Mercurial > hg > CbC > CbC_gcc
view libgo/go/encoding/base64/base64.go @ 138:fc828634a951
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| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Thu, 08 Nov 2018 14:17:14 +0900 |
| parents | 84e7813d76e9 |
| children | 1830386684a0 |
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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 base64 implements base64 encoding as specified by RFC 4648. package base64 import ( "encoding/binary" "io" "strconv" ) /* * Encodings */ // An Encoding is a radix 64 encoding/decoding scheme, defined by a // 64-character alphabet. The most common encoding is the "base64" // encoding defined in RFC 4648 and used in MIME (RFC 2045) and PEM // (RFC 1421). RFC 4648 also defines an alternate encoding, which is // the standard encoding with - and _ substituted for + and /. type Encoding struct { encode [64]byte decodeMap [256]byte padChar rune strict bool } const ( StdPadding rune = '=' // Standard padding character NoPadding rune = -1 // No padding ) const encodeStd = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/" const encodeURL = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789-_" // NewEncoding returns a new padded Encoding defined by the given alphabet, // which must be a 64-byte string that does not contain the padding character // or CR / LF ('\r', '\n'). // The resulting Encoding uses the default padding character ('='), // which may be changed or disabled via WithPadding. func NewEncoding(encoder string) *Encoding { if len(encoder) != 64 { panic("encoding alphabet is not 64-bytes long") } for i := 0; i < len(encoder); i++ { if encoder[i] == '\n' || encoder[i] == '\r' { panic("encoding alphabet contains newline character") } } e := new(Encoding) e.padChar = StdPadding copy(e.encode[:], encoder) for i := 0; i < len(e.decodeMap); i++ { e.decodeMap[i] = 0xFF } for i := 0; i < len(encoder); i++ { e.decodeMap[encoder[i]] = byte(i) } return e } // WithPadding creates a new encoding identical to enc except // with a specified padding character, or NoPadding to disable padding. // The padding character must not be '\r' or '\n', must not // be contained in the encoding's alphabet and must be a rune equal or // below '\xff'. func (enc Encoding) WithPadding(padding rune) *Encoding { if padding == '\r' || padding == '\n' || padding > 0xff { panic("invalid padding") } for i := 0; i < len(enc.encode); i++ { if rune(enc.encode[i]) == padding { panic("padding contained in alphabet") } } enc.padChar = padding return &enc } // Strict creates a new encoding identical to enc except with // strict decoding enabled. In this mode, the decoder requires that // trailing padding bits are zero, as described in RFC 4648 section 3.5. func (enc Encoding) Strict() *Encoding { enc.strict = true return &enc } // StdEncoding is the standard base64 encoding, as defined in // RFC 4648. var StdEncoding = NewEncoding(encodeStd) // URLEncoding is the alternate base64 encoding defined in RFC 4648. // It is typically used in URLs and file names. var URLEncoding = NewEncoding(encodeURL) // RawStdEncoding is the standard raw, unpadded base64 encoding, // as defined in RFC 4648 section 3.2. // This is the same as StdEncoding but omits padding characters. var RawStdEncoding = StdEncoding.WithPadding(NoPadding) // RawURLEncoding is the unpadded alternate base64 encoding defined in RFC 4648. // It is typically used in URLs and file names. // This is the same as URLEncoding but omits padding characters. var RawURLEncoding = URLEncoding.WithPadding(NoPadding) /* * Encoder */ // Encode encodes src using the encoding enc, writing // EncodedLen(len(src)) bytes to dst. // // The encoding pads the output to a multiple of 4 bytes, // so Encode is not appropriate for use on individual blocks // of a large data stream. Use NewEncoder() instead. func (enc *Encoding) Encode(dst, src []byte) { if len(src) == 0 { return } di, si := 0, 0 n := (len(src) / 3) * 3 for si < n { // Convert 3x 8bit source bytes into 4 bytes val := uint(src[si+0])<<16 | uint(src[si+1])<<8 | uint(src[si+2]) dst[di+0] = enc.encode[val>>18&0x3F] dst[di+1] = enc.encode[val>>12&0x3F] dst[di+2] = enc.encode[val>>6&0x3F] dst[di+3] = enc.encode[val&0x3F] si += 3 di += 4 } remain := len(src) - si if remain == 0 { return } // Add the remaining small block val := uint(src[si+0]) << 16 if remain == 2 { val |= uint(src[si+1]) << 8 } dst[di+0] = enc.encode[val>>18&0x3F] dst[di+1] = enc.encode[val>>12&0x3F] switch remain { case 2: dst[di+2] = enc.encode[val>>6&0x3F] if enc.padChar != NoPadding { dst[di+3] = byte(enc.padChar) } case 1: if enc.padChar != NoPadding { dst[di+2] = byte(enc.padChar) dst[di+3] = byte(enc.padChar) } } } // EncodeToString returns the base64 encoding of src. func (enc *Encoding) EncodeToString(src []byte) string { buf := make([]byte, enc.EncodedLen(len(src))) enc.Encode(buf, src) return string(buf) } type encoder struct { err error enc *Encoding w io.Writer buf [3]byte // buffered data waiting to be encoded nbuf int // number of bytes in buf out [1024]byte // output buffer } func (e *encoder) Write(p []byte) (n int, err error) { if e.err != nil { return 0, e.err } // Leading fringe. if e.nbuf > 0 { var i int for i = 0; i < len(p) && e.nbuf < 3; i++ { e.buf[e.nbuf] = p[i] e.nbuf++ } n += i p = p[i:] if e.nbuf < 3 { return } e.enc.Encode(e.out[:], e.buf[:]) if _, e.err = e.w.Write(e.out[:4]); e.err != nil { return n, e.err } e.nbuf = 0 } // Large interior chunks. for len(p) >= 3 { nn := len(e.out) / 4 * 3 if nn > len(p) { nn = len(p) nn -= nn % 3 } e.enc.Encode(e.out[:], p[:nn]) if _, e.err = e.w.Write(e.out[0 : nn/3*4]); e.err != nil { return n, e.err } n += nn p = p[nn:] } // Trailing fringe. for i := 0; i < len(p); i++ { e.buf[i] = p[i] } e.nbuf = len(p) n += len(p) return } // Close flushes any pending output from the encoder. // It is an error to call Write after calling Close. func (e *encoder) Close() error { // If there's anything left in the buffer, flush it out if e.err == nil && e.nbuf > 0 { e.enc.Encode(e.out[:], e.buf[:e.nbuf]) _, e.err = e.w.Write(e.out[:e.enc.EncodedLen(e.nbuf)]) e.nbuf = 0 } return e.err } // NewEncoder returns a new base64 stream encoder. Data written to // the returned writer will be encoded using enc and then written to w. // Base64 encodings operate in 4-byte blocks; when finished // writing, the caller must Close the returned encoder to flush any // partially written blocks. func NewEncoder(enc *Encoding, w io.Writer) io.WriteCloser { return &encoder{enc: enc, w: w} } // EncodedLen returns the length in bytes of the base64 encoding // of an input buffer of length n. func (enc *Encoding) EncodedLen(n int) int { if enc.padChar == NoPadding { return (n*8 + 5) / 6 // minimum # chars at 6 bits per char } return (n + 2) / 3 * 4 // minimum # 4-char quanta, 3 bytes each } /* * Decoder */ type CorruptInputError int64 func (e CorruptInputError) Error() string { return "illegal base64 data at input byte " + strconv.FormatInt(int64(e), 10) } // decodeQuantum decodes up to 4 base64 bytes. It takes for parameters // the destination buffer dst, the source buffer src and an index in the // source buffer si. // It returns the number of bytes read from src, the number of bytes written // to dst, and an error, if any. func (enc *Encoding) decodeQuantum(dst, src []byte, si int) (nsi, n int, err error) { // Decode quantum using the base64 alphabet var dbuf [4]byte dinc, dlen := 3, 4 for j := 0; j < len(dbuf); j++ { if len(src) == si { switch { case j == 0: return si, 0, nil case j == 1, enc.padChar != NoPadding: return si, 0, CorruptInputError(si - j) } dinc, dlen = j-1, j break } in := src[si] si++ out := enc.decodeMap[in] if out != 0xff { dbuf[j] = out continue } if in == '\n' || in == '\r' { j-- continue } if rune(in) != enc.padChar { return si, 0, CorruptInputError(si - 1) } // We've reached the end and there's padding switch j { case 0, 1: // incorrect padding return si, 0, CorruptInputError(si - 1) case 2: // "==" is expected, the first "=" is already consumed. // skip over newlines for si < len(src) && (src[si] == '\n' || src[si] == '\r') { si++ } if si == len(src) { // not enough padding return si, 0, CorruptInputError(len(src)) } if rune(src[si]) != enc.padChar { // incorrect padding return si, 0, CorruptInputError(si - 1) } si++ } // skip over newlines for si < len(src) && (src[si] == '\n' || src[si] == '\r') { si++ } if si < len(src) { // trailing garbage err = CorruptInputError(si) } dinc, dlen = 3, j break } // Convert 4x 6bit source bytes into 3 bytes val := uint(dbuf[0])<<18 | uint(dbuf[1])<<12 | uint(dbuf[2])<<6 | uint(dbuf[3]) dbuf[2], dbuf[1], dbuf[0] = byte(val>>0), byte(val>>8), byte(val>>16) switch dlen { case 4: dst[2] = dbuf[2] dbuf[2] = 0 fallthrough case 3: dst[1] = dbuf[1] if enc.strict && dbuf[2] != 0 { return si, 0, CorruptInputError(si - 1) } dbuf[1] = 0 fallthrough case 2: dst[0] = dbuf[0] if enc.strict && (dbuf[1] != 0 || dbuf[2] != 0) { return si, 0, CorruptInputError(si - 2) } } dst = dst[dinc:] return si, dlen - 1, err } // DecodeString returns the bytes represented by the base64 string s. func (enc *Encoding) DecodeString(s string) ([]byte, error) { dbuf := make([]byte, enc.DecodedLen(len(s))) n, err := enc.Decode(dbuf, []byte(s)) return dbuf[:n], err } type decoder struct { err error readErr error // error from r.Read enc *Encoding r io.Reader buf [1024]byte // leftover input nbuf int out []byte // leftover decoded output outbuf [1024 / 4 * 3]byte } func (d *decoder) Read(p []byte) (n int, err error) { // Use leftover decoded output from last read. if len(d.out) > 0 { n = copy(p, d.out) d.out = d.out[n:] return n, nil } if d.err != nil { return 0, d.err } // This code assumes that d.r strips supported whitespace ('\r' and '\n'). // Refill buffer. for d.nbuf < 4 && d.readErr == nil { nn := len(p) / 3 * 4 if nn < 4 { nn = 4 } if nn > len(d.buf) { nn = len(d.buf) } nn, d.readErr = d.r.Read(d.buf[d.nbuf:nn]) d.nbuf += nn } if d.nbuf < 4 { if d.enc.padChar == NoPadding && d.nbuf > 0 { // Decode final fragment, without padding. var nw int nw, d.err = d.enc.Decode(d.outbuf[:], d.buf[:d.nbuf]) d.nbuf = 0 d.out = d.outbuf[:nw] n = copy(p, d.out) d.out = d.out[n:] if n > 0 || len(p) == 0 && len(d.out) > 0 { return n, nil } if d.err != nil { return 0, d.err } } d.err = d.readErr if d.err == io.EOF && d.nbuf > 0 { d.err = io.ErrUnexpectedEOF } return 0, d.err } // Decode chunk into p, or d.out and then p if p is too small. nr := d.nbuf / 4 * 4 nw := d.nbuf / 4 * 3 if nw > len(p) { nw, d.err = d.enc.Decode(d.outbuf[:], d.buf[:nr]) d.out = d.outbuf[:nw] n = copy(p, d.out) d.out = d.out[n:] } else { n, d.err = d.enc.Decode(p, d.buf[:nr]) } d.nbuf -= nr copy(d.buf[:d.nbuf], d.buf[nr:]) return n, d.err } // Decode decodes src using the encoding enc. It writes at most // DecodedLen(len(src)) bytes to dst and returns the number of bytes // written. If src contains invalid base64 data, it will return the // number of bytes successfully written and CorruptInputError. // New line characters (\r and \n) are ignored. func (enc *Encoding) Decode(dst, src []byte) (n int, err error) { if len(src) == 0 { return 0, nil } si := 0 ilen := len(src) olen := len(dst) for strconv.IntSize >= 64 && ilen-si >= 8 && olen-n >= 8 { if ok := enc.decode64(dst[n:], src[si:]); ok { n += 6 si += 8 } else { var ninc int si, ninc, err = enc.decodeQuantum(dst[n:], src, si) n += ninc if err != nil { return n, err } } } for ilen-si >= 4 && olen-n >= 4 { if ok := enc.decode32(dst[n:], src[si:]); ok { n += 3 si += 4 } else { var ninc int si, ninc, err = enc.decodeQuantum(dst[n:], src, si) n += ninc if err != nil { return n, err } } } for si < len(src) { var ninc int si, ninc, err = enc.decodeQuantum(dst[n:], src, si) n += ninc if err != nil { return n, err } } return n, err } // decode32 tries to decode 4 base64 char into 3 bytes. // len(dst) and len(src) must both be >= 4. // Returns true if decode succeeded. func (enc *Encoding) decode32(dst, src []byte) bool { var dn, n uint32 if n = uint32(enc.decodeMap[src[0]]); n == 0xff { return false } dn |= n << 26 if n = uint32(enc.decodeMap[src[1]]); n == 0xff { return false } dn |= n << 20 if n = uint32(enc.decodeMap[src[2]]); n == 0xff { return false } dn |= n << 14 if n = uint32(enc.decodeMap[src[3]]); n == 0xff { return false } dn |= n << 8 binary.BigEndian.PutUint32(dst, dn) return true } // decode64 tries to decode 8 base64 char into 6 bytes. // len(dst) and len(src) must both be >= 8. // Returns true if decode succeeded. func (enc *Encoding) decode64(dst, src []byte) bool { var dn, n uint64 if n = uint64(enc.decodeMap[src[0]]); n == 0xff { return false } dn |= n << 58 if n = uint64(enc.decodeMap[src[1]]); n == 0xff { return false } dn |= n << 52 if n = uint64(enc.decodeMap[src[2]]); n == 0xff { return false } dn |= n << 46 if n = uint64(enc.decodeMap[src[3]]); n == 0xff { return false } dn |= n << 40 if n = uint64(enc.decodeMap[src[4]]); n == 0xff { return false } dn |= n << 34 if n = uint64(enc.decodeMap[src[5]]); n == 0xff { return false } dn |= n << 28 if n = uint64(enc.decodeMap[src[6]]); n == 0xff { return false } dn |= n << 22 if n = uint64(enc.decodeMap[src[7]]); n == 0xff { return false } dn |= n << 16 binary.BigEndian.PutUint64(dst, dn) return true } type newlineFilteringReader struct { wrapped io.Reader } func (r *newlineFilteringReader) Read(p []byte) (int, error) { n, err := r.wrapped.Read(p) for n > 0 { offset := 0 for i, b := range p[:n] { if b != '\r' && b != '\n' { if i != offset { p[offset] = b } offset++ } } if offset > 0 { return offset, err } // Previous buffer entirely whitespace, read again n, err = r.wrapped.Read(p) } return n, err } // NewDecoder constructs a new base64 stream decoder. func NewDecoder(enc *Encoding, r io.Reader) io.Reader { return &decoder{enc: enc, r: &newlineFilteringReader{r}} } // DecodedLen returns the maximum length in bytes of the decoded data // corresponding to n bytes of base64-encoded data. func (enc *Encoding) DecodedLen(n int) int { if enc.padChar == NoPadding { // Unpadded data may end with partial block of 2-3 characters. return n * 6 / 8 } // Padded base64 should always be a multiple of 4 characters in length. return n / 4 * 3 }