// Copyright (c) 2012-2015 Ugorji Nwoke. All rights reserved. // Use of this source code is governed by a MIT license found in the LICENSE file. package codec import ( "math" "reflect" "time" ) const ( cborMajorUint byte = iota cborMajorNegInt cborMajorBytes cborMajorText cborMajorArray cborMajorMap cborMajorTag cborMajorOther ) const ( cborBdFalse byte = 0xf4 + iota cborBdTrue cborBdNil cborBdUndefined cborBdExt cborBdFloat16 cborBdFloat32 cborBdFloat64 ) const ( cborBdIndefiniteBytes byte = 0x5f cborBdIndefiniteString = 0x7f cborBdIndefiniteArray = 0x9f cborBdIndefiniteMap = 0xbf cborBdBreak = 0xff ) // These define some in-stream descriptors for // manual encoding e.g. when doing explicit indefinite-length const ( CborStreamBytes byte = 0x5f CborStreamString = 0x7f CborStreamArray = 0x9f CborStreamMap = 0xbf CborStreamBreak = 0xff ) const ( cborBaseUint byte = 0x00 cborBaseNegInt = 0x20 cborBaseBytes = 0x40 cborBaseString = 0x60 cborBaseArray = 0x80 cborBaseMap = 0xa0 cborBaseTag = 0xc0 cborBaseSimple = 0xe0 ) // ------------------- type cborEncDriver struct { noBuiltInTypes encDriverNoopContainerWriter // encNoSeparator e *Encoder w encWriter h *CborHandle x [8]byte } func (e *cborEncDriver) EncodeNil() { e.w.writen1(cborBdNil) } func (e *cborEncDriver) EncodeBool(b bool) { if b { e.w.writen1(cborBdTrue) } else { e.w.writen1(cborBdFalse) } } func (e *cborEncDriver) EncodeFloat32(f float32) { e.w.writen1(cborBdFloat32) bigenHelper{e.x[:4], e.w}.writeUint32(math.Float32bits(f)) } func (e *cborEncDriver) EncodeFloat64(f float64) { e.w.writen1(cborBdFloat64) bigenHelper{e.x[:8], e.w}.writeUint64(math.Float64bits(f)) } func (e *cborEncDriver) encUint(v uint64, bd byte) { if v <= 0x17 { e.w.writen1(byte(v) + bd) } else if v <= math.MaxUint8 { e.w.writen2(bd+0x18, uint8(v)) } else if v <= math.MaxUint16 { e.w.writen1(bd + 0x19) bigenHelper{e.x[:2], e.w}.writeUint16(uint16(v)) } else if v <= math.MaxUint32 { e.w.writen1(bd + 0x1a) bigenHelper{e.x[:4], e.w}.writeUint32(uint32(v)) } else { // if v <= math.MaxUint64 { e.w.writen1(bd + 0x1b) bigenHelper{e.x[:8], e.w}.writeUint64(v) } } func (e *cborEncDriver) EncodeInt(v int64) { if v < 0 { e.encUint(uint64(-1-v), cborBaseNegInt) } else { e.encUint(uint64(v), cborBaseUint) } } func (e *cborEncDriver) EncodeUint(v uint64) { e.encUint(v, cborBaseUint) } func (e *cborEncDriver) encLen(bd byte, length int) { e.encUint(uint64(length), bd) } func (e *cborEncDriver) EncodeTime(t time.Time) { if t.IsZero() { e.EncodeNil() } else if e.h.TimeRFC3339 { e.encUint(0, cborBaseTag) e.EncodeString(cUTF8, t.Format(time.RFC3339Nano)) } else { e.encUint(1, cborBaseTag) t = t.UTC().Round(time.Microsecond) sec, nsec := t.Unix(), uint64(t.Nanosecond()) if nsec == 0 { e.EncodeInt(sec) } else { e.EncodeFloat64(float64(sec) + float64(nsec)/1e9) } } } func (e *cborEncDriver) EncodeExt(rv interface{}, xtag uint64, ext Ext, en *Encoder) { e.encUint(uint64(xtag), cborBaseTag) if v := ext.ConvertExt(rv); v == nil { e.EncodeNil() } else { en.encode(v) } } func (e *cborEncDriver) EncodeRawExt(re *RawExt, en *Encoder) { e.encUint(uint64(re.Tag), cborBaseTag) if false && re.Data != nil { en.encode(re.Data) } else if re.Value != nil { en.encode(re.Value) } else { e.EncodeNil() } } func (e *cborEncDriver) WriteArrayStart(length int) { if e.h.IndefiniteLength { e.w.writen1(cborBdIndefiniteArray) } else { e.encLen(cborBaseArray, length) } } func (e *cborEncDriver) WriteMapStart(length int) { if e.h.IndefiniteLength { e.w.writen1(cborBdIndefiniteMap) } else { e.encLen(cborBaseMap, length) } } func (e *cborEncDriver) WriteMapEnd() { if e.h.IndefiniteLength { e.w.writen1(cborBdBreak) } } func (e *cborEncDriver) WriteArrayEnd() { if e.h.IndefiniteLength { e.w.writen1(cborBdBreak) } } func (e *cborEncDriver) EncodeSymbol(v string) { e.encStringBytesS(cborBaseString, v) } func (e *cborEncDriver) EncodeString(c charEncoding, v string) { e.encStringBytesS(cborBaseString, v) } func (e *cborEncDriver) EncodeStringBytes(c charEncoding, v []byte) { if v == nil { e.EncodeNil() } else if c == cRAW { e.encStringBytesS(cborBaseBytes, stringView(v)) } else { e.encStringBytesS(cborBaseString, stringView(v)) } } func (e *cborEncDriver) encStringBytesS(bb byte, v string) { if e.h.IndefiniteLength { if bb == cborBaseBytes { e.w.writen1(cborBdIndefiniteBytes) } else { e.w.writen1(cborBdIndefiniteString) } blen := len(v) / 4 if blen == 0 { blen = 64 } else if blen > 1024 { blen = 1024 } for i := 0; i < len(v); { var v2 string i2 := i + blen if i2 < len(v) { v2 = v[i:i2] } else { v2 = v[i:] } e.encLen(bb, len(v2)) e.w.writestr(v2) i = i2 } e.w.writen1(cborBdBreak) } else { e.encLen(bb, len(v)) e.w.writestr(v) } } // ---------------------- type cborDecDriver struct { d *Decoder h *CborHandle r decReader b [scratchByteArrayLen]byte br bool // bytes reader bdRead bool bd byte noBuiltInTypes // decNoSeparator decDriverNoopContainerReader } func (d *cborDecDriver) readNextBd() { d.bd = d.r.readn1() d.bdRead = true } func (d *cborDecDriver) uncacheRead() { if d.bdRead { d.r.unreadn1() d.bdRead = false } } func (d *cborDecDriver) ContainerType() (vt valueType) { if !d.bdRead { d.readNextBd() } if d.bd == cborBdNil { return valueTypeNil } else if d.bd == cborBdIndefiniteBytes || (d.bd >= cborBaseBytes && d.bd < cborBaseString) { return valueTypeBytes } else if d.bd == cborBdIndefiniteString || (d.bd >= cborBaseString && d.bd < cborBaseArray) { return valueTypeString } else if d.bd == cborBdIndefiniteArray || (d.bd >= cborBaseArray && d.bd < cborBaseMap) { return valueTypeArray } else if d.bd == cborBdIndefiniteMap || (d.bd >= cborBaseMap && d.bd < cborBaseTag) { return valueTypeMap } // else { // d.d.errorf("isContainerType: unsupported parameter: %v", vt) // } return valueTypeUnset } func (d *cborDecDriver) TryDecodeAsNil() bool { if !d.bdRead { d.readNextBd() } // treat Nil and Undefined as nil values if d.bd == cborBdNil || d.bd == cborBdUndefined { d.bdRead = false return true } return false } func (d *cborDecDriver) CheckBreak() bool { if !d.bdRead { d.readNextBd() } if d.bd == cborBdBreak { d.bdRead = false return true } return false } func (d *cborDecDriver) decUint() (ui uint64) { v := d.bd & 0x1f if v <= 0x17 { ui = uint64(v) } else { if v == 0x18 { ui = uint64(d.r.readn1()) } else if v == 0x19 { ui = uint64(bigen.Uint16(d.r.readx(2))) } else if v == 0x1a { ui = uint64(bigen.Uint32(d.r.readx(4))) } else if v == 0x1b { ui = uint64(bigen.Uint64(d.r.readx(8))) } else { d.d.errorf("decUint: Invalid descriptor: %v", d.bd) return } } return } func (d *cborDecDriver) decCheckInteger() (neg bool) { if !d.bdRead { d.readNextBd() } major := d.bd >> 5 if major == cborMajorUint { } else if major == cborMajorNegInt { neg = true } else { d.d.errorf("invalid major: %v (bd: %v)", major, d.bd) return } return } func (d *cborDecDriver) DecodeInt(bitsize uint8) (i int64) { neg := d.decCheckInteger() ui := d.decUint() // check if this number can be converted to an int without overflow var overflow bool if neg { if i, overflow = chkOvf.SignedInt(ui + 1); overflow { d.d.errorf("cbor: overflow converting %v to signed integer", ui+1) return } i = -i } else { if i, overflow = chkOvf.SignedInt(ui); overflow { d.d.errorf("cbor: overflow converting %v to signed integer", ui) return } } if chkOvf.Int(i, bitsize) { d.d.errorf("cbor: overflow integer: %v", i) return } d.bdRead = false return } func (d *cborDecDriver) DecodeUint(bitsize uint8) (ui uint64) { if d.decCheckInteger() { d.d.errorf("Assigning negative signed value to unsigned type") return } ui = d.decUint() if chkOvf.Uint(ui, bitsize) { d.d.errorf("cbor: overflow integer: %v", ui) return } d.bdRead = false return } func (d *cborDecDriver) DecodeFloat(chkOverflow32 bool) (f float64) { if !d.bdRead { d.readNextBd() } if bd := d.bd; bd == cborBdFloat16 { f = float64(math.Float32frombits(halfFloatToFloatBits(bigen.Uint16(d.r.readx(2))))) } else if bd == cborBdFloat32 { f = float64(math.Float32frombits(bigen.Uint32(d.r.readx(4)))) } else if bd == cborBdFloat64 { f = math.Float64frombits(bigen.Uint64(d.r.readx(8))) } else if bd >= cborBaseUint && bd < cborBaseBytes { f = float64(d.DecodeInt(64)) } else { d.d.errorf("Float only valid from float16/32/64: Invalid descriptor: %v", bd) return } if chkOverflow32 && chkOvf.Float32(f) { d.d.errorf("cbor: float32 overflow: %v", f) return } d.bdRead = false return } // bool can be decoded from bool only (single byte). func (d *cborDecDriver) DecodeBool() (b bool) { if !d.bdRead { d.readNextBd() } if bd := d.bd; bd == cborBdTrue { b = true } else if bd == cborBdFalse { } else { d.d.errorf("Invalid single-byte value for bool: %s: %x", msgBadDesc, d.bd) return } d.bdRead = false return } func (d *cborDecDriver) ReadMapStart() (length int) { if !d.bdRead { d.readNextBd() } d.bdRead = false if d.bd == cborBdIndefiniteMap { return -1 } return d.decLen() } func (d *cborDecDriver) ReadArrayStart() (length int) { if !d.bdRead { d.readNextBd() } d.bdRead = false if d.bd == cborBdIndefiniteArray { return -1 } return d.decLen() } func (d *cborDecDriver) decLen() int { return int(d.decUint()) } func (d *cborDecDriver) decAppendIndefiniteBytes(bs []byte) []byte { d.bdRead = false for { if d.CheckBreak() { break } if major := d.bd >> 5; major != cborMajorBytes && major != cborMajorText { d.d.errorf("cbor: expect bytes or string major type in indefinite string/bytes; got: %v, byte: %v", major, d.bd) return nil } n := d.decLen() oldLen := len(bs) newLen := oldLen + n if newLen > cap(bs) { bs2 := make([]byte, newLen, 2*cap(bs)+n) copy(bs2, bs) bs = bs2 } else { bs = bs[:newLen] } d.r.readb(bs[oldLen:newLen]) // bs = append(bs, d.r.readn()...) d.bdRead = false } d.bdRead = false return bs } func (d *cborDecDriver) DecodeBytes(bs []byte, zerocopy bool) (bsOut []byte) { if !d.bdRead { d.readNextBd() } if d.bd == cborBdNil || d.bd == cborBdUndefined { d.bdRead = false return nil } if d.bd == cborBdIndefiniteBytes || d.bd == cborBdIndefiniteString { d.bdRead = false if bs == nil { return d.decAppendIndefiniteBytes(zeroByteSlice) } return d.decAppendIndefiniteBytes(bs[:0]) } // check if an "array" of uint8's (see ContainerType for how to infer if an array) if d.bd == cborBdIndefiniteArray || (d.bd >= cborBaseArray && d.bd < cborBaseMap) { bsOut, _ = fastpathTV.DecSliceUint8V(bs, true, d.d) return } clen := d.decLen() d.bdRead = false if zerocopy { if d.br { return d.r.readx(clen) } else if len(bs) == 0 { bs = d.b[:] } } return decByteSlice(d.r, clen, d.d.h.MaxInitLen, bs) } func (d *cborDecDriver) DecodeString() (s string) { return string(d.DecodeBytes(d.b[:], true)) } func (d *cborDecDriver) DecodeStringAsBytes() (s []byte) { return d.DecodeBytes(d.b[:], true) } func (d *cborDecDriver) DecodeTime() (t time.Time) { if !d.bdRead { d.readNextBd() } if d.bd == cborBdNil || d.bd == cborBdUndefined { d.bdRead = false return } xtag := d.decUint() d.bdRead = false return d.decodeTime(xtag) } func (d *cborDecDriver) decodeTime(xtag uint64) (t time.Time) { if !d.bdRead { d.readNextBd() } switch xtag { case 0: var err error if t, err = time.Parse(time.RFC3339, stringView(d.DecodeStringAsBytes())); err != nil { d.d.error(err) } case 1: // decode an int64 or a float, and infer time.Time from there. // for floats, round to microseconds, as that is what is guaranteed to fit well. switch { case d.bd == cborBdFloat16, d.bd == cborBdFloat32: f1, f2 := math.Modf(d.DecodeFloat(true)) t = time.Unix(int64(f1), int64(f2*1e9)) case d.bd == cborBdFloat64: f1, f2 := math.Modf(d.DecodeFloat(false)) t = time.Unix(int64(f1), int64(f2*1e9)) case d.bd >= cborBaseUint && d.bd < cborBaseNegInt, d.bd >= cborBaseNegInt && d.bd < cborBaseBytes: t = time.Unix(d.DecodeInt(64), 0) default: d.d.errorf("cbor: time.Time can only be decoded from a number (or RFC3339 string)") } default: d.d.errorf("cbor: invalid tag for time.Time - expecting 0 or 1, got 0x%x", xtag) } t = t.UTC().Round(time.Microsecond) return } func (d *cborDecDriver) DecodeExt(rv interface{}, xtag uint64, ext Ext) (realxtag uint64) { if !d.bdRead { d.readNextBd() } u := d.decUint() d.bdRead = false realxtag = u if ext == nil { re := rv.(*RawExt) re.Tag = realxtag d.d.decode(&re.Value) } else if xtag != realxtag { d.d.errorf("Wrong extension tag. Got %b. Expecting: %v", realxtag, xtag) return } else { var v interface{} d.d.decode(&v) ext.UpdateExt(rv, v) } d.bdRead = false return } func (d *cborDecDriver) DecodeNaked() { if !d.bdRead { d.readNextBd() } n := d.d.n var decodeFurther bool switch d.bd { case cborBdNil: n.v = valueTypeNil case cborBdFalse: n.v = valueTypeBool n.b = false case cborBdTrue: n.v = valueTypeBool n.b = true case cborBdFloat16, cborBdFloat32: n.v = valueTypeFloat n.f = d.DecodeFloat(true) case cborBdFloat64: n.v = valueTypeFloat n.f = d.DecodeFloat(false) case cborBdIndefiniteBytes: n.v = valueTypeBytes n.l = d.DecodeBytes(nil, false) case cborBdIndefiniteString: n.v = valueTypeString n.s = d.DecodeString() case cborBdIndefiniteArray: n.v = valueTypeArray decodeFurther = true case cborBdIndefiniteMap: n.v = valueTypeMap decodeFurther = true default: switch { case d.bd >= cborBaseUint && d.bd < cborBaseNegInt: if d.h.SignedInteger { n.v = valueTypeInt n.i = d.DecodeInt(64) } else { n.v = valueTypeUint n.u = d.DecodeUint(64) } case d.bd >= cborBaseNegInt && d.bd < cborBaseBytes: n.v = valueTypeInt n.i = d.DecodeInt(64) case d.bd >= cborBaseBytes && d.bd < cborBaseString: n.v = valueTypeBytes n.l = d.DecodeBytes(nil, false) case d.bd >= cborBaseString && d.bd < cborBaseArray: n.v = valueTypeString n.s = d.DecodeString() case d.bd >= cborBaseArray && d.bd < cborBaseMap: n.v = valueTypeArray decodeFurther = true case d.bd >= cborBaseMap && d.bd < cborBaseTag: n.v = valueTypeMap decodeFurther = true case d.bd >= cborBaseTag && d.bd < cborBaseSimple: n.v = valueTypeExt n.u = d.decUint() n.l = nil if n.u == 0 || n.u == 1 { d.bdRead = false n.v = valueTypeTime n.t = d.decodeTime(n.u) } // d.bdRead = false // d.d.decode(&re.Value) // handled by decode itself. // decodeFurther = true default: d.d.errorf("decodeNaked: Unrecognized d.bd: 0x%x", d.bd) return } } if !decodeFurther { d.bdRead = false } return } // ------------------------- // CborHandle is a Handle for the CBOR encoding format, // defined at http://tools.ietf.org/html/rfc7049 and documented further at http://cbor.io . // // CBOR is comprehensively supported, including support for: // - indefinite-length arrays/maps/bytes/strings // - (extension) tags in range 0..0xffff (0 .. 65535) // - half, single and double-precision floats // - all numbers (1, 2, 4 and 8-byte signed and unsigned integers) // - nil, true, false, ... // - arrays and maps, bytes and text strings // // None of the optional extensions (with tags) defined in the spec are supported out-of-the-box. // Users can implement them as needed (using SetExt), including spec-documented ones: // - timestamp, BigNum, BigFloat, Decimals, // - Encoded Text (e.g. URL, regexp, base64, MIME Message), etc. type CborHandle struct { binaryEncodingType noElemSeparators BasicHandle // IndefiniteLength=true, means that we encode using indefinitelength IndefiniteLength bool // TimeRFC3339 says to encode time.Time using RFC3339 format. // If unset, we encode time.Time using seconds past epoch. TimeRFC3339 bool } // SetInterfaceExt sets an extension func (h *CborHandle) SetInterfaceExt(rt reflect.Type, tag uint64, ext InterfaceExt) (err error) { return h.SetExt(rt, tag, &setExtWrapper{i: ext}) } func (h *CborHandle) newEncDriver(e *Encoder) encDriver { return &cborEncDriver{e: e, w: e.w, h: h} } func (h *CborHandle) newDecDriver(d *Decoder) decDriver { return &cborDecDriver{d: d, h: h, r: d.r, br: d.bytes} } func (e *cborEncDriver) reset() { e.w = e.e.w } func (d *cborDecDriver) reset() { d.r, d.br = d.d.r, d.d.bytes d.bd, d.bdRead = 0, false } var _ decDriver = (*cborDecDriver)(nil) var _ encDriver = (*cborEncDriver)(nil)