160 lines
3.5 KiB
Go
160 lines
3.5 KiB
Go
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// Copyright 2014 The Go Authors.
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// See https://code.google.com/p/go/source/browse/CONTRIBUTORS
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// Licensed under the same terms as Go itself:
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// https://code.google.com/p/go/source/browse/LICENSE
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package hpack
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import (
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"bytes"
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"io"
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"sync"
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)
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var bufPool = sync.Pool{
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New: func() interface{} { return new(bytes.Buffer) },
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}
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// HuffmanDecode decodes the string in v and writes the expanded
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// result to w, returning the number of bytes written to w and the
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// Write call's return value. At most one Write call is made.
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func HuffmanDecode(w io.Writer, v []byte) (int, error) {
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buf := bufPool.Get().(*bytes.Buffer)
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buf.Reset()
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defer bufPool.Put(buf)
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n := rootHuffmanNode
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cur, nbits := uint(0), uint8(0)
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for _, b := range v {
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cur = cur<<8 | uint(b)
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nbits += 8
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for nbits >= 8 {
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n = n.children[byte(cur>>(nbits-8))]
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if n.children == nil {
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buf.WriteByte(n.sym)
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nbits -= n.codeLen
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n = rootHuffmanNode
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} else {
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nbits -= 8
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}
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}
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}
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for nbits > 0 {
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n = n.children[byte(cur<<(8-nbits))]
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if n.children != nil || n.codeLen > nbits {
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break
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}
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buf.WriteByte(n.sym)
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nbits -= n.codeLen
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n = rootHuffmanNode
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}
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return w.Write(buf.Bytes())
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}
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type node struct {
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// children is non-nil for internal nodes
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children []*node
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// The following are only valid if children is nil:
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codeLen uint8 // number of bits that led to the output of sym
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sym byte // output symbol
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}
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func newInternalNode() *node {
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return &node{children: make([]*node, 256)}
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}
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var rootHuffmanNode = newInternalNode()
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func init() {
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for i, code := range huffmanCodes {
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if i > 255 {
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panic("too many huffman codes")
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}
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addDecoderNode(byte(i), code, huffmanCodeLen[i])
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}
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}
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func addDecoderNode(sym byte, code uint32, codeLen uint8) {
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cur := rootHuffmanNode
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for codeLen > 8 {
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codeLen -= 8
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i := uint8(code >> codeLen)
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if cur.children[i] == nil {
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cur.children[i] = newInternalNode()
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}
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cur = cur.children[i]
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}
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shift := 8 - codeLen
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start, end := int(uint8(code<<shift)), int(1<<shift)
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for i := start; i < start+end; i++ {
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cur.children[i] = &node{sym: sym, codeLen: codeLen}
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}
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}
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// AppendHuffmanString appends s, as encoded in Huffman codes, to dst
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// and returns the extended buffer.
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func AppendHuffmanString(dst []byte, s string) []byte {
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rembits := uint8(8)
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for i := 0; i < len(s); i++ {
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if rembits == 8 {
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dst = append(dst, 0)
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}
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dst, rembits = appendByteToHuffmanCode(dst, rembits, s[i])
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}
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if rembits < 8 {
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// special EOS symbol
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code := uint32(0x3fffffff)
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nbits := uint8(30)
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t := uint8(code >> (nbits - rembits))
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dst[len(dst)-1] |= t
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}
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return dst
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}
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// HuffmanEncodeLength returns the number of bytes required to encode
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// s in Huffman codes. The result is round up to byte boundary.
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func HuffmanEncodeLength(s string) uint64 {
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n := uint64(0)
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for i := 0; i < len(s); i++ {
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n += uint64(huffmanCodeLen[s[i]])
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}
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return (n + 7) / 8
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}
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// appendByteToHuffmanCode appends Huffman code for c to dst and
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// returns the extended buffer and the remaining bits in the last
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// element. The appending is not byte aligned and the remaining bits
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// in the last element of dst is given in rembits.
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func appendByteToHuffmanCode(dst []byte, rembits uint8, c byte) ([]byte, uint8) {
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code := huffmanCodes[c]
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nbits := huffmanCodeLen[c]
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for {
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if rembits > nbits {
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t := uint8(code << (rembits - nbits))
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dst[len(dst)-1] |= t
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rembits -= nbits
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break
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}
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t := uint8(code >> (nbits - rembits))
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dst[len(dst)-1] |= t
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nbits -= rembits
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rembits = 8
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if nbits == 0 {
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break
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}
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dst = append(dst, 0)
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}
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return dst, rembits
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}
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