// Go support for Protocol Buffers - Google's data interchange format // // Copyright 2015 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. /* Package jsonpb provides marshaling and unmarshaling between protocol buffers and JSON. It follows the specification at https://developers.google.com/protocol-buffers/docs/proto3#json. This package produces a different output than the standard "encoding/json" package, which does not operate correctly on protocol buffers. */ package jsonpb import ( "bytes" "encoding/json" "errors" "fmt" "io" "reflect" "sort" "strconv" "strings" "time" "github.com/gogo/protobuf/proto" "github.com/gogo/protobuf/types" ) // Marshaler is a configurable object for converting between // protocol buffer objects and a JSON representation for them. type Marshaler struct { // Whether to render enum values as integers, as opposed to string values. EnumsAsInts bool // Whether to render fields with zero values. EmitDefaults bool // A string to indent each level by. The presence of this field will // also cause a space to appear between the field separator and // value, and for newlines to be appear between fields and array // elements. Indent string // Whether to use the original (.proto) name for fields. OrigName bool } // Marshal marshals a protocol buffer into JSON. func (m *Marshaler) Marshal(out io.Writer, pb proto.Message) error { writer := &errWriter{writer: out} return m.marshalObject(writer, pb, "", "") } // MarshalToString converts a protocol buffer object to JSON string. func (m *Marshaler) MarshalToString(pb proto.Message) (string, error) { var buf bytes.Buffer if err := m.Marshal(&buf, pb); err != nil { return "", err } return buf.String(), nil } type int32Slice []int32 // For sorting extensions ids to ensure stable output. func (s int32Slice) Len() int { return len(s) } func (s int32Slice) Less(i, j int) bool { return s[i] < s[j] } func (s int32Slice) Swap(i, j int) { s[i], s[j] = s[j], s[i] } type isWkt interface { XXX_WellKnownType() string } // marshalObject writes a struct to the Writer. func (m *Marshaler) marshalObject(out *errWriter, v proto.Message, indent, typeURL string) error { s := reflect.ValueOf(v).Elem() // Handle well-known types. if wkt, ok := v.(isWkt); ok { switch wkt.XXX_WellKnownType() { case "DoubleValue", "FloatValue", "Int64Value", "UInt64Value", "Int32Value", "UInt32Value", "BoolValue", "StringValue", "BytesValue": // "Wrappers use the same representation in JSON // as the wrapped primitive type, ..." sprop := proto.GetProperties(s.Type()) return m.marshalValue(out, sprop.Prop[0], s.Field(0), indent) case "Any": // Any is a bit more involved. return m.marshalAny(out, v, indent) case "Duration": // "Generated output always contains 3, 6, or 9 fractional digits, // depending on required precision." s, ns := s.Field(0).Int(), s.Field(1).Int() d := time.Duration(s)*time.Second + time.Duration(ns)*time.Nanosecond x := fmt.Sprintf("%.9f", d.Seconds()) x = strings.TrimSuffix(x, "000") x = strings.TrimSuffix(x, "000") out.write(`"`) out.write(x) out.write(`s"`) return out.err case "Struct": // Let marshalValue handle the `fields` map. // TODO: pass the correct Properties if needed. return m.marshalValue(out, &proto.Properties{}, s.Field(0), indent) case "Timestamp": // "RFC 3339, where generated output will always be Z-normalized // and uses 3, 6 or 9 fractional digits." s, ns := s.Field(0).Int(), s.Field(1).Int() t := time.Unix(s, ns).UTC() // time.RFC3339Nano isn't exactly right (we need to get 3/6/9 fractional digits). x := t.Format("2006-01-02T15:04:05.000000000") x = strings.TrimSuffix(x, "000") x = strings.TrimSuffix(x, "000") out.write(`"`) out.write(x) out.write(`Z"`) return out.err case "Value": // Value has a single oneof. kind := s.Field(0) if kind.IsNil() { // "absence of any variant indicates an error" return errors.New("nil Value") } // oneof -> *T -> T -> T.F x := kind.Elem().Elem().Field(0) // TODO: pass the correct Properties if needed. return m.marshalValue(out, &proto.Properties{}, x, indent) } } out.write("{") if m.Indent != "" { out.write("\n") } firstField := true if typeURL != "" { if err := m.marshalTypeURL(out, indent, typeURL); err != nil { return err } firstField = false } for i := 0; i < s.NumField(); i++ { value := s.Field(i) valueField := s.Type().Field(i) if strings.HasPrefix(valueField.Name, "XXX_") { continue } // IsNil will panic on most value kinds. switch value.Kind() { case reflect.Chan, reflect.Func, reflect.Interface, reflect.Map, reflect.Ptr, reflect.Slice: if value.IsNil() { continue } } if !m.EmitDefaults { switch value.Kind() { case reflect.Bool: if !value.Bool() { continue } case reflect.Int32, reflect.Int64: if value.Int() == 0 { continue } case reflect.Uint32, reflect.Uint64: if value.Uint() == 0 { continue } case reflect.Float32, reflect.Float64: if value.Float() == 0 { continue } case reflect.String: if value.Len() == 0 { continue } } } // Oneof fields need special handling. if valueField.Tag.Get("protobuf_oneof") != "" { // value is an interface containing &T{real_value}. sv := value.Elem().Elem() // interface -> *T -> T value = sv.Field(0) valueField = sv.Type().Field(0) } prop := jsonProperties(valueField, m.OrigName) if !firstField { m.writeSep(out) } // If the map value is a cast type, it may not implement proto.Message, therefore // allow the struct tag to declare the underlying message type. Instead of changing // the signatures of the child types (and because prop.mvalue is not public), use // CustomType as a passer. if value.Kind() == reflect.Map { if tag := valueField.Tag.Get("protobuf"); tag != "" { for _, v := range strings.Split(tag, ",") { if !strings.HasPrefix(v, "castvaluetype=") { continue } v = strings.TrimPrefix(v, "castvaluetype=") prop.CustomType = v break } } } if err := m.marshalField(out, prop, value, indent); err != nil { return err } firstField = false } // Handle proto2 extensions. if ep, ok := v.(proto.Message); ok { extensions := proto.RegisteredExtensions(v) // Sort extensions for stable output. ids := make([]int32, 0, len(extensions)) for id, desc := range extensions { if !proto.HasExtension(ep, desc) { continue } ids = append(ids, id) } sort.Sort(int32Slice(ids)) for _, id := range ids { desc := extensions[id] if desc == nil { // unknown extension continue } ext, extErr := proto.GetExtension(ep, desc) if extErr != nil { return extErr } value := reflect.ValueOf(ext) var prop proto.Properties prop.Parse(desc.Tag) prop.JSONName = fmt.Sprintf("[%s]", desc.Name) if !firstField { m.writeSep(out) } if err := m.marshalField(out, &prop, value, indent); err != nil { return err } firstField = false } } if m.Indent != "" { out.write("\n") out.write(indent) } out.write("}") return out.err } func (m *Marshaler) writeSep(out *errWriter) { if m.Indent != "" { out.write(",\n") } else { out.write(",") } } func (m *Marshaler) marshalAny(out *errWriter, any proto.Message, indent string) error { // "If the Any contains a value that has a special JSON mapping, // it will be converted as follows: {"@type": xxx, "value": yyy}. // Otherwise, the value will be converted into a JSON object, // and the "@type" field will be inserted to indicate the actual data type." v := reflect.ValueOf(any).Elem() turl := v.Field(0).String() val := v.Field(1).Bytes() // Only the part of type_url after the last slash is relevant. mname := turl if slash := strings.LastIndex(mname, "/"); slash >= 0 { mname = mname[slash+1:] } mt := proto.MessageType(mname) if mt == nil { return fmt.Errorf("unknown message type %q", mname) } msg := reflect.New(mt.Elem()).Interface().(proto.Message) if err := proto.Unmarshal(val, msg); err != nil { return err } if _, ok := msg.(isWkt); ok { out.write("{") if m.Indent != "" { out.write("\n") } if err := m.marshalTypeURL(out, indent, turl); err != nil { return err } m.writeSep(out) if m.Indent != "" { out.write(indent) out.write(m.Indent) out.write(`"value": `) } else { out.write(`"value":`) } if err := m.marshalObject(out, msg, indent+m.Indent, ""); err != nil { return err } if m.Indent != "" { out.write("\n") out.write(indent) } out.write("}") return out.err } return m.marshalObject(out, msg, indent, turl) } func (m *Marshaler) marshalTypeURL(out *errWriter, indent, typeURL string) error { if m.Indent != "" { out.write(indent) out.write(m.Indent) } out.write(`"@type":`) if m.Indent != "" { out.write(" ") } b, err := json.Marshal(typeURL) if err != nil { return err } out.write(string(b)) return out.err } // marshalField writes field description and value to the Writer. func (m *Marshaler) marshalField(out *errWriter, prop *proto.Properties, v reflect.Value, indent string) error { if m.Indent != "" { out.write(indent) out.write(m.Indent) } out.write(`"`) out.write(prop.JSONName) out.write(`":`) if m.Indent != "" { out.write(" ") } if err := m.marshalValue(out, prop, v, indent); err != nil { return err } return nil } // marshalValue writes the value to the Writer. func (m *Marshaler) marshalValue(out *errWriter, prop *proto.Properties, v reflect.Value, indent string) error { v = reflect.Indirect(v) // Handle repeated elements. if v.Kind() == reflect.Slice && v.Type().Elem().Kind() != reflect.Uint8 { out.write("[") comma := "" for i := 0; i < v.Len(); i++ { sliceVal := v.Index(i) out.write(comma) if m.Indent != "" { out.write("\n") out.write(indent) out.write(m.Indent) out.write(m.Indent) } if err := m.marshalValue(out, prop, sliceVal, indent+m.Indent); err != nil { return err } comma = "," } if m.Indent != "" { out.write("\n") out.write(indent) out.write(m.Indent) } out.write("]") return out.err } // Handle well-known types. // Most are handled up in marshalObject (because 99% are messages). if wkt, ok := v.Interface().(isWkt); ok { switch wkt.XXX_WellKnownType() { case "NullValue": out.write("null") return out.err } } if t, ok := v.Interface().(time.Time); ok { ts, err := types.TimestampProto(t) if err != nil { return err } return m.marshalValue(out, prop, reflect.ValueOf(ts), indent) } if d, ok := v.Interface().(time.Duration); ok { dur := types.DurationProto(d) return m.marshalValue(out, prop, reflect.ValueOf(dur), indent) } // Handle enumerations. if !m.EnumsAsInts && prop.Enum != "" { // Unknown enum values will are stringified by the proto library as their // value. Such values should _not_ be quoted or they will be interpreted // as an enum string instead of their value. enumStr := v.Interface().(fmt.Stringer).String() var valStr string if v.Kind() == reflect.Ptr { valStr = strconv.Itoa(int(v.Elem().Int())) } else { valStr = strconv.Itoa(int(v.Int())) } if m, ok := v.Interface().(interface { MarshalJSON() ([]byte, error) }); ok { data, err := m.MarshalJSON() if err != nil { return err } enumStr = string(data) enumStr, err = strconv.Unquote(enumStr) if err != nil { return err } } isKnownEnum := enumStr != valStr if isKnownEnum { out.write(`"`) } out.write(enumStr) if isKnownEnum { out.write(`"`) } return out.err } // Handle nested messages. if v.Kind() == reflect.Struct { i := v if v.CanAddr() { i = v.Addr() } else { i = reflect.New(v.Type()) i.Elem().Set(v) } iface := i.Interface() if iface == nil { out.write(`null`) return out.err } pm, ok := iface.(proto.Message) if !ok { if prop.CustomType == "" { return fmt.Errorf("%v does not implement proto.Message", v.Type()) } t := proto.MessageType(prop.CustomType) if t == nil || !i.Type().ConvertibleTo(t) { return fmt.Errorf("%v declared custom type %s but it is not convertible to %v", v.Type(), prop.CustomType, t) } pm = i.Convert(t).Interface().(proto.Message) } return m.marshalObject(out, pm, indent+m.Indent, "") } // Handle maps. // Since Go randomizes map iteration, we sort keys for stable output. if v.Kind() == reflect.Map { out.write(`{`) keys := v.MapKeys() sort.Sort(mapKeys(keys)) for i, k := range keys { if i > 0 { out.write(`,`) } if m.Indent != "" { out.write("\n") out.write(indent) out.write(m.Indent) out.write(m.Indent) } b, err := json.Marshal(k.Interface()) if err != nil { return err } s := string(b) // If the JSON is not a string value, encode it again to make it one. if !strings.HasPrefix(s, `"`) { b, err := json.Marshal(s) if err != nil { return err } s = string(b) } out.write(s) out.write(`:`) if m.Indent != "" { out.write(` `) } if err := m.marshalValue(out, prop, v.MapIndex(k), indent+m.Indent); err != nil { return err } } if m.Indent != "" { out.write("\n") out.write(indent) out.write(m.Indent) } out.write(`}`) return out.err } // Default handling defers to the encoding/json library. b, err := json.Marshal(v.Interface()) if err != nil { return err } needToQuote := string(b[0]) != `"` && (v.Kind() == reflect.Int64 || v.Kind() == reflect.Uint64) if needToQuote { out.write(`"`) } out.write(string(b)) if needToQuote { out.write(`"`) } return out.err } // Unmarshaler is a configurable object for converting from a JSON // representation to a protocol buffer object. type Unmarshaler struct { // Whether to allow messages to contain unknown fields, as opposed to // failing to unmarshal. AllowUnknownFields bool } // UnmarshalNext unmarshals the next protocol buffer from a JSON object stream. // This function is lenient and will decode any options permutations of the // related Marshaler. func (u *Unmarshaler) UnmarshalNext(dec *json.Decoder, pb proto.Message) error { inputValue := json.RawMessage{} if err := dec.Decode(&inputValue); err != nil { return err } return u.unmarshalValue(reflect.ValueOf(pb).Elem(), inputValue, nil) } // Unmarshal unmarshals a JSON object stream into a protocol // buffer. This function is lenient and will decode any options // permutations of the related Marshaler. func (u *Unmarshaler) Unmarshal(r io.Reader, pb proto.Message) error { dec := json.NewDecoder(r) return u.UnmarshalNext(dec, pb) } // UnmarshalNext unmarshals the next protocol buffer from a JSON object stream. // This function is lenient and will decode any options permutations of the // related Marshaler. func UnmarshalNext(dec *json.Decoder, pb proto.Message) error { return new(Unmarshaler).UnmarshalNext(dec, pb) } // Unmarshal unmarshals a JSON object stream into a protocol // buffer. This function is lenient and will decode any options // permutations of the related Marshaler. func Unmarshal(r io.Reader, pb proto.Message) error { return new(Unmarshaler).Unmarshal(r, pb) } // UnmarshalString will populate the fields of a protocol buffer based // on a JSON string. This function is lenient and will decode any options // permutations of the related Marshaler. func UnmarshalString(str string, pb proto.Message) error { return new(Unmarshaler).Unmarshal(strings.NewReader(str), pb) } // unmarshalValue converts/copies a value into the target. // prop may be nil. func (u *Unmarshaler) unmarshalValue(target reflect.Value, inputValue json.RawMessage, prop *proto.Properties) error { targetType := target.Type() // Allocate memory for pointer fields. if targetType.Kind() == reflect.Ptr { target.Set(reflect.New(targetType.Elem())) return u.unmarshalValue(target.Elem(), inputValue, prop) } // Handle well-known types. if wkt, ok := target.Addr().Interface().(isWkt); ok { switch wkt.XXX_WellKnownType() { case "DoubleValue", "FloatValue", "Int64Value", "UInt64Value", "Int32Value", "UInt32Value", "BoolValue", "StringValue", "BytesValue": // "Wrappers use the same representation in JSON // as the wrapped primitive type, except that null is allowed." // encoding/json will turn JSON `null` into Go `nil`, // so we don't have to do any extra work. return u.unmarshalValue(target.Field(0), inputValue, prop) case "Any": return fmt.Errorf("unmarshaling Any not supported yet") case "Duration": ivStr := string(inputValue) if ivStr == "null" { target.Field(0).SetInt(0) target.Field(1).SetInt(0) return nil } unq, err := strconv.Unquote(ivStr) if err != nil { return err } d, err := time.ParseDuration(unq) if err != nil { return fmt.Errorf("bad Duration: %v", err) } ns := d.Nanoseconds() s := ns / 1e9 ns %= 1e9 target.Field(0).SetInt(s) target.Field(1).SetInt(ns) return nil case "Timestamp": ivStr := string(inputValue) if ivStr == "null" { target.Field(0).SetInt(0) target.Field(1).SetInt(0) return nil } unq, err := strconv.Unquote(ivStr) if err != nil { return err } t, err := time.Parse(time.RFC3339Nano, unq) if err != nil { return fmt.Errorf("bad Timestamp: %v", err) } target.Field(0).SetInt(int64(t.Unix())) target.Field(1).SetInt(int64(t.Nanosecond())) return nil } } if t, ok := target.Addr().Interface().(*time.Time); ok { ts := &types.Timestamp{} if err := u.unmarshalValue(reflect.ValueOf(ts).Elem(), inputValue, prop); err != nil { return err } tt, err := types.TimestampFromProto(ts) if err != nil { return err } *t = tt return nil } if d, ok := target.Addr().Interface().(*time.Duration); ok { dur := &types.Duration{} if err := u.unmarshalValue(reflect.ValueOf(dur).Elem(), inputValue, prop); err != nil { return err } dd, err := types.DurationFromProto(dur) if err != nil { return err } *d = dd return nil } // Handle enums, which have an underlying type of int32, // and may appear as strings. // The case of an enum appearing as a number is handled // at the bottom of this function. if inputValue[0] == '"' && prop != nil && prop.Enum != "" { vmap := proto.EnumValueMap(prop.Enum) // Don't need to do unquoting; valid enum names // are from a limited character set. s := inputValue[1 : len(inputValue)-1] n, ok := vmap[string(s)] if !ok { return fmt.Errorf("unknown value %q for enum %s", s, prop.Enum) } if target.Kind() == reflect.Ptr { // proto2 target.Set(reflect.New(targetType.Elem())) target = target.Elem() } target.SetInt(int64(n)) return nil } // Handle nested messages. if targetType.Kind() == reflect.Struct { var jsonFields map[string]json.RawMessage if err := json.Unmarshal(inputValue, &jsonFields); err != nil { return err } consumeField := func(prop *proto.Properties) (json.RawMessage, bool) { // Be liberal in what names we accept; both orig_name and camelName are okay. fieldNames := acceptedJSONFieldNames(prop) vOrig, okOrig := jsonFields[fieldNames.orig] vCamel, okCamel := jsonFields[fieldNames.camel] if !okOrig && !okCamel { return nil, false } // If, for some reason, both are present in the data, favour the camelName. var raw json.RawMessage if okOrig { raw = vOrig delete(jsonFields, fieldNames.orig) } if okCamel { raw = vCamel delete(jsonFields, fieldNames.camel) } return raw, true } sprops := proto.GetProperties(targetType) for i := 0; i < target.NumField(); i++ { ft := target.Type().Field(i) if strings.HasPrefix(ft.Name, "XXX_") { continue } valueForField, ok := consumeField(sprops.Prop[i]) if !ok { continue } if err := u.unmarshalValue(target.Field(i), valueForField, sprops.Prop[i]); err != nil { return err } } // Check for any oneof fields. if len(jsonFields) > 0 { for _, oop := range sprops.OneofTypes { raw, ok := consumeField(oop.Prop) if !ok { continue } nv := reflect.New(oop.Type.Elem()) target.Field(oop.Field).Set(nv) if err := u.unmarshalValue(nv.Elem().Field(0), raw, oop.Prop); err != nil { return err } } } if !u.AllowUnknownFields && len(jsonFields) > 0 { // Pick any field to be the scapegoat. var f string for fname := range jsonFields { f = fname break } return fmt.Errorf("unknown field %q in %v", f, targetType) } return nil } // Handle arrays if targetType.Kind() == reflect.Slice { if targetType.Elem().Kind() == reflect.Uint8 { outRef := reflect.New(targetType) outVal := outRef.Interface() //CustomType with underlying type []byte if _, ok := outVal.(interface { UnmarshalJSON([]byte) error }); ok { if err := json.Unmarshal(inputValue, outVal); err != nil { return err } target.Set(outRef.Elem()) return nil } // Special case for encoded bytes. Pre-go1.5 doesn't support unmarshalling // strings into aliased []byte types. // https://github.com/golang/go/commit/4302fd0409da5e4f1d71471a6770dacdc3301197 // https://github.com/golang/go/commit/c60707b14d6be26bf4213114d13070bff00d0b0a var out []byte if err := json.Unmarshal(inputValue, &out); err != nil { return err } target.SetBytes(out) return nil } var slc []json.RawMessage if err := json.Unmarshal(inputValue, &slc); err != nil { return err } len := len(slc) target.Set(reflect.MakeSlice(targetType, len, len)) for i := 0; i < len; i++ { if err := u.unmarshalValue(target.Index(i), slc[i], prop); err != nil { return err } } return nil } // Handle maps (whose keys are always strings) if targetType.Kind() == reflect.Map { var mp map[string]json.RawMessage if err := json.Unmarshal(inputValue, &mp); err != nil { return err } target.Set(reflect.MakeMap(targetType)) var keyprop, valprop *proto.Properties if prop != nil { // These could still be nil if the protobuf metadata is broken somehow. // TODO: This won't work because the fields are unexported. // We should probably just reparse them. //keyprop, valprop = prop.mkeyprop, prop.mvalprop } for ks, raw := range mp { // Unmarshal map key. The core json library already decoded the key into a // string, so we handle that specially. Other types were quoted post-serialization. var k reflect.Value if targetType.Key().Kind() == reflect.String { k = reflect.ValueOf(ks) } else { k = reflect.New(targetType.Key()).Elem() if err := u.unmarshalValue(k, json.RawMessage(ks), keyprop); err != nil { return err } } if !k.Type().AssignableTo(targetType.Key()) { k = k.Convert(targetType.Key()) } // Unmarshal map value. v := reflect.New(targetType.Elem()).Elem() if err := u.unmarshalValue(v, raw, valprop); err != nil { return err } target.SetMapIndex(k, v) } return nil } // 64-bit integers can be encoded as strings. In this case we drop // the quotes and proceed as normal. isNum := targetType.Kind() == reflect.Int64 || targetType.Kind() == reflect.Uint64 if isNum && strings.HasPrefix(string(inputValue), `"`) { inputValue = inputValue[1 : len(inputValue)-1] } // Use the encoding/json for parsing other value types. return json.Unmarshal(inputValue, target.Addr().Interface()) } // jsonProperties returns parsed proto.Properties for the field and corrects JSONName attribute. func jsonProperties(f reflect.StructField, origName bool) *proto.Properties { var prop proto.Properties prop.Init(f.Type, f.Name, f.Tag.Get("protobuf"), &f) if origName || prop.JSONName == "" { prop.JSONName = prop.OrigName } return &prop } type fieldNames struct { orig, camel string } func acceptedJSONFieldNames(prop *proto.Properties) fieldNames { opts := fieldNames{orig: prop.OrigName, camel: prop.OrigName} if prop.JSONName != "" { opts.camel = prop.JSONName } return opts } // Writer wrapper inspired by https://blog.golang.org/errors-are-values type errWriter struct { writer io.Writer err error } func (w *errWriter) write(str string) { if w.err != nil { return } _, w.err = w.writer.Write([]byte(str)) } // Map fields may have key types of non-float scalars, strings and enums. // The easiest way to sort them in some deterministic order is to use fmt. // If this turns out to be inefficient we can always consider other options, // such as doing a Schwartzian transform. // // Numeric keys are sorted in numeric order per // https://developers.google.com/protocol-buffers/docs/proto#maps. type mapKeys []reflect.Value func (s mapKeys) Len() int { return len(s) } func (s mapKeys) Swap(i, j int) { s[i], s[j] = s[j], s[i] } func (s mapKeys) Less(i, j int) bool { if k := s[i].Kind(); k == s[j].Kind() { switch k { case reflect.Int32, reflect.Int64: return s[i].Int() < s[j].Int() case reflect.Uint32, reflect.Uint64: return s[i].Uint() < s[j].Uint() } } return fmt.Sprint(s[i].Interface()) < fmt.Sprint(s[j].Interface()) }