// Copyright 2013 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 transform provides reader and writer wrappers that transform the // bytes passing through as well as various transformations. Example // transformations provided by other packages include normalization and // conversion between character sets. package transform import ( "bytes" "errors" "io" "unicode/utf8" ) var ( // ErrShortDst means that the destination buffer was too short to // receive all of the transformed bytes. ErrShortDst = errors.New("transform: short destination buffer") // ErrShortSrc means that the source buffer has insufficient data to // complete the transformation. ErrShortSrc = errors.New("transform: short source buffer") // errInconsistentByteCount means that Transform returned success (nil // error) but also returned nSrc inconsistent with the src argument. errInconsistentByteCount = errors.New("transform: inconsistent byte count returned") // errShortInternal means that an internal buffer is not large enough // to make progress and the Transform operation must be aborted. errShortInternal = errors.New("transform: short internal buffer") ) // Transformer transforms bytes. type Transformer interface { // Transform writes to dst the transformed bytes read from src, and // returns the number of dst bytes written and src bytes read. The // atEOF argument tells whether src represents the last bytes of the // input. // // Callers should always process the nDst bytes produced and account // for the nSrc bytes consumed before considering the error err. // // A nil error means that all of the transformed bytes (whether freshly // transformed from src or left over from previous Transform calls) // were written to dst. A nil error can be returned regardless of // whether atEOF is true. If err is nil then nSrc must equal len(src); // the converse is not necessarily true. // // ErrShortDst means that dst was too short to receive all of the // transformed bytes. ErrShortSrc means that src had insufficient data // to complete the transformation. If both conditions apply, then // either error may be returned. Other than the error conditions listed // here, implementations are free to report other errors that arise. Transform(dst, src []byte, atEOF bool) (nDst, nSrc int, err error) // Reset resets the state and allows a Transformer to be reused. Reset() } // NopResetter can be embedded by implementations of Transformer to add a nop // Reset method. type NopResetter struct{} // Reset implements the Reset method of the Transformer interface. func (NopResetter) Reset() {} // Reader wraps another io.Reader by transforming the bytes read. type Reader struct { r io.Reader t Transformer err error // dst[dst0:dst1] contains bytes that have been transformed by t but // not yet copied out via Read. dst []byte dst0, dst1 int // src[src0:src1] contains bytes that have been read from r but not // yet transformed through t. src []byte src0, src1 int // transformComplete is whether the transformation is complete, // regardless of whether or not it was successful. transformComplete bool } const defaultBufSize = 4096 // NewReader returns a new Reader that wraps r by transforming the bytes read // via t. It calls Reset on t. func NewReader(r io.Reader, t Transformer) *Reader { t.Reset() return &Reader{ r: r, t: t, dst: make([]byte, defaultBufSize), src: make([]byte, defaultBufSize), } } // Read implements the io.Reader interface. func (r *Reader) Read(p []byte) (int, error) { n, err := 0, error(nil) for { // Copy out any transformed bytes and return the final error if we are done. if r.dst0 != r.dst1 { n = copy(p, r.dst[r.dst0:r.dst1]) r.dst0 += n if r.dst0 == r.dst1 && r.transformComplete { return n, r.err } return n, nil } else if r.transformComplete { return 0, r.err } // Try to transform some source bytes, or to flush the transformer if we // are out of source bytes. We do this even if r.r.Read returned an error. // As the io.Reader documentation says, "process the n > 0 bytes returned // before considering the error". if r.src0 != r.src1 || r.err != nil { r.dst0 = 0 r.dst1, n, err = r.t.Transform(r.dst, r.src[r.src0:r.src1], r.err == io.EOF) r.src0 += n switch { case err == nil: if r.src0 != r.src1 { r.err = errInconsistentByteCount } // The Transform call was successful; we are complete if we // cannot read more bytes into src. r.transformComplete = r.err != nil continue case err == ErrShortDst && (r.dst1 != 0 || n != 0): // Make room in dst by copying out, and try again. continue case err == ErrShortSrc && r.src1-r.src0 != len(r.src) && r.err == nil: // Read more bytes into src via the code below, and try again. default: r.transformComplete = true // The reader error (r.err) takes precedence over the // transformer error (err) unless r.err is nil or io.EOF. if r.err == nil || r.err == io.EOF { r.err = err } continue } } // Move any untransformed source bytes to the start of the buffer // and read more bytes. if r.src0 != 0 { r.src0, r.src1 = 0, copy(r.src, r.src[r.src0:r.src1]) } n, r.err = r.r.Read(r.src[r.src1:]) r.src1 += n } } // TODO: implement ReadByte (and ReadRune??). // Writer wraps another io.Writer by transforming the bytes read. // The user needs to call Close to flush unwritten bytes that may // be buffered. type Writer struct { w io.Writer t Transformer dst []byte // src[:n] contains bytes that have not yet passed through t. src []byte n int } // NewWriter returns a new Writer that wraps w by transforming the bytes written // via t. It calls Reset on t. func NewWriter(w io.Writer, t Transformer) *Writer { t.Reset() return &Writer{ w: w, t: t, dst: make([]byte, defaultBufSize), src: make([]byte, defaultBufSize), } } // Write implements the io.Writer interface. If there are not enough // bytes available to complete a Transform, the bytes will be buffered // for the next write. Call Close to convert the remaining bytes. func (w *Writer) Write(data []byte) (n int, err error) { src := data if w.n > 0 { // Append bytes from data to the last remainder. // TODO: limit the amount copied on first try. n = copy(w.src[w.n:], data) w.n += n src = w.src[:w.n] } for { nDst, nSrc, err := w.t.Transform(w.dst, src, false) if _, werr := w.w.Write(w.dst[:nDst]); werr != nil { return n, werr } src = src[nSrc:] if w.n > 0 && len(src) <= n { // Enough bytes from w.src have been consumed. We make src point // to data instead to reduce the copying. w.n = 0 n -= len(src) src = data[n:] if n < len(data) && (err == nil || err == ErrShortSrc) { continue } } else { n += nSrc } switch { case err == ErrShortDst && (nDst > 0 || nSrc > 0): case err == ErrShortSrc && len(src) < len(w.src): m := copy(w.src, src) // If w.n > 0, bytes from data were already copied to w.src and n // was already set to the number of bytes consumed. if w.n == 0 { n += m } w.n = m return n, nil case err == nil && w.n > 0: return n, errInconsistentByteCount default: return n, err } } } // Close implements the io.Closer interface. func (w *Writer) Close() error { for src := w.src[:w.n]; len(src) > 0; { nDst, nSrc, err := w.t.Transform(w.dst, src, true) if nDst == 0 { return err } if _, werr := w.w.Write(w.dst[:nDst]); werr != nil { return werr } if err != ErrShortDst { return err } src = src[nSrc:] } return nil } type nop struct{ NopResetter } func (nop) Transform(dst, src []byte, atEOF bool) (nDst, nSrc int, err error) { n := copy(dst, src) if n < len(src) { err = ErrShortDst } return n, n, err } type discard struct{ NopResetter } func (discard) Transform(dst, src []byte, atEOF bool) (nDst, nSrc int, err error) { return 0, len(src), nil } var ( // Discard is a Transformer for which all Transform calls succeed // by consuming all bytes and writing nothing. Discard Transformer = discard{} // Nop is a Transformer that copies src to dst. Nop Transformer = nop{} ) // chain is a sequence of links. A chain with N Transformers has N+1 links and // N+1 buffers. Of those N+1 buffers, the first and last are the src and dst // buffers given to chain.Transform and the middle N-1 buffers are intermediate // buffers owned by the chain. The i'th link transforms bytes from the i'th // buffer chain.link[i].b at read offset chain.link[i].p to the i+1'th buffer // chain.link[i+1].b at write offset chain.link[i+1].n, for i in [0, N). type chain struct { link []link err error // errStart is the index at which the error occurred plus 1. Processing // errStart at this level at the next call to Transform. As long as // errStart > 0, chain will not consume any more source bytes. errStart int } func (c *chain) fatalError(errIndex int, err error) { if i := errIndex + 1; i > c.errStart { c.errStart = i c.err = err } } type link struct { t Transformer // b[p:n] holds the bytes to be transformed by t. b []byte p int n int } func (l *link) src() []byte { return l.b[l.p:l.n] } func (l *link) dst() []byte { return l.b[l.n:] } // Chain returns a Transformer that applies t in sequence. func Chain(t ...Transformer) Transformer { if len(t) == 0 { return nop{} } c := &chain{link: make([]link, len(t)+1)} for i, tt := range t { c.link[i].t = tt } // Allocate intermediate buffers. b := make([][defaultBufSize]byte, len(t)-1) for i := range b { c.link[i+1].b = b[i][:] } return c } // Reset resets the state of Chain. It calls Reset on all the Transformers. func (c *chain) Reset() { for i, l := range c.link { if l.t != nil { l.t.Reset() } c.link[i].p, c.link[i].n = 0, 0 } } // Transform applies the transformers of c in sequence. func (c *chain) Transform(dst, src []byte, atEOF bool) (nDst, nSrc int, err error) { // Set up src and dst in the chain. srcL := &c.link[0] dstL := &c.link[len(c.link)-1] srcL.b, srcL.p, srcL.n = src, 0, len(src) dstL.b, dstL.n = dst, 0 var lastFull, needProgress bool // for detecting progress // i is the index of the next Transformer to apply, for i in [low, high]. // low is the lowest index for which c.link[low] may still produce bytes. // high is the highest index for which c.link[high] has a Transformer. // The error returned by Transform determines whether to increase or // decrease i. We try to completely fill a buffer before converting it. for low, i, high := c.errStart, c.errStart, len(c.link)-2; low <= i && i <= high; { in, out := &c.link[i], &c.link[i+1] nDst, nSrc, err0 := in.t.Transform(out.dst(), in.src(), atEOF && low == i) out.n += nDst in.p += nSrc if i > 0 && in.p == in.n { in.p, in.n = 0, 0 } needProgress, lastFull = lastFull, false switch err0 { case ErrShortDst: // Process the destination buffer next. Return if we are already // at the high index. if i == high { return dstL.n, srcL.p, ErrShortDst } if out.n != 0 { i++ // If the Transformer at the next index is not able to process any // source bytes there is nothing that can be done to make progress // and the bytes will remain unprocessed. lastFull is used to // detect this and break out of the loop with a fatal error. lastFull = true continue } // The destination buffer was too small, but is completely empty. // Return a fatal error as this transformation can never complete. c.fatalError(i, errShortInternal) case ErrShortSrc: if i == 0 { // Save ErrShortSrc in err. All other errors take precedence. err = ErrShortSrc break } // Source bytes were depleted before filling up the destination buffer. // Verify we made some progress, move the remaining bytes to the errStart // and try to get more source bytes. if needProgress && nSrc == 0 || in.n-in.p == len(in.b) { // There were not enough source bytes to proceed while the source // buffer cannot hold any more bytes. Return a fatal error as this // transformation can never complete. c.fatalError(i, errShortInternal) break } // in.b is an internal buffer and we can make progress. in.p, in.n = 0, copy(in.b, in.src()) fallthrough case nil: // if i == low, we have depleted the bytes at index i or any lower levels. // In that case we increase low and i. In all other cases we decrease i to // fetch more bytes before proceeding to the next index. if i > low { i-- continue } default: c.fatalError(i, err0) } // Exhausted level low or fatal error: increase low and continue // to process the bytes accepted so far. i++ low = i } // If c.errStart > 0, this means we found a fatal error. We will clear // all upstream buffers. At this point, no more progress can be made // downstream, as Transform would have bailed while handling ErrShortDst. if c.errStart > 0 { for i := 1; i < c.errStart; i++ { c.link[i].p, c.link[i].n = 0, 0 } err, c.errStart, c.err = c.err, 0, nil } return dstL.n, srcL.p, err } // RemoveFunc returns a Transformer that removes from the input all runes r for // which f(r) is true. Illegal bytes in the input are replaced by RuneError. func RemoveFunc(f func(r rune) bool) Transformer { return removeF(f) } type removeF func(r rune) bool func (removeF) Reset() {} // Transform implements the Transformer interface. func (t removeF) Transform(dst, src []byte, atEOF bool) (nDst, nSrc int, err error) { for r, sz := rune(0), 0; len(src) > 0; src = src[sz:] { if r = rune(src[0]); r < utf8.RuneSelf { sz = 1 } else { r, sz = utf8.DecodeRune(src) if sz == 1 { // Invalid rune. if !atEOF && !utf8.FullRune(src) { err = ErrShortSrc break } // We replace illegal bytes with RuneError. Not doing so might // otherwise turn a sequence of invalid UTF-8 into valid UTF-8. // The resulting byte sequence may subsequently contain runes // for which t(r) is true that were passed unnoticed. if !t(r) { if nDst+3 > len(dst) { err = ErrShortDst break } nDst += copy(dst[nDst:], "\uFFFD") } nSrc++ continue } } if !t(r) { if nDst+sz > len(dst) { err = ErrShortDst break } nDst += copy(dst[nDst:], src[:sz]) } nSrc += sz } return } // grow returns a new []byte that is longer than b, and copies the first n bytes // of b to the start of the new slice. func grow(b []byte, n int) []byte { m := len(b) if m <= 256 { m *= 2 } else { m += m >> 1 } buf := make([]byte, m) copy(buf, b[:n]) return buf } const initialBufSize = 128 // String returns a string with the result of converting s[:n] using t, where // n <= len(s). If err == nil, n will be len(s). It calls Reset on t. func String(t Transformer, s string) (result string, n int, err error) { if s == "" { return "", 0, nil } t.Reset() // Allocate only once. Note that both dst and src escape when passed to // Transform. buf := [2 * initialBufSize]byte{} dst := buf[:initialBufSize:initialBufSize] src := buf[initialBufSize : 2*initialBufSize] // Avoid allocation if the transformed string is identical to the original. // After this loop, pDst will point to the furthest point in s for which it // could be detected that t gives equal results, src[:nSrc] will // indicated the last processed chunk of s for which the output is not equal // and dst[:nDst] will be the transform of this chunk. var nDst, nSrc int pDst := 0 // Used as index in both src and dst in this loop. for { n := copy(src, s[pDst:]) nDst, nSrc, err = t.Transform(dst, src[:n], pDst+n == len(s)) // Note 1: we will not enter the loop with pDst == len(s) and we will // not end the loop with it either. So if nSrc is 0, this means there is // some kind of error from which we cannot recover given the current // buffer sizes. We will give up in this case. // Note 2: it is not entirely correct to simply do a bytes.Equal as // a Transformer may buffer internally. It will work in most cases, // though, and no harm is done if it doesn't work. // TODO: let transformers implement an optional Spanner interface, akin // to norm's QuickSpan. This would even allow us to avoid any allocation. if nSrc == 0 || !bytes.Equal(dst[:nDst], src[:nSrc]) { break } if pDst += nDst; pDst == len(s) { return s, pDst, nil } } // Move the bytes seen so far to dst. pSrc := pDst + nSrc if pDst+nDst <= initialBufSize { copy(dst[pDst:], dst[:nDst]) } else { b := make([]byte, len(s)+nDst-nSrc) copy(b[pDst:], dst[:nDst]) dst = b } copy(dst, s[:pDst]) pDst += nDst if err != nil && err != ErrShortDst && err != ErrShortSrc { return string(dst[:pDst]), pSrc, err } // Complete the string with the remainder. for { n := copy(src, s[pSrc:]) nDst, nSrc, err = t.Transform(dst[pDst:], src[:n], pSrc+n == len(s)) pDst += nDst pSrc += nSrc switch err { case nil: if pSrc == len(s) { return string(dst[:pDst]), pSrc, nil } case ErrShortDst: // Do not grow as long as we can make progress. This may avoid // excessive allocations. if nDst == 0 { dst = grow(dst, pDst) } case ErrShortSrc: if nSrc == 0 { src = grow(src, 0) } default: return string(dst[:pDst]), pSrc, err } } } // Bytes returns a new byte slice with the result of converting b[:n] using t, // where n <= len(b). If err == nil, n will be len(b). It calls Reset on t. func Bytes(t Transformer, b []byte) (result []byte, n int, err error) { t.Reset() dst := make([]byte, len(b)) pDst, pSrc := 0, 0 for { nDst, nSrc, err := t.Transform(dst[pDst:], b[pSrc:], true) pDst += nDst pSrc += nSrc if err != ErrShortDst { return dst[:pDst], pSrc, err } // Grow the destination buffer, but do not grow as long as we can make // progress. This may avoid excessive allocations. if nDst == 0 { dst = grow(dst, pDst) } } }