/* hyperloglog.c - Redis HyperLogLog probabilistic cardinality approximation. * This file implements the algorithm and the exported Redis commands. * * Copyright (c) 2014, Salvatore Sanfilippo * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of Redis nor the names of its contributors may be used * to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include "duckdb/common/vector.hpp" #include "duckdb/common/types/hyperloglog.hpp" #include "hyperloglog.hpp" #include "sds.hpp" #include #include #include #include #include #include namespace duckdb_hll { #define HLL_SPARSE_MAX_BYTES 3000 /* The Redis HyperLogLog implementation is based on the following ideas: * * * The use of a 64 bit hash function as proposed in [1], in order to don't * limited to cardinalities up to 10^9, at the cost of just 1 additional * bit per register. * * The use of 16384 6-bit registers for a great level of accuracy, using * a total of 12k per key. * * The use of the Redis string data type. No new type is introduced. * * No attempt is made to compress the data structure as in [1]. Also the * algorithm used is the original HyperLogLog Algorithm as in [2], with * the only difference that a 64 bit hash function is used, so no correction * is performed for values near 2^32 as in [1]. * * [1] Heule, Nunkesser, Hall: HyperLogLog in Practice: Algorithmic * Engineering of a State of The Art Cardinality Estimation Algorithm. * * [2] P. Flajolet, Éric Fusy, O. Gandouet, and F. Meunier. Hyperloglog: The * analysis of a near-optimal cardinality estimation algorithm. * * Redis uses two representations: * * 1) A "dense" representation where every entry is represented by * a 6-bit integer. * 2) A "sparse" representation using run length compression suitable * for representing HyperLogLogs with many registers set to 0 in * a memory efficient way. * * * HLL header * === * * Both the dense and sparse representation have a 16 byte header as follows: * * +------+---+-----+----------+ * | HYLL | E | N/U | Cardin. | * +------+---+-----+----------+ * * The first 4 bytes are a magic string set to the bytes "HYLL". * "E" is one byte encoding, currently set to HLL_DENSE or * HLL_SPARSE. N/U are three not used bytes. * * The "Cardin." field is a 64 bit integer stored in little endian format * with the latest cardinality computed that can be reused if the data * structure was not modified since the last computation (this is useful * because there are high probabilities that HLLADD operations don't * modify the actual data structure and hence the approximated cardinality). * * When the most significant bit in the most significant byte of the cached * cardinality is set, it means that the data structure was modified and * we can't reuse the cached value that must be recomputed. * * Dense representation * === * * The dense representation used by Redis is the following: * * +--------+--------+--------+------// //--+ * |11000000|22221111|33333322|55444444 .... | * +--------+--------+--------+------// //--+ * * The 6 bits counters are encoded one after the other starting from the * LSB to the MSB, and using the next bytes as needed. * * Sparse representation * === * * The sparse representation encodes registers using a run length * encoding composed of three opcodes, two using one byte, and one using * of two bytes. The opcodes are called ZERO, XZERO and VAL. * * ZERO opcode is represented as 00xxxxxx. The 6-bit integer represented * by the six bits 'xxxxxx', plus 1, means that there are N registers set * to 0. This opcode can represent from 1 to 64 contiguous registers set * to the value of 0. * * XZERO opcode is represented by two bytes 01xxxxxx yyyyyyyy. The 14-bit * integer represented by the bits 'xxxxxx' as most significant bits and * 'yyyyyyyy' as least significant bits, plus 1, means that there are N * registers set to 0. This opcode can represent from 0 to 16384 contiguous * registers set to the value of 0. * * VAL opcode is represented as 1vvvvvxx. It contains a 5-bit integer * representing the value of a register, and a 2-bit integer representing * the number of contiguous registers set to that value 'vvvvv'. * To obtain the value and run length, the integers vvvvv and xx must be * incremented by one. This opcode can represent values from 1 to 32, * repeated from 1 to 4 times. * * The sparse representation can't represent registers with a value greater * than 32, however it is very unlikely that we find such a register in an * HLL with a cardinality where the sparse representation is still more * memory efficient than the dense representation. When this happens the * HLL is converted to the dense representation. * * The sparse representation is purely positional. For example a sparse * representation of an empty HLL is just: XZERO:16384. * * An HLL having only 3 non-zero registers at position 1000, 1020, 1021 * respectively set to 2, 3, 3, is represented by the following three * opcodes: * * XZERO:1000 (Registers 0-999 are set to 0) * VAL:2,1 (1 register set to value 2, that is register 1000) * ZERO:19 (Registers 1001-1019 set to 0) * VAL:3,2 (2 registers set to value 3, that is registers 1020,1021) * XZERO:15362 (Registers 1022-16383 set to 0) * * In the example the sparse representation used just 7 bytes instead * of 12k in order to represent the HLL registers. In general for low * cardinality there is a big win in terms of space efficiency, traded * with CPU time since the sparse representation is slower to access: * * The following table shows average cardinality vs bytes used, 100 * samples per cardinality (when the set was not representable because * of registers with too big value, the dense representation size was used * as a sample). * * 100 267 * 200 485 * 300 678 * 400 859 * 500 1033 * 600 1205 * 700 1375 * 800 1544 * 900 1713 * 1000 1882 * 2000 3480 * 3000 4879 * 4000 6089 * 5000 7138 * 6000 8042 * 7000 8823 * 8000 9500 * 9000 10088 * 10000 10591 * * The dense representation uses 12288 bytes, so there is a big win up to * a cardinality of ~2000-3000. For bigger cardinalities the constant times * involved in updating the sparse representation is not justified by the * memory savings. The exact maximum length of the sparse representation * when this implementation switches to the dense representation is * configured via the define server.hll_sparse_max_bytes. */ struct hllhdr { char magic[4]; /* "HYLL" */ uint8_t encoding; /* HLL_DENSE or HLL_SPARSE. */ uint8_t notused[3]; /* Reserved for future use, must be zero. */ uint8_t card[8]; /* Cached cardinality, little endian. */ uint8_t registers[1]; /* Data bytes. */ }; /* The cached cardinality MSB is used to signal validity of the cached value. */ #define HLL_INVALIDATE_CACHE(hdr) (hdr)->card[7] |= (1<<7) #define HLL_VALID_CACHE(hdr) (((hdr)->card[7] & (1<<7)) == 0) #define HLL_P 12 /* The greater is P, the smaller the error. */ #define HLL_Q (64-HLL_P) /* The number of bits of the hash value used for determining the number of leading zeros. */ #define HLL_REGISTERS (1< 6 * * Right shift b0 of 'fb' bits. * * +--------+ * |11000000| <- Initial value of b0 * |00000011| <- After right shift of 6 pos. * +--------+ * * Left shift b1 of bits 8-fb bits (2 bits) * * +--------+ * |22221111| <- Initial value of b1 * |22111100| <- After left shift of 2 bits. * +--------+ * * OR the two bits, and finally AND with 111111 (63 in decimal) to * clean the higher order bits we are not interested in: * * +--------+ * |00000011| <- b0 right shifted * |22111100| <- b1 left shifted * |22111111| <- b0 OR b1 * | 111111| <- (b0 OR b1) AND 63, our value. * +--------+ * * We can try with a different example, like pos = 0. In this case * the 6-bit counter is actually contained in a single byte. * * b0 = 6 * pos / 8 = 0 * * +--------+ * |11000000| <- Our byte at b0 * +--------+ * * fb = 6 * pos % 8 = 0 * * So we right shift of 0 bits (no shift in practice) and * left shift the next byte of 8 bits, even if we don't use it, * but this has the effect of clearing the bits so the result * will not be affacted after the OR. * * ------------------------------------------------------------------------- * * Setting the register is a bit more complex, let's assume that 'val' * is the value we want to set, already in the right range. * * We need two steps, in one we need to clear the bits, and in the other * we need to bitwise-OR the new bits. * * Let's try with 'pos' = 1, so our first byte at 'b' is 0, * * "fb" is 6 in this case. * * +--------+ * |11000000| <- Our byte at b0 * +--------+ * * To create a AND-mask to clear the bits about this position, we just * initialize the mask with the value 63, left shift it of "fs" bits, * and finally invert the result. * * +--------+ * |00111111| <- "mask" starts at 63 * |11000000| <- "mask" after left shift of "ls" bits. * |00111111| <- "mask" after invert. * +--------+ * * Now we can bitwise-AND the byte at "b" with the mask, and bitwise-OR * it with "val" left-shifted of "ls" bits to set the new bits. * * Now let's focus on the next byte b1: * * +--------+ * |22221111| <- Initial value of b1 * +--------+ * * To build the AND mask we start again with the 63 value, right shift * it by 8-fb bits, and invert it. * * +--------+ * |00111111| <- "mask" set at 2&6-1 * |00001111| <- "mask" after the right shift by 8-fb = 2 bits * |11110000| <- "mask" after bitwise not. * +--------+ * * Now we can mask it with b+1 to clear the old bits, and bitwise-OR * with "val" left-shifted by "rs" bits to set the new value. */ /* Note: if we access the last counter, we will also access the b+1 byte * that is out of the array, but sds strings always have an implicit null * term, so the byte exists, and we can skip the conditional (or the need * to allocate 1 byte more explicitly). */ /* Store the value of the register at position 'regnum' into variable 'target'. * 'p' is an array of unsigned bytes. */ #define HLL_DENSE_GET_REGISTER(target,p,regnum) do { \ uint8_t *_p = (uint8_t*) p; \ unsigned long _byte = regnum*HLL_BITS/8; \ unsigned long _fb = regnum*HLL_BITS&7; \ unsigned long _fb8 = 8 - _fb; \ unsigned long b0 = _p[_byte]; \ unsigned long b1 = _p[_byte+1]; \ target = ((b0 >> _fb) | (b1 << _fb8)) & HLL_REGISTER_MAX; \ } while(0) /* Set the value of the register at position 'regnum' to 'val'. * 'p' is an array of unsigned bytes. */ #define HLL_DENSE_SET_REGISTER(p,regnum,val) do { \ uint8_t *_p = (uint8_t*) p; \ unsigned long _byte = regnum*HLL_BITS/8; \ unsigned long _fb = regnum*HLL_BITS&7; \ unsigned long _fb8 = 8 - _fb; \ unsigned long _v = val; \ _p[_byte] &= ~(HLL_REGISTER_MAX << _fb); \ _p[_byte] |= _v << _fb; \ _p[_byte+1] &= ~(HLL_REGISTER_MAX >> _fb8); \ _p[_byte+1] |= _v >> _fb8; \ } while(0) /* Macros to access the sparse representation. * The macros parameter is expected to be an uint8_t pointer. */ #define HLL_SPARSE_XZERO_BIT 0x40 /* 01xxxxxx */ #define HLL_SPARSE_VAL_BIT 0x80 /* 1vvvvvxx */ #define HLL_SPARSE_IS_ZERO(p) (((*(p)) & 0xc0) == 0) /* 00xxxxxx */ #define HLL_SPARSE_IS_XZERO(p) (((*(p)) & 0xc0) == HLL_SPARSE_XZERO_BIT) #define HLL_SPARSE_IS_VAL(p) ((*(p)) & HLL_SPARSE_VAL_BIT) #define HLL_SPARSE_ZERO_LEN(p) (((*(p)) & 0x3f)+1) #define HLL_SPARSE_XZERO_LEN(p) (((((*(p)) & 0x3f) << 8) | (*((p)+1)))+1) #define HLL_SPARSE_VAL_VALUE(p) ((((*(p)) >> 2) & 0x1f)+1) #define HLL_SPARSE_VAL_LEN(p) (((*(p)) & 0x3)+1) #define HLL_SPARSE_VAL_MAX_VALUE 32 #define HLL_SPARSE_VAL_MAX_LEN 4 #define HLL_SPARSE_ZERO_MAX_LEN 64 #define HLL_SPARSE_XZERO_MAX_LEN 16384 #define HLL_SPARSE_VAL_SET(p,val,len) do { \ *(p) = (((val)-1)<<2|((len)-1))|HLL_SPARSE_VAL_BIT; \ } while(0) #define HLL_SPARSE_ZERO_SET(p,len) do { \ *(p) = (len)-1; \ } while(0) #define HLL_SPARSE_XZERO_SET(p,len) do { \ int _l = (len)-1; \ *(p) = (_l>>8) | HLL_SPARSE_XZERO_BIT; \ *((p)+1) = (_l&0xff); \ } while(0) #define HLL_ALPHA_INF 0.721347520444481703680 /* constant for 0.5/ln(2) */ /* ========================= HyperLogLog algorithm ========================= */ /* Our hash function is MurmurHash2, 64 bit version. * It was modified for Redis in order to provide the same result in * big and little endian archs (endian neutral). */ uint64_t MurmurHash64A (const void * key, int len, unsigned int seed) { const uint64_t m = 0xc6a4a7935bd1e995; const int r = 47; uint64_t h = seed ^ (len * m); const uint8_t *data = (const uint8_t *)key; const uint8_t *end = data + (len-(len&7)); while(data != end) { uint64_t k; #if (BYTE_ORDER == LITTLE_ENDIAN) #ifdef USE_ALIGNED_ACCESS memcpy(&k,data,sizeof(uint64_t)); #else k = *((uint64_t*)data); #endif #else k = (uint64_t) data[0]; k |= (uint64_t) data[1] << 8; k |= (uint64_t) data[2] << 16; k |= (uint64_t) data[3] << 24; k |= (uint64_t) data[4] << 32; k |= (uint64_t) data[5] << 40; k |= (uint64_t) data[6] << 48; k |= (uint64_t) data[7] << 56; #endif k *= m; k ^= k >> r; k *= m; h ^= k; h *= m; data += 8; } switch(len & 7) { case 7: h ^= (uint64_t)data[6] << 48; /* fall-thru */ case 6: h ^= (uint64_t)data[5] << 40; /* fall-thru */ case 5: h ^= (uint64_t)data[4] << 32; /* fall-thru */ case 4: h ^= (uint64_t)data[3] << 24; /* fall-thru */ case 3: h ^= (uint64_t)data[2] << 16; /* fall-thru */ case 2: h ^= (uint64_t)data[1] << 8; /* fall-thru */ case 1: h ^= (uint64_t)data[0]; h *= m; /* fall-thru */ }; h ^= h >> r; h *= m; h ^= h >> r; return h; } /* Given a string element to add to the HyperLogLog, returns the length * of the pattern 000..1 of the element hash. As a side effect 'regp' is * set to the register index this element hashes to. */ int hllPatLen(unsigned char *ele, size_t elesize, long *regp) { uint64_t hash, bit, index; int count; /* Count the number of zeroes starting from bit HLL_REGISTERS * (that is a power of two corresponding to the first bit we don't use * as index). The max run can be 64-P+1 = Q+1 bits. * * Note that the final "1" ending the sequence of zeroes must be * included in the count, so if we find "001" the count is 3, and * the smallest count possible is no zeroes at all, just a 1 bit * at the first position, that is a count of 1. * * This may sound like inefficient, but actually in the average case * there are high probabilities to find a 1 after a few iterations. */ hash = MurmurHash64A(ele,elesize,0xadc83b19ULL); index = hash & HLL_P_MASK; /* Register index. */ hash >>= HLL_P; /* Remove bits used to address the register. */ hash |= ((uint64_t)1< oldcount) { HLL_DENSE_SET_REGISTER(registers,index,count); return 1; } else { return 0; } } /* "Add" the element in the dense hyperloglog data structure. * Actually nothing is added, but the max 0 pattern counter of the subset * the element belongs to is incremented if needed. * * This is just a wrapper to hllDenseSet(), performing the hashing of the * element in order to retrieve the index and zero-run count. */ int hllDenseAdd(uint8_t *registers, unsigned char *ele, size_t elesize) { long index; uint8_t count = hllPatLen(ele,elesize,&index); /* Update the register if this element produced a longer run of zeroes. */ return hllDenseSet(registers,index,count); } /* Compute the register histogram in the dense representation. */ void hllDenseRegHisto(uint8_t *registers, int* reghisto) { int j; /* Redis default is to use 16384 registers 6 bits each. The code works * with other values by modifying the defines, but for our target value * we take a faster path with unrolled loops. */ if (HLL_REGISTERS == 16384 && HLL_BITS == 6) { uint8_t *r = registers; unsigned long r0, r1, r2, r3, r4, r5, r6, r7, r8, r9, r10, r11, r12, r13, r14, r15; for (j = 0; j < 1024; j++) { /* Handle 16 registers per iteration. */ r0 = r[0] & 63; r1 = (r[0] >> 6 | r[1] << 2) & 63; r2 = (r[1] >> 4 | r[2] << 4) & 63; r3 = (r[2] >> 2) & 63; r4 = r[3] & 63; r5 = (r[3] >> 6 | r[4] << 2) & 63; r6 = (r[4] >> 4 | r[5] << 4) & 63; r7 = (r[5] >> 2) & 63; r8 = r[6] & 63; r9 = (r[6] >> 6 | r[7] << 2) & 63; r10 = (r[7] >> 4 | r[8] << 4) & 63; r11 = (r[8] >> 2) & 63; r12 = r[9] & 63; r13 = (r[9] >> 6 | r[10] << 2) & 63; r14 = (r[10] >> 4 | r[11] << 4) & 63; r15 = (r[11] >> 2) & 63; reghisto[r0]++; reghisto[r1]++; reghisto[r2]++; reghisto[r3]++; reghisto[r4]++; reghisto[r5]++; reghisto[r6]++; reghisto[r7]++; reghisto[r8]++; reghisto[r9]++; reghisto[r10]++; reghisto[r11]++; reghisto[r12]++; reghisto[r13]++; reghisto[r14]++; reghisto[r15]++; r += 12; } } else { for(j = 0; j < HLL_REGISTERS; j++) { unsigned long reg; HLL_DENSE_GET_REGISTER(reg,registers,j); reghisto[reg]++; } } } /* ================== Sparse representation implementation ================= */ /* Convert the HLL with sparse representation given as input in its dense * representation. Both representations are represented by SDS strings, and * the input representation is freed as a side effect. * * The function returns C_OK if the sparse representation was valid, * otherwise C_ERR is returned if the representation was corrupted. */ int hllSparseToDense(robj *o) { sds sparse = (sds) o->ptr, dense; struct hllhdr *hdr, *oldhdr = (struct hllhdr*)sparse; int idx = 0, runlen, regval; uint8_t *p = (uint8_t*)sparse, *end = p+sdslen(sparse); /* If the representation is already the right one return ASAP. */ hdr = (struct hllhdr*) sparse; if (hdr->encoding == HLL_DENSE) return HLL_C_OK; /* Create a string of the right size filled with zero bytes. * Note that the cached cardinality is set to 0 as a side effect * that is exactly the cardinality of an empty HLL. */ dense = sdsnewlen(NULL,HLL_DENSE_SIZE); hdr = (struct hllhdr*) dense; *hdr = *oldhdr; /* This will copy the magic and cached cardinality. */ hdr->encoding = HLL_DENSE; /* Now read the sparse representation and set non-zero registers * accordingly. */ p += HLL_HDR_SIZE; while(p < end) { if (HLL_SPARSE_IS_ZERO(p)) { runlen = HLL_SPARSE_ZERO_LEN(p); idx += runlen; p++; } else if (HLL_SPARSE_IS_XZERO(p)) { runlen = HLL_SPARSE_XZERO_LEN(p); idx += runlen; p += 2; } else { runlen = HLL_SPARSE_VAL_LEN(p); regval = HLL_SPARSE_VAL_VALUE(p); while(runlen--) { HLL_DENSE_SET_REGISTER(hdr->registers + 1,idx,regval); idx++; } p++; } } /* If the sparse representation was valid, we expect to find idx * set to HLL_REGISTERS. */ if (idx != HLL_REGISTERS) { sdsfree(dense); return HLL_C_ERR; } /* Free the old representation and set the new one. */ sdsfree((sds) o->ptr); o->ptr = dense; return HLL_C_OK; } /* Low level function to set the sparse HLL register at 'index' to the * specified value if the current value is smaller than 'count'. * * The object 'o' is the String object holding the HLL. The function requires * a reference to the object in order to be able to enlarge the string if * needed. * * On success, the function returns 1 if the cardinality changed, or 0 * if the register for this element was not updated. * On error (if the representation is invalid) -1 is returned. * * As a side effect the function may promote the HLL representation from * sparse to dense: this happens when a register requires to be set to a value * not representable with the sparse representation, or when the resulting * size would be greater than server.hll_sparse_max_bytes. */ int hllSparseSet(robj *o, long index, uint8_t count) { struct hllhdr *hdr; uint8_t oldcount, *sparse, *end, *p, *prev, *next; long first, span; long is_zero = 0, is_xzero = 0, is_val = 0, runlen = 0; uint8_t seq[5], *n; int last; int len; int seqlen; int oldlen; int deltalen; /* If the count is too big to be representable by the sparse representation * switch to dense representation. */ if (count > HLL_SPARSE_VAL_MAX_VALUE) goto promote; /* When updating a sparse representation, sometimes we may need to * enlarge the buffer for up to 3 bytes in the worst case (XZERO split * into XZERO-VAL-XZERO). Make sure there is enough space right now * so that the pointers we take during the execution of the function * will be valid all the time. */ o->ptr = (sds) sdsMakeRoomFor((sds) o->ptr,3); /* Step 1: we need to locate the opcode we need to modify to check * if a value update is actually needed. */ sparse = p = ((uint8_t*)o->ptr) + HLL_HDR_SIZE; end = p + sdslen((sds) o->ptr) - HLL_HDR_SIZE; first = 0; prev = NULL; /* Points to previous opcode at the end of the loop. */ next = NULL; /* Points to the next opcode at the end of the loop. */ span = 0; while(p < end) { long oplen; /* Set span to the number of registers covered by this opcode. * * This is the most performance critical loop of the sparse * representation. Sorting the conditionals from the most to the * least frequent opcode in many-bytes sparse HLLs is faster. */ oplen = 1; if (HLL_SPARSE_IS_ZERO(p)) { span = HLL_SPARSE_ZERO_LEN(p); } else if (HLL_SPARSE_IS_VAL(p)) { span = HLL_SPARSE_VAL_LEN(p); } else { /* XZERO. */ span = HLL_SPARSE_XZERO_LEN(p); oplen = 2; } /* Break if this opcode covers the register as 'index'. */ if (index <= first+span-1) break; prev = p; p += oplen; first += span; } if (span == 0) return -1; /* Invalid format. */ next = HLL_SPARSE_IS_XZERO(p) ? p+2 : p+1; if (next >= end) next = NULL; /* Cache current opcode type to avoid using the macro again and * again for something that will not change. * Also cache the run-length of the opcode. */ if (HLL_SPARSE_IS_ZERO(p)) { is_zero = 1; runlen = HLL_SPARSE_ZERO_LEN(p); } else if (HLL_SPARSE_IS_XZERO(p)) { is_xzero = 1; runlen = HLL_SPARSE_XZERO_LEN(p); } else { is_val = 1; runlen = HLL_SPARSE_VAL_LEN(p); } /* Step 2: After the loop: * * 'first' stores to the index of the first register covered * by the current opcode, which is pointed by 'p'. * * 'next' ad 'prev' store respectively the next and previous opcode, * or NULL if the opcode at 'p' is respectively the last or first. * * 'span' is set to the number of registers covered by the current * opcode. * * There are different cases in order to update the data structure * in place without generating it from scratch: * * A) If it is a VAL opcode already set to a value >= our 'count' * no update is needed, regardless of the VAL run-length field. * In this case PFADD returns 0 since no changes are performed. * * B) If it is a VAL opcode with len = 1 (representing only our * register) and the value is less than 'count', we just update it * since this is a trivial case. */ if (is_val) { oldcount = HLL_SPARSE_VAL_VALUE(p); /* Case A. */ if (oldcount >= count) return 0; /* Case B. */ if (runlen == 1) { HLL_SPARSE_VAL_SET(p,count,1); goto updated; } } /* C) Another trivial to handle case is a ZERO opcode with a len of 1. * We can just replace it with a VAL opcode with our value and len of 1. */ if (is_zero && runlen == 1) { HLL_SPARSE_VAL_SET(p,count,1); goto updated; } /* D) General case. * * The other cases are more complex: our register requires to be updated * and is either currently represented by a VAL opcode with len > 1, * by a ZERO opcode with len > 1, or by an XZERO opcode. * * In those cases the original opcode must be split into multiple * opcodes. The worst case is an XZERO split in the middle resuling into * XZERO - VAL - XZERO, so the resulting sequence max length is * 5 bytes. * * We perform the split writing the new sequence into the 'new' buffer * with 'newlen' as length. Later the new sequence is inserted in place * of the old one, possibly moving what is on the right a few bytes * if the new sequence is longer than the older one. */ n = seq; last = first+span-1; /* Last register covered by the sequence. */ if (is_zero || is_xzero) { /* Handle splitting of ZERO / XZERO. */ if (index != first) { len = index-first; if (len > HLL_SPARSE_ZERO_MAX_LEN) { HLL_SPARSE_XZERO_SET(n,len); n += 2; } else { HLL_SPARSE_ZERO_SET(n,len); n++; } } HLL_SPARSE_VAL_SET(n,count,1); n++; if (index != last) { len = last-index; if (len > HLL_SPARSE_ZERO_MAX_LEN) { HLL_SPARSE_XZERO_SET(n,len); n += 2; } else { HLL_SPARSE_ZERO_SET(n,len); n++; } } } else { /* Handle splitting of VAL. */ int curval = HLL_SPARSE_VAL_VALUE(p); if (index != first) { len = index-first; HLL_SPARSE_VAL_SET(n,curval,len); n++; } HLL_SPARSE_VAL_SET(n,count,1); n++; if (index != last) { len = last-index; HLL_SPARSE_VAL_SET(n,curval,len); n++; } } /* Step 3: substitute the new sequence with the old one. * * Note that we already allocated space on the sds string * calling sdsMakeRoomFor(). */ seqlen = n-seq; oldlen = is_xzero ? 2 : 1; deltalen = seqlen-oldlen; if (deltalen > 0 && sdslen((sds) o->ptr)+deltalen > HLL_SPARSE_MAX_BYTES) goto promote; if (deltalen && next) memmove(next+deltalen,next,end-next); sdsIncrLen((sds) o->ptr,deltalen); memcpy(p,seq,seqlen); end += deltalen; updated: { /* Step 4: Merge adjacent values if possible. * * The representation was updated, however the resulting representation * may not be optimal: adjacent VAL opcodes can sometimes be merged into * a single one. */ p = prev ? prev : sparse; int scanlen = 5; /* Scan up to 5 upcodes starting from prev. */ while (p < end && scanlen--) { if (HLL_SPARSE_IS_XZERO(p)) { p += 2; continue; } else if (HLL_SPARSE_IS_ZERO(p)) { p++; continue; } /* We need two adjacent VAL opcodes to try a merge, having * the same value, and a len that fits the VAL opcode max len. */ if (p+1 < end && HLL_SPARSE_IS_VAL(p+1)) { int v1 = HLL_SPARSE_VAL_VALUE(p); int v2 = HLL_SPARSE_VAL_VALUE(p+1); if (v1 == v2) { int len = HLL_SPARSE_VAL_LEN(p)+HLL_SPARSE_VAL_LEN(p+1); if (len <= HLL_SPARSE_VAL_MAX_LEN) { HLL_SPARSE_VAL_SET(p+1,v1,len); memmove(p,p+1,end-p); sdsIncrLen((sds) o->ptr,-1); end--; /* After a merge we reiterate without incrementing 'p' * in order to try to merge the just merged value with * a value on its right. */ continue; } } } p++; } /* Invalidate the cached cardinality. */ hdr = (struct hllhdr *) o->ptr; HLL_INVALIDATE_CACHE(hdr); return 1; } promote: /* Promote to dense representation. */ if (hllSparseToDense(o) == HLL_C_ERR) return -1; /* Corrupted HLL. */ hdr = (struct hllhdr *) o->ptr; /* We need to call hllDenseAdd() to perform the operation after the * conversion. However the result must be 1, since if we need to * convert from sparse to dense a register requires to be updated. * * Note that this in turn means that PFADD will make sure the command * is propagated to slaves / AOF, so if there is a sparse -> dense * conversion, it will be performed in all the slaves as well. */ int dense_retval = hllDenseSet(hdr->registers + 1,index,count); assert(dense_retval == 1); return dense_retval; } /* "Add" the element in the sparse hyperloglog data structure. * Actually nothing is added, but the max 0 pattern counter of the subset * the element belongs to is incremented if needed. * * This function is actually a wrapper for hllSparseSet(), it only performs * the hashshing of the elmenet to obtain the index and zeros run length. */ int hllSparseAdd(robj *o, unsigned char *ele, size_t elesize) { long index; uint8_t count = hllPatLen(ele,elesize,&index); /* Update the register if this element produced a longer run of zeroes. */ return hllSparseSet(o,index,count); } /* Compute the register histogram in the sparse representation. */ void hllSparseRegHisto(uint8_t *sparse, int sparselen, int *invalid, int* reghisto) { int idx = 0, runlen, regval; uint8_t *end = sparse+sparselen, *p = sparse; while(p < end) { if (HLL_SPARSE_IS_ZERO(p)) { runlen = HLL_SPARSE_ZERO_LEN(p); idx += runlen; reghisto[0] += runlen; p++; } else if (HLL_SPARSE_IS_XZERO(p)) { runlen = HLL_SPARSE_XZERO_LEN(p); idx += runlen; reghisto[0] += runlen; p += 2; } else { runlen = HLL_SPARSE_VAL_LEN(p); regval = HLL_SPARSE_VAL_VALUE(p); idx += runlen; reghisto[regval] += runlen; p++; } } if (idx != HLL_REGISTERS && invalid) *invalid = 1; } /* ========================= HyperLogLog Count ============================== * This is the core of the algorithm where the approximated count is computed. * The function uses the lower level hllDenseRegHisto() and hllSparseRegHisto() * functions as helpers to compute histogram of register values part of the * computation, which is representation-specific, while all the rest is common. */ /* Implements the register histogram calculation for uint8_t data type * which is only used internally as speedup for PFCOUNT with multiple keys. */ void hllRawRegHisto(uint8_t *registers, int* reghisto) { uint64_t *word = (uint64_t*) registers; uint8_t *bytes; int j; for (j = 0; j < HLL_REGISTERS/8; j++) { if (*word == 0) { reghisto[0] += 8; } else { bytes = (uint8_t*) word; reghisto[bytes[0]]++; reghisto[bytes[1]]++; reghisto[bytes[2]]++; reghisto[bytes[3]]++; reghisto[bytes[4]]++; reghisto[bytes[5]]++; reghisto[bytes[6]]++; reghisto[bytes[7]]++; } word++; } } // somehow this is missing on some platforms #ifndef INFINITY // from math.h #define INFINITY 1e50f #endif /* Helper function sigma as defined in * "New cardinality estimation algorithms for HyperLogLog sketches" * Otmar Ertl, arXiv:1702.01284 */ double hllSigma(double x) { if (x == 1.) return INFINITY; double zPrime; double y = 1; double z = x; do { x *= x; zPrime = z; z += x * y; y += y; } while(zPrime != z); return z; } /* Helper function tau as defined in * "New cardinality estimation algorithms for HyperLogLog sketches" * Otmar Ertl, arXiv:1702.01284 */ double hllTau(double x) { if (x == 0. || x == 1.) return 0.; double zPrime; double y = 1.0; double z = 1 - x; do { x = sqrt(x); zPrime = z; y *= 0.5; z -= pow(1 - x, 2)*y; } while(zPrime != z); return z / 3; } /* Return the approximated cardinality of the set based on the harmonic * mean of the registers values. 'hdr' points to the start of the SDS * representing the String object holding the HLL representation. * * If the sparse representation of the HLL object is not valid, the integer * pointed by 'invalid' is set to non-zero, otherwise it is left untouched. * * hllCount() supports a special internal-only encoding of HLL_RAW, that * is, hdr->registers will point to an uint8_t array of HLL_REGISTERS element. * This is useful in order to speedup PFCOUNT when called against multiple * keys (no need to work with 6-bit integers encoding). */ uint64_t hllCount(struct hllhdr *hdr, int *invalid) { double m = HLL_REGISTERS; double E; int j; int reghisto[HLL_Q+2] = {0}; /* Compute register histogram */ if (hdr->encoding == HLL_DENSE) { hllDenseRegHisto(hdr->registers + 1,reghisto); } else if (hdr->encoding == HLL_SPARSE) { hllSparseRegHisto(hdr->registers + 1, sdslen((sds)hdr)-HLL_HDR_SIZE,invalid,reghisto); } else if (hdr->encoding == HLL_RAW) { hllRawRegHisto(hdr->registers + 1,reghisto); } else { *invalid = 1; return 0; //serverPanic("Unknown HyperLogLog encoding in hllCount()"); } /* Estimate cardinality form register histogram. See: * "New cardinality estimation algorithms for HyperLogLog sketches" * Otmar Ertl, arXiv:1702.01284 */ double z = m * hllTau((m-reghisto[HLL_Q+1])/(double)m); for (j = HLL_Q; j >= 1; --j) { z += reghisto[j]; z *= 0.5; } z += m * hllSigma(reghisto[0]/(double)m); E = llroundl(HLL_ALPHA_INF*m*m/z); return (uint64_t) E; } /* Call hllDenseAdd() or hllSparseAdd() according to the HLL encoding. */ int hll_add(robj *o, unsigned char *ele, size_t elesize) { struct hllhdr *hdr = (struct hllhdr *) o->ptr; switch(hdr->encoding) { case HLL_DENSE: return hllDenseAdd(hdr->registers + 1,ele,elesize); case HLL_SPARSE: return hllSparseAdd(o,ele,elesize); default: return -1; /* Invalid representation. */ } } /* Merge by computing MAX(registers[i],hll[i]) the HyperLogLog 'hll' * with an array of uint8_t HLL_REGISTERS registers pointed by 'max'. * * The hll object must be already validated via isHLLObjectOrReply() * or in some other way. * * If the HyperLogLog is sparse and is found to be invalid, C_ERR * is returned, otherwise the function always succeeds. */ int hllMerge(uint8_t *max, robj *hll) { struct hllhdr *hdr = (struct hllhdr *) hll->ptr; int i; if (hdr->encoding == HLL_DENSE) { uint8_t val; for (i = 0; i < HLL_REGISTERS; i++) { HLL_DENSE_GET_REGISTER(val,hdr->registers + 1,i); if (val > max[i]) max[i] = val; } } else { uint8_t *p = (uint8_t *) hll->ptr, *end = p + sdslen((sds) hll->ptr); long runlen, regval; p += HLL_HDR_SIZE; i = 0; while(p < end) { if (HLL_SPARSE_IS_ZERO(p)) { runlen = HLL_SPARSE_ZERO_LEN(p); i += runlen; p++; } else if (HLL_SPARSE_IS_XZERO(p)) { runlen = HLL_SPARSE_XZERO_LEN(p); i += runlen; p += 2; } else { runlen = HLL_SPARSE_VAL_LEN(p); regval = HLL_SPARSE_VAL_VALUE(p); while(runlen--) { if (regval > max[i]) max[i] = regval; i++; } p++; } } if (i != HLL_REGISTERS) return HLL_C_ERR; } return HLL_C_OK; } /* ========================== robj creation ========================== */ robj *createObject(void *ptr) { robj *result = (robj*) malloc(sizeof(robj)); result->ptr = ptr; return result; } void destroyObject(robj *obj) { free(obj); } /* ========================== HyperLogLog commands ========================== */ /* Create an HLL object. We always create the HLL using sparse encoding. * This will be upgraded to the dense representation as needed. */ robj *hll_create(void) { robj *o; struct hllhdr *hdr; sds s; uint8_t *p; int sparselen = HLL_HDR_SIZE + (((HLL_REGISTERS+(HLL_SPARSE_XZERO_MAX_LEN-1)) / HLL_SPARSE_XZERO_MAX_LEN)*2); int aux; /* Populate the sparse representation with as many XZERO opcodes as * needed to represent all the registers. */ aux = HLL_REGISTERS; s = sdsnewlen(NULL,sparselen); p = (uint8_t*)s + HLL_HDR_SIZE; while(aux) { int xzero = HLL_SPARSE_XZERO_MAX_LEN; if (xzero > aux) xzero = aux; HLL_SPARSE_XZERO_SET(p,xzero); p += 2; aux -= xzero; } assert((p-(uint8_t*)s) == sparselen); /* Create the actual object. */ o = createObject(s); hdr = (struct hllhdr *) o->ptr; memcpy(hdr->magic,"HYLL",4); hdr->encoding = HLL_SPARSE; return o; } void hll_destroy(robj *obj) { if (!obj) { return; } sdsfree((sds) obj->ptr); destroyObject(obj); } int hll_count(robj *o, size_t *result) { int invalid = 0; *result = hllCount((struct hllhdr*) o->ptr, &invalid); return invalid == 0 ? HLL_C_OK : HLL_C_ERR; } robj *hll_merge(robj **hlls, size_t hll_count) { uint8_t max[HLL_REGISTERS]; struct hllhdr *hdr; size_t j; /* Use dense representation as target? */ int use_dense = 0; /* Compute an HLL with M[i] = MAX(M[i]_j). * We store the maximum into the max array of registers. We'll write * it to the target variable later. */ memset(max, 0, sizeof(max)); for (j = 0; j < hll_count; j++) { /* Check type and size. */ robj *o = hlls[j]; if (o == NULL) continue; /* Assume empty HLL for non existing var. */ /* If at least one involved HLL is dense, use the dense representation * as target ASAP to save time and avoid the conversion step. */ hdr = (struct hllhdr *) o->ptr; if (hdr->encoding == HLL_DENSE) use_dense = 1; /* Merge with this HLL with our 'max' HHL by setting max[i] * to MAX(max[i],hll[i]). */ if (hllMerge(max, o) == HLL_C_ERR) { return NULL; } } /* Create the destination key's value. */ robj *result = hll_create(); if (!result) { return NULL; } /* Convert the destination object to dense representation if at least * one of the inputs was dense. */ if (use_dense && hllSparseToDense(result) == HLL_C_ERR) { hll_destroy(result); return NULL; } /* Write the resulting HLL to the destination HLL registers and * invalidate the cached value. */ for (j = 0; j < HLL_REGISTERS; j++) { if (max[j] == 0) continue; hdr = (struct hllhdr *) result->ptr; switch(hdr->encoding) { case HLL_DENSE: hllDenseSet(hdr->registers + 1,j,max[j]); break; case HLL_SPARSE: hllSparseSet(result,j,max[j]); break; } } return result; } uint64_t get_size() { return HLL_DENSE_SIZE; } uint64_t num_registers() { return HLL_REGISTERS; } uint8_t maximum_zeros() { return HLL_Q; } uint8_t get_register(robj *o, size_t index) { struct hllhdr *hdr = (struct hllhdr *) o->ptr; uint8_t result; HLL_DENSE_GET_REGISTER(result, hdr->registers + 1, index); return result; } void set_register(robj *o, size_t index, uint8_t count) { struct hllhdr *hdr = (struct hllhdr *) o->ptr; HLL_DENSE_SET_REGISTER(hdr->registers + 1, index, count); } }