ceph-csi/vendor/github.com/pierrec/lz4/block.go
Niels de Vos 91774fc936 rebase: vendor dependencies for Vault API
Uses github.com/libopenstorage/secrets to communicate with Vault. This
removes the need for maintaining our own limited Vault APIs.

By adding the new dependency, several other packages got updated in the
process. Unused indirect dependencies have been removed from go.mod.

Signed-off-by: Niels de Vos <ndevos@redhat.com>
2020-11-29 04:03:59 +00:00

414 lines
10 KiB
Go

package lz4
import (
"encoding/binary"
"math/bits"
"sync"
)
// blockHash hashes the lower 6 bytes into a value < htSize.
func blockHash(x uint64) uint32 {
const prime6bytes = 227718039650203
return uint32(((x << (64 - 48)) * prime6bytes) >> (64 - hashLog))
}
// CompressBlockBound returns the maximum size of a given buffer of size n, when not compressible.
func CompressBlockBound(n int) int {
return n + n/255 + 16
}
// UncompressBlock uncompresses the source buffer into the destination one,
// and returns the uncompressed size.
//
// The destination buffer must be sized appropriately.
//
// An error is returned if the source data is invalid or the destination buffer is too small.
func UncompressBlock(src, dst []byte) (int, error) {
if len(src) == 0 {
return 0, nil
}
if di := decodeBlock(dst, src); di >= 0 {
return di, nil
}
return 0, ErrInvalidSourceShortBuffer
}
// CompressBlock compresses the source buffer into the destination one.
// This is the fast version of LZ4 compression and also the default one.
//
// The argument hashTable is scratch space for a hash table used by the
// compressor. If provided, it should have length at least 1<<16. If it is
// shorter (or nil), CompressBlock allocates its own hash table.
//
// The size of the compressed data is returned.
//
// If the destination buffer size is lower than CompressBlockBound and
// the compressed size is 0 and no error, then the data is incompressible.
//
// An error is returned if the destination buffer is too small.
func CompressBlock(src, dst []byte, hashTable []int) (_ int, err error) {
defer recoverBlock(&err)
// Return 0, nil only if the destination buffer size is < CompressBlockBound.
isNotCompressible := len(dst) < CompressBlockBound(len(src))
// adaptSkipLog sets how quickly the compressor begins skipping blocks when data is incompressible.
// This significantly speeds up incompressible data and usually has very small impact on compression.
// bytes to skip = 1 + (bytes since last match >> adaptSkipLog)
const adaptSkipLog = 7
if len(hashTable) < htSize {
htIface := htPool.Get()
defer htPool.Put(htIface)
hashTable = (*(htIface).(*[htSize]int))[:]
}
// Prove to the compiler the table has at least htSize elements.
// The compiler can see that "uint32() >> hashShift" cannot be out of bounds.
hashTable = hashTable[:htSize]
// si: Current position of the search.
// anchor: Position of the current literals.
var si, di, anchor int
sn := len(src) - mfLimit
if sn <= 0 {
goto lastLiterals
}
// Fast scan strategy: the hash table only stores the last 4 bytes sequences.
for si < sn {
// Hash the next 6 bytes (sequence)...
match := binary.LittleEndian.Uint64(src[si:])
h := blockHash(match)
h2 := blockHash(match >> 8)
// We check a match at s, s+1 and s+2 and pick the first one we get.
// Checking 3 only requires us to load the source one.
ref := hashTable[h]
ref2 := hashTable[h2]
hashTable[h] = si
hashTable[h2] = si + 1
offset := si - ref
// If offset <= 0 we got an old entry in the hash table.
if offset <= 0 || offset >= winSize || // Out of window.
uint32(match) != binary.LittleEndian.Uint32(src[ref:]) { // Hash collision on different matches.
// No match. Start calculating another hash.
// The processor can usually do this out-of-order.
h = blockHash(match >> 16)
ref = hashTable[h]
// Check the second match at si+1
si += 1
offset = si - ref2
if offset <= 0 || offset >= winSize ||
uint32(match>>8) != binary.LittleEndian.Uint32(src[ref2:]) {
// No match. Check the third match at si+2
si += 1
offset = si - ref
hashTable[h] = si
if offset <= 0 || offset >= winSize ||
uint32(match>>16) != binary.LittleEndian.Uint32(src[ref:]) {
// Skip one extra byte (at si+3) before we check 3 matches again.
si += 2 + (si-anchor)>>adaptSkipLog
continue
}
}
}
// Match found.
lLen := si - anchor // Literal length.
// We already matched 4 bytes.
mLen := 4
// Extend backwards if we can, reducing literals.
tOff := si - offset - 1
for lLen > 0 && tOff >= 0 && src[si-1] == src[tOff] {
si--
tOff--
lLen--
mLen++
}
// Add the match length, so we continue search at the end.
// Use mLen to store the offset base.
si, mLen = si+mLen, si+minMatch
// Find the longest match by looking by batches of 8 bytes.
for si+8 < sn {
x := binary.LittleEndian.Uint64(src[si:]) ^ binary.LittleEndian.Uint64(src[si-offset:])
if x == 0 {
si += 8
} else {
// Stop is first non-zero byte.
si += bits.TrailingZeros64(x) >> 3
break
}
}
mLen = si - mLen
if mLen < 0xF {
dst[di] = byte(mLen)
} else {
dst[di] = 0xF
}
// Encode literals length.
if lLen < 0xF {
dst[di] |= byte(lLen << 4)
} else {
dst[di] |= 0xF0
di++
l := lLen - 0xF
for ; l >= 0xFF; l -= 0xFF {
dst[di] = 0xFF
di++
}
dst[di] = byte(l)
}
di++
// Literals.
copy(dst[di:di+lLen], src[anchor:anchor+lLen])
di += lLen + 2
anchor = si
// Encode offset.
_ = dst[di] // Bound check elimination.
dst[di-2], dst[di-1] = byte(offset), byte(offset>>8)
// Encode match length part 2.
if mLen >= 0xF {
for mLen -= 0xF; mLen >= 0xFF; mLen -= 0xFF {
dst[di] = 0xFF
di++
}
dst[di] = byte(mLen)
di++
}
// Check if we can load next values.
if si >= sn {
break
}
// Hash match end-2
h = blockHash(binary.LittleEndian.Uint64(src[si-2:]))
hashTable[h] = si - 2
}
lastLiterals:
if isNotCompressible && anchor == 0 {
// Incompressible.
return 0, nil
}
// Last literals.
lLen := len(src) - anchor
if lLen < 0xF {
dst[di] = byte(lLen << 4)
} else {
dst[di] = 0xF0
di++
for lLen -= 0xF; lLen >= 0xFF; lLen -= 0xFF {
dst[di] = 0xFF
di++
}
dst[di] = byte(lLen)
}
di++
// Write the last literals.
if isNotCompressible && di >= anchor {
// Incompressible.
return 0, nil
}
di += copy(dst[di:di+len(src)-anchor], src[anchor:])
return di, nil
}
// Pool of hash tables for CompressBlock.
var htPool = sync.Pool{
New: func() interface{} {
return new([htSize]int)
},
}
// blockHash hashes 4 bytes into a value < winSize.
func blockHashHC(x uint32) uint32 {
const hasher uint32 = 2654435761 // Knuth multiplicative hash.
return x * hasher >> (32 - winSizeLog)
}
// CompressBlockHC compresses the source buffer src into the destination dst
// with max search depth (use 0 or negative value for no max).
//
// CompressBlockHC compression ratio is better than CompressBlock but it is also slower.
//
// The size of the compressed data is returned.
//
// If the destination buffer size is lower than CompressBlockBound and
// the compressed size is 0 and no error, then the data is incompressible.
//
// An error is returned if the destination buffer is too small.
func CompressBlockHC(src, dst []byte, depth int) (_ int, err error) {
defer recoverBlock(&err)
// Return 0, nil only if the destination buffer size is < CompressBlockBound.
isNotCompressible := len(dst) < CompressBlockBound(len(src))
// adaptSkipLog sets how quickly the compressor begins skipping blocks when data is incompressible.
// This significantly speeds up incompressible data and usually has very small impact on compression.
// bytes to skip = 1 + (bytes since last match >> adaptSkipLog)
const adaptSkipLog = 7
var si, di, anchor int
// hashTable: stores the last position found for a given hash
// chainTable: stores previous positions for a given hash
var hashTable, chainTable [winSize]int
if depth <= 0 {
depth = winSize
}
sn := len(src) - mfLimit
if sn <= 0 {
goto lastLiterals
}
for si < sn {
// Hash the next 4 bytes (sequence).
match := binary.LittleEndian.Uint32(src[si:])
h := blockHashHC(match)
// Follow the chain until out of window and give the longest match.
mLen := 0
offset := 0
for next, try := hashTable[h], depth; try > 0 && next > 0 && si-next < winSize; next = chainTable[next&winMask] {
// The first (mLen==0) or next byte (mLen>=minMatch) at current match length
// must match to improve on the match length.
if src[next+mLen] != src[si+mLen] {
continue
}
ml := 0
// Compare the current position with a previous with the same hash.
for ml < sn-si {
x := binary.LittleEndian.Uint64(src[next+ml:]) ^ binary.LittleEndian.Uint64(src[si+ml:])
if x == 0 {
ml += 8
} else {
// Stop is first non-zero byte.
ml += bits.TrailingZeros64(x) >> 3
break
}
}
if ml < minMatch || ml <= mLen {
// Match too small (<minMath) or smaller than the current match.
continue
}
// Found a longer match, keep its position and length.
mLen = ml
offset = si - next
// Try another previous position with the same hash.
try--
}
chainTable[si&winMask] = hashTable[h]
hashTable[h] = si
// No match found.
if mLen == 0 {
si += 1 + (si-anchor)>>adaptSkipLog
continue
}
// Match found.
// Update hash/chain tables with overlapping bytes:
// si already hashed, add everything from si+1 up to the match length.
winStart := si + 1
if ws := si + mLen - winSize; ws > winStart {
winStart = ws
}
for si, ml := winStart, si+mLen; si < ml; {
match >>= 8
match |= uint32(src[si+3]) << 24
h := blockHashHC(match)
chainTable[si&winMask] = hashTable[h]
hashTable[h] = si
si++
}
lLen := si - anchor
si += mLen
mLen -= minMatch // Match length does not include minMatch.
if mLen < 0xF {
dst[di] = byte(mLen)
} else {
dst[di] = 0xF
}
// Encode literals length.
if lLen < 0xF {
dst[di] |= byte(lLen << 4)
} else {
dst[di] |= 0xF0
di++
l := lLen - 0xF
for ; l >= 0xFF; l -= 0xFF {
dst[di] = 0xFF
di++
}
dst[di] = byte(l)
}
di++
// Literals.
copy(dst[di:di+lLen], src[anchor:anchor+lLen])
di += lLen
anchor = si
// Encode offset.
di += 2
dst[di-2], dst[di-1] = byte(offset), byte(offset>>8)
// Encode match length part 2.
if mLen >= 0xF {
for mLen -= 0xF; mLen >= 0xFF; mLen -= 0xFF {
dst[di] = 0xFF
di++
}
dst[di] = byte(mLen)
di++
}
}
if isNotCompressible && anchor == 0 {
// Incompressible.
return 0, nil
}
// Last literals.
lastLiterals:
lLen := len(src) - anchor
if lLen < 0xF {
dst[di] = byte(lLen << 4)
} else {
dst[di] = 0xF0
di++
lLen -= 0xF
for ; lLen >= 0xFF; lLen -= 0xFF {
dst[di] = 0xFF
di++
}
dst[di] = byte(lLen)
}
di++
// Write the last literals.
if isNotCompressible && di >= anchor {
// Incompressible.
return 0, nil
}
di += copy(dst[di:di+len(src)-anchor], src[anchor:])
return di, nil
}