// Copyright 2009 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 gob import ( "bufio" "bytes" "io" "os" "reflect" "sync" ) // A Decoder manages the receipt of type and data information read from the // remote side of a connection. type Decoder struct { mutex sync.Mutex // each item must be received atomically r io.Reader // source of the data buf bytes.Buffer // buffer for more efficient i/o from r wireType map[typeId]*wireType // map from remote ID to local description decoderCache map[reflect.Type]map[typeId]**decEngine // cache of compiled engines ignorerCache map[typeId]**decEngine // ditto for ignored objects freeList *decoderState // list of free decoderStates; avoids reallocation countBuf []byte // used for decoding integers while parsing messages tmp []byte // temporary storage for i/o; saves reallocating err os.Error } // NewDecoder returns a new decoder that reads from the io.Reader. // If r does not also implement io.ByteReader, it will be wrapped in a // bufio.Reader. func NewDecoder(r io.Reader) *Decoder { dec := new(Decoder) // We use the ability to read bytes as a plausible surrogate for buffering. if _, ok := r.(io.ByteReader); !ok { r = bufio.NewReader(r) } dec.r = r dec.wireType = make(map[typeId]*wireType) dec.decoderCache = make(map[reflect.Type]map[typeId]**decEngine) dec.ignorerCache = make(map[typeId]**decEngine) dec.countBuf = make([]byte, 9) // counts may be uint64s (unlikely!), require 9 bytes return dec } // recvType loads the definition of a type. func (dec *Decoder) recvType(id typeId) { // Have we already seen this type? That's an error if id < firstUserId || dec.wireType[id] != nil { dec.err = os.NewError("gob: duplicate type received") return } // Type: wire := new(wireType) dec.decodeValue(tWireType, reflect.ValueOf(wire)) if dec.err != nil { return } // Remember we've seen this type. dec.wireType[id] = wire } var errBadCount = os.NewError("invalid message length") // recvMessage reads the next count-delimited item from the input. It is the converse // of Encoder.writeMessage. It returns false on EOF or other error reading the message. func (dec *Decoder) recvMessage() bool { // Read a count. nbytes, _, err := decodeUintReader(dec.r, dec.countBuf) if err != nil { dec.err = err return false } if nbytes >= 1<<31 { dec.err = errBadCount return false } dec.readMessage(int(nbytes)) return dec.err == nil } // readMessage reads the next nbytes bytes from the input. func (dec *Decoder) readMessage(nbytes int) { // Allocate the buffer. if cap(dec.tmp) < nbytes { dec.tmp = make([]byte, nbytes+100) // room to grow } dec.tmp = dec.tmp[:nbytes] // Read the data _, dec.err = io.ReadFull(dec.r, dec.tmp) if dec.err != nil { if dec.err == os.EOF { dec.err = io.ErrUnexpectedEOF } return } dec.buf.Write(dec.tmp) } // toInt turns an encoded uint64 into an int, according to the marshaling rules. func toInt(x uint64) int64 { i := int64(x >> 1) if x&1 != 0 { i = ^i } return i } func (dec *Decoder) nextInt() int64 { n, _, err := decodeUintReader(&dec.buf, dec.countBuf) if err != nil { dec.err = err } return toInt(n) } func (dec *Decoder) nextUint() uint64 { n, _, err := decodeUintReader(&dec.buf, dec.countBuf) if err != nil { dec.err = err } return n } // decodeTypeSequence parses: // TypeSequence // (TypeDefinition DelimitedTypeDefinition*)? // and returns the type id of the next value. It returns -1 at // EOF. Upon return, the remainder of dec.buf is the value to be // decoded. If this is an interface value, it can be ignored by // simply resetting that buffer. func (dec *Decoder) decodeTypeSequence(isInterface bool) typeId { for dec.err == nil { if dec.buf.Len() == 0 { if !dec.recvMessage() { break } } // Receive a type id. id := typeId(dec.nextInt()) if id >= 0 { // Value follows. return id } // Type definition for (-id) follows. dec.recvType(-id) // When decoding an interface, after a type there may be a // DelimitedValue still in the buffer. Skip its count. // (Alternatively, the buffer is empty and the byte count // will be absorbed by recvMessage.) if dec.buf.Len() > 0 { if !isInterface { dec.err = os.NewError("extra data in buffer") break } dec.nextUint() } } return -1 } // Decode reads the next value from the connection and stores // it in the data represented by the empty interface value. // If e is nil, the value will be discarded. Otherwise, // the value underlying e must be a pointer to the // correct type for the next data item received. func (dec *Decoder) Decode(e interface{}) os.Error { if e == nil { return dec.DecodeValue(reflect.Value{}) } value := reflect.ValueOf(e) // If e represents a value as opposed to a pointer, the answer won't // get back to the caller. Make sure it's a pointer. if value.Type().Kind() != reflect.Ptr { dec.err = os.NewError("gob: attempt to decode into a non-pointer") return dec.err } return dec.DecodeValue(value) } // DecodeValue reads the next value from the connection. // If v is the zero reflect.Value (v.Kind() == Invalid), DecodeValue discards the value. // Otherwise, it stores the value into v. In that case, v must represent // a non-nil pointer to data or be an assignable reflect.Value (v.CanSet()) func (dec *Decoder) DecodeValue(v reflect.Value) os.Error { if v.IsValid() { if v.Kind() == reflect.Ptr && !v.IsNil() { // That's okay, we'll store through the pointer. } else if !v.CanSet() { return os.NewError("gob: DecodeValue of unassignable value") } } // Make sure we're single-threaded through here. dec.mutex.Lock() defer dec.mutex.Unlock() dec.buf.Reset() // In case data lingers from previous invocation. dec.err = nil id := dec.decodeTypeSequence(false) if dec.err == nil { dec.decodeValue(id, v) } return dec.err } // If debug.go is compiled into the program , debugFunc prints a human-readable // representation of the gob data read from r by calling that file's Debug function. // Otherwise it is nil. var debugFunc func(io.Reader)