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// 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 protocmp
import (
"bytes"
"fmt"
"math"
"reflect"
"strings"
"github.com/google/go-cmp/cmp"
"github.com/google/go-cmp/cmp/cmpopts"
"google.golang.org/protobuf/proto"
"google.golang.org/protobuf/reflect/protoreflect"
)
var (
enumReflectType = reflect.TypeOf(Enum{})
messageReflectType = reflect.TypeOf(Message{})
)
// FilterEnum filters opt to only be applicable on standalone Enums,
// singular fields of enums, list fields of enums, or map fields of enum values,
// where the enum is the same type as the specified enum.
//
// The Go type of the last path step may be an:
// • Enum for singular fields, elements of a repeated field,
// values of a map field, or standalone Enums
// • []Enum for list fields
// • map[K]Enum for map fields
// • interface{} for a Message map entry value
//
// This must be used in conjunction with Transform.
func FilterEnum(enum protoreflect.Enum, opt cmp.Option) cmp.Option {
return FilterDescriptor(enum.Descriptor(), opt)
}
// FilterMessage filters opt to only be applicable on standalone Messages,
// singular fields of messages, list fields of messages, or map fields of
// message values, where the message is the same type as the specified message.
//
// The Go type of the last path step may be an:
// • Message for singular fields, elements of a repeated field,
// values of a map field, or standalone Messages
// • []Message for list fields
// • map[K]Message for map fields
// • interface{} for a Message map entry value
//
// This must be used in conjunction with Transform.
func FilterMessage(message proto.Message, opt cmp.Option) cmp.Option {
return FilterDescriptor(message.ProtoReflect().Descriptor(), opt)
}
// FilterField filters opt to only be applicable on the specified field
// in the message. It panics if a field of the given name does not exist.
//
// The Go type of the last path step may be an:
// • T for singular fields
// • []T for list fields
// • map[K]T for map fields
// • interface{} for a Message map entry value
//
// This must be used in conjunction with Transform.
func FilterField(message proto.Message, name protoreflect.Name, opt cmp.Option) cmp.Option {
md := message.ProtoReflect().Descriptor()
return FilterDescriptor(mustFindFieldDescriptor(md, name), opt)
}
// FilterOneof filters opt to only be applicable on all fields within the
// specified oneof in the message. It panics if a oneof of the given name
// does not exist.
//
// The Go type of the last path step may be an:
// • T for singular fields
// • []T for list fields
// • map[K]T for map fields
// • interface{} for a Message map entry value
//
// This must be used in conjunction with Transform.
func FilterOneof(message proto.Message, name protoreflect.Name, opt cmp.Option) cmp.Option {
md := message.ProtoReflect().Descriptor()
return FilterDescriptor(mustFindOneofDescriptor(md, name), opt)
}
// FilterDescriptor ignores the specified descriptor.
//
// The following descriptor types may be specified:
// • protoreflect.EnumDescriptor
// • protoreflect.MessageDescriptor
// • protoreflect.FieldDescriptor
// • protoreflect.OneofDescriptor
//
// For the behavior of each, see the corresponding filter function.
// Since this filter accepts a protoreflect.FieldDescriptor, it can be used
// to also filter for extension fields as a protoreflect.ExtensionDescriptor
// is just an alias to protoreflect.FieldDescriptor.
//
// This must be used in conjunction with Transform.
func FilterDescriptor(desc protoreflect.Descriptor, opt cmp.Option) cmp.Option {
f := newNameFilters(desc)
return cmp.FilterPath(f.Filter, opt)
}
// IgnoreEnums ignores all enums of the specified types.
// It is equivalent to FilterEnum(enum, cmp.Ignore()) for each enum.
//
// This must be used in conjunction with Transform.
func IgnoreEnums(enums ...protoreflect.Enum) cmp.Option {
var ds []protoreflect.Descriptor
for _, e := range enums {
ds = append(ds, e.Descriptor())
}
return IgnoreDescriptors(ds...)
}
// IgnoreMessages ignores all messages of the specified types.
// It is equivalent to FilterMessage(message, cmp.Ignore()) for each message.
//
// This must be used in conjunction with Transform.
func IgnoreMessages(messages ...proto.Message) cmp.Option {
var ds []protoreflect.Descriptor
for _, m := range messages {
ds = append(ds, m.ProtoReflect().Descriptor())
}
return IgnoreDescriptors(ds...)
}
// IgnoreFields ignores the specified fields in the specified message.
// It is equivalent to FilterField(message, name, cmp.Ignore()) for each field
// in the message.
//
// This must be used in conjunction with Transform.
func IgnoreFields(message proto.Message, names ...protoreflect.Name) cmp.Option {
var ds []protoreflect.Descriptor
md := message.ProtoReflect().Descriptor()
for _, s := range names {
ds = append(ds, mustFindFieldDescriptor(md, s))
}
return IgnoreDescriptors(ds...)
}
// IgnoreOneofs ignores fields of the specified oneofs in the specified message.
// It is equivalent to FilterOneof(message, name, cmp.Ignore()) for each oneof
// in the message.
//
// This must be used in conjunction with Transform.
func IgnoreOneofs(message proto.Message, names ...protoreflect.Name) cmp.Option {
var ds []protoreflect.Descriptor
md := message.ProtoReflect().Descriptor()
for _, s := range names {
ds = append(ds, mustFindOneofDescriptor(md, s))
}
return IgnoreDescriptors(ds...)
}
// IgnoreDescriptors ignores the specified set of descriptors.
// It is equivalent to FilterDescriptor(desc, cmp.Ignore()) for each descriptor.
//
// This must be used in conjunction with Transform.
func IgnoreDescriptors(descs ...protoreflect.Descriptor) cmp.Option {
return cmp.FilterPath(newNameFilters(descs...).Filter, cmp.Ignore())
}
func mustFindFieldDescriptor(md protoreflect.MessageDescriptor, s protoreflect.Name) protoreflect.FieldDescriptor {
d := findDescriptor(md, s)
if fd, ok := d.(protoreflect.FieldDescriptor); ok && fd.TextName() == string(s) {
return fd
}
var suggestion string
switch d := d.(type) {
case protoreflect.FieldDescriptor:
suggestion = fmt.Sprintf("; consider specifying field %q instead", d.TextName())
case protoreflect.OneofDescriptor:
suggestion = fmt.Sprintf("; consider specifying oneof %q with IgnoreOneofs instead", d.Name())
}
panic(fmt.Sprintf("message %q has no field %q%s", md.FullName(), s, suggestion))
}
func mustFindOneofDescriptor(md protoreflect.MessageDescriptor, s protoreflect.Name) protoreflect.OneofDescriptor {
d := findDescriptor(md, s)
if od, ok := d.(protoreflect.OneofDescriptor); ok && d.Name() == s {
return od
}
var suggestion string
switch d := d.(type) {
case protoreflect.OneofDescriptor:
suggestion = fmt.Sprintf("; consider specifying oneof %q instead", d.Name())
case protoreflect.FieldDescriptor:
suggestion = fmt.Sprintf("; consider specifying field %q with IgnoreFields instead", d.TextName())
}
panic(fmt.Sprintf("message %q has no oneof %q%s", md.FullName(), s, suggestion))
}
func findDescriptor(md protoreflect.MessageDescriptor, s protoreflect.Name) protoreflect.Descriptor {
// Exact match.
if fd := md.Fields().ByTextName(string(s)); fd != nil {
return fd
}
if od := md.Oneofs().ByName(s); od != nil && !od.IsSynthetic() {
return od
}
// Best-effort match.
//
// It's a common user mistake to use the CamelCased field name as it appears
// in the generated Go struct. Instead of complaining that it doesn't exist,
// suggest the real protobuf name that the user may have desired.
normalize := func(s protoreflect.Name) string {
return strings.Replace(strings.ToLower(string(s)), "_", "", -1)
}
for i := 0; i < md.Fields().Len(); i++ {
if fd := md.Fields().Get(i); normalize(fd.Name()) == normalize(s) {
return fd
}
}
for i := 0; i < md.Oneofs().Len(); i++ {
if od := md.Oneofs().Get(i); normalize(od.Name()) == normalize(s) {
return od
}
}
return nil
}
type nameFilters struct {
names map[protoreflect.FullName]bool
}
func newNameFilters(descs ...protoreflect.Descriptor) *nameFilters {
f := &nameFilters{names: make(map[protoreflect.FullName]bool)}
for _, d := range descs {
switch d := d.(type) {
case protoreflect.EnumDescriptor:
f.names[d.FullName()] = true
case protoreflect.MessageDescriptor:
f.names[d.FullName()] = true
case protoreflect.FieldDescriptor:
f.names[d.FullName()] = true
case protoreflect.OneofDescriptor:
for i := 0; i < d.Fields().Len(); i++ {
f.names[d.Fields().Get(i).FullName()] = true
}
default:
panic("invalid descriptor type")
}
}
return f
}
func (f *nameFilters) Filter(p cmp.Path) bool {
vx, vy := p.Last().Values()
return (f.filterValue(vx) && f.filterValue(vy)) || f.filterFields(p)
}
func (f *nameFilters) filterFields(p cmp.Path) bool {
// Trim off trailing type-assertions so that the filter can match on the
// concrete value held within an interface value.
if _, ok := p.Last().(cmp.TypeAssertion); ok {
p = p[:len(p)-1]
}
// Filter for Message maps.
mi, ok := p.Index(-1).(cmp.MapIndex)
if !ok {
return false
}
ps := p.Index(-2)
if ps.Type() != messageReflectType {
return false
}
// Check field name.
vx, vy := ps.Values()
mx := vx.Interface().(Message)
my := vy.Interface().(Message)
k := mi.Key().String()
if f.filterFieldName(mx, k) && f.filterFieldName(my, k) {
return true
}
// Check field value.
vx, vy = mi.Values()
if f.filterFieldValue(vx) && f.filterFieldValue(vy) {
return true
}
return false
}
func (f *nameFilters) filterFieldName(m Message, k string) bool {
if _, ok := m[k]; !ok {
return true // treat missing fields as already filtered
}
var fd protoreflect.FieldDescriptor
switch mt := m[messageTypeKey].(messageType); {
case protoreflect.Name(k).IsValid():
fd = mt.md.Fields().ByTextName(k)
default:
fd = mt.xds[k]
}
if fd != nil {
return f.names[fd.FullName()]
}
return false
}
func (f *nameFilters) filterFieldValue(v reflect.Value) bool {
if !v.IsValid() {
return true // implies missing slice element or map entry
}
v = v.Elem() // map entries are always populated values
switch t := v.Type(); {
case t == enumReflectType || t == messageReflectType:
// Check for singular message or enum field.
return f.filterValue(v)
case t.Kind() == reflect.Slice && (t.Elem() == enumReflectType || t.Elem() == messageReflectType):
// Check for list field of enum or message type.
return f.filterValue(v.Index(0))
case t.Kind() == reflect.Map && (t.Elem() == enumReflectType || t.Elem() == messageReflectType):
// Check for map field of enum or message type.
return f.filterValue(v.MapIndex(v.MapKeys()[0]))
}
return false
}
func (f *nameFilters) filterValue(v reflect.Value) bool {
if !v.IsValid() {
return true // implies missing slice element or map entry
}
if !v.CanInterface() {
return false // implies unexported struct field
}
switch v := v.Interface().(type) {
case Enum:
return v.Descriptor() != nil && f.names[v.Descriptor().FullName()]
case Message:
return v.Descriptor() != nil && f.names[v.Descriptor().FullName()]
}
return false
}
// IgnoreDefaultScalars ignores singular scalars that are unpopulated or
// explicitly set to the default value.
// This option does not effect elements in a list or entries in a map.
//
// This must be used in conjunction with Transform.
func IgnoreDefaultScalars() cmp.Option {
return cmp.FilterPath(func(p cmp.Path) bool {
// Filter for Message maps.
mi, ok := p.Index(-1).(cmp.MapIndex)
if !ok {
return false
}
ps := p.Index(-2)
if ps.Type() != messageReflectType {
return false
}
// Check whether both fields are default or unpopulated scalars.
vx, vy := ps.Values()
mx := vx.Interface().(Message)
my := vy.Interface().(Message)
k := mi.Key().String()
return isDefaultScalar(mx, k) && isDefaultScalar(my, k)
}, cmp.Ignore())
}
func isDefaultScalar(m Message, k string) bool {
if _, ok := m[k]; !ok {
return true
}
var fd protoreflect.FieldDescriptor
switch mt := m[messageTypeKey].(messageType); {
case protoreflect.Name(k).IsValid():
fd = mt.md.Fields().ByTextName(k)
default:
fd = mt.xds[k]
}
if fd == nil || !fd.Default().IsValid() {
return false
}
switch fd.Kind() {
case protoreflect.BytesKind:
v, ok := m[k].([]byte)
return ok && bytes.Equal(fd.Default().Bytes(), v)
case protoreflect.FloatKind:
v, ok := m[k].(float32)
return ok && equalFloat64(fd.Default().Float(), float64(v))
case protoreflect.DoubleKind:
v, ok := m[k].(float64)
return ok && equalFloat64(fd.Default().Float(), float64(v))
case protoreflect.EnumKind:
v, ok := m[k].(Enum)
return ok && fd.Default().Enum() == v.Number()
default:
return reflect.DeepEqual(fd.Default().Interface(), m[k])
}
}
func equalFloat64(x, y float64) bool {
return x == y || (math.IsNaN(x) && math.IsNaN(y))
}
// IgnoreEmptyMessages ignores messages that are empty or unpopulated.
// It applies to standalone Messages, singular message fields,
// list fields of messages, and map fields of message values.
//
// This must be used in conjunction with Transform.
func IgnoreEmptyMessages() cmp.Option {
return cmp.FilterPath(func(p cmp.Path) bool {
vx, vy := p.Last().Values()
return (isEmptyMessage(vx) && isEmptyMessage(vy)) || isEmptyMessageFields(p)
}, cmp.Ignore())
}
func isEmptyMessageFields(p cmp.Path) bool {
// Filter for Message maps.
mi, ok := p.Index(-1).(cmp.MapIndex)
if !ok {
return false
}
ps := p.Index(-2)
if ps.Type() != messageReflectType {
return false
}
// Check field value.
vx, vy := mi.Values()
if isEmptyMessageFieldValue(vx) && isEmptyMessageFieldValue(vy) {
return true
}
return false
}
func isEmptyMessageFieldValue(v reflect.Value) bool {
if !v.IsValid() {
return true // implies missing slice element or map entry
}
v = v.Elem() // map entries are always populated values
switch t := v.Type(); {
case t == messageReflectType:
// Check singular field for empty message.
if !isEmptyMessage(v) {
return false
}
case t.Kind() == reflect.Slice && t.Elem() == messageReflectType:
// Check list field for all empty message elements.
for i := 0; i < v.Len(); i++ {
if !isEmptyMessage(v.Index(i)) {
return false
}
}
case t.Kind() == reflect.Map && t.Elem() == messageReflectType:
// Check map field for all empty message values.
for _, k := range v.MapKeys() {
if !isEmptyMessage(v.MapIndex(k)) {
return false
}
}
default:
return false
}
return true
}
func isEmptyMessage(v reflect.Value) bool {
if !v.IsValid() {
return true // implies missing slice element or map entry
}
if !v.CanInterface() {
return false // implies unexported struct field
}
if m, ok := v.Interface().(Message); ok {
for k := range m {
if k != messageTypeKey && k != messageInvalidKey {
return false
}
}
return true
}
return false
}
// IgnoreUnknown ignores unknown fields in all messages.
//
// This must be used in conjunction with Transform.
func IgnoreUnknown() cmp.Option {
return cmp.FilterPath(func(p cmp.Path) bool {
// Filter for Message maps.
mi, ok := p.Index(-1).(cmp.MapIndex)
if !ok {
return false
}
ps := p.Index(-2)
if ps.Type() != messageReflectType {
return false
}
// Filter for unknown fields (which always have a numeric map key).
return strings.Trim(mi.Key().String(), "0123456789") == ""
}, cmp.Ignore())
}
// SortRepeated sorts repeated fields of the specified element type.
// The less function must be of the form "func(T, T) bool" where T is the
// Go element type for the repeated field kind.
//
// The element type T can be one of the following:
// • Go type for a protobuf scalar kind except for an enum
// (i.e., bool, int32, int64, uint32, uint64, float32, float64, string, and []byte)
// • E where E is a concrete enum type that implements protoreflect.Enum
// • M where M is a concrete message type that implement proto.Message
//
// This option only applies to repeated fields within a protobuf message.
// It does not operate on higher-order Go types that seem like a repeated field.
// For example, a []T outside the context of a protobuf message will not be
// handled by this option. To sort Go slices that are not repeated fields,
// consider using "github.com/google/go-cmp/cmp/cmpopts".SortSlices instead.
//
// This must be used in conjunction with Transform.
func SortRepeated(lessFunc interface{}) cmp.Option {
t, ok := checkTTBFunc(lessFunc)
if !ok {
panic(fmt.Sprintf("invalid less function: %T", lessFunc))
}
var opt cmp.Option
var sliceType reflect.Type
switch vf := reflect.ValueOf(lessFunc); {
case t.Implements(enumV2Type):
et := reflect.Zero(t).Interface().(protoreflect.Enum).Type()
lessFunc = func(x, y Enum) bool {
vx := reflect.ValueOf(et.New(x.Number()))
vy := reflect.ValueOf(et.New(y.Number()))
return vf.Call([]reflect.Value{vx, vy})[0].Bool()
}
opt = FilterDescriptor(et.Descriptor(), cmpopts.SortSlices(lessFunc))
sliceType = reflect.SliceOf(enumReflectType)
case t.Implements(messageV2Type):
mt := reflect.Zero(t).Interface().(protoreflect.ProtoMessage).ProtoReflect().Type()
lessFunc = func(x, y Message) bool {
mx := mt.New().Interface()
my := mt.New().Interface()
proto.Merge(mx, x)
proto.Merge(my, y)
vx := reflect.ValueOf(mx)
vy := reflect.ValueOf(my)
return vf.Call([]reflect.Value{vx, vy})[0].Bool()
}
opt = FilterDescriptor(mt.Descriptor(), cmpopts.SortSlices(lessFunc))
sliceType = reflect.SliceOf(messageReflectType)
default:
switch t {
case reflect.TypeOf(bool(false)):
case reflect.TypeOf(int32(0)):
case reflect.TypeOf(int64(0)):
case reflect.TypeOf(uint32(0)):
case reflect.TypeOf(uint64(0)):
case reflect.TypeOf(float32(0)):
case reflect.TypeOf(float64(0)):
case reflect.TypeOf(string("")):
case reflect.TypeOf([]byte(nil)):
default:
panic(fmt.Sprintf("invalid element type: %v", t))
}
opt = cmpopts.SortSlices(lessFunc)
sliceType = reflect.SliceOf(t)
}
return cmp.FilterPath(func(p cmp.Path) bool {
// Filter to only apply to repeated fields within a message.
if t := p.Index(-1).Type(); t == nil || t != sliceType {
return false
}
if t := p.Index(-2).Type(); t == nil || t.Kind() != reflect.Interface {
return false
}
if t := p.Index(-3).Type(); t == nil || t != messageReflectType {
return false
}
return true
}, opt)
}
func checkTTBFunc(lessFunc interface{}) (reflect.Type, bool) {
switch t := reflect.TypeOf(lessFunc); {
case t == nil:
return nil, false
case t.NumIn() != 2 || t.In(0) != t.In(1) || t.IsVariadic():
return nil, false
case t.NumOut() != 1 || t.Out(0) != reflect.TypeOf(false):
return nil, false
default:
return t.In(0), true
}
}
// SortRepeatedFields sorts the specified repeated fields.
// Sorting a repeated field is useful for treating the list as a multiset
// (i.e., a set where each value can appear multiple times).
// It panics if the field does not exist or is not a repeated field.
//
// The sort ordering is as follows:
// • Booleans are sorted where false is sorted before true.
// • Integers are sorted in ascending order.
// • Floating-point numbers are sorted in ascending order according to
// the total ordering defined by IEEE-754 (section 5.10).
// • Strings and bytes are sorted lexicographically in ascending order.
// • Enums are sorted in ascending order based on its numeric value.
// • Messages are sorted according to some arbitrary ordering
// which is undefined and may change in future implementations.
//
// The ordering chosen for repeated messages is unlikely to be aesthetically
// preferred by humans. Consider using a custom sort function:
//
// FilterField(m, "foo_field", SortRepeated(func(x, y *foopb.MyMessage) bool {
// ... // user-provided definition for less
// }))
//
// This must be used in conjunction with Transform.
func SortRepeatedFields(message proto.Message, names ...protoreflect.Name) cmp.Option {
var opts cmp.Options
md := message.ProtoReflect().Descriptor()
for _, name := range names {
fd := mustFindFieldDescriptor(md, name)
if !fd.IsList() {
panic(fmt.Sprintf("message field %q is not repeated", fd.FullName()))
}
var lessFunc interface{}
switch fd.Kind() {
case protoreflect.BoolKind:
lessFunc = func(x, y bool) bool { return !x && y }
case protoreflect.Int32Kind, protoreflect.Sint32Kind, protoreflect.Sfixed32Kind:
lessFunc = func(x, y int32) bool { return x < y }
case protoreflect.Int64Kind, protoreflect.Sint64Kind, protoreflect.Sfixed64Kind:
lessFunc = func(x, y int64) bool { return x < y }
case protoreflect.Uint32Kind, protoreflect.Fixed32Kind:
lessFunc = func(x, y uint32) bool { return x < y }
case protoreflect.Uint64Kind, protoreflect.Fixed64Kind:
lessFunc = func(x, y uint64) bool { return x < y }
case protoreflect.FloatKind:
lessFunc = lessF32
case protoreflect.DoubleKind:
lessFunc = lessF64
case protoreflect.StringKind:
lessFunc = func(x, y string) bool { return x < y }
case protoreflect.BytesKind:
lessFunc = func(x, y []byte) bool { return bytes.Compare(x, y) < 0 }
case protoreflect.EnumKind:
lessFunc = func(x, y Enum) bool { return x.Number() < y.Number() }
case protoreflect.MessageKind, protoreflect.GroupKind:
lessFunc = func(x, y Message) bool { return x.String() < y.String() }
default:
panic(fmt.Sprintf("invalid kind: %v", fd.Kind()))
}
opts = append(opts, FilterDescriptor(fd, cmpopts.SortSlices(lessFunc)))
}
return opts
}
func lessF32(x, y float32) bool {
// Bit-wise implementation of IEEE-754, section 5.10.
xi := int32(math.Float32bits(x))
yi := int32(math.Float32bits(y))
xi ^= int32(uint32(xi>>31) >> 1)
yi ^= int32(uint32(yi>>31) >> 1)
return xi < yi
}
func lessF64(x, y float64) bool {
// Bit-wise implementation of IEEE-754, section 5.10.
xi := int64(math.Float64bits(x))
yi := int64(math.Float64bits(y))
xi ^= int64(uint64(xi>>63) >> 1)
yi ^= int64(uint64(yi>>63) >> 1)
return xi < yi
}