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[/] [openrisc/] [trunk/] [gnu-dev/] [or1k-gcc/] [libgo/] [go/] [encoding/] [gob/] [decode.go] - Rev 747
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// 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// TODO(rsc): When garbage collector changes, revisit// the allocations in this file that use unsafe.Pointer.import ("bytes""errors""io""math""reflect""unsafe")var (errBadUint = errors.New("gob: encoded unsigned integer out of range")errBadType = errors.New("gob: unknown type id or corrupted data")errRange = errors.New("gob: bad data: field numbers out of bounds"))// decoderState is the execution state of an instance of the decoder. A new state// is created for nested objects.type decoderState struct {dec *Decoder// The buffer is stored with an extra indirection because it may be replaced// if we load a type during decode (when reading an interface value).b *bytes.Bufferfieldnum int // the last field number read.buf []bytenext *decoderState // for free list}// We pass the bytes.Buffer separately for easier testing of the infrastructure// without requiring a full Decoder.func (dec *Decoder) newDecoderState(buf *bytes.Buffer) *decoderState {d := dec.freeListif d == nil {d = new(decoderState)d.dec = decd.buf = make([]byte, uint64Size)} else {dec.freeList = d.next}d.b = bufreturn d}func (dec *Decoder) freeDecoderState(d *decoderState) {d.next = dec.freeListdec.freeList = d}func overflow(name string) error {return errors.New(`value for "` + name + `" out of range`)}// decodeUintReader reads an encoded unsigned integer from an io.Reader.// Used only by the Decoder to read the message length.func decodeUintReader(r io.Reader, buf []byte) (x uint64, width int, err error) {width = 1_, err = r.Read(buf[0:width])if err != nil {return}b := buf[0]if b <= 0x7f {return uint64(b), width, nil}n := -int(int8(b))if n > uint64Size {err = errBadUintreturn}width, err = io.ReadFull(r, buf[0:n])if err != nil {if err == io.EOF {err = io.ErrUnexpectedEOF}return}// Could check that the high byte is zero but it's not worth it.for _, b := range buf[0:width] {x = x<<8 | uint64(b)}width++ // +1 for length bytereturn}// decodeUint reads an encoded unsigned integer from state.r.// Does not check for overflow.func (state *decoderState) decodeUint() (x uint64) {b, err := state.b.ReadByte()if err != nil {error_(err)}if b <= 0x7f {return uint64(b)}n := -int(int8(b))if n > uint64Size {error_(errBadUint)}width, err := state.b.Read(state.buf[0:n])if err != nil {error_(err)}// Don't need to check error; it's safe to loop regardless.// Could check that the high byte is zero but it's not worth it.for _, b := range state.buf[0:width] {x = x<<8 | uint64(b)}return x}// decodeInt reads an encoded signed integer from state.r.// Does not check for overflow.func (state *decoderState) decodeInt() int64 {x := state.decodeUint()if x&1 != 0 {return ^int64(x >> 1)}return int64(x >> 1)}// decOp is the signature of a decoding operator for a given type.type decOp func(i *decInstr, state *decoderState, p unsafe.Pointer)// The 'instructions' of the decoding machinetype decInstr struct {op decOpfield int // field number of the wire typeindir int // how many pointer indirections to reach the value in the structoffset uintptr // offset in the structure of the field to encodeovfl error // error message for overflow/underflow (for arrays, of the elements)}// Since the encoder writes no zeros, if we arrive at a decoder we have// a value to extract and store. The field number has already been read// (it's how we knew to call this decoder).// Each decoder is responsible for handling any indirections associated// with the data structure. If any pointer so reached is nil, allocation must// be done.// Walk the pointer hierarchy, allocating if we find a nil. Stop one before the end.func decIndirect(p unsafe.Pointer, indir int) unsafe.Pointer {for ; indir > 1; indir-- {if *(*unsafe.Pointer)(p) == nil {// Allocation required*(*unsafe.Pointer)(p) = unsafe.Pointer(new(unsafe.Pointer))}p = *(*unsafe.Pointer)(p)}return p}// ignoreUint discards a uint value with no destination.func ignoreUint(i *decInstr, state *decoderState, p unsafe.Pointer) {state.decodeUint()}// ignoreTwoUints discards a uint value with no destination. It's used to skip// complex values.func ignoreTwoUints(i *decInstr, state *decoderState, p unsafe.Pointer) {state.decodeUint()state.decodeUint()}// decBool decodes a uint and stores it as a boolean through p.func decBool(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(bool))}p = *(*unsafe.Pointer)(p)}*(*bool)(p) = state.decodeUint() != 0}// decInt8 decodes an integer and stores it as an int8 through p.func decInt8(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(int8))}p = *(*unsafe.Pointer)(p)}v := state.decodeInt()if v < math.MinInt8 || math.MaxInt8 < v {error_(i.ovfl)} else {*(*int8)(p) = int8(v)}}// decUint8 decodes an unsigned integer and stores it as a uint8 through p.func decUint8(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(uint8))}p = *(*unsafe.Pointer)(p)}v := state.decodeUint()if math.MaxUint8 < v {error_(i.ovfl)} else {*(*uint8)(p) = uint8(v)}}// decInt16 decodes an integer and stores it as an int16 through p.func decInt16(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(int16))}p = *(*unsafe.Pointer)(p)}v := state.decodeInt()if v < math.MinInt16 || math.MaxInt16 < v {error_(i.ovfl)} else {*(*int16)(p) = int16(v)}}// decUint16 decodes an unsigned integer and stores it as a uint16 through p.func decUint16(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(uint16))}p = *(*unsafe.Pointer)(p)}v := state.decodeUint()if math.MaxUint16 < v {error_(i.ovfl)} else {*(*uint16)(p) = uint16(v)}}// decInt32 decodes an integer and stores it as an int32 through p.func decInt32(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(int32))}p = *(*unsafe.Pointer)(p)}v := state.decodeInt()if v < math.MinInt32 || math.MaxInt32 < v {error_(i.ovfl)} else {*(*int32)(p) = int32(v)}}// decUint32 decodes an unsigned integer and stores it as a uint32 through p.func decUint32(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(uint32))}p = *(*unsafe.Pointer)(p)}v := state.decodeUint()if math.MaxUint32 < v {error_(i.ovfl)} else {*(*uint32)(p) = uint32(v)}}// decInt64 decodes an integer and stores it as an int64 through p.func decInt64(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(int64))}p = *(*unsafe.Pointer)(p)}*(*int64)(p) = int64(state.decodeInt())}// decUint64 decodes an unsigned integer and stores it as a uint64 through p.func decUint64(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(uint64))}p = *(*unsafe.Pointer)(p)}*(*uint64)(p) = uint64(state.decodeUint())}// Floating-point numbers are transmitted as uint64s holding the bits// of the underlying representation. They are sent byte-reversed, with// the exponent end coming out first, so integer floating point numbers// (for example) transmit more compactly. This routine does the// unswizzling.func floatFromBits(u uint64) float64 {var v uint64for i := 0; i < 8; i++ {v <<= 8v |= u & 0xFFu >>= 8}return math.Float64frombits(v)}// storeFloat32 decodes an unsigned integer, treats it as a 32-bit floating-point// number, and stores it through p. It's a helper function for float32 and complex64.func storeFloat32(i *decInstr, state *decoderState, p unsafe.Pointer) {v := floatFromBits(state.decodeUint())av := vif av < 0 {av = -av}// +Inf is OK in both 32- and 64-bit floats. Underflow is always OK.if math.MaxFloat32 < av && av <= math.MaxFloat64 {error_(i.ovfl)} else {*(*float32)(p) = float32(v)}}// decFloat32 decodes an unsigned integer, treats it as a 32-bit floating-point// number, and stores it through p.func decFloat32(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(float32))}p = *(*unsafe.Pointer)(p)}storeFloat32(i, state, p)}// decFloat64 decodes an unsigned integer, treats it as a 64-bit floating-point// number, and stores it through p.func decFloat64(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(float64))}p = *(*unsafe.Pointer)(p)}*(*float64)(p) = floatFromBits(uint64(state.decodeUint()))}// decComplex64 decodes a pair of unsigned integers, treats them as a// pair of floating point numbers, and stores them as a complex64 through p.// The real part comes first.func decComplex64(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(complex64))}p = *(*unsafe.Pointer)(p)}storeFloat32(i, state, p)storeFloat32(i, state, unsafe.Pointer(uintptr(p)+unsafe.Sizeof(float32(0))))}// decComplex128 decodes a pair of unsigned integers, treats them as a// pair of floating point numbers, and stores them as a complex128 through p.// The real part comes first.func decComplex128(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(complex128))}p = *(*unsafe.Pointer)(p)}real := floatFromBits(uint64(state.decodeUint()))imag := floatFromBits(uint64(state.decodeUint()))*(*complex128)(p) = complex(real, imag)}// decUint8Slice decodes a byte slice and stores through p a slice header// describing the data.// uint8 slices are encoded as an unsigned count followed by the raw bytes.func decUint8Slice(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new([]uint8))}p = *(*unsafe.Pointer)(p)}n := int(state.decodeUint())if n < 0 {errorf("negative length decoding []byte")}slice := (*[]uint8)(p)if cap(*slice) < n {*slice = make([]uint8, n)} else {*slice = (*slice)[0:n]}if _, err := state.b.Read(*slice); err != nil {errorf("error decoding []byte: %s", err)}}// decString decodes byte array and stores through p a string header// describing the data.// Strings are encoded as an unsigned count followed by the raw bytes.func decString(i *decInstr, state *decoderState, p unsafe.Pointer) {if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.Pointer(new(string))}p = *(*unsafe.Pointer)(p)}b := make([]byte, state.decodeUint())state.b.Read(b)// It would be a shame to do the obvious thing here,// *(*string)(p) = string(b)// because we've already allocated the storage and this would// allocate again and copy. So we do this ugly hack, which is even// even more unsafe than it looks as it depends the memory// representation of a string matching the beginning of the memory// representation of a byte slice (a byte slice is longer).*(*string)(p) = *(*string)(unsafe.Pointer(&b))}// ignoreUint8Array skips over the data for a byte slice value with no destination.func ignoreUint8Array(i *decInstr, state *decoderState, p unsafe.Pointer) {b := make([]byte, state.decodeUint())state.b.Read(b)}// Execution engine// The encoder engine is an array of instructions indexed by field number of the incoming// decoder. It is executed with random access according to field number.type decEngine struct {instr []decInstrnumInstr int // the number of active instructions}// allocate makes sure storage is available for an object of underlying type rtyp// that is indir levels of indirection through p.func allocate(rtyp reflect.Type, p uintptr, indir int) uintptr {if indir == 0 {return p}up := unsafe.Pointer(p)if indir > 1 {up = decIndirect(up, indir)}if *(*unsafe.Pointer)(up) == nil {// Allocate object.*(*unsafe.Pointer)(up) = unsafe.New(rtyp)}return *(*uintptr)(up)}// decodeSingle decodes a top-level value that is not a struct and stores it through p.// Such values are preceded by a zero, making them have the memory layout of a// struct field (although with an illegal field number).func (dec *Decoder) decodeSingle(engine *decEngine, ut *userTypeInfo, basep uintptr) (err error) {state := dec.newDecoderState(&dec.buf)state.fieldnum = singletonFielddelta := int(state.decodeUint())if delta != 0 {errorf("decode: corrupted data: non-zero delta for singleton")}instr := &engine.instr[singletonField]if instr.indir != ut.indir {return errors.New("gob: internal error: inconsistent indirection")}ptr := unsafe.Pointer(basep) // offset will be zeroif instr.indir > 1 {ptr = decIndirect(ptr, instr.indir)}instr.op(instr, state, ptr)dec.freeDecoderState(state)return nil}// decodeSingle decodes a top-level struct and stores it through p.// Indir is for the value, not the type. At the time of the call it may// differ from ut.indir, which was computed when the engine was built.// This state cannot arise for decodeSingle, which is called directly// from the user's value, not from the innards of an engine.func (dec *Decoder) decodeStruct(engine *decEngine, ut *userTypeInfo, p uintptr, indir int) {p = allocate(ut.base, p, indir)state := dec.newDecoderState(&dec.buf)state.fieldnum = -1basep := pfor state.b.Len() > 0 {delta := int(state.decodeUint())if delta < 0 {errorf("decode: corrupted data: negative delta")}if delta == 0 { // struct terminator is zero delta fieldnumbreak}fieldnum := state.fieldnum + deltaif fieldnum >= len(engine.instr) {error_(errRange)break}instr := &engine.instr[fieldnum]p := unsafe.Pointer(basep + instr.offset)if instr.indir > 1 {p = decIndirect(p, instr.indir)}instr.op(instr, state, p)state.fieldnum = fieldnum}dec.freeDecoderState(state)}// ignoreStruct discards the data for a struct with no destination.func (dec *Decoder) ignoreStruct(engine *decEngine) {state := dec.newDecoderState(&dec.buf)state.fieldnum = -1for state.b.Len() > 0 {delta := int(state.decodeUint())if delta < 0 {errorf("ignore decode: corrupted data: negative delta")}if delta == 0 { // struct terminator is zero delta fieldnumbreak}fieldnum := state.fieldnum + deltaif fieldnum >= len(engine.instr) {error_(errRange)}instr := &engine.instr[fieldnum]instr.op(instr, state, unsafe.Pointer(nil))state.fieldnum = fieldnum}dec.freeDecoderState(state)}// ignoreSingle discards the data for a top-level non-struct value with no// destination. It's used when calling Decode with a nil value.func (dec *Decoder) ignoreSingle(engine *decEngine) {state := dec.newDecoderState(&dec.buf)state.fieldnum = singletonFielddelta := int(state.decodeUint())if delta != 0 {errorf("decode: corrupted data: non-zero delta for singleton")}instr := &engine.instr[singletonField]instr.op(instr, state, unsafe.Pointer(nil))dec.freeDecoderState(state)}// decodeArrayHelper does the work for decoding arrays and slices.func (dec *Decoder) decodeArrayHelper(state *decoderState, p uintptr, elemOp decOp, elemWid uintptr, length, elemIndir int, ovfl error) {instr := &decInstr{elemOp, 0, elemIndir, 0, ovfl}for i := 0; i < length; i++ {up := unsafe.Pointer(p)if elemIndir > 1 {up = decIndirect(up, elemIndir)}elemOp(instr, state, up)p += uintptr(elemWid)}}// decodeArray decodes an array and stores it through p, that is, p points to the zeroth element.// The length is an unsigned integer preceding the elements. Even though the length is redundant// (it's part of the type), it's a useful check and is included in the encoding.func (dec *Decoder) decodeArray(atyp reflect.Type, state *decoderState, p uintptr, elemOp decOp, elemWid uintptr, length, indir, elemIndir int, ovfl error) {if indir > 0 {p = allocate(atyp, p, 1) // All but the last level has been allocated by dec.Indirect}if n := state.decodeUint(); n != uint64(length) {errorf("length mismatch in decodeArray")}dec.decodeArrayHelper(state, p, elemOp, elemWid, length, elemIndir, ovfl)}// decodeIntoValue is a helper for map decoding. Since maps are decoded using reflection,// unlike the other items we can't use a pointer directly.func decodeIntoValue(state *decoderState, op decOp, indir int, v reflect.Value, ovfl error) reflect.Value {instr := &decInstr{op, 0, indir, 0, ovfl}up := unsafe.Pointer(unsafeAddr(v))if indir > 1 {up = decIndirect(up, indir)}op(instr, state, up)return v}// decodeMap decodes a map and stores its header through p.// Maps are encoded as a length followed by key:value pairs.// Because the internals of maps are not visible to us, we must// use reflection rather than pointer magic.func (dec *Decoder) decodeMap(mtyp reflect.Type, state *decoderState, p uintptr, keyOp, elemOp decOp, indir, keyIndir, elemIndir int, ovfl error) {if indir > 0 {p = allocate(mtyp, p, 1) // All but the last level has been allocated by dec.Indirect}up := unsafe.Pointer(p)if *(*unsafe.Pointer)(up) == nil { // maps are represented as a pointer in the runtime// Allocate map.*(*unsafe.Pointer)(up) = unsafe.Pointer(reflect.MakeMap(mtyp).Pointer())}// Maps cannot be accessed by moving addresses around the way// that slices etc. can. We must recover a full reflection value for// the iteration.v := reflect.ValueOf(unsafe.Unreflect(mtyp, unsafe.Pointer(p)))n := int(state.decodeUint())for i := 0; i < n; i++ {key := decodeIntoValue(state, keyOp, keyIndir, allocValue(mtyp.Key()), ovfl)elem := decodeIntoValue(state, elemOp, elemIndir, allocValue(mtyp.Elem()), ovfl)v.SetMapIndex(key, elem)}}// ignoreArrayHelper does the work for discarding arrays and slices.func (dec *Decoder) ignoreArrayHelper(state *decoderState, elemOp decOp, length int) {instr := &decInstr{elemOp, 0, 0, 0, errors.New("no error")}for i := 0; i < length; i++ {elemOp(instr, state, nil)}}// ignoreArray discards the data for an array value with no destination.func (dec *Decoder) ignoreArray(state *decoderState, elemOp decOp, length int) {if n := state.decodeUint(); n != uint64(length) {errorf("length mismatch in ignoreArray")}dec.ignoreArrayHelper(state, elemOp, length)}// ignoreMap discards the data for a map value with no destination.func (dec *Decoder) ignoreMap(state *decoderState, keyOp, elemOp decOp) {n := int(state.decodeUint())keyInstr := &decInstr{keyOp, 0, 0, 0, errors.New("no error")}elemInstr := &decInstr{elemOp, 0, 0, 0, errors.New("no error")}for i := 0; i < n; i++ {keyOp(keyInstr, state, nil)elemOp(elemInstr, state, nil)}}// decodeSlice decodes a slice and stores the slice header through p.// Slices are encoded as an unsigned length followed by the elements.func (dec *Decoder) decodeSlice(atyp reflect.Type, state *decoderState, p uintptr, elemOp decOp, elemWid uintptr, indir, elemIndir int, ovfl error) {n := int(uintptr(state.decodeUint()))if indir > 0 {up := unsafe.Pointer(p)if *(*unsafe.Pointer)(up) == nil {// Allocate the slice header.*(*unsafe.Pointer)(up) = unsafe.Pointer(new([]unsafe.Pointer))}p = *(*uintptr)(up)}// Allocate storage for the slice elements, that is, the underlying array,// if the existing slice does not have the capacity.// Always write a header at p.hdrp := (*reflect.SliceHeader)(unsafe.Pointer(p))if hdrp.Cap < n {hdrp.Data = uintptr(unsafe.NewArray(atyp.Elem(), n))hdrp.Cap = n}hdrp.Len = ndec.decodeArrayHelper(state, hdrp.Data, elemOp, elemWid, n, elemIndir, ovfl)}// ignoreSlice skips over the data for a slice value with no destination.func (dec *Decoder) ignoreSlice(state *decoderState, elemOp decOp) {dec.ignoreArrayHelper(state, elemOp, int(state.decodeUint()))}// setInterfaceValue sets an interface value to a concrete value,// but first it checks that the assignment will succeed.func setInterfaceValue(ivalue reflect.Value, value reflect.Value) {if !value.Type().AssignableTo(ivalue.Type()) {errorf("cannot assign value of type %s to %s", value.Type(), ivalue.Type())}ivalue.Set(value)}// decodeInterface decodes an interface value and stores it through p.// Interfaces are encoded as the name of a concrete type followed by a value.// If the name is empty, the value is nil and no value is sent.func (dec *Decoder) decodeInterface(ityp reflect.Type, state *decoderState, p uintptr, indir int) {// Create a writable interface reflect.Value. We need one even for the nil case.ivalue := allocValue(ityp)// Read the name of the concrete type.nr := state.decodeUint()if nr < 0 || nr > 1<<31 { // zero is permissible for anonymous typeserrorf("invalid type name length %d", nr)}b := make([]byte, nr)state.b.Read(b)name := string(b)if name == "" {// Copy the representation of the nil interface value to the target.// This is horribly unsafe and special.*(*[2]uintptr)(unsafe.Pointer(p)) = ivalue.InterfaceData()return}// The concrete type must be registered.typ, ok := nameToConcreteType[name]if !ok {errorf("name not registered for interface: %q", name)}// Read the type id of the concrete value.concreteId := dec.decodeTypeSequence(true)if concreteId < 0 {error_(dec.err)}// Byte count of value is next; we don't care what it is (it's there// in case we want to ignore the value by skipping it completely).state.decodeUint()// Read the concrete value.value := allocValue(typ)dec.decodeValue(concreteId, value)if dec.err != nil {error_(dec.err)}// Allocate the destination interface value.if indir > 0 {p = allocate(ityp, p, 1) // All but the last level has been allocated by dec.Indirect}// Assign the concrete value to the interface.// Tread carefully; it might not satisfy the interface.setInterfaceValue(ivalue, value)// Copy the representation of the interface value to the target.// This is horribly unsafe and special.*(*[2]uintptr)(unsafe.Pointer(p)) = ivalue.InterfaceData()}// ignoreInterface discards the data for an interface value with no destination.func (dec *Decoder) ignoreInterface(state *decoderState) {// Read the name of the concrete type.b := make([]byte, state.decodeUint())_, err := state.b.Read(b)if err != nil {error_(err)}id := dec.decodeTypeSequence(true)if id < 0 {error_(dec.err)}// At this point, the decoder buffer contains a delimited value. Just toss it.state.b.Next(int(state.decodeUint()))}// decodeGobDecoder decodes something implementing the GobDecoder interface.// The data is encoded as a byte slice.func (dec *Decoder) decodeGobDecoder(state *decoderState, v reflect.Value) {// Read the bytes for the value.b := make([]byte, state.decodeUint())_, err := state.b.Read(b)if err != nil {error_(err)}// We know it's a GobDecoder, so just call the method directly.err = v.Interface().(GobDecoder).GobDecode(b)if err != nil {error_(err)}}// ignoreGobDecoder discards the data for a GobDecoder value with no destination.func (dec *Decoder) ignoreGobDecoder(state *decoderState) {// Read the bytes for the value.b := make([]byte, state.decodeUint())_, err := state.b.Read(b)if err != nil {error_(err)}}// Index by Go types.var decOpTable = [...]decOp{reflect.Bool: decBool,reflect.Int8: decInt8,reflect.Int16: decInt16,reflect.Int32: decInt32,reflect.Int64: decInt64,reflect.Uint8: decUint8,reflect.Uint16: decUint16,reflect.Uint32: decUint32,reflect.Uint64: decUint64,reflect.Float32: decFloat32,reflect.Float64: decFloat64,reflect.Complex64: decComplex64,reflect.Complex128: decComplex128,reflect.String: decString,}// Indexed by gob types. tComplex will be added during type.init().var decIgnoreOpMap = map[typeId]decOp{tBool: ignoreUint,tInt: ignoreUint,tUint: ignoreUint,tFloat: ignoreUint,tBytes: ignoreUint8Array,tString: ignoreUint8Array,tComplex: ignoreTwoUints,}// decOpFor returns the decoding op for the base type under rt and// the indirection count to reach it.func (dec *Decoder) decOpFor(wireId typeId, rt reflect.Type, name string, inProgress map[reflect.Type]*decOp) (*decOp, int) {ut := userType(rt)// If the type implements GobEncoder, we handle it without further processing.if ut.isGobDecoder {return dec.gobDecodeOpFor(ut)}// If this type is already in progress, it's a recursive type (e.g. map[string]*T).// Return the pointer to the op we're already building.if opPtr := inProgress[rt]; opPtr != nil {return opPtr, ut.indir}typ := ut.baseindir := ut.indirvar op decOpk := typ.Kind()if int(k) < len(decOpTable) {op = decOpTable[k]}if op == nil {inProgress[rt] = &op// Special casesswitch t := typ; t.Kind() {case reflect.Array:name = "element of " + nameelemId := dec.wireType[wireId].ArrayT.ElemelemOp, elemIndir := dec.decOpFor(elemId, t.Elem(), name, inProgress)ovfl := overflow(name)op = func(i *decInstr, state *decoderState, p unsafe.Pointer) {state.dec.decodeArray(t, state, uintptr(p), *elemOp, t.Elem().Size(), t.Len(), i.indir, elemIndir, ovfl)}case reflect.Map:name = "element of " + namekeyId := dec.wireType[wireId].MapT.KeyelemId := dec.wireType[wireId].MapT.ElemkeyOp, keyIndir := dec.decOpFor(keyId, t.Key(), name, inProgress)elemOp, elemIndir := dec.decOpFor(elemId, t.Elem(), name, inProgress)ovfl := overflow(name)op = func(i *decInstr, state *decoderState, p unsafe.Pointer) {up := unsafe.Pointer(p)state.dec.decodeMap(t, state, uintptr(up), *keyOp, *elemOp, i.indir, keyIndir, elemIndir, ovfl)}case reflect.Slice:name = "element of " + nameif t.Elem().Kind() == reflect.Uint8 {op = decUint8Slicebreak}var elemId typeIdif tt, ok := builtinIdToType[wireId]; ok {elemId = tt.(*sliceType).Elem} else {elemId = dec.wireType[wireId].SliceT.Elem}elemOp, elemIndir := dec.decOpFor(elemId, t.Elem(), name, inProgress)ovfl := overflow(name)op = func(i *decInstr, state *decoderState, p unsafe.Pointer) {state.dec.decodeSlice(t, state, uintptr(p), *elemOp, t.Elem().Size(), i.indir, elemIndir, ovfl)}case reflect.Struct:// Generate a closure that calls out to the engine for the nested type.enginePtr, err := dec.getDecEnginePtr(wireId, userType(typ))if err != nil {error_(err)}op = func(i *decInstr, state *decoderState, p unsafe.Pointer) {// indirect through enginePtr to delay evaluation for recursive structs.dec.decodeStruct(*enginePtr, userType(typ), uintptr(p), i.indir)}case reflect.Interface:op = func(i *decInstr, state *decoderState, p unsafe.Pointer) {state.dec.decodeInterface(t, state, uintptr(p), i.indir)}}}if op == nil {errorf("decode can't handle type %s", rt)}return &op, indir}// decIgnoreOpFor returns the decoding op for a field that has no destination.func (dec *Decoder) decIgnoreOpFor(wireId typeId) decOp {op, ok := decIgnoreOpMap[wireId]if !ok {if wireId == tInterface {// Special case because it's a method: the ignored item might// define types and we need to record their state in the decoder.op = func(i *decInstr, state *decoderState, p unsafe.Pointer) {state.dec.ignoreInterface(state)}return op}// Special caseswire := dec.wireType[wireId]switch {case wire == nil:errorf("bad data: undefined type %s", wireId.string())case wire.ArrayT != nil:elemId := wire.ArrayT.ElemelemOp := dec.decIgnoreOpFor(elemId)op = func(i *decInstr, state *decoderState, p unsafe.Pointer) {state.dec.ignoreArray(state, elemOp, wire.ArrayT.Len)}case wire.MapT != nil:keyId := dec.wireType[wireId].MapT.KeyelemId := dec.wireType[wireId].MapT.ElemkeyOp := dec.decIgnoreOpFor(keyId)elemOp := dec.decIgnoreOpFor(elemId)op = func(i *decInstr, state *decoderState, p unsafe.Pointer) {state.dec.ignoreMap(state, keyOp, elemOp)}case wire.SliceT != nil:elemId := wire.SliceT.ElemelemOp := dec.decIgnoreOpFor(elemId)op = func(i *decInstr, state *decoderState, p unsafe.Pointer) {state.dec.ignoreSlice(state, elemOp)}case wire.StructT != nil:// Generate a closure that calls out to the engine for the nested type.enginePtr, err := dec.getIgnoreEnginePtr(wireId)if err != nil {error_(err)}op = func(i *decInstr, state *decoderState, p unsafe.Pointer) {// indirect through enginePtr to delay evaluation for recursive structsstate.dec.ignoreStruct(*enginePtr)}case wire.GobEncoderT != nil:op = func(i *decInstr, state *decoderState, p unsafe.Pointer) {state.dec.ignoreGobDecoder(state)}}}if op == nil {errorf("bad data: ignore can't handle type %s", wireId.string())}return op}// gobDecodeOpFor returns the op for a type that is known to implement// GobDecoder.func (dec *Decoder) gobDecodeOpFor(ut *userTypeInfo) (*decOp, int) {rcvrType := ut.userif ut.decIndir == -1 {rcvrType = reflect.PtrTo(rcvrType)} else if ut.decIndir > 0 {for i := int8(0); i < ut.decIndir; i++ {rcvrType = rcvrType.Elem()}}var op decOpop = func(i *decInstr, state *decoderState, p unsafe.Pointer) {// Caller has gotten us to within one indirection of our value.if i.indir > 0 {if *(*unsafe.Pointer)(p) == nil {*(*unsafe.Pointer)(p) = unsafe.New(ut.base)}}// Now p is a pointer to the base type. Do we need to climb out to// get to the receiver type?var v reflect.Valueif ut.decIndir == -1 {v = reflect.ValueOf(unsafe.Unreflect(rcvrType, unsafe.Pointer(&p)))} else {v = reflect.ValueOf(unsafe.Unreflect(rcvrType, p))}state.dec.decodeGobDecoder(state, v)}return &op, int(ut.indir)}// compatibleType asks: Are these two gob Types compatible?// Answers the question for basic types, arrays, maps and slices, plus// GobEncoder/Decoder pairs.// Structs are considered ok; fields will be checked later.func (dec *Decoder) compatibleType(fr reflect.Type, fw typeId, inProgress map[reflect.Type]typeId) bool {if rhs, ok := inProgress[fr]; ok {return rhs == fw}inProgress[fr] = fwut := userType(fr)wire, ok := dec.wireType[fw]// If fr is a GobDecoder, the wire type must be GobEncoder.// And if fr is not a GobDecoder, the wire type must not be either.if ut.isGobDecoder != (ok && wire.GobEncoderT != nil) { // the parentheses look odd but are correct.return false}if ut.isGobDecoder { // This test trumps all others.return true}switch t := ut.base; t.Kind() {default:// chan, etc: cannot handle.return falsecase reflect.Bool:return fw == tBoolcase reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:return fw == tIntcase reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr:return fw == tUintcase reflect.Float32, reflect.Float64:return fw == tFloatcase reflect.Complex64, reflect.Complex128:return fw == tComplexcase reflect.String:return fw == tStringcase reflect.Interface:return fw == tInterfacecase reflect.Array:if !ok || wire.ArrayT == nil {return false}array := wire.ArrayTreturn t.Len() == array.Len && dec.compatibleType(t.Elem(), array.Elem, inProgress)case reflect.Map:if !ok || wire.MapT == nil {return false}MapType := wire.MapTreturn dec.compatibleType(t.Key(), MapType.Key, inProgress) && dec.compatibleType(t.Elem(), MapType.Elem, inProgress)case reflect.Slice:// Is it an array of bytes?if t.Elem().Kind() == reflect.Uint8 {return fw == tBytes}// Extract and compare element types.var sw *sliceTypeif tt, ok := builtinIdToType[fw]; ok {sw, _ = tt.(*sliceType)} else if wire != nil {sw = wire.SliceT}elem := userType(t.Elem()).basereturn sw != nil && dec.compatibleType(elem, sw.Elem, inProgress)case reflect.Struct:return true}return true}// typeString returns a human-readable description of the type identified by remoteId.func (dec *Decoder) typeString(remoteId typeId) string {if t := idToType[remoteId]; t != nil {// globally known type.return t.string()}return dec.wireType[remoteId].string()}// compileSingle compiles the decoder engine for a non-struct top-level value, including// GobDecoders.func (dec *Decoder) compileSingle(remoteId typeId, ut *userTypeInfo) (engine *decEngine, err error) {rt := ut.userengine = new(decEngine)engine.instr = make([]decInstr, 1) // one itemname := rt.String() // best we can doif !dec.compatibleType(rt, remoteId, make(map[reflect.Type]typeId)) {remoteType := dec.typeString(remoteId)// Common confusing case: local interface type, remote concrete type.if ut.base.Kind() == reflect.Interface && remoteId != tInterface {return nil, errors.New("gob: local interface type " + name + " can only be decoded from remote interface type; received concrete type " + remoteType)}return nil, errors.New("gob: decoding into local type " + name + ", received remote type " + remoteType)}op, indir := dec.decOpFor(remoteId, rt, name, make(map[reflect.Type]*decOp))ovfl := errors.New(`value for "` + name + `" out of range`)engine.instr[singletonField] = decInstr{*op, singletonField, indir, 0, ovfl}engine.numInstr = 1return}// compileIgnoreSingle compiles the decoder engine for a non-struct top-level value that will be discarded.func (dec *Decoder) compileIgnoreSingle(remoteId typeId) (engine *decEngine, err error) {engine = new(decEngine)engine.instr = make([]decInstr, 1) // one itemop := dec.decIgnoreOpFor(remoteId)ovfl := overflow(dec.typeString(remoteId))engine.instr[0] = decInstr{op, 0, 0, 0, ovfl}engine.numInstr = 1return}// compileDec compiles the decoder engine for a value. If the value is not a struct,// it calls out to compileSingle.func (dec *Decoder) compileDec(remoteId typeId, ut *userTypeInfo) (engine *decEngine, err error) {rt := ut.basesrt := rtif srt.Kind() != reflect.Struct ||ut.isGobDecoder {return dec.compileSingle(remoteId, ut)}var wireStruct *structType// Builtin types can come from global pool; the rest must be defined by the decoder.// Also we know we're decoding a struct now, so the client must have sent one.if t, ok := builtinIdToType[remoteId]; ok {wireStruct, _ = t.(*structType)} else {wire := dec.wireType[remoteId]if wire == nil {error_(errBadType)}wireStruct = wire.StructT}if wireStruct == nil {errorf("type mismatch in decoder: want struct type %s; got non-struct", rt)}engine = new(decEngine)engine.instr = make([]decInstr, len(wireStruct.Field))seen := make(map[reflect.Type]*decOp)// Loop over the fields of the wire type.for fieldnum := 0; fieldnum < len(wireStruct.Field); fieldnum++ {wireField := wireStruct.Field[fieldnum]if wireField.Name == "" {errorf("empty name for remote field of type %s", wireStruct.Name)}ovfl := overflow(wireField.Name)// Find the field of the local type with the same name.localField, present := srt.FieldByName(wireField.Name)// TODO(r): anonymous namesif !present || !isExported(wireField.Name) {op := dec.decIgnoreOpFor(wireField.Id)engine.instr[fieldnum] = decInstr{op, fieldnum, 0, 0, ovfl}continue}if !dec.compatibleType(localField.Type, wireField.Id, make(map[reflect.Type]typeId)) {errorf("wrong type (%s) for received field %s.%s", localField.Type, wireStruct.Name, wireField.Name)}op, indir := dec.decOpFor(wireField.Id, localField.Type, localField.Name, seen)engine.instr[fieldnum] = decInstr{*op, fieldnum, indir, uintptr(localField.Offset), ovfl}engine.numInstr++}return}// getDecEnginePtr returns the engine for the specified type.func (dec *Decoder) getDecEnginePtr(remoteId typeId, ut *userTypeInfo) (enginePtr **decEngine, err error) {rt := ut.basedecoderMap, ok := dec.decoderCache[rt]if !ok {decoderMap = make(map[typeId]**decEngine)dec.decoderCache[rt] = decoderMap}if enginePtr, ok = decoderMap[remoteId]; !ok {// To handle recursive types, mark this engine as underway before compiling.enginePtr = new(*decEngine)decoderMap[remoteId] = enginePtr*enginePtr, err = dec.compileDec(remoteId, ut)if err != nil {delete(decoderMap, remoteId)}}return}// emptyStruct is the type we compile into when ignoring a struct value.type emptyStruct struct{}var emptyStructType = reflect.TypeOf(emptyStruct{})// getDecEnginePtr returns the engine for the specified type when the value is to be discarded.func (dec *Decoder) getIgnoreEnginePtr(wireId typeId) (enginePtr **decEngine, err error) {var ok boolif enginePtr, ok = dec.ignorerCache[wireId]; !ok {// To handle recursive types, mark this engine as underway before compiling.enginePtr = new(*decEngine)dec.ignorerCache[wireId] = enginePtrwire := dec.wireType[wireId]if wire != nil && wire.StructT != nil {*enginePtr, err = dec.compileDec(wireId, userType(emptyStructType))} else {*enginePtr, err = dec.compileIgnoreSingle(wireId)}if err != nil {delete(dec.ignorerCache, wireId)}}return}// decodeValue decodes the data stream representing a value and stores it in val.func (dec *Decoder) decodeValue(wireId typeId, val reflect.Value) {defer catchError(&dec.err)// If the value is nil, it means we should just ignore this item.if !val.IsValid() {dec.decodeIgnoredValue(wireId)return}// Dereference down to the underlying type.ut := userType(val.Type())base := ut.basevar enginePtr **decEngineenginePtr, dec.err = dec.getDecEnginePtr(wireId, ut)if dec.err != nil {return}engine := *enginePtrif st := base; st.Kind() == reflect.Struct && !ut.isGobDecoder {if engine.numInstr == 0 && st.NumField() > 0 && len(dec.wireType[wireId].StructT.Field) > 0 {name := base.Name()errorf("type mismatch: no fields matched compiling decoder for %s", name)}dec.decodeStruct(engine, ut, uintptr(unsafeAddr(val)), ut.indir)} else {dec.decodeSingle(engine, ut, uintptr(unsafeAddr(val)))}}// decodeIgnoredValue decodes the data stream representing a value of the specified type and discards it.func (dec *Decoder) decodeIgnoredValue(wireId typeId) {var enginePtr **decEngineenginePtr, dec.err = dec.getIgnoreEnginePtr(wireId)if dec.err != nil {return}wire := dec.wireType[wireId]if wire != nil && wire.StructT != nil {dec.ignoreStruct(*enginePtr)} else {dec.ignoreSingle(*enginePtr)}}func init() {var iop, uop decOpswitch reflect.TypeOf(int(0)).Bits() {case 32:iop = decInt32uop = decUint32case 64:iop = decInt64uop = decUint64default:panic("gob: unknown size of int/uint")}decOpTable[reflect.Int] = iopdecOpTable[reflect.Uint] = uop// Finally uintptrswitch reflect.TypeOf(uintptr(0)).Bits() {case 32:uop = decUint32case 64:uop = decUint64default:panic("gob: unknown size of uintptr")}decOpTable[reflect.Uintptr] = uop}// Gob assumes it can call UnsafeAddr on any Value// in order to get a pointer it can copy data from.// Values that have just been created and do not point// into existing structs or slices cannot be addressed,// so simulate it by returning a pointer to a copy.// Each call allocates once.func unsafeAddr(v reflect.Value) uintptr {if v.CanAddr() {return v.UnsafeAddr()}x := reflect.New(v.Type()).Elem()x.Set(v)return x.UnsafeAddr()}// Gob depends on being able to take the address// of zeroed Values it creates, so use this wrapper instead// of the standard reflect.Zero.// Each call allocates once.func allocValue(t reflect.Type) reflect.Value {return reflect.New(t).Elem()}