i++ {
 		s[i] = pointer{v: p.v.Elem().Index(i)}
 	}
 	return s
 }

 // setPointerSlice copies []pointer into p as a new []*T.
 // This behavior differs from the implementation in pointer_unsafe.go.
 func (p pointer) setPointerSlice(v []pointer) {
 	if v == nil {
 		p.v.Elem().Set(reflect.New(p.v.Elem().Type()).Elem())
 		return
 	}
 	s := reflect.MakeSlice(p.v.Elem().Type(), 0, len(v))
 	for _, p := range v {
 		s = reflect.Append(s, p.v)
 	}
 	p.v.Elem().Set(s)
 }

 // getInterfacePointer returns a pointer that points to the
 // interface data of the interface pointed by p.
 func (p pointer) getInterfacePointer() pointer {
 	if p.v.Elem().IsNil() {
 		return pointer{v: p.v.Elem()}
 	}
 	return pointer{v: p.v.Elem().Elem().Elem().Field(0).Addr()} // *interface -> interface -> *struct -> struct
 }

 func (p pointer) asPointerTo(t reflect.Type) reflect.Value {
 	// TODO: check that p.v.Type().Elem() == t?
 	return p.v
 }

 func atomicLoadUnmarshalInfo(p **unmarshalInfo) *unmarshalInfo {
 	atomicLock.Lock()
 	defer atomicLock.Unlock()
 	return *p
 }
 func atomicStoreUnmarshalInfo(p **unmarshalInfo, v *unmarshalInfo) {
 	atomicLock.Lock()
 	defer atomicLock.Unlock()
 	*p = v
 }
 func atomicLoadMarshalInfo(p **marshalInfo) *marshalInfo {
 	atomicLock.Lock()
 	defer atomicLock.Unlock()
 	return *p
 }
 func atomicStoreMarshalInfo(p **marshalInfo, v *marshalInfo) {
 	atomicLock.Lock()
 	defer atomicLock.Unlock()
 	*p = v
 }
 func atomicLoadMergeInfo(p **mergeInfo) *mergeInfo {
 	atomicLock.Lock()
 	defer atomicLock.Unlock()
 	return *p
 }
 func atomicStoreMergeInfo(p **mergeInfo, v *mergeInfo) {
 	atomicLock.Lock()
 	defer atomicLock.Unlock()
 	*p = v
 }
 func atomicLoadDiscardInfo(p **discardInfo) *discardInfo {
 	atomicLock.Lock()
 	defer atomicLock.Unlock()
 	return *p
 }
 func atomicStoreDiscardInfo(p **discardInfo, v *discardInfo) {
 	atomicLock.Lock()
 	defer atomicLock.Unlock()
 	*p = v
 }

 var atomicLock sync.Mutex
	// Go support for Protocol Buffers - Google's data interchange format
	//
	// Copyright 2012 The Go Authors. All rights reserved.
	// https://github.com/golang/protobuf
	//
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following disclaimer
	// in the documentation and/or other materials provided with the
	// distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived from
	// this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	// +build purego appengine js

	// This file contains an implementation of proto field accesses using package reflect.
	// It is slower than the code in pointer_unsafe.go but it avoids package unsafe and can
	// be used on App Engine.

	package proto

	import (
	"reflect"
	"sync"
	)

	const unsafeAllowed = false

	// A field identifies a field in a struct, accessible from a pointer.
	// In this implementation, a field is identified by the sequence of field indices
	// passed to reflect's FieldByIndex.
	type field []int

	// toField returns a field equivalent to the given reflect field.
	func toField(f *reflect.StructField) field {
	return f.Index
	}

	// invalidField is an invalid field identifier.
	var invalidField = field(nil)

	// zeroField is a noop when calling pointer.offset.
	var zeroField = field([]int{})

	// IsValid reports whether the field identifier is valid.
	func (f field) IsValid() bool { return f != nil }

	// The pointer type is for the table-driven decoder.
	// The implementation here uses a reflect.Value of pointer type to
	// create a generic pointer. In pointer_unsafe.go we use unsafe
	// instead of reflect to implement the same (but faster) interface.
	type pointer struct {
	v reflect.Value
	}

	// toPointer converts an interface of pointer type to a pointer
	// that points to the same target.
	func toPointer(i *Message) pointer {
	return pointer{v: reflect.ValueOf(*i)}
	}

	// toAddrPointer converts an interface to a pointer that points to
	// the interface data.
	func toAddrPointer(i *interface{}, isptr bool) pointer {
	v := reflect.ValueOf(*i)
	u := reflect.New(v.Type())
	u.Elem().Set(v)
	return pointer{v: u}
	}

	// valToPointer converts v to a pointer. v must be of pointer type.
	func valToPointer(v reflect.Value) pointer {
	return pointer{v: v}
	}

	// offset converts from a pointer to a structure to a pointer to
	// one of its fields.
	func (p pointer) offset(f field) pointer {
	return pointer{v: p.v.Elem().FieldByIndex(f).Addr()}
	}

	func (p pointer) isNil() bool {
	return p.v.IsNil()
	}

	// grow updates the slice s in place to make it one element longer.
	// s must be addressable.
	// Returns the (addressable) new element.
	func grow(s reflect.Value) reflect.Value {
	n, m := s.Len(), s.Cap()
	if n < m {
	s.SetLen(n + 1)
	} else {
	s.Set(reflect.Append(s, reflect.Zero(s.Type().Elem())))
	}
	return s.Index(n)
	}

	func (p pointer) toInt64() *int64 {
	return p.v.Interface().(*int64)
	}
	func (p pointer) toInt64Ptr() **int64 {
	return p.v.Interface().(**int64)
	}
	func (p pointer) toInt64Slice() *[]int64 {
	return p.v.Interface().(*[]int64)
	}

	var int32ptr = reflect.TypeOf((*int32)(nil))

	func (p pointer) toInt32() *int32 {
	return p.v.Convert(int32ptr).Interface().(*int32)
	}

	// The toInt32Ptr/Slice methods don't work because of enums.
	// Instead, we must use set/get methods for the int32ptr/slice case.
	/*
	func (p pointer) toInt32Ptr() **int32 {
	return p.v.Interface().(**int32)
	}
	func (p pointer) toInt32Slice() *[]int32 {
	return p.v.Interface().(*[]int32)
	}
	*/
	func (p pointer) getInt32Ptr() *int32 {
	if p.v.Type().Elem().Elem() == reflect.TypeOf(int32(0)) {
	// raw int32 type
	return p.v.Elem().Interface().(*int32)
	}
	// an enum
	return p.v.Elem().Convert(int32PtrType).Interface().(*int32)
	}
	func (p pointer) setInt32Ptr(v int32) {
	// Allocate value in a int32. Possibly convert that to a enum.
	// Then assign it to a int32 or enum.
	// Note: we can convert int32 to enum, but we can't convert
	// int32 to enum!
	p.v.Elem().Set(reflect.ValueOf(&v).Convert(p.v.Type().Elem()))
	}

	// getInt32Slice copies []int32 from p as a new slice.
	// This behavior differs from the implementation in pointer_unsafe.go.
	func (p pointer) getInt32Slice() []int32 {
	if p.v.Type().Elem().Elem() == reflect.TypeOf(int32(0)) {
	// raw int32 type
	return p.v.Elem().Interface().([]int32)
	}
	// an enum
	// Allocate a []int32, then assign []enum's values into it.
	// Note: we can't convert []enum to []int32.
	slice := p.v.Elem()
	s := make([]int32, slice.Len())
	for i := 0; i < slice.Len(); i++ {
	s[i] = int32(slice.Index(i).Int())
	}
	return s
	}

	// setInt32Slice copies []int32 into p as a new slice.
	// This behavior differs from the implementation in pointer_unsafe.go.
	func (p pointer) setInt32Slice(v []int32) {
	if p.v.Type().Elem().Elem() == reflect.TypeOf(int32(0)) {
	// raw int32 type
	p.v.Elem().Set(reflect.ValueOf(v))
	return
	}
	// an enum
	// Allocate a []enum, then assign []int32's values into it.
	// Note: we can't convert []enum to []int32.
	slice := reflect.MakeSlice(p.v.Type().Elem(), len(v), cap(v))
	for i, x := range v {
	slice.Index(i).SetInt(int64(x))
	}
	p.v.Elem().Set(slice)
	}
	func (p pointer) appendInt32Slice(v int32) {
	grow(p.v.Elem()).SetInt(int64(v))
	}

	func (p pointer) toUint64() *uint64 {
	return p.v.Interface().(*uint64)
	}
	func (p pointer) toUint64Ptr() **uint64 {
	return p.v.Interface().(**uint64)
	}
	func (p pointer) toUint64Slice() *[]uint64 {
	return p.v.Interface().(*[]uint64)
	}
	func (p pointer) toUint32() *uint32 {
	return p.v.Interface().(*uint32)
	}
	func (p pointer) toUint32Ptr() **uint32 {
	return p.v.Interface().(**uint32)
	}
	func (p pointer) toUint32Slice() *[]uint32 {
	return p.v.Interface().(*[]uint32)
	}
	func (p pointer) toBool() *bool {
	return p.v.Interface().(*bool)
	}
	func (p pointer) toBoolPtr() **bool {
	return p.v.Interface().(**bool)
	}
	func (p pointer) toBoolSlice() *[]bool {
	return p.v.Interface().(*[]bool)
	}
	func (p pointer) toFloat64() *float64 {
	return p.v.Interface().(*float64)
	}
	func (p pointer) toFloat64Ptr() **float64 {
	return p.v.Interface().(**float64)
	}
	func (p pointer) toFloat64Slice() *[]float64 {
	return p.v.Interface().(*[]float64)
	}
	func (p pointer) toFloat32() *float32 {
	return p.v.Interface().(*float32)
	}
	func (p pointer) toFloat32Ptr() **float32 {
	return p.v.Interface().(**float32)
	}
	func (p pointer) toFloat32Slice() *[]float32 {
	return p.v.Interface().(*[]float32)
	}
	func (p pointer) toString() *string {
	return p.v.Interface().(*string)
	}
	func (p pointer) toStringPtr() **string {
	return p.v.Interface().(**string)
	}
	func (p pointer) toStringSlice() *[]string {
	return p.v.Interface().(*[]string)
	}
	func (p pointer) toBytes() *[]byte {
	return p.v.Interface().(*[]byte)
	}
	func (p pointer) toBytesSlice() *[][]byte {
	return p.v.Interface().(*[][]byte)
	}
	func (p pointer) toExtensions() *XXX_InternalExtensions {
	return p.v.Interface().(*XXX_InternalExtensions)
	}
	func (p pointer) toOldExtensions() *map[int32]Extension {
	return p.v.Interface().(*map[int32]Extension)
	}
	func (p pointer) getPointer() pointer {
	return pointer{v: p.v.Elem()}
	}
	func (p pointer) setPointer(q pointer) {
	p.v.Elem().Set(q.v)
	}
	func (p pointer) appendPointer(q pointer) {
	grow(p.v.Elem()).Set(q.v)
	}

	// getPointerSlice copies []*T from p as a new []pointer.
	// This behavior differs from the implementation in pointer_unsafe.go.
	func (p pointer) getPointerSlice() []pointer {
	if p.v.IsNil() {
	return nil
	}
	n := p.v.Elem().Len()
	s := make([]pointer, n)
	for i := 0; i < n; i++ {
	s[i] = pointer{v: p.v.Elem().Index(i)}
	}
	return s
	}

	// setPointerSlice copies []pointer into p as a new []*T.
	// This behavior differs from the implementation in pointer_unsafe.go.
	func (p pointer) setPointerSlice(v []pointer) {
	if v == nil {
	p.v.Elem().Set(reflect.New(p.v.Elem().Type()).Elem())
	return
	}
	s := reflect.MakeSlice(p.v.Elem().Type(), 0, len(v))
	for _, p := range v {
	s = reflect.Append(s, p.v)
	}
	p.v.Elem().Set(s)
	}

	// getInterfacePointer returns a pointer that points to the
	// interface data of the interface pointed by p.
	func (p pointer) getInterfacePointer() pointer {
	if p.v.Elem().IsNil() {
	return pointer{v: p.v.Elem()}
	}
	return pointer{v: p.v.Elem().Elem().Elem().Field(0).Addr()} // interface -> interface -> struct -> struct
	}

	func (p pointer) asPointerTo(t reflect.Type) reflect.Value {
	// TODO: check that p.v.Type().Elem() == t?
	return p.v
	}

	func atomicLoadUnmarshalInfo(p *unmarshalInfo) unmarshalInfo {
	atomicLock.Lock()
	defer atomicLock.Unlock()
	return *p
	}
	func atomicStoreUnmarshalInfo(p *unmarshalInfo, v unmarshalInfo) {
	atomicLock.Lock()
	defer atomicLock.Unlock()
	*p = v
	}
	func atomicLoadMarshalInfo(p *marshalInfo) marshalInfo {
	atomicLock.Lock()
	defer atomicLock.Unlock()
	return *p
	}
	func atomicStoreMarshalInfo(p *marshalInfo, v marshalInfo) {
	atomicLock.Lock()
	defer atomicLock.Unlock()
	*p = v
	}
	func atomicLoadMergeInfo(p *mergeInfo) mergeInfo {
	atomicLock.Lock()
	defer atomicLock.Unlock()
	return *p
	}
	func atomicStoreMergeInfo(p *mergeInfo, v mergeInfo) {
	atomicLock.Lock()
	defer atomicLock.Unlock()
	*p = v
	}
	func atomicLoadDiscardInfo(p *discardInfo) discardInfo {
	atomicLock.Lock()
	defer atomicLock.Unlock()
	return *p
	}
	func atomicStoreDiscardInfo(p *discardInfo, v discardInfo) {
	atomicLock.Lock()
	defer atomicLock.Unlock()
	*p = v
	}

	var atomicLock sync.Mutex