/*############################################################################## HPCC SYSTEMS software Copyright (C) 2012 HPCC Systems®. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. ############################################################################## */ /* FastLZ - lightning-fast lossless compression library Copyright (C) 2007 Ariya Hidayat (ariya@kde.org) Copyright (C) 2006 Ariya Hidayat (ariya@kde.org) Copyright (C) 2005 Ariya Hidayat (ariya@kde.org) Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #if !defined(FASTLZ_COMPRESSOR) && !defined(FASTLZ_DECOMPRESSOR) // adapted for jlib #include "platform.h" #include "jfcmp.hpp" #include "jflz.hpp" #include "jcrc.hpp" /* * Always check for bound when decompressing. * Generally it is best to leave it defined. */ #define FASTLZ_SAFE /* * Give hints to the compiler for branch prediction optimization. */ #if defined(__GNUC__) && (__GNUC__ > 2) #define FASTLZ_EXPECT_CONDITIONAL(c) (__builtin_expect((c), 1)) #define FASTLZ_UNEXPECT_CONDITIONAL(c) (__builtin_expect((c), 0)) #else #define FASTLZ_EXPECT_CONDITIONAL(c) (c) #define FASTLZ_UNEXPECT_CONDITIONAL(c) (c) #endif /* * Use inlined functions for supported systems. */ #if defined(__GNUC__) || defined(__DMC__) || defined(__POCC__) || defined(__WATCOMC__) || defined(__SUNPRO_C) #define FASTLZ_INLINE inline #elif defined(__BORLANDC__) || defined(_MSC_VER) || defined(__LCC__) #define FASTLZ_INLINE __inline #else #define FASTLZ_INLINE #endif /* * Prevent accessing more than 8-bit at once, except on x86 architectures. */ #if !defined(FASTLZ_STRICT_ALIGN) #define FASTLZ_STRICT_ALIGN #if defined(__i386__) || defined(__386) /* GNU C, Sun Studio */ #undef FASTLZ_STRICT_ALIGN #elif defined(__i486__) || defined(__i586__) || defined(__i686__) /* GNU C */ #undef FASTLZ_STRICT_ALIGN #elif defined(_M_IX86) /* Intel, MSVC */ #undef FASTLZ_STRICT_ALIGN #elif defined(__386) #undef FASTLZ_STRICT_ALIGN #elif defined(_X86_) /* MinGW */ #undef FASTLZ_STRICT_ALIGN #elif defined(__I86__) /* Digital Mars */ #undef FASTLZ_STRICT_ALIGN #endif #endif /* * FIXME: use preprocessor magic to set this on different platforms! */ typedef byte flzuint8; typedef unsigned short flzuint16; typedef unsigned int flzuint32; /* prototypes */ //size32_t fastlz_compress(const void* input, size32_t length, void* output); //size32_t fastlz_compress_level(int level, const void* input, size32_t length, void* output); //size32_t fastlz_decompress(const void* input, size32_t length, void* output, size32_t maxout); #define MAX_COPY 32 #define MAX_LEN 264 /* 256 + 8 */ #define MAX_DISTANCE 8192 #if !defined(FASTLZ_STRICT_ALIGN) #define FASTLZ_READU16(p) *((const flzuint16*)(p)) #else #define FASTLZ_READU16(p) ((p)[0] | (p)[1]<<8) #endif #define HASH_LOG 13 #define HASH_SIZE (1<< HASH_LOG) #define HASH_MASK (HASH_SIZE-1) #define HASH_FUNCTION(v,p) { v = FASTLZ_READU16(p); v ^= FASTLZ_READU16(p+1)^(v>>(16-HASH_LOG));v &= HASH_MASK; } typedef const flzuint8* HTAB_T[HASH_SIZE]; #undef FASTLZ_LEVEL #define FASTLZ_LEVEL 1 #undef FASTLZ_COMPRESSOR #undef FASTLZ_DECOMPRESSOR #define FASTLZ_COMPRESSOR fastlz1_compress #define FASTLZ_DECOMPRESSOR fastlz1_decompress static FASTLZ_INLINE size32_t FASTLZ_COMPRESSOR(const void* input, size32_t length, void* output, HTAB_T &htab); static FASTLZ_INLINE size32_t FASTLZ_DECOMPRESSOR(const void* input, size32_t length, void* output, size32_t maxout); #include "jflz.cpp" #undef FASTLZ_LEVEL #define FASTLZ_LEVEL 2 #undef MAX_DISTANCE #define MAX_DISTANCE 8191 #define MAX_FARDISTANCE (65535+MAX_DISTANCE-1) #undef FASTLZ_COMPRESSOR #undef FASTLZ_DECOMPRESSOR #define FASTLZ_COMPRESSOR fastlz2_compress #define FASTLZ_DECOMPRESSOR fastlz2_decompress static FASTLZ_INLINE size32_t FASTLZ_COMPRESSOR(const void* input, size32_t length, void* output, HTAB_T &htab); static FASTLZ_INLINE size32_t FASTLZ_DECOMPRESSOR(const void* input, size32_t length, void* output, size32_t maxout); #include "jflz.cpp" #define FASTLZ__JLIBCOMPRESSOR 1 inline size32_t fastlz_compress(const void* input, size32_t length, void* output, HTAB_T &htab) { /* for short block, choose fastlz1 */ if(length < 65536) return fastlz1_compress(input, length, output, htab); /* else... */ return fastlz2_compress(input, length, output, htab); } size32_t fastlz_compress(const void* input, size32_t length, void* output) { MemoryAttr ma; HTAB_T *ht = (HTAB_T *)ma.allocate(sizeof(HTAB_T)); // HTAB_T too big for stack really return fastlz_compress(input,length,output,*ht); } size32_t fastlz_decompress(const void* input, size32_t length, void* output, size32_t maxout) { /* magic identifier for compression level */ int level = ((*(const flzuint8*)input) >> 5) + 1; if(level == 1) return fastlz1_decompress(input, length, output, maxout); if(level == 2) return fastlz2_decompress(input, length, output, maxout); /* unknown level, trigger error */ return 0; } size32_t fastlz_compress_level(int level, const void* input, size32_t length, void* output) { MemoryAttr ma; HTAB_T *ht = (HTAB_T *)ma.allocate(sizeof(HTAB_T)); // HTAB_T too big for stack really if(level == 1) return fastlz1_compress(input, length, output, *ht); if(level == 2) return fastlz2_compress(input, length, output, *ht); return 0; } #else /* !defined(FASTLZ_COMPRESSOR) && !defined(FASTLZ_DECOMPRESSOR) */ static FASTLZ_INLINE size32_t FASTLZ_COMPRESSOR(const void* input, size32_t length, void* output, HTAB_T &htab) { const flzuint8* ip = (const flzuint8*) input; const flzuint8* ip_bound = ip + length - 2; const flzuint8* ip_limit = ip + length - 12; flzuint8* op = (flzuint8*) output; const flzuint8** hslot; flzuint32 hval; flzuint32 copy; /* sanity check */ if(FASTLZ_UNEXPECT_CONDITIONAL(length < 4)) { if(length) { /* create literal copy only */ *op++ = length-1; ip_bound++; while(ip <= ip_bound) *op++ = *ip++; return length+1; } else return 0; } /* initializes hash table */ for (hslot = htab; hslot < htab + HASH_SIZE; hslot++) *hslot = ip; /* we start with literal copy */ copy = 2; *op++ = MAX_COPY-1; *op++ = *ip++; *op++ = *ip++; /* main loop */ while(FASTLZ_EXPECT_CONDITIONAL(ip < ip_limit)) { const flzuint8* ref; flzuint32 distance; /* minimum match length */ flzuint32 len = 3; /* comparison starting-point */ const flzuint8* anchor = ip; /* check for a run */ #if FASTLZ_LEVEL==2 if(ip[0] == ip[-1] && FASTLZ_READU16(ip-1)==FASTLZ_READU16(ip+1)) { distance = 1; ip += 3; ref = anchor - 1 + 3; goto match; } #endif /* find potential match */ HASH_FUNCTION(hval,ip); hslot = htab + hval; ref = htab[hval]; /* calculate distance to the match */ distance = anchor - ref; /* update hash table */ *hslot = anchor; /* is this a match? check the first 3 bytes */ if(distance==0 || #if FASTLZ_LEVEL==1 (distance >= MAX_DISTANCE) || #else (distance >= MAX_FARDISTANCE) || #endif *ref++ != *ip++ || *ref++!=*ip++ || *ref++!=*ip++) goto literal; #if FASTLZ_LEVEL==2 /* far, needs at least 5-byte match */ if(distance >= MAX_DISTANCE) { if(*ip++ != *ref++ || *ip++!= *ref++) goto literal; len += 2; } match: #endif /* last matched byte */ ip = anchor + len; /* distance is biased */ distance--; if(!distance) { /* zero distance means a run */ flzuint8 x = ip[-1]; while(ip < ip_bound) if(*ref++ != x) break; else ip++; } else for(;;) { /* safe because the outer check against ip limit */ if(*ref++ != *ip++) break; if(*ref++ != *ip++) break; if(*ref++ != *ip++) break; if(*ref++ != *ip++) break; if(*ref++ != *ip++) break; if(*ref++ != *ip++) break; if(*ref++ != *ip++) break; if(*ref++ != *ip++) break; while(ip < ip_bound) if(*ref++ != *ip++) break; break; } /* if we have copied something, adjust the copy count */ if(copy) /* copy is biased, '0' means 1 byte copy */ *(op-copy-1) = copy-1; else /* back, to overwrite the copy count */ op--; /* reset literal counter */ copy = 0; /* length is biased, '1' means a match of 3 bytes */ ip -= 3; len = ip - anchor; /* encode the match */ #if FASTLZ_LEVEL==2 if(distance < MAX_DISTANCE) { if(len < 7) { *op++ = (len << 5) + (distance >> 8); *op++ = (distance & 255); } else { *op++ = (7 << 5) + (distance >> 8); for(len-=7; len >= 255; len-= 255) *op++ = 255; *op++ = len; *op++ = (distance & 255); } } else { /* far away, but not yet in the another galaxy... */ if(len < 7) { distance -= MAX_DISTANCE; *op++ = (len << 5) + 31; *op++ = 255; *op++ = distance >> 8; *op++ = distance & 255; } else { distance -= MAX_DISTANCE; *op++ = (7 << 5) + 31; for(len-=7; len >= 255; len-= 255) *op++ = 255; *op++ = len; *op++ = 255; *op++ = distance >> 8; *op++ = distance & 255; } } #else if(FASTLZ_UNEXPECT_CONDITIONAL(len > MAX_LEN-2)) while(len > MAX_LEN-2) { *op++ = (7 << 5) + (distance >> 8); *op++ = MAX_LEN - 2 - 7 -2; *op++ = (distance & 255); len -= MAX_LEN-2; } if(len < 7) { *op++ = (len << 5) + (distance >> 8); *op++ = (distance & 255); } else { *op++ = (7 << 5) + (distance >> 8); *op++ = len - 7; *op++ = (distance & 255); } #endif /* update the hash at match boundary */ HASH_FUNCTION(hval,ip); htab[hval] = ip++; HASH_FUNCTION(hval,ip); htab[hval] = ip++; /* assuming literal copy */ *op++ = MAX_COPY-1; continue; literal: *op++ = *anchor++; ip = anchor; copy++; if(FASTLZ_UNEXPECT_CONDITIONAL(copy == MAX_COPY)) { copy = 0; *op++ = MAX_COPY-1; } } /* left-over as literal copy */ ip_bound++; while(ip <= ip_bound) { *op++ = *ip++; copy++; if(copy == MAX_COPY) { copy = 0; *op++ = MAX_COPY-1; } } /* if we have copied something, adjust the copy length */ if(copy) *(op-copy-1) = copy-1; else op--; #if FASTLZ_LEVEL==2 /* marker for fastlz2 */ *(flzuint8*)output |= (1 << 5); #endif return op - (flzuint8*)output; } static FASTLZ_INLINE size32_t FASTLZ_DECOMPRESSOR(const void* input, size32_t length, void* output, size32_t maxout) { const flzuint8* ip = (const flzuint8*) input; const flzuint8* ip_limit = ip + length; flzuint8* op = (flzuint8*) output; flzuint8* op_limit = op + maxout; flzuint32 ctrl = (*ip++) & 31; int loopidx = 1; do { const flzuint8* ref = op; flzuint32 len = ctrl >> 5; flzuint32 ofs = (ctrl & 31) << 8; if(ctrl >= 32) { #if FASTLZ_LEVEL==2 flzuint8 code; #endif len--; ref -= ofs; if (len == 7-1) #if FASTLZ_LEVEL==1 len += *ip++; ref -= *ip++; #else do { code = *ip++; len += code; } while (code==255); code = *ip++; ref -= code; /* match from 16-bit distance */ if(FASTLZ_UNEXPECT_CONDITIONAL(code==255)) if(FASTLZ_EXPECT_CONDITIONAL(ofs==(31 << 8))) { ofs = (*ip++) << 8; ofs += *ip++; ref = op - ofs - MAX_DISTANCE; } #endif #ifdef FASTLZ_SAFE if (FASTLZ_UNEXPECT_CONDITIONAL(op + len + 3 > op_limit)) return 0; if (FASTLZ_UNEXPECT_CONDITIONAL(ref-1 < (flzuint8 *)output)) return 0; #endif if(FASTLZ_EXPECT_CONDITIONAL(ip < ip_limit)) ctrl = *ip++; else loopidx = 0; if(ref == op) { /* optimize copy for a run */ flzuint8 b = ref[-1]; *op++ = b; *op++ = b; *op++ = b; for(; len; --len) *op++ = b; } else { #if !defined(FASTLZ_STRICT_ALIGN) const flzuint16* p; flzuint16* q; #endif /* copy from reference */ ref--; *op++ = *ref++; *op++ = *ref++; *op++ = *ref++; #if !defined(FASTLZ_STRICT_ALIGN) /* copy a byte, so that now it's word aligned */ if(len & 1) { *op++ = *ref++; len--; } /* copy 16-bit at once */ q = (flzuint16*) op; op += len; p = (const flzuint16*) ref; for(len>>=1; len > 4; len-=4) { *q++ = *p++; *q++ = *p++; *q++ = *p++; *q++ = *p++; } for(; len; --len) *q++ = *p++; #else for(; len; --len) *op++ = *ref++; #endif } } else { ctrl++; #ifdef FASTLZ_SAFE if (FASTLZ_UNEXPECT_CONDITIONAL(op + ctrl > op_limit)) return 0; if (FASTLZ_UNEXPECT_CONDITIONAL(ip + ctrl > ip_limit)) return 0; #endif *op++ = *ip++; for(--ctrl; ctrl; ctrl--) *op++ = *ip++; loopidx = FASTLZ_EXPECT_CONDITIONAL(ip < ip_limit); if(loopidx) ctrl = *ip++; } } while(FASTLZ_EXPECT_CONDITIONAL(loopidx)); return op - (flzuint8*)output; } #undef FASTLZ__JLIBCOMPRESSOR // avoid being compiled twice!! #endif /* !defined(FASTLZ_COMPRESSOR) && !defined(FASTLZ_DECOMPRESSOR) */ #if defined(FASTLZ__JLIBCOMPRESSOR) /* Format: size32_t totalexpsize; { size32_t subcmpsize; bytes subcmpdata; } size32_t trailsize; bytes traildata; // unexpanded */ class jlib_decl CFastLZCompressor : public CFcmpCompressor { HTAB_T ht; virtual void setinmax() { inmax = blksz-outlen-sizeof(size32_t); if (inmax<256) trailing = true; // too small to bother compressing else { trailing = false; inmax -= (fastlzSlack(inmax) + sizeof(size32_t)); } } virtual void flushcommitted() { // only does non trailing if (trailing) return; size32_t toflush = (inlenblk==COMMITTED)?inlen:inlenblk; if (toflush == 0) return; size32_t outSzRequired = outlen+sizeof(size32_t)*2+toflush+fastlzSlack(toflush); if (!dynamicOutSz) assertex(outSzRequired<=blksz); else { if (outSzRequired>dynamicOutSz) { verifyex(outBufMb->ensureCapacity(outBufStart+outSzRequired)); dynamicOutSz = outBufMb->capacity(); outbuf = ((byte *)outBufMb->bufferBase()+outBufStart); } } size32_t *cmpsize = (size32_t *)(outbuf+outlen); byte *out = (byte *)(cmpsize+1); *cmpsize = fastlz_compress(inbuf, toflush, out, ht); if (*cmpsizebufalloc) { if (bufalloc) free(outbuf); bufalloc = outlen; outbuf = (unsigned char *)malloc(bufalloc); if (!outbuf) throw MakeStringException(MSGAUD_operator,0, "Out of memory in FastLZExpander::expand, requesting %d bytes", bufalloc); } size32_t done = 0; for (;;) { const size32_t szchunk = *in; in++; if (szchunk+doneoutlen)) throw MakeStringException(0, "FastLZExpander - corrupt data(1) %d %d",written,szchunk); } else { if (szchunk+done!=outlen) throw MakeStringException(0, "FastLZExpander - corrupt data(2) %d %d",szchunk,outlen); memcpy((byte *)buf+done,in,szchunk); break; } in = (const size32_t *)(((const byte *)in)+szchunk); } } }; void fastLZCompressToBuffer(MemoryBuffer & out, size32_t len, const void * src) { size32_t outbase = out.length(); out.append(len); DelayedMarker cmpSzMarker(out); void *cmpData = out.reserve(len+fastlzSlack(len)); size32_t sz = (len>16)?fastlz_compress(src, len, cmpData):16; if (sz>=len) { sz = len; memcpy(cmpData, src, len); } cmpSzMarker.write(sz); out.setLength(outbase+sz+sizeof(size32_t)*2); } void fastLZDecompressToBuffer(MemoryBuffer & out, const void * src) { size32_t *sz = (size32_t *)src; size32_t expsz = *(sz++); size32_t cmpsz = *(sz++); void *o = out.reserve(expsz); if (cmpsz!=expsz) { size32_t written = fastlz_decompress(sz,cmpsz,o,expsz); if (written!=expsz) throw MakeStringException(0, "fastLZDecompressToBuffer - corrupt data(1) %d %d",written,expsz); } else memcpy(o,sz,expsz); } void fastLZDecompressToBuffer(MemoryBuffer & out, MemoryBuffer & in) { size32_t expsz; size32_t cmpsz; in.read(expsz).read(cmpsz); void *o = out.reserve(expsz); if (cmpsz!=expsz) { size32_t written = fastlz_decompress(in.readDirect(cmpsz),cmpsz,o,expsz); if (written!=expsz) throw MakeStringException(0, "fastLZDecompressToBuffer - corrupt data(3) %d %d",written,expsz); } else memcpy(o,in.readDirect(cmpsz),expsz); } void fastLZDecompressToAttr(MemoryAttr & out, const void * src) { size32_t *sz = (size32_t *)src; size32_t expsz = *(sz++); size32_t cmpsz = *(sz++); void *o = out.allocate(expsz); if (cmpsz!=expsz) { size32_t written = fastlz_decompress(sz,cmpsz,o,expsz); if (written!=expsz) throw MakeStringException(0, "fastLZDecompressToBuffer - corrupt data(2) %d %d",written,expsz); } else memcpy(o,sz,expsz); } void fastLZDecompressToBuffer(MemoryAttr & out, MemoryBuffer & in) { size32_t expsz; size32_t cmpsz; in.read(expsz).read(cmpsz); void *o = out.allocate(expsz); if (cmpsz!=expsz) { size32_t written = fastlz_decompress(in.readDirect(cmpsz),cmpsz,o,expsz); if (written!=expsz) throw MakeStringException(0, "fastLZDecompressToBuffer - corrupt data(4) %d %d",written,expsz); } else memcpy(o,in.readDirect(cmpsz),expsz); } ICompressor *createFastLZCompressor() { return new CFastLZCompressor; } IExpander *createFastLZExpander() { return new CFastLZExpander; } static const __uint64 FLZSTRMCOMPRESSEDFILEFLAG = I64C(0xc3518de42f15da57); class CFastLZStream : public CFcmpStream { bool load() { bufpos = 0; bufsize = 0; if (expOffset==expSize) return false; size32_t sz[2]; if (baseio->read(cmpOffset,sizeof(size32_t)*2,&sz)!=sizeof(size32_t)*2) return false; bufsize = sz[0]; if (!bufsize) return false; cmpOffset += sizeof(size32_t)*2; if (ma.length()read(cmpOffset,sz[1],cmpbuf)!=sz[1]) throw MakeStringException(-1,"CFastLZStream: file corrupt.1"); if (fastlz_decompress(cmpbuf,sz[1],ma.bufferBase(),bufsize)!=bufsize) throw MakeStringException(-1,"CFastLZStream: file corrupt.2"); cmpOffset += sz[1]; return true; } void save() { if (bufsize) { MemoryAttr dstma; byte *dst = (byte *)dstma.allocate(sizeof(size32_t)*2+bufsize+fastlzSlack(bufsize)); size32_t sz = fastlz_compress(ma.get(),bufsize,sizeof(size32_t)*2+dst); memcpy(dst,&bufsize,sizeof(size32_t)); memcpy(dst+sizeof(size32_t),&sz,sizeof(size32_t)); baseio->write(cmpOffset,sz+sizeof(size32_t)*2,dst); cmpOffset += sz+sizeof(size32_t)*2; } bufsize = 0; } public: CFastLZStream() { compType = FLZSTRMCOMPRESSEDFILEFLAG; } virtual ~CFastLZStream() { flush(); } }; IFileIOStream *createFastLZStreamRead(IFileIO *base) { Owned strm = new CFastLZStream(); if (strm->attach(base)) return strm.getClear(); return NULL; } IFileIOStream *createFastLZStreamWrite(IFileIO *base) { Owned strm = new CFastLZStream(); strm->create(base); return strm.getClear(); } #endif