mirror of https://github.com/tidwall/tile38.git
446 lines
11 KiB
Go
446 lines
11 KiB
Go
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package lz4
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import (
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"encoding/binary"
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"errors"
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)
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// block represents a frame data block.
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// Used when compressing or decompressing frame blocks concurrently.
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type block struct {
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compressed bool
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zdata []byte // compressed data
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data []byte // decompressed data
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offset int // offset within the data as with block dependency the 64Kb window is prepended to it
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checksum uint32 // compressed data checksum
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err error // error while [de]compressing
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}
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var (
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// ErrInvalidSource is returned by UncompressBlock when a compressed block is corrupted.
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ErrInvalidSource = errors.New("lz4: invalid source")
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// ErrShortBuffer is returned by UncompressBlock, CompressBlock or CompressBlockHC when
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// the supplied buffer for [de]compression is too small.
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ErrShortBuffer = errors.New("lz4: short buffer")
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)
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// CompressBlockBound returns the maximum size of a given buffer of size n, when not compressible.
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func CompressBlockBound(n int) int {
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return n + n/255 + 16
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}
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// UncompressBlock decompresses the source buffer into the destination one,
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// starting at the di index and returning the decompressed size.
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//
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// The destination buffer must be sized appropriately.
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//
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// An error is returned if the source data is invalid or the destination buffer is too small.
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func UncompressBlock(src, dst []byte, di int) (int, error) {
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si, sn, di0 := 0, len(src), di
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if sn == 0 {
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return 0, nil
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}
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for {
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// literals and match lengths (token)
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lLen := int(src[si] >> 4)
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mLen := int(src[si] & 0xF)
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if si++; si == sn {
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return di, ErrInvalidSource
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}
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// literals
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if lLen > 0 {
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if lLen == 0xF {
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for src[si] == 0xFF {
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lLen += 0xFF
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if si++; si == sn {
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return di - di0, ErrInvalidSource
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}
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}
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lLen += int(src[si])
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if si++; si == sn {
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return di - di0, ErrInvalidSource
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}
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}
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if len(dst)-di < lLen || si+lLen > sn {
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return di - di0, ErrShortBuffer
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}
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di += copy(dst[di:], src[si:si+lLen])
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if si += lLen; si >= sn {
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return di - di0, nil
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}
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}
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if si += 2; si >= sn {
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return di, ErrInvalidSource
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}
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offset := int(src[si-2]) | int(src[si-1])<<8
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if di-offset < 0 || offset == 0 {
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return di - di0, ErrInvalidSource
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}
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// match
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if mLen == 0xF {
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for src[si] == 0xFF {
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mLen += 0xFF
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if si++; si == sn {
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return di - di0, ErrInvalidSource
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}
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}
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mLen += int(src[si])
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if si++; si == sn {
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return di - di0, ErrInvalidSource
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}
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}
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// minimum match length is 4
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mLen += 4
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if len(dst)-di <= mLen {
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return di - di0, ErrShortBuffer
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}
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// copy the match (NB. match is at least 4 bytes long)
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// NB. past di, copy() would write old bytes instead of
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// the ones we just copied, so split the work into the largest chunk.
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for ; mLen >= offset; mLen -= offset {
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di += copy(dst[di:], dst[di-offset:di])
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}
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di += copy(dst[di:], dst[di-offset:di-offset+mLen])
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}
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}
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// CompressBlock compresses the source buffer starting at soffet into the destination one.
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// This is the fast version of LZ4 compression and also the default one.
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//
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// The size of the compressed data is returned. If it is 0 and no error, then the data is incompressible.
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//
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// An error is returned if the destination buffer is too small.
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func CompressBlock(src, dst []byte, soffset int) (int, error) {
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sn, dn := len(src)-mfLimit, len(dst)
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if sn <= 0 || dn == 0 || soffset >= sn {
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return 0, nil
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}
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var si, di int
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// fast scan strategy:
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// we only need a hash table to store the last sequences (4 bytes)
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var hashTable [1 << hashLog]int
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var hashShift = uint((minMatch * 8) - hashLog)
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// Initialise the hash table with the first 64Kb of the input buffer
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// (used when compressing dependent blocks)
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for si < soffset {
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h := binary.LittleEndian.Uint32(src[si:]) * hasher >> hashShift
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si++
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hashTable[h] = si
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}
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anchor := si
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fma := 1 << skipStrength
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for si < sn-minMatch {
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// hash the next 4 bytes (sequence)...
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h := binary.LittleEndian.Uint32(src[si:]) * hasher >> hashShift
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// -1 to separate existing entries from new ones
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ref := hashTable[h] - 1
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// ...and store the position of the hash in the hash table (+1 to compensate the -1 upon saving)
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hashTable[h] = si + 1
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// no need to check the last 3 bytes in the first literal 4 bytes as
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// this guarantees that the next match, if any, is compressed with
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// a lower size, since to have some compression we must have:
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// ll+ml-overlap > 1 + (ll-15)/255 + (ml-4-15)/255 + 2 (uncompressed size>compressed size)
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// => ll+ml>3+2*overlap => ll+ml>= 4+2*overlap
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// and by definition we do have:
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// ll >= 1, ml >= 4
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// => ll+ml >= 5
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// => so overlap must be 0
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// the sequence is new, out of bound (64kb) or not valid: try next sequence
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if ref < 0 || fma&(1<<skipStrength-1) < 4 ||
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(si-ref)>>winSizeLog > 0 ||
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src[ref] != src[si] ||
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src[ref+1] != src[si+1] ||
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src[ref+2] != src[si+2] ||
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src[ref+3] != src[si+3] {
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// variable step: improves performance on non-compressible data
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si += fma >> skipStrength
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fma++
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continue
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}
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// match found
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fma = 1 << skipStrength
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lLen := si - anchor
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offset := si - ref
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// encode match length part 1
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si += minMatch
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mLen := si // match length has minMatch already
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for si <= sn && src[si] == src[si-offset] {
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si++
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}
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mLen = si - mLen
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if mLen < 0xF {
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dst[di] = byte(mLen)
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} else {
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dst[di] = 0xF
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}
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// encode literals length
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if lLen < 0xF {
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dst[di] |= byte(lLen << 4)
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} else {
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dst[di] |= 0xF0
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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l := lLen - 0xF
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for ; l >= 0xFF; l -= 0xFF {
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dst[di] = 0xFF
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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}
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dst[di] = byte(l)
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}
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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// literals
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if di+lLen >= dn {
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return di, ErrShortBuffer
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}
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di += copy(dst[di:], src[anchor:anchor+lLen])
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anchor = si
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// encode offset
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if di += 2; di >= dn {
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return di, ErrShortBuffer
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}
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dst[di-2], dst[di-1] = byte(offset), byte(offset>>8)
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// encode match length part 2
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if mLen >= 0xF {
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for mLen -= 0xF; mLen >= 0xFF; mLen -= 0xFF {
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dst[di] = 0xFF
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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}
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dst[di] = byte(mLen)
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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}
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}
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if anchor == 0 {
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// incompressible
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return 0, nil
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}
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// last literals
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lLen := len(src) - anchor
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if lLen < 0xF {
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dst[di] = byte(lLen << 4)
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} else {
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dst[di] = 0xF0
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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lLen -= 0xF
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for ; lLen >= 0xFF; lLen -= 0xFF {
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dst[di] = 0xFF
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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}
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dst[di] = byte(lLen)
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}
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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// write literals
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src = src[anchor:]
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switch n := di + len(src); {
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case n > dn:
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return di, ErrShortBuffer
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case n >= sn:
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// incompressible
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return 0, nil
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}
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di += copy(dst[di:], src)
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return di, nil
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}
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// CompressBlockHC compresses the source buffer starting at soffet into the destination one.
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// CompressBlockHC compression ratio is better than CompressBlock but it is also slower.
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//
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// The size of the compressed data is returned. If it is 0 and no error, then the data is not compressible.
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//
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// An error is returned if the destination buffer is too small.
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func CompressBlockHC(src, dst []byte, soffset int) (int, error) {
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sn, dn := len(src)-mfLimit, len(dst)
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if sn <= 0 || dn == 0 || soffset >= sn {
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return 0, nil
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}
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var si, di int
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// Hash Chain strategy:
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// we need a hash table and a chain table
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// the chain table cannot contain more entries than the window size (64Kb entries)
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var hashTable [1 << hashLog]int
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var chainTable [winSize]int
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var hashShift = uint((minMatch * 8) - hashLog)
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// Initialise the hash table with the first 64Kb of the input buffer
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// (used when compressing dependent blocks)
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for si < soffset {
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h := binary.LittleEndian.Uint32(src[si:]) * hasher >> hashShift
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chainTable[si&winMask] = hashTable[h]
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si++
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hashTable[h] = si
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}
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anchor := si
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for si < sn-minMatch {
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// hash the next 4 bytes (sequence)...
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h := binary.LittleEndian.Uint32(src[si:]) * hasher >> hashShift
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// follow the chain until out of window and give the longest match
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mLen := 0
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offset := 0
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for next := hashTable[h] - 1; next > 0 && next > si-winSize; next = chainTable[next&winMask] - 1 {
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// the first (mLen==0) or next byte (mLen>=minMatch) at current match length must match to improve on the match length
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if src[next+mLen] == src[si+mLen] {
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for ml := 0; ; ml++ {
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if src[next+ml] != src[si+ml] || si+ml > sn {
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// found a longer match, keep its position and length
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if mLen < ml && ml >= minMatch {
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mLen = ml
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offset = si - next
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}
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break
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}
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}
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}
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}
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chainTable[si&winMask] = hashTable[h]
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hashTable[h] = si + 1
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// no match found
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if mLen == 0 {
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si++
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continue
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}
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// match found
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// update hash/chain tables with overlaping bytes:
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// si already hashed, add everything from si+1 up to the match length
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for si, ml := si+1, si+mLen; si < ml; {
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h := binary.LittleEndian.Uint32(src[si:]) * hasher >> hashShift
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chainTable[si&winMask] = hashTable[h]
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si++
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hashTable[h] = si
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}
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lLen := si - anchor
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si += mLen
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mLen -= minMatch // match length does not include minMatch
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if mLen < 0xF {
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dst[di] = byte(mLen)
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} else {
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dst[di] = 0xF
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}
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// encode literals length
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if lLen < 0xF {
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dst[di] |= byte(lLen << 4)
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} else {
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dst[di] |= 0xF0
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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l := lLen - 0xF
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for ; l >= 0xFF; l -= 0xFF {
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dst[di] = 0xFF
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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}
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dst[di] = byte(l)
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}
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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// literals
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if di+lLen >= dn {
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return di, ErrShortBuffer
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}
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di += copy(dst[di:], src[anchor:anchor+lLen])
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anchor = si
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// encode offset
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if di += 2; di >= dn {
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return di, ErrShortBuffer
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}
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dst[di-2], dst[di-1] = byte(offset), byte(offset>>8)
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// encode match length part 2
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if mLen >= 0xF {
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for mLen -= 0xF; mLen >= 0xFF; mLen -= 0xFF {
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dst[di] = 0xFF
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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}
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dst[di] = byte(mLen)
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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}
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}
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if anchor == 0 {
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// incompressible
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return 0, nil
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}
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// last literals
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lLen := len(src) - anchor
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if lLen < 0xF {
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dst[di] = byte(lLen << 4)
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} else {
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dst[di] = 0xF0
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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lLen -= 0xF
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for ; lLen >= 0xFF; lLen -= 0xFF {
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dst[di] = 0xFF
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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}
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dst[di] = byte(lLen)
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}
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if di++; di == dn {
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return di, ErrShortBuffer
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}
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// write literals
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src = src[anchor:]
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switch n := di + len(src); {
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case n > dn:
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return di, ErrShortBuffer
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case n >= sn:
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// incompressible
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return 0, nil
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}
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di += copy(dst[di:], src)
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return di, nil
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}
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