// Protocol Buffers for Go with Gadgets // // Copyright (c) 2013, The GoGo Authors. All rights reserved. // http://github.com/gogo/protobuf // // Go support for Protocol Buffers - Google's data interchange format // // Copyright 2010 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 proto /* * Routines for encoding data into the wire format for protocol buffers. */ import ( "fmt" "log" "os" "reflect" "sort" "strconv" "strings" "sync" ) const debug bool = false // Constants that identify the encoding of a value on the wire. const ( WireVarint = 0 WireFixed64 = 1 WireBytes = 2 WireStartGroup = 3 WireEndGroup = 4 WireFixed32 = 5 ) // tagMap is an optimization over map[int]int for typical protocol buffer // use-cases. Encoded protocol buffers are often in tag order with small tag // numbers. type tagMap struct { fastTags []int slowTags map[int]int } // tagMapFastLimit is the upper bound on the tag number that will be stored in // the tagMap slice rather than its map. const tagMapFastLimit = 1024 func (p *tagMap) get(t int) (int, bool) { if t > 0 && t < tagMapFastLimit { if t >= len(p.fastTags) { return 0, false } fi := p.fastTags[t] return fi, fi >= 0 } fi, ok := p.slowTags[t] return fi, ok } func (p *tagMap) put(t int, fi int) { if t > 0 && t < tagMapFastLimit { for len(p.fastTags) < t+1 { p.fastTags = append(p.fastTags, -1) } p.fastTags[t] = fi return } if p.slowTags == nil { p.slowTags = make(map[int]int) } p.slowTags[t] = fi } // StructProperties represents properties for all the fields of a struct. // decoderTags and decoderOrigNames should only be used by the decoder. type StructProperties struct { Prop []*Properties // properties for each field reqCount int // required count decoderTags tagMap // map from proto tag to struct field number decoderOrigNames map[string]int // map from original name to struct field number order []int // list of struct field numbers in tag order // OneofTypes contains information about the oneof fields in this message. // It is keyed by the original name of a field. OneofTypes map[string]*OneofProperties } // OneofProperties represents information about a specific field in a oneof. type OneofProperties struct { Type reflect.Type // pointer to generated struct type for this oneof field Field int // struct field number of the containing oneof in the message Prop *Properties } // Implement the sorting interface so we can sort the fields in tag order, as recommended by the spec. // See encode.go, (*Buffer).enc_struct. func (sp *StructProperties) Len() int { return len(sp.order) } func (sp *StructProperties) Less(i, j int) bool { return sp.Prop[sp.order[i]].Tag < sp.Prop[sp.order[j]].Tag } func (sp *StructProperties) Swap(i, j int) { sp.order[i], sp.order[j] = sp.order[j], sp.order[i] } // Properties represents the protocol-specific behavior of a single struct field. type Properties struct { Name string // name of the field, for error messages OrigName string // original name before protocol compiler (always set) JSONName string // name to use for JSON; determined by protoc Wire string WireType int Tag int Required bool Optional bool Repeated bool Packed bool // relevant for repeated primitives only Enum string // set for enum types only proto3 bool // whether this is known to be a proto3 field oneof bool // whether this is a oneof field Default string // default value HasDefault bool // whether an explicit default was provided CustomType string CastType string StdTime bool StdDuration bool WktPointer bool stype reflect.Type // set for struct types only ctype reflect.Type // set for custom types only sprop *StructProperties // set for struct types only mtype reflect.Type // set for map types only MapKeyProp *Properties // set for map types only MapValProp *Properties // set for map types only } // String formats the properties in the protobuf struct field tag style. func (p *Properties) String() string { s := p.Wire s += "," s += strconv.Itoa(p.Tag) if p.Required { s += ",req" } if p.Optional { s += ",opt" } if p.Repeated { s += ",rep" } if p.Packed { s += ",packed" } s += ",name=" + p.OrigName if p.JSONName != p.OrigName { s += ",json=" + p.JSONName } if p.proto3 { s += ",proto3" } if p.oneof { s += ",oneof" } if len(p.Enum) > 0 { s += ",enum=" + p.Enum } if p.HasDefault { s += ",def=" + p.Default } return s } // Parse populates p by parsing a string in the protobuf struct field tag style. func (p *Properties) Parse(s string) { // "bytes,49,opt,name=foo,def=hello!" fields := strings.Split(s, ",") // breaks def=, but handled below. if len(fields) < 2 { fmt.Fprintf(os.Stderr, "proto: tag has too few fields: %q\n", s) return } p.Wire = fields[0] switch p.Wire { case "varint": p.WireType = WireVarint case "fixed32": p.WireType = WireFixed32 case "fixed64": p.WireType = WireFixed64 case "zigzag32": p.WireType = WireVarint case "zigzag64": p.WireType = WireVarint case "bytes", "group": p.WireType = WireBytes // no numeric converter for non-numeric types default: fmt.Fprintf(os.Stderr, "proto: tag has unknown wire type: %q\n", s) return } var err error p.Tag, err = strconv.Atoi(fields[1]) if err != nil { return } outer: for i := 2; i < len(fields); i++ { f := fields[i] switch { case f == "req": p.Required = true case f == "opt": p.Optional = true case f == "rep": p.Repeated = true case f == "packed": p.Packed = true case strings.HasPrefix(f, "name="): p.OrigName = f[5:] case strings.HasPrefix(f, "json="): p.JSONName = f[5:] case strings.HasPrefix(f, "enum="): p.Enum = f[5:] case f == "proto3": p.proto3 = true case f == "oneof": p.oneof = true case strings.HasPrefix(f, "def="): p.HasDefault = true p.Default = f[4:] // rest of string if i+1 < len(fields) { // Commas aren't escaped, and def is always last. p.Default += "," + strings.Join(fields[i+1:], ",") break outer } case strings.HasPrefix(f, "embedded="): p.OrigName = strings.Split(f, "=")[1] case strings.HasPrefix(f, "customtype="): p.CustomType = strings.Split(f, "=")[1] case strings.HasPrefix(f, "casttype="): p.CastType = strings.Split(f, "=")[1] case f == "stdtime": p.StdTime = true case f == "stdduration": p.StdDuration = true case f == "wktptr": p.WktPointer = true } } } var protoMessageType = reflect.TypeOf((*Message)(nil)).Elem() // setFieldProps initializes the field properties for submessages and maps. func (p *Properties) setFieldProps(typ reflect.Type, f *reflect.StructField, lockGetProp bool) { isMap := typ.Kind() == reflect.Map if len(p.CustomType) > 0 && !isMap { p.ctype = typ p.setTag(lockGetProp) return } if p.StdTime && !isMap { p.setTag(lockGetProp) return } if p.StdDuration && !isMap { p.setTag(lockGetProp) return } if p.WktPointer && !isMap { p.setTag(lockGetProp) return } switch t1 := typ; t1.Kind() { case reflect.Struct: p.stype = typ case reflect.Ptr: if t1.Elem().Kind() == reflect.Struct { p.stype = t1.Elem() } case reflect.Slice: switch t2 := t1.Elem(); t2.Kind() { case reflect.Ptr: switch t3 := t2.Elem(); t3.Kind() { case reflect.Struct: p.stype = t3 } case reflect.Struct: p.stype = t2 } case reflect.Map: p.mtype = t1 p.MapKeyProp = &Properties{} p.MapKeyProp.init(reflect.PtrTo(p.mtype.Key()), "Key", f.Tag.Get("protobuf_key"), nil, lockGetProp) p.MapValProp = &Properties{} vtype := p.mtype.Elem() if vtype.Kind() != reflect.Ptr && vtype.Kind() != reflect.Slice { // The value type is not a message (*T) or bytes ([]byte), // so we need encoders for the pointer to this type. vtype = reflect.PtrTo(vtype) } p.MapValProp.CustomType = p.CustomType p.MapValProp.StdDuration = p.StdDuration p.MapValProp.StdTime = p.StdTime p.MapValProp.WktPointer = p.WktPointer p.MapValProp.init(vtype, "Value", f.Tag.Get("protobuf_val"), nil, lockGetProp) } p.setTag(lockGetProp) } func (p *Properties) setTag(lockGetProp bool) { if p.stype != nil { if lockGetProp { p.sprop = GetProperties(p.stype) } else { p.sprop = getPropertiesLocked(p.stype) } } } var ( marshalerType = reflect.TypeOf((*Marshaler)(nil)).Elem() ) // Init populates the properties from a protocol buffer struct tag. func (p *Properties) Init(typ reflect.Type, name, tag string, f *reflect.StructField) { p.init(typ, name, tag, f, true) } func (p *Properties) init(typ reflect.Type, name, tag string, f *reflect.StructField, lockGetProp bool) { // "bytes,49,opt,def=hello!" p.Name = name p.OrigName = name if tag == "" { return } p.Parse(tag) p.setFieldProps(typ, f, lockGetProp) } var ( propertiesMu sync.RWMutex propertiesMap = make(map[reflect.Type]*StructProperties) ) // GetProperties returns the list of properties for the type represented by t. // t must represent a generated struct type of a protocol message. func GetProperties(t reflect.Type) *StructProperties { if t.Kind() != reflect.Struct { panic("proto: type must have kind struct") } // Most calls to GetProperties in a long-running program will be // retrieving details for types we have seen before. propertiesMu.RLock() sprop, ok := propertiesMap[t] propertiesMu.RUnlock() if ok { return sprop } propertiesMu.Lock() sprop = getPropertiesLocked(t) propertiesMu.Unlock() return sprop } // getPropertiesLocked requires that propertiesMu is held. func getPropertiesLocked(t reflect.Type) *StructProperties { if prop, ok := propertiesMap[t]; ok { return prop } prop := new(StructProperties) // in case of recursive protos, fill this in now. propertiesMap[t] = prop // build properties prop.Prop = make([]*Properties, t.NumField()) prop.order = make([]int, t.NumField()) isOneofMessage := false for i := 0; i < t.NumField(); i++ { f := t.Field(i) p := new(Properties) name := f.Name p.init(f.Type, name, f.Tag.Get("protobuf"), &f, false) oneof := f.Tag.Get("protobuf_oneof") // special case if oneof != "" { isOneofMessage = true // Oneof fields don't use the traditional protobuf tag. p.OrigName = oneof } prop.Prop[i] = p prop.order[i] = i if debug { print(i, " ", f.Name, " ", t.String(), " ") if p.Tag > 0 { print(p.String()) } print("\n") } } // Re-order prop.order. sort.Sort(prop) type oneofMessage interface { XXX_OneofFuncs() (func(Message, *Buffer) error, func(Message, int, int, *Buffer) (bool, error), func(Message) int, []interface{}) } if om, ok := reflect.Zero(reflect.PtrTo(t)).Interface().(oneofMessage); isOneofMessage && ok { var oots []interface{} _, _, _, oots = om.XXX_OneofFuncs() // Interpret oneof metadata. prop.OneofTypes = make(map[string]*OneofProperties) for _, oot := range oots { oop := &OneofProperties{ Type: reflect.ValueOf(oot).Type(), // *T Prop: new(Properties), } sft := oop.Type.Elem().Field(0) oop.Prop.Name = sft.Name oop.Prop.Parse(sft.Tag.Get("protobuf")) // There will be exactly one interface field that // this new value is assignable to. for i := 0; i < t.NumField(); i++ { f := t.Field(i) if f.Type.Kind() != reflect.Interface { continue } if !oop.Type.AssignableTo(f.Type) { continue } oop.Field = i break } prop.OneofTypes[oop.Prop.OrigName] = oop } } // build required counts // build tags reqCount := 0 prop.decoderOrigNames = make(map[string]int) for i, p := range prop.Prop { if strings.HasPrefix(p.Name, "XXX_") { // Internal fields should not appear in tags/origNames maps. // They are handled specially when encoding and decoding. continue } if p.Required { reqCount++ } prop.decoderTags.put(p.Tag, i) prop.decoderOrigNames[p.OrigName] = i } prop.reqCount = reqCount return prop } // A global registry of enum types. // The generated code will register the generated maps by calling RegisterEnum. var enumValueMaps = make(map[string]map[string]int32) var enumStringMaps = make(map[string]map[int32]string) // RegisterEnum is called from the generated code to install the enum descriptor // maps into the global table to aid parsing text format protocol buffers. func RegisterEnum(typeName string, unusedNameMap map[int32]string, valueMap map[string]int32) { if _, ok := enumValueMaps[typeName]; ok { panic("proto: duplicate enum registered: " + typeName) } enumValueMaps[typeName] = valueMap if _, ok := enumStringMaps[typeName]; ok { panic("proto: duplicate enum registered: " + typeName) } enumStringMaps[typeName] = unusedNameMap } // EnumValueMap returns the mapping from names to integers of the // enum type enumType, or a nil if not found. func EnumValueMap(enumType string) map[string]int32 { return enumValueMaps[enumType] } // A registry of all linked message types. // The string is a fully-qualified proto name ("pkg.Message"). var ( protoTypedNils = make(map[string]Message) // a map from proto names to typed nil pointers protoMapTypes = make(map[string]reflect.Type) // a map from proto names to map types revProtoTypes = make(map[reflect.Type]string) ) // RegisterType is called from generated code and maps from the fully qualified // proto name to the type (pointer to struct) of the protocol buffer. func RegisterType(x Message, name string) { if _, ok := protoTypedNils[name]; ok { // TODO: Some day, make this a panic. log.Printf("proto: duplicate proto type registered: %s", name) return } t := reflect.TypeOf(x) if v := reflect.ValueOf(x); v.Kind() == reflect.Ptr && v.Pointer() == 0 { // Generated code always calls RegisterType with nil x. // This check is just for extra safety. protoTypedNils[name] = x } else { protoTypedNils[name] = reflect.Zero(t).Interface().(Message) } revProtoTypes[t] = name } // RegisterMapType is called from generated code and maps from the fully qualified // proto name to the native map type of the proto map definition. func RegisterMapType(x interface{}, name string) { if reflect.TypeOf(x).Kind() != reflect.Map { panic(fmt.Sprintf("RegisterMapType(%T, %q); want map", x, name)) } if _, ok := protoMapTypes[name]; ok { log.Printf("proto: duplicate proto type registered: %s", name) return } t := reflect.TypeOf(x) protoMapTypes[name] = t revProtoTypes[t] = name } // MessageName returns the fully-qualified proto name for the given message type. func MessageName(x Message) string { type xname interface { XXX_MessageName() string } if m, ok := x.(xname); ok { return m.XXX_MessageName() } return revProtoTypes[reflect.TypeOf(x)] } // MessageType returns the message type (pointer to struct) for a named message. // The type is not guaranteed to implement proto.Message if the name refers to a // map entry. func MessageType(name string) reflect.Type { if t, ok := protoTypedNils[name]; ok { return reflect.TypeOf(t) } return protoMapTypes[name] } // A registry of all linked proto files. var ( protoFiles = make(map[string][]byte) // file name => fileDescriptor ) // RegisterFile is called from generated code and maps from the // full file name of a .proto file to its compressed FileDescriptorProto. func RegisterFile(filename string, fileDescriptor []byte) { protoFiles[filename] = fileDescriptor } // FileDescriptor returns the compressed FileDescriptorProto for a .proto file. func FileDescriptor(filename string) []byte { return protoFiles[filename] }