dispatch/vendor/github.com/dsnet/compress/brotli/prefix_decoder.go

187 lines
6.2 KiB
Go

// Copyright 2015, Joe Tsai. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE.md file.
package brotli
import (
"github.com/dsnet/compress/internal/errors"
)
// The algorithm used to decode variable length codes is based on the lookup
// method in zlib. If the code is less-than-or-equal to prefixMaxChunkBits,
// then the symbol can be decoded using a single lookup into the chunks table.
// Otherwise, the links table will be used for a second level lookup.
//
// The chunks slice is keyed by the contents of the bit buffer ANDed with
// the chunkMask to avoid a out-of-bounds lookup. The value of chunks is a tuple
// that is decoded as follow:
//
// var length = chunks[bitBuffer&chunkMask] & prefixCountMask
// var symbol = chunks[bitBuffer&chunkMask] >> prefixCountBits
//
// If the decoded length is larger than chunkBits, then an overflow link table
// must be used for further decoding. In this case, the symbol is actually the
// index into the links tables. The second-level links table returned is
// processed in the same way as the chunks table.
//
// if length > chunkBits {
// var index = symbol // Previous symbol is index into links tables
// length = links[index][bitBuffer>>chunkBits & linkMask] & prefixCountMask
// symbol = links[index][bitBuffer>>chunkBits & linkMask] >> prefixCountBits
// }
//
// See the following:
// http://www.gzip.org/algorithm.txt
const (
// These values add up to the width of a uint32 integer.
prefixCountBits = 5 // Number of bits to store the bit-width of the code
prefixSymbolBits = 27 // Number of bits to store the symbol value
prefixCountMask = (1 << prefixCountBits) - 1
prefixMaxChunkBits = 9 // This can be tuned for better performance
)
type prefixDecoder struct {
chunks []uint32 // First-level lookup map
links [][]uint32 // Second-level lookup map
chunkMask uint32 // Mask the width of the chunks table
linkMask uint32 // Mask the width of the link table
chunkBits uint32 // Bit-width of the chunks table
minBits uint32 // The minimum number of bits to safely make progress
numSyms uint32 // Number of symbols
}
// Init initializes prefixDecoder according to the codes provided.
// The symbols provided must be unique and in ascending order.
//
// If assignCodes is true, then generate a canonical prefix tree using the
// prefixCode.len field and assign the generated value to prefixCode.val.
//
// If assignCodes is false, then initialize using the information inside the
// codes themselves. The input codes must form a valid prefix tree.
func (pd *prefixDecoder) Init(codes []prefixCode, assignCodes bool) {
// Handle special case trees.
if len(codes) <= 1 {
switch {
case len(codes) == 0: // Empty tree (should error if used later)
*pd = prefixDecoder{chunks: pd.chunks[:0], links: pd.links[:0], numSyms: 0}
case len(codes) == 1: // Single code tree (bit-width of zero)
*pd = prefixDecoder{
chunks: append(pd.chunks[:0], codes[0].sym<<prefixCountBits|0),
links: pd.links[:0],
numSyms: 1,
}
}
return
}
// Compute basic statistics on the symbols.
var bitCnts [maxPrefixBits + 1]uint
c0 := codes[0]
bitCnts[c0.len]++
minBits, maxBits, symLast := c0.len, c0.len, int(c0.sym)
for _, c := range codes[1:] {
if int(c.sym) <= symLast {
errors.Panic(errCorrupted) // Non-unique or non-monotonically increasing
}
if minBits > c.len {
minBits = c.len
}
if maxBits < c.len {
maxBits = c.len
}
bitCnts[c.len]++ // Histogram of bit counts
symLast = int(c.sym) // Keep track of last symbol
}
if maxBits >= 1<<prefixCountBits || minBits == 0 {
errors.Panic(errCorrupted) // Bit-width is too long or too short
}
if symLast >= 1<<prefixSymbolBits {
errors.Panic(errCorrupted) // Alphabet cardinality too large
}
// Compute the next code for a symbol of a given bit length.
var nextCodes [maxPrefixBits + 1]uint
var code uint
for i := minBits; i <= maxBits; i++ {
code <<= 1
nextCodes[i] = code
code += bitCnts[i]
}
if code != 1<<maxBits {
errors.Panic(errCorrupted) // Tree is under or over subscribed
}
// Allocate chunks table if necessary.
pd.numSyms = uint32(len(codes))
pd.minBits = minBits
pd.chunkBits = maxBits
if pd.chunkBits > prefixMaxChunkBits {
pd.chunkBits = prefixMaxChunkBits
}
numChunks := 1 << pd.chunkBits
pd.chunks = allocUint32s(pd.chunks, numChunks)
pd.chunkMask = uint32(numChunks - 1)
// Allocate links tables if necessary.
pd.links = pd.links[:0]
pd.linkMask = 0
if pd.chunkBits < maxBits {
numLinks := 1 << (maxBits - pd.chunkBits)
pd.linkMask = uint32(numLinks - 1)
if assignCodes {
baseCode := nextCodes[pd.chunkBits+1] >> 1
pd.links = extendSliceUints32s(pd.links, numChunks-int(baseCode))
for linkIdx := range pd.links {
code := reverseBits(uint32(baseCode)+uint32(linkIdx), uint(pd.chunkBits))
pd.links[linkIdx] = allocUint32s(pd.links[linkIdx], numLinks)
pd.chunks[code] = uint32(linkIdx<<prefixCountBits) | (pd.chunkBits + 1)
}
} else {
for i := range pd.chunks {
pd.chunks[i] = 0 // Logic below relies zero value as uninitialized
}
for _, c := range codes {
if c.len <= pd.chunkBits {
continue // Ignore symbols that don't require links
}
code := c.val & pd.chunkMask
if pd.chunks[code] > 0 {
continue // Link table already initialized
}
linkIdx := len(pd.links)
pd.links = extendSliceUints32s(pd.links, len(pd.links)+1)
pd.links[linkIdx] = allocUint32s(pd.links[linkIdx], numLinks)
pd.chunks[code] = uint32(linkIdx<<prefixCountBits) | (pd.chunkBits + 1)
}
}
}
// Fill out chunks and links tables with values.
for i, c := range codes {
chunk := c.sym<<prefixCountBits | c.len
if assignCodes {
codes[i].val = reverseBits(uint32(nextCodes[c.len]), uint(c.len))
nextCodes[c.len]++
c = codes[i]
}
if c.len <= pd.chunkBits {
skip := 1 << uint(c.len)
for j := int(c.val); j < len(pd.chunks); j += skip {
pd.chunks[j] = chunk
}
} else {
linkIdx := pd.chunks[c.val&pd.chunkMask] >> prefixCountBits
links := pd.links[linkIdx]
skip := 1 << uint(c.len-pd.chunkBits)
for j := int(c.val >> pd.chunkBits); j < len(links); j += skip {
links[j] = chunk
}
}
}
}