// this software is distributed under the MIT License (http://www.opensource.org/licenses/MIT): // // Copyright 2018-2019, CWI, TU Munich // // 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. // // You can contact the authors via the FSST source repository : https://github.com/cwida/fsst #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace std; #include "fsst12.h" // the official FSST API -- also usable by C mortals /* workhorse type for string and buffer lengths: 64-bits on 64-bits platforms and 32-bits on 32-bits platforms */ typedef unsigned long ulong; /* unsigned integers */ typedef uint8_t u8; typedef uint16_t u16; typedef uint32_t u32; typedef uint64_t u64; #define FSST_ENDIAN_MARKER ((u64) 1) #define FSST_VERSION_20190218 20190218 #define FSST_VERSION ((u64) FSST_VERSION_20190218) // "symbols" are character sequences (up to 8 bytes) // A symbol is compressed into a "code" of, 1.5 bytes (12 bits) #define FSST_CODE_MAX 4096 #define FSST_CODE_MASK ((u16) (FSST_CODE_MAX-1)) inline uint64_t fsst_unaligned_load(u8 const* V) { uint64_t Ret; memcpy(&Ret, V, sizeof(uint64_t)); // compiler will generate efficient code (unaligned load, where possible) return Ret; } struct Symbol { static const unsigned maxLength = 8; // gcl = u32 garbageBits:16,code:12,length:4 -- but we avoid exposing this bit-field notation u32 gcl; // use a single u32 to be sure "code" is accessed with one load and can be compared with one comparison mutable u32 gain; // mutable because gain value should be ignored in find() on unordered_set of Symbols // the byte sequence that this symbol stands for u8 symbol[maxLength]; Symbol() : gcl(0) {} explicit Symbol(u8 c, u16 code) : gcl((1<<28)|(code<<16)|7) { *(u64*) symbol = c; } // single-char symbol explicit Symbol(const char* input, u32 len) { if (len < 8) { *(u64*) symbol = 0; for(u32 i=0; i> 28; } u16 code() const { return (gcl >> 16) & FSST_CODE_MASK; } u8 garbageBits() const { return gcl; } u8 first() const { return 0xFF & *(u64*) symbol; } u16 first2() const { assert(length() > 1); return (0xFFFF & *(u64*) symbol); } #define FSST_HASH_LOG2SIZE 14 #define FSST_HASH_SHIFT 15 #define FSST_HASH_PRIME1 2971215073LL #define FSST_HASH(w) (((w)*FSST_HASH_PRIME1)^(((w)*FSST_HASH_PRIME1)>>13)) ulong hash() const { uint v0 = 0xFFFFFFFF & *(ulong*) symbol; return FSST_HASH(v0); } bool operator==(const Symbol& other) const { return *(u64*) symbol == *(u64*) other.symbol && length() == other.length(); } }; // during search for the best dictionary, we probe both (in this order, first wins): // - Symbol hashtable[8192] (keyed by the next four bytes, for s.length>2 -- certain 4-byte sequences will map to the same 3-byte symbol), // - u16 shortCodes[65536] array at the position of the next two-byte pattern (s.length==2) and // this search will yield a u16 code, it points into Symbol symbols[4096]. // you always find a hit, because the lowest 256 codes are all single-byte symbols // in the hash table, the gcl field contains (low-to-high) garbageBits:16,code:12,length:4 #define FSST_GCL_FREE ((15<<28)|(((u32)FSST_CODE_MASK)<<16)) // high bits of gcl (len=15,code=FSST_CODE_MASK) indicates free bucket // garbageBits is (8-length)*8, which is the amount of high bits to zero in the input word before comparing with the hashtable key // ..it could of course be computed from len during lookup, but storing it precomputed in some loose bits is faster // // the gain field is only used in the symbol queue that sorts symbols on gain struct SymbolMap { static const u32 hashTabSize = 1<> (u8) s.gcl); return true; } bool add(Symbol s) { assert(symbolCount < 4096); u32 len = s.length(); assert(len > 1); s.set_code_len(symbolCount, len); if (len == 2) { assert(shortCodes[s.first2()] == 4096 + s.first()); // cannot be in use shortCodes[s.first2()] = 8192 + symbolCount; // 8192 = (len == 2) << 12 } else if (!hashInsert(s)) { return false; } symbols[symbolCount++] = s; lenHisto[len-1]++; return true; } /// Find symbol in hash table, return code u16 hashFind(Symbol s) const { ulong idx = s.hash() & (hashTabSize-1); if (hashTab[idx].gcl <= s.gcl && *(u64*) hashTab[idx].symbol == (*(u64*) s.symbol & (0xFFFFFFFFFFFFFFFF >> ((u8) hashTab[idx].gcl)))) return (hashTab[idx].gcl>>16); // matched a long symbol return 0; } /// Find longest expansion, return code u16 findExpansion(Symbol s) const { if (s.length() == 1) { return 4096 + s.first(); } u16 ret = hashFind(s); return ret?ret:shortCodes[s.first2()]; } }; #if 0 //def NONOPT_FSST struct Counters { u16 count1[FSST_CODE_MAX]; // array to count frequency of symbols as they occur in the sample u16 count2[FSST_CODE_MAX][FSST_CODE_MAX]; // array to count subsequent combinations of two symbols in the sample void count1Set(u32 pos1, u16 val) { count1[pos1] = val; } void count1Inc(u32 pos1) { count1[pos1]++; } void count2Inc(u32 pos1, u32 pos2) { count2[pos1][pos2]++; } u32 count1GetNext(u32 &pos1) { return count1[pos1]; } u32 count2GetNext(u32 pos1, u32 &pos2) { return count2[pos1][pos2]; } void backup1(u8 *buf) { memcpy(buf, count1, FSST_CODE_MAX*sizeof(u16)); } void restore1(u8 *buf) { memcpy(count1, buf, FSST_CODE_MAX*sizeof(u16)); } }; #else // we keep two counters count1[pos] and count2[pos1][pos2] of resp 16 and 12-bits. Both are split into two columns for performance reasons // first reason is to make the column we update the most during symbolTable construction (the low bits) thinner, thus reducing CPU cache pressure. // second reason is that when scanning the array, after seeing a 64-bits 0 in the high bits column, we can quickly skip over many codes (15 or 7) struct Counters { // high arrays come before low arrays, because our GetNext() methods may overrun their 64-bits reads a few bytes u8 count1High[FSST_CODE_MAX]; // array to count frequency of symbols as they occur in the sample (16-bits) u8 count1Low[FSST_CODE_MAX]; // it is split in a low and high byte: cnt = count1High*256 + count1Low u8 count2High[FSST_CODE_MAX][FSST_CODE_MAX/2]; // array to count subsequent combinations of two symbols in the sample (12-bits: 8-bits low, 4-bits high) u8 count2Low[FSST_CODE_MAX][FSST_CODE_MAX]; // its value is (count2High*256+count2Low) -- but high is 4-bits (we put two numbers in one, hence /2) // 385KB -- but hot area likely just 10 + 30*4 = 130 cache lines (=8KB) void count1Set(u32 pos1, u16 val) { count1Low[pos1] = val&255; count1High[pos1] = val>>8; } void count1Inc(u32 pos1) { if (!count1Low[pos1]++) // increment high early (when low==0, not when low==255). This means (high > 0) <=> (cnt > 0) count1High[pos1]++; //(0,0)->(1,1)->..->(255,1)->(0,1)->(1,2)->(2,2)->(3,2)..(255,2)->(0,2)->(1,3)->(2,3)... } void count2Inc(u32 pos1, u32 pos2) { if (!count2Low[pos1][pos2]++) // increment high early (when low==0, not when low==255). This means (high > 0) <=> (cnt > 0) // inc 4-bits high counter with 1<<0 (1) or 1<<4 (16) -- depending on whether pos2 is even or odd, repectively count2High[pos1][(pos2)>>1] += 1 << (((pos2)&1)<<2); // we take our chances with overflow.. (4K maxval, on a 8K sample) } u32 count1GetNext(u32 &pos1) { // note: we will advance pos1 to the next nonzero counter in register range // read 16-bits single symbol counter, split into two 8-bits numbers (count1Low, count1High), while skipping over zeros u64 high = *(u64*) &count1High[pos1]; // note: this reads 8 subsequent counters [pos1..pos1+7] u32 zero = high?(__builtin_ctzl(high)>>3):7; // number of zero bytes high = (high >> (zero << 3)) & 255; // advance to nonzero counter if (((pos1 += zero) >= FSST_CODE_MAX) || !high) // SKIP! advance pos2 return 0; // all zero u64 low = count1Low[pos1]; if (low) high--; // high is incremented early and low late, so decrement high (unless low==0) return (high << 8) + low; } u32 count2GetNext(u32 pos1, u32 &pos2) { // note: we will advance pos2 to the next nonzero counter in register range // read 12-bits pairwise symbol counter, split into low 8-bits and high 4-bits number while skipping over zeros u64 high = *(u64*) &count2High[pos1][pos2>>1]; // note: this reads 16 subsequent counters [pos2..pos2+15] high >>= (pos2&1) << 2; // odd pos2: ignore the lowest 4 bits & we see only 15 counters u32 zero = high?(__builtin_ctzl(high)>>2):(15-(pos2&1)); // number of zero 4-bits counters high = (high >> (zero << 2)) & 15; // advance to nonzero counter if (((pos2 += zero) >= FSST_CODE_MAX) || !high) // SKIP! advance pos2 return 0; // all zero u64 low = count2Low[pos1][pos2]; if (low) high--; // high is incremented early and low late, so decrement high (unless low==0) return (high << 8) + low; } void backup1(u8 *buf) { memcpy(buf, count1High, FSST_CODE_MAX); memcpy(buf+FSST_CODE_MAX, count1Low, FSST_CODE_MAX); } void restore1(u8 *buf) { memcpy(count1High, buf, FSST_CODE_MAX); memcpy(count1Low, buf+FSST_CODE_MAX, FSST_CODE_MAX); } }; #endif // an encoder is a symbolmap plus some bufferspace, needed during map construction as well as compression struct Encoder { shared_ptr symbolMap; // symbols, plus metadata and data structures for quick compression (shortCode,hashTab, etc) union { Counters counters; // for counting symbol occurences during map construction }; }; // C++ fsst-compress function with some more control of how the compression happens (algorithm flavor, simd unroll degree) ulong compressImpl(Encoder *encoder, ulong n, ulong lenIn[], u8 *strIn[], ulong size, u8 * output, ulong *lenOut, u8 *strOut[], bool noSuffixOpt, bool avoidBranch, int simd); ulong compressAuto(Encoder *encoder, ulong n, ulong lenIn[], u8 *strIn[], ulong size, u8 * output, ulong *lenOut, u8 *strOut[], int simd);