const tagLiteral* = 0x00 tagCopy1* = 0x01 tagCopy2* = 0x02 tagCopy4* = 0x03 inputMargin = 16 - 1 # PutUvarint encodes a uint64 into buf and returns the number of bytes written. func putUvarint(buf: var openArray[byte], x: uint64): int = var i = 0 x = x while x >= 0x80'u64: buf[i] = byte(x and 0xFF) or 0x80 x = x shr 7 inc i buf[i] = byte(x and 0xFF) result = i + 1 # Uvarint decodes a uint64 from buf and returns that value and the # number of bytes read (> 0). If an error occurred, the value is 0 # and the number of bytes n is <= 0 meaning: # # n == 0: buf too small # n < 0: value larger than 64 bits (overflow) # and -n is the number of bytes read # func uvarint(buf: openArray[byte]): (uint64, int) = var x: uint64 var s: uint for i, b in buf: if int(b) < 0x80: if (i > 9) or (i == 9) and (int(b) > 1): return (0'u64, -(i + 1)) # overflow return (x or (uint64(b) shl s), i + 1) x = x or (uint64(b and 0x7F) shl s) inc(s, 7) result = (0'u64, 0) template sliceImpl(r: openArray[byte], a, b: int): auto = toOpenArray(cast[ptr array[0, byte]](r[0].unsafeAddr)[], a, b) template `%`(s, i: untyped): untyped = (when i is BackwardsIndex: s.len - int(i) else: int(i)) template `[]`[U, V](r: openArray[byte], s: HSlice[U, V]): auto = sliceImpl(r, r % s.a, r % s.b) func load32(b: openArray[byte]): uint32 {.inline.} = result = uint32(b[0]) or (uint32(b[1]) shl 8 ) or (uint32(b[2]) shl 16) or (uint32(b[3]) shl 24) func load32(b: openArray[byte], i: int): uint32 = result = load32(b[i..= 68: # Emit a length 64 copy, encoded as 3 bytes. dst[i+0] = (63 shl 2) or tagCopy2 dst[i+1] = byte(offset) dst[i+2] = byte(offset shr 8) inc(i, 3) dec(length, 64) if length > 64: # Emit a length 60 copy, encoded as 3 bytes. dst[i+0] = (59 shl 2) or tagCopy2 dst[i+1] = byte(offset) dst[i+2] = byte(offset shr 8) inc(i, 3) dec(length, 60) if (length >= 12) or (offset >= 2048): # Emit the remaining copy, encoded as 3 bytes. dst[i+0] = (byte(length-1) shl 2) or tagCopy2 dst[i+1] = byte(offset) dst[i+2] = byte(offset shr 8) return i + 3 # Emit the remaining copy, encoded as 2 bytes. dst[i+0] = (byte(offset shr 8) shl 5) or (byte(length-4) shl 2) or tagCopy1 dst[i+1] = byte(offset) result = i + 2 when false: # extendMatch returns the largest k such that k <= len(src) and that # src[i:i+k-j] and src[j:k] have the same contents. # # It assumes that: # 0 <= i and i < j and j <= len(src) func extendMatch(src: openArray[byte], i, j: int): int = var i = i j = j while j < src.len and src[i] == src[j]: inc i inc j result = j func hash(u, shift: uint32): uint32 = result = (u * 0x1e35a7bd) shr shift # encodeBlock encodes a non-empty src to a guaranteed-large-enough dst. It # assumes that the varint-encoded length of the decompressed bytes has already # been written. # # It also assumes that: # len(dst) >= MaxEncodedLen(len(src)) and # minNonLiteralBlockSize <= len(src) and len(src) <= maxBlockSize func encodeBlock(dst, src: var openArray[byte]): int = # Initialize the hash table. Its size ranges from 1shl8 to 1shl14 inclusive. # The table element type is uint16, as s < sLimit and sLimit < len(src) # and len(src) <= maxBlockSize and maxBlockSize == 65536. const maxTableSize = 1 shl 14 # tableMask is redundant, but helps the compiler eliminate bounds # checks. tableMask = maxTableSize - 1 var shift = 32 - 8 tableSize = 1 shl 8 while tableSize < maxTableSize and tableSize < src.len: tableSize = tableSize * 2 dec shift # In Nim, all array elements are zero-initialized, so there is no advantage # to a smaller tableSize per se. However, it matches the C++ algorithm, # and in the asm versions of this code, we can get away with zeroing only # the first tableSize elements. var table: array[maxTableSize, uint16] # sLimit is when to stop looking for offset/length copies. The inputMargin # lets us use a fast path for emitLiteral in the main loop, while we are # looking for copies. var sLimit = src.len - inputMargin # nextEmit is where in src the next emitLiteral should start from. var nextEmit = 0 # The encoded form must start with a literal, as there are no previous # bytes to copy, so we start looking for hash matches at s == 1. var s = 1 var nextHash = hash(load32(src, s), shift.uint32) var d = 0 template emitRemainder(): untyped = if nextEmit < src.len: let litLen = emitLiteral(dst[d..^1], src[nextEmit..^1]) inc(d, litLen) return d while true: # Copied from the C++ snappy implementation: # # Heuristic match skipping: If 32 bytes are scanned with no matches # found, start looking only at every other byte. If 32 more bytes are # scanned (or skipped), look at every third byte, etc.. When a match # is found, immediately go back to looking at every byte. This is a # small loss (~5% performance, ~0.1% density) for compressible data # due to more bookkeeping, but for non-compressible data (such as # JPEG) it's a huge win since the compressor quickly "realizes" the # data is incompressible and doesn't bother looking for matches # everywhere. # # The "skip" variable keeps track of how many bytes there are since # the last match; dividing it by 32 (ie. right-shifting by five) gives # the number of bytes to move ahead for each iteration. var skip = 32 var nextS = s var candidate = 0 while true: s = nextS let bytesBetweenHashLookups = skip shr 5 nextS = s + bytesBetweenHashLookups inc(skip, bytesBetweenHashLookups) if nextS > sLimit: emitRemainder() candidate = int(table[nextHash and tableMask]) table[nextHash and tableMask] = uint16(s) nextHash = hash(load32(src, nextS), shift.uint32) if load32(src, s) == load32(src, candidate): break # A 4-byte match has been found. We'll later see if more than 4 bytes # match. But, prior to the match, src[nextEmit:s] are unmatched. Emit # them as literal bytes. var litLen = emitLiteral(dst[d..^1], src[nextEmit..= sLimit: emitRemainder() # We could immediately start working at s now, but to improve # compression we first update the hash table at s-1 and at s. If # another emitCopy is not our next move, also calculate nextHash # at s+1. At least on ARCH=amd64, these three hash calculations # are faster as one load64 call (with some shifts) instead of # three load32 calls. var x = load64(src, s-1) var prevHash = hash(uint32(x shr 0), shift.uint32) table[prevHash and tableMask] = uint16(s - 1) var currHash = hash(uint32(x shr 8), shift.uint32) candidate = int(table[currHash and tableMask]) table[currHash and tableMask] = uint16(s) if uint32(x shr 8) != load32(src, candidate): nextHash = hash(uint32(x shr 16), shift.uint32) inc s break result = d const decodeErrCodeCorrupt = 1 decodeErrCodeUnsupportedLiteralLength = 2 func decode(dst, src: var openArray[byte]): int = var d = 0 s = 0 offset = 0 length = 0 while s < src.len: let tag = src[s] and 0x03 case tag of tagLiteral: var x = int(src[s]) shr 2 if x < 60: inc s elif x == 60: inc(s, 2) if s > src.len: return decodeErrCodeCorrupt x = int(src[s-1]) elif x == 61: inc(s, 3) if s > src.len: return decodeErrCodeCorrupt x = int(src[s-2]) or (int(src[s-1]) shl 8) elif x == 62: inc(s, 4) if s > src.len: return decodeErrCodeCorrupt x = int(src[s-3]) or (int(src[s-2]) shl 8) or (int(src[s-1]) shl 16) elif x == 63: inc(s, 5) if s > src.len: return decodeErrCodeCorrupt x = int(src[s-4]) or (int(src[s-3]) shl 8) or (int(src[s-2]) shl 16) or (int(src[s-1]) shl 24) length = x + 1 if length <= 0: return decodeErrCodeUnsupportedLiteralLength if (length > (dst.len-d)) or (length > (src.len-s)): return decodeErrCodeCorrupt copyMem(dst[d].addr, src[s].addr, length) inc(d, length) inc(s, length) continue of tagCopy1: inc(s, 2) if s > src.len: return decodeErrCodeCorrupt length = 4 + ((int(src[s-2]) shr 2) and 0x07) offset = ((int(src[s-2]) and 0xe0) shl 3) or int(src[s-1]) of tagCopy2: s += 3 if s > src.len: return decodeErrCodeCorrupt length = 1 + (int(src[s-3]) shr 2) offset = int(src[s-2]) or (int(src[s-1]) shl 8) of tagCopy4: s += 5 if s > src.len: return decodeErrCodeCorrupt length = 1 + (int(src[s-5]) shr 2) offset = int(src[s-4]) or (int(src[s-3]) shl 8) or (int(src[s-2]) shl 16) or (int(src[s-1]) shl 24) else: discard if offset <= 0 or d < offset or (length > (dst.len-d)): return decodeErrCodeCorrupt # Copy from an earlier sub-slice of dst to a later sub-slice. Unlike # the built-in copy function, this byte-by-byte copy always runs # forwards, even if the slices overlap. Conceptually, this is: # # d += forwardCopy(dst[d:d+length], dst[d-offset:]) var stop = d + length while d != stop: dst[d] = dst[d-offset] inc d if d != dst.len: return decodeErrCodeCorrupt return 0 # MaxEncodedLen returns the maximum length of a snappy block, given its # uncompressed length. # # It will return a zero value if srcLen is too large to encode. func maxEncodedLen(srcLen: int): int = var n = uint64(srcLen) if n > 0xffffffff'u64: return 0 # Compressed data can be defined as: # compressed := item* literal* # item := literal* copy # # The trailing literal sequence has a space blowup of at most 62/60 # since a literal of length 60 needs one tag byte + one extra byte # for length information. # # Item blowup is trickier to measure. Suppose the "copy" op copies # 4 bytes of data. Because of a special check in the encoding code, # we produce a 4-byte copy only if the offset is < 65536. Therefore # the copy op takes 3 bytes to encode, and this type of item leads # to at most the 62/60 blowup for representing literals. # # Suppose the "copy" op copies 5 bytes of data. If the offset is big # enough, it will take 5 bytes to encode the copy op. Therefore the # worst case here is a one-byte literal followed by a five-byte copy. # That is, 6 bytes of input turn into 7 bytes of "compressed" data. # # This last factor dominates the blowup, so the final estimate is: n = 32'u64 + n + n div 6'u64 if n > 0xffffffff'u64: return 0 result = int(n) const maxBlockSize = 65536 # minNonLiteralBlockSize is the minimum size of the input to encodeBlock that # could be encoded with a copy tag. This is the minimum with respect to the # algorithm used by encodeBlock, not a minimum enforced by the file format. # # The encoded output must start with at least a 1 byte literal, as there are # no previous bytes to copy. A minimal (1 byte) copy after that, generated # from an emitCopy call in encodeBlock's main loop, would require at least # another inputMargin bytes, for the reason above: we want any emitLiteral # calls inside encodeBlock's main loop to use the fast path if possible, which # requires being able to overrun by inputMargin bytes. Thus, # minNonLiteralBlockSize equals 1 + 1 + inputMargin. # # The C++ code doesn't use this exact threshold, but it could, as discussed at # https:#groups.google.com/d/topic/snappy-compression/oGbhsdIJSJ8/discussion # The difference between Nim (2+inputMargin) and C++ (inputMargin) is purely an # optimization. It should not affect the encoded form. This is tested by # TestSameEncodingAsCppShortCopies. const minNonLiteralBlockSize = 1 + 1 + inputMargin # Encode returns the encoded form of src. The returned slice may be a sub- # slice of dst if dst was large enough to hold the entire encoded block. # Otherwise, a newly allocated slice will be returned. # # The dst and src must not overlap. It is valid to pass a nil dst. func encode*(src: openArray[byte]): seq[byte] = let n = maxEncodedLen(src.len) if n == 0: return var dst = newSeq[byte](n) # The block starts with the varint-encoded length of the decompressed bytes. var p = 0 d = putUVarInt(dst, uint64(src.len)) len = src.len while len > 0: var blockSize = len if blockSize > maxBlockSize: blockSize = maxBlockSize if blockSize < minNonLiteralBlockSize: let litLen = emitLiteral(dst[d..^1], src[p.. 0xffffffff'u64: return const wordSize = sizeof(uint) * 8 if (wordSize == 32) and (len > 0x7fffffff'u64): return if int(len) > 0: result = newSeq[byte](len) let errCode = decode(result, src[bytesRead..^1]) if errCode != 0: result = @[] template compress*(src: openArray[byte]): seq[byte] = snappy.encode(src) template uncompress*(src: openArray[byte]): seq[byte] = snappy.decode(src)