/* * Copyright (c) 2009-2012, Salvatore Sanfilippo * Copyright (c) 2009-2012, Pieter Noordhuis * 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. */ /*----------------------------------------------------------------------------- * Sorted set API *----------------------------------------------------------------------------*/ /* ZSETs are ordered sets using two data structures to hold the same elements * in order to get O(log(N)) INSERT and REMOVE operations into a sorted * data structure. * * The elements are added to a hash table mapping Redis objects to scores. * At the same time the elements are added to a skip list mapping scores * to Redis objects (so objects are sorted by scores in this "view"). * * Note that the SDS string representing the element is the same in both * the hash table and skiplist in order to save memory. What we do in order * to manage the shared SDS string more easily is to free the SDS string * only in zslFreeNode(). The dictionary has no value free method set. * So we should always remove an element from the dictionary, and later from * the skiplist. * * This skiplist implementation is almost a C translation of the original * algorithm described by William Pugh in "Skip Lists: A Probabilistic * Alternative to Balanced Trees", modified in three ways: * a) this implementation allows for repeated scores. * b) the comparison is not just by key (our 'score') but by satellite data. * c) there is a back pointer, so it's a doubly linked list with the back * pointers being only at "level 1". This allows to traverse the list * from tail to head, useful for ZREVRANGE. */ #include "server.h" #include /*----------------------------------------------------------------------------- * Skiplist implementation of the low level API *----------------------------------------------------------------------------*/ static int zslLexValueGteMin(sds value, zlexrangespec *spec); static int zslLexValueLteMax(sds value, zlexrangespec *spec); /* Create a skiplist node with the specified number of levels. * The SDS string 'ele' is referenced by the node after the call. */ zskiplistNode *zslCreateNode(int level, double score, sds ele) { zskiplistNode *zn = zmalloc(sizeof(*zn)+level*sizeof(struct zskiplistLevel)); zn->score = score; zn->ele = ele; return zn; } /* Create a new skiplist. */ zskiplist *zslCreate(void) { int j; zskiplist *zsl; zsl = zmalloc(sizeof(*zsl)); zsl->level = 1; zsl->length = 0; zsl->header = zslCreateNode(ZSKIPLIST_MAXLEVEL,0,NULL); for (j = 0; j < ZSKIPLIST_MAXLEVEL; j++) { zsl->header->level[j].forward = NULL; zsl->header->level[j].span = 0; } zsl->header->backward = NULL; zsl->tail = NULL; return zsl; } /* Free the specified skiplist node. The referenced SDS string representation * of the element is freed too, unless node->ele is set to NULL before calling * this function. */ void zslFreeNode(zskiplistNode *node) { sdsfree(node->ele); zfree(node); } /* Free a whole skiplist. */ void zslFree(zskiplist *zsl) { zskiplistNode *node = zsl->header->level[0].forward, *next; zfree(zsl->header); while(node) { next = node->level[0].forward; zslFreeNode(node); node = next; } zfree(zsl); } /* Returns a random level for the new skiplist node we are going to create. * The return value of this function is between 1 and ZSKIPLIST_MAXLEVEL * (both inclusive), with a powerlaw-alike distribution where higher * levels are less likely to be returned. */ int zslRandomLevel(void) { int level = 1; while ((random()&0xFFFF) < (ZSKIPLIST_P * 0xFFFF)) level += 1; return (levelheader; for (i = zsl->level-1; i >= 0; i--) { /* store rank that is crossed to reach the insert position */ rank[i] = i == (zsl->level-1) ? 0 : rank[i+1]; while (x->level[i].forward && (x->level[i].forward->score < score || (x->level[i].forward->score == score && sdscmp(x->level[i].forward->ele,ele) < 0))) { rank[i] += x->level[i].span; x = x->level[i].forward; } update[i] = x; } /* we assume the element is not already inside, since we allow duplicated * scores, reinserting the same element should never happen since the * caller of zslInsert() should test in the hash table if the element is * already inside or not. */ level = zslRandomLevel(); if (level > zsl->level) { for (i = zsl->level; i < level; i++) { rank[i] = 0; update[i] = zsl->header; update[i]->level[i].span = zsl->length; } zsl->level = level; } x = zslCreateNode(level,score,ele); for (i = 0; i < level; i++) { x->level[i].forward = update[i]->level[i].forward; update[i]->level[i].forward = x; /* update span covered by update[i] as x is inserted here */ x->level[i].span = update[i]->level[i].span - (rank[0] - rank[i]); update[i]->level[i].span = (rank[0] - rank[i]) + 1; } /* increment span for untouched levels */ for (i = level; i < zsl->level; i++) { update[i]->level[i].span++; } x->backward = (update[0] == zsl->header) ? NULL : update[0]; if (x->level[0].forward) x->level[0].forward->backward = x; else zsl->tail = x; zsl->length++; return x; } /* Internal function used by zslDelete, zslDeleteByScore and zslDeleteByRank */ void zslDeleteNode(zskiplist *zsl, zskiplistNode *x, zskiplistNode **update) { int i; for (i = 0; i < zsl->level; i++) { if (update[i]->level[i].forward == x) { update[i]->level[i].span += x->level[i].span - 1; update[i]->level[i].forward = x->level[i].forward; } else { update[i]->level[i].span -= 1; } } if (x->level[0].forward) { x->level[0].forward->backward = x->backward; } else { zsl->tail = x->backward; } while(zsl->level > 1 && zsl->header->level[zsl->level-1].forward == NULL) zsl->level--; zsl->length--; } /* Delete an element with matching score/element from the skiplist. * The function returns 1 if the node was found and deleted, otherwise * 0 is returned. * * If 'node' is NULL the deleted node is freed by zslFreeNode(), otherwise * it is not freed (but just unlinked) and *node is set to the node pointer, * so that it is possible for the caller to reuse the node (including the * referenced SDS string at node->ele). */ int zslDelete(zskiplist *zsl, double score, sds ele, zskiplistNode **node) { zskiplistNode *update[ZSKIPLIST_MAXLEVEL], *x; int i; x = zsl->header; for (i = zsl->level-1; i >= 0; i--) { while (x->level[i].forward && (x->level[i].forward->score < score || (x->level[i].forward->score == score && sdscmp(x->level[i].forward->ele,ele) < 0))) { x = x->level[i].forward; } update[i] = x; } /* We may have multiple elements with the same score, what we need * is to find the element with both the right score and object. */ x = x->level[0].forward; if (x && score == x->score && sdscmp(x->ele,ele) == 0) { zslDeleteNode(zsl, x, update); if (!node) zslFreeNode(x); else *node = x; return 1; } return 0; /* not found */ } static int zslValueGteMin(double value, zrangespec *spec) { return spec->minex ? (value > spec->min) : (value >= spec->min); } int zslValueLteMax(double value, zrangespec *spec) { return spec->maxex ? (value < spec->max) : (value <= spec->max); } /* Returns if there is a part of the zset is in range. */ int zslIsInRange(zskiplist *zsl, zrangespec *range) { zskiplistNode *x; /* Test for ranges that will always be empty. */ if (range->min > range->max || (range->min == range->max && (range->minex || range->maxex))) return 0; x = zsl->tail; if (x == NULL || !zslValueGteMin(x->score,range)) return 0; x = zsl->header->level[0].forward; if (x == NULL || !zslValueLteMax(x->score,range)) return 0; return 1; } /* Find the first node that is contained in the specified range. * Returns NULL when no element is contained in the range. */ zskiplistNode *zslFirstInRange(zskiplist *zsl, zrangespec *range) { zskiplistNode *x; int i; /* If everything is out of range, return early. */ if (!zslIsInRange(zsl,range)) return NULL; x = zsl->header; for (i = zsl->level-1; i >= 0; i--) { /* Go forward while *OUT* of range. */ while (x->level[i].forward && !zslValueGteMin(x->level[i].forward->score,range)) x = x->level[i].forward; } /* This is an inner range, so the next node cannot be NULL. */ x = x->level[0].forward; serverAssert(x != NULL); /* Check if score <= max. */ if (!zslValueLteMax(x->score,range)) return NULL; return x; } /* Find the last node that is contained in the specified range. * Returns NULL when no element is contained in the range. */ zskiplistNode *zslLastInRange(zskiplist *zsl, zrangespec *range) { zskiplistNode *x; int i; /* If everything is out of range, return early. */ if (!zslIsInRange(zsl,range)) return NULL; x = zsl->header; for (i = zsl->level-1; i >= 0; i--) { /* Go forward while *IN* range. */ while (x->level[i].forward && zslValueLteMax(x->level[i].forward->score,range)) x = x->level[i].forward; } /* This is an inner range, so this node cannot be NULL. */ serverAssert(x != NULL); /* Check if score >= min. */ if (!zslValueGteMin(x->score,range)) return NULL; return x; } /* Delete all the elements with score between min and max from the skiplist. * Min and max are inclusive, so a score >= min || score <= max is deleted. * Note that this function takes the reference to the hash table view of the * sorted set, in order to remove the elements from the hash table too. */ unsigned long zslDeleteRangeByScore(zskiplist *zsl, zrangespec *range, dict *dict) { zskiplistNode *update[ZSKIPLIST_MAXLEVEL], *x; unsigned long removed = 0; int i; x = zsl->header; for (i = zsl->level-1; i >= 0; i--) { while (x->level[i].forward && (range->minex ? x->level[i].forward->score <= range->min : x->level[i].forward->score < range->min)) x = x->level[i].forward; update[i] = x; } /* Current node is the last with score < or <= min. */ x = x->level[0].forward; /* Delete nodes while in range. */ while (x && (range->maxex ? x->score < range->max : x->score <= range->max)) { zskiplistNode *next = x->level[0].forward; zslDeleteNode(zsl,x,update); dictDelete(dict,x->ele); zslFreeNode(x); /* Here is where x->ele is actually released. */ removed++; x = next; } return removed; } unsigned long zslDeleteRangeByLex(zskiplist *zsl, zlexrangespec *range, dict *dict) { zskiplistNode *update[ZSKIPLIST_MAXLEVEL], *x; unsigned long removed = 0; int i; x = zsl->header; for (i = zsl->level-1; i >= 0; i--) { while (x->level[i].forward && !zslLexValueGteMin(x->level[i].forward->ele,range)) x = x->level[i].forward; update[i] = x; } /* Current node is the last with score < or <= min. */ x = x->level[0].forward; /* Delete nodes while in range. */ while (x && zslLexValueLteMax(x->ele,range)) { zskiplistNode *next = x->level[0].forward; zslDeleteNode(zsl,x,update); dictDelete(dict,x->ele); zslFreeNode(x); /* Here is where x->ele is actually released. */ removed++; x = next; } return removed; } /* Delete all the elements with rank between start and end from the skiplist. * Start and end are inclusive. Note that start and end need to be 1-based */ unsigned long zslDeleteRangeByRank(zskiplist *zsl, unsigned int start, unsigned int end, dict *dict) { zskiplistNode *update[ZSKIPLIST_MAXLEVEL], *x; unsigned long traversed = 0, removed = 0; int i; x = zsl->header; for (i = zsl->level-1; i >= 0; i--) { while (x->level[i].forward && (traversed + x->level[i].span) < start) { traversed += x->level[i].span; x = x->level[i].forward; } update[i] = x; } traversed++; x = x->level[0].forward; while (x && traversed <= end) { zskiplistNode *next = x->level[0].forward; zslDeleteNode(zsl,x,update); dictDelete(dict,x->ele); zslFreeNode(x); removed++; traversed++; x = next; } return removed; } /* Find the rank for an element by both score and key. * Returns 0 when the element cannot be found, rank otherwise. * Note that the rank is 1-based due to the span of zsl->header to the * first element. */ unsigned long zslGetRank(zskiplist *zsl, double score, sds ele) { zskiplistNode *x; unsigned long rank = 0; int i; x = zsl->header; for (i = zsl->level-1; i >= 0; i--) { while (x->level[i].forward && (x->level[i].forward->score < score || (x->level[i].forward->score == score && sdscmp(x->level[i].forward->ele,ele) <= 0))) { rank += x->level[i].span; x = x->level[i].forward; } /* x might be equal to zsl->header, so test if obj is non-NULL */ if (x->ele && sdscmp(x->ele,ele) == 0) { return rank; } } return 0; } /* Finds an element by its rank. The rank argument needs to be 1-based. */ zskiplistNode* zslGetElementByRank(zskiplist *zsl, unsigned long rank) { zskiplistNode *x; unsigned long traversed = 0; int i; x = zsl->header; for (i = zsl->level-1; i >= 0; i--) { while (x->level[i].forward && (traversed + x->level[i].span) <= rank) { traversed += x->level[i].span; x = x->level[i].forward; } if (traversed == rank) { return x; } } return NULL; } /* Populate the rangespec according to the objects min and max. */ static int zslParseRange(robj *min, robj *max, zrangespec *spec) { char *eptr; spec->minex = spec->maxex = 0; /* Parse the min-max interval. If one of the values is prefixed * by the "(" character, it's considered "open". For instance * ZRANGEBYSCORE zset (1.5 (2.5 will match min < x < max * ZRANGEBYSCORE zset 1.5 2.5 will instead match min <= x <= max */ if (min->encoding == OBJ_ENCODING_INT) { spec->min = (long)min->ptr; } else { if (((char*)min->ptr)[0] == '(') { spec->min = strtod((char*)min->ptr+1,&eptr); if (eptr[0] != '\0' || isnan(spec->min)) return C_ERR; spec->minex = 1; } else { spec->min = strtod((char*)min->ptr,&eptr); if (eptr[0] != '\0' || isnan(spec->min)) return C_ERR; } } if (max->encoding == OBJ_ENCODING_INT) { spec->max = (long)max->ptr; } else { if (((char*)max->ptr)[0] == '(') { spec->max = strtod((char*)max->ptr+1,&eptr); if (eptr[0] != '\0' || isnan(spec->max)) return C_ERR; spec->maxex = 1; } else { spec->max = strtod((char*)max->ptr,&eptr); if (eptr[0] != '\0' || isnan(spec->max)) return C_ERR; } } return C_OK; } /* ------------------------ Lexicographic ranges ---------------------------- */ /* Parse max or min argument of ZRANGEBYLEX. * (foo means foo (open interval) * [foo means foo (closed interval) * - means the min string possible * + means the max string possible * * If the string is valid the *dest pointer is set to the redis object * that will be used for the comparision, and ex will be set to 0 or 1 * respectively if the item is exclusive or inclusive. C_OK will be * returned. * * If the string is not a valid range C_ERR is returned, and the value * of *dest and *ex is undefined. */ int zslParseLexRangeItem(robj *item, sds *dest, int *ex) { char *c = item->ptr; switch(c[0]) { case '+': if (c[1] != '\0') return C_ERR; *ex = 0; *dest = shared.maxstring; return C_OK; case '-': if (c[1] != '\0') return C_ERR; *ex = 0; *dest = shared.minstring; return C_OK; case '(': *ex = 1; *dest = sdsnewlen(c+1,sdslen(c)-1); return C_OK; case '[': *ex = 0; *dest = sdsnewlen(c+1,sdslen(c)-1); return C_OK; default: return C_ERR; } } /* Free a lex range structure, must be called only after zelParseLexRange() * populated the structure with success (C_OK returned). */ void zslFreeLexRange(zlexrangespec *spec) { if (spec->min != shared.minstring && spec->min != shared.maxstring) sdsfree(spec->min); if (spec->max != shared.minstring && spec->max != shared.maxstring) sdsfree(spec->max); } /* Populate the rangespec according to the objects min and max. * * Return C_OK on success. On error C_ERR is returned. * When OK is returned the structure must be freed with zslFreeLexRange(), * otherwise no release is needed. */ static int zslParseLexRange(robj *min, robj *max, zlexrangespec *spec) { /* The range can't be valid if objects are integer encoded. * Every item must start with ( or [. */ if (min->encoding == OBJ_ENCODING_INT || max->encoding == OBJ_ENCODING_INT) return C_ERR; spec->min = spec->max = NULL; if (zslParseLexRangeItem(min, &spec->min, &spec->minex) == C_ERR || zslParseLexRangeItem(max, &spec->max, &spec->maxex) == C_ERR) { zslFreeLexRange(spec); return C_ERR; } else { return C_OK; } } /* This is just a wrapper to sdscmp() that is able to * handle shared.minstring and shared.maxstring as the equivalent of * -inf and +inf for strings */ int sdscmplex(sds a, sds b) { if (a == b) return 0; if (a == shared.minstring || b == shared.maxstring) return -1; if (a == shared.maxstring || b == shared.minstring) return 1; return sdscmp(a,b); } static int zslLexValueGteMin(sds value, zlexrangespec *spec) { return spec->minex ? (sdscmplex(value,spec->min) > 0) : (sdscmplex(value,spec->min) >= 0); } static int zslLexValueLteMax(sds value, zlexrangespec *spec) { return spec->maxex ? (sdscmplex(value,spec->max) < 0) : (sdscmplex(value,spec->max) <= 0); } /* Returns if there is a part of the zset is in the lex range. */ int zslIsInLexRange(zskiplist *zsl, zlexrangespec *range) { zskiplistNode *x; /* Test for ranges that will always be empty. */ if (sdscmplex(range->min,range->max) > 1 || (sdscmp(range->min,range->max) == 0 && (range->minex || range->maxex))) return 0; x = zsl->tail; if (x == NULL || !zslLexValueGteMin(x->ele,range)) return 0; x = zsl->header->level[0].forward; if (x == NULL || !zslLexValueLteMax(x->ele,range)) return 0; return 1; } /* Find the first node that is contained in the specified lex range. * Returns NULL when no element is contained in the range. */ zskiplistNode *zslFirstInLexRange(zskiplist *zsl, zlexrangespec *range) { zskiplistNode *x; int i; /* If everything is out of range, return early. */ if (!zslIsInLexRange(zsl,range)) return NULL; x = zsl->header; for (i = zsl->level-1; i >= 0; i--) { /* Go forward while *OUT* of range. */ while (x->level[i].forward && !zslLexValueGteMin(x->level[i].forward->ele,range)) x = x->level[i].forward; } /* This is an inner range, so the next node cannot be NULL. */ x = x->level[0].forward; serverAssert(x != NULL); /* Check if score <= max. */ if (!zslLexValueLteMax(x->ele,range)) return NULL; return x; } /* Find the last node that is contained in the specified range. * Returns NULL when no element is contained in the range. */ zskiplistNode *zslLastInLexRange(zskiplist *zsl, zlexrangespec *range) { zskiplistNode *x; int i; /* If everything is out of range, return early. */ if (!zslIsInLexRange(zsl,range)) return NULL; x = zsl->header; for (i = zsl->level-1; i >= 0; i--) { /* Go forward while *IN* range. */ while (x->level[i].forward && zslLexValueLteMax(x->level[i].forward->ele,range)) x = x->level[i].forward; } /* This is an inner range, so this node cannot be NULL. */ serverAssert(x != NULL); /* Check if score >= min. */ if (!zslLexValueGteMin(x->ele,range)) return NULL; return x; } /*----------------------------------------------------------------------------- * Ziplist-backed sorted set API *----------------------------------------------------------------------------*/ double zzlGetScore(unsigned char *sptr) { unsigned char *vstr; unsigned int vlen; long long vlong; char buf[128]; double score; serverAssert(sptr != NULL); serverAssert(ziplistGet(sptr,&vstr,&vlen,&vlong)); if (vstr) { memcpy(buf,vstr,vlen); buf[vlen] = '\0'; score = strtod(buf,NULL); } else { score = vlong; } return score; } /* Return a ziplist element as an SDS string. */ sds ziplistGetObject(unsigned char *sptr) { unsigned char *vstr; unsigned int vlen; long long vlong; serverAssert(sptr != NULL); serverAssert(ziplistGet(sptr,&vstr,&vlen,&vlong)); if (vstr) { return sdsnewlen((char*)vstr,vlen); } else { return sdsfromlonglong(vlong); } } /* Compare element in sorted set with given element. */ int zzlCompareElements(unsigned char *eptr, unsigned char *cstr, unsigned int clen) { unsigned char *vstr; unsigned int vlen; long long vlong; unsigned char vbuf[32]; int minlen, cmp; serverAssert(ziplistGet(eptr,&vstr,&vlen,&vlong)); if (vstr == NULL) { /* Store string representation of long long in buf. */ vlen = ll2string((char*)vbuf,sizeof(vbuf),vlong); vstr = vbuf; } minlen = (vlen < clen) ? vlen : clen; cmp = memcmp(vstr,cstr,minlen); if (cmp == 0) return vlen-clen; return cmp; } unsigned int zzlLength(unsigned char *zl) { return ziplistLen(zl)/2; } /* Move to next entry based on the values in eptr and sptr. Both are set to * NULL when there is no next entry. */ void zzlNext(unsigned char *zl, unsigned char **eptr, unsigned char **sptr) { unsigned char *_eptr, *_sptr; serverAssert(*eptr != NULL && *sptr != NULL); _eptr = ziplistNext(zl,*sptr); if (_eptr != NULL) { _sptr = ziplistNext(zl,_eptr); serverAssert(_sptr != NULL); } else { /* No next entry. */ _sptr = NULL; } *eptr = _eptr; *sptr = _sptr; } /* Move to the previous entry based on the values in eptr and sptr. Both are * set to NULL when there is no next entry. */ void zzlPrev(unsigned char *zl, unsigned char **eptr, unsigned char **sptr) { unsigned char *_eptr, *_sptr; serverAssert(*eptr != NULL && *sptr != NULL); _sptr = ziplistPrev(zl,*eptr); if (_sptr != NULL) { _eptr = ziplistPrev(zl,_sptr); serverAssert(_eptr != NULL); } else { /* No previous entry. */ _eptr = NULL; } *eptr = _eptr; *sptr = _sptr; } /* Returns if there is a part of the zset is in range. Should only be used * internally by zzlFirstInRange and zzlLastInRange. */ int zzlIsInRange(unsigned char *zl, zrangespec *range) { unsigned char *p; double score; /* Test for ranges that will always be empty. */ if (range->min > range->max || (range->min == range->max && (range->minex || range->maxex))) return 0; p = ziplistIndex(zl,-1); /* Last score. */ if (p == NULL) return 0; /* Empty sorted set */ score = zzlGetScore(p); if (!zslValueGteMin(score,range)) return 0; p = ziplistIndex(zl,1); /* First score. */ serverAssert(p != NULL); score = zzlGetScore(p); if (!zslValueLteMax(score,range)) return 0; return 1; } /* Find pointer to the first element contained in the specified range. * Returns NULL when no element is contained in the range. */ unsigned char *zzlFirstInRange(unsigned char *zl, zrangespec *range) { unsigned char *eptr = ziplistIndex(zl,0), *sptr; double score; /* If everything is out of range, return early. */ if (!zzlIsInRange(zl,range)) return NULL; while (eptr != NULL) { sptr = ziplistNext(zl,eptr); serverAssert(sptr != NULL); score = zzlGetScore(sptr); if (zslValueGteMin(score,range)) { /* Check if score <= max. */ if (zslValueLteMax(score,range)) return eptr; return NULL; } /* Move to next element. */ eptr = ziplistNext(zl,sptr); } return NULL; } /* Find pointer to the last element contained in the specified range. * Returns NULL when no element is contained in the range. */ unsigned char *zzlLastInRange(unsigned char *zl, zrangespec *range) { unsigned char *eptr = ziplistIndex(zl,-2), *sptr; double score; /* If everything is out of range, return early. */ if (!zzlIsInRange(zl,range)) return NULL; while (eptr != NULL) { sptr = ziplistNext(zl,eptr); serverAssert(sptr != NULL); score = zzlGetScore(sptr); if (zslValueLteMax(score,range)) { /* Check if score >= min. */ if (zslValueGteMin(score,range)) return eptr; return NULL; } /* Move to previous element by moving to the score of previous element. * When this returns NULL, we know there also is no element. */ sptr = ziplistPrev(zl,eptr); if (sptr != NULL) serverAssert((eptr = ziplistPrev(zl,sptr)) != NULL); else eptr = NULL; } return NULL; } static int zzlLexValueGteMin(unsigned char *p, zlexrangespec *spec) { sds value = ziplistGetObject(p); int res = zslLexValueGteMin(value,spec); sdsfree(value); return res; } static int zzlLexValueLteMax(unsigned char *p, zlexrangespec *spec) { sds value = ziplistGetObject(p); int res = zslLexValueLteMax(value,spec); sdsfree(value); return res; } /* Returns if there is a part of the zset is in range. Should only be used * internally by zzlFirstInRange and zzlLastInRange. */ int zzlIsInLexRange(unsigned char *zl, zlexrangespec *range) { unsigned char *p; /* Test for ranges that will always be empty. */ if (sdscmplex(range->min,range->max) > 1 || (sdscmp(range->min,range->max) == 0 && (range->minex || range->maxex))) return 0; p = ziplistIndex(zl,-2); /* Last element. */ if (p == NULL) return 0; if (!zzlLexValueGteMin(p,range)) return 0; p = ziplistIndex(zl,0); /* First element. */ serverAssert(p != NULL); if (!zzlLexValueLteMax(p,range)) return 0; return 1; } /* Find pointer to the first element contained in the specified lex range. * Returns NULL when no element is contained in the range. */ unsigned char *zzlFirstInLexRange(unsigned char *zl, zlexrangespec *range) { unsigned char *eptr = ziplistIndex(zl,0), *sptr; /* If everything is out of range, return early. */ if (!zzlIsInLexRange(zl,range)) return NULL; while (eptr != NULL) { if (zzlLexValueGteMin(eptr,range)) { /* Check if score <= max. */ if (zzlLexValueLteMax(eptr,range)) return eptr; return NULL; } /* Move to next element. */ sptr = ziplistNext(zl,eptr); /* This element score. Skip it. */ serverAssert(sptr != NULL); eptr = ziplistNext(zl,sptr); /* Next element. */ } return NULL; } /* Find pointer to the last element contained in the specified lex range. * Returns NULL when no element is contained in the range. */ unsigned char *zzlLastInLexRange(unsigned char *zl, zlexrangespec *range) { unsigned char *eptr = ziplistIndex(zl,-2), *sptr; /* If everything is out of range, return early. */ if (!zzlIsInLexRange(zl,range)) return NULL; while (eptr != NULL) { if (zzlLexValueLteMax(eptr,range)) { /* Check if score >= min. */ if (zzlLexValueGteMin(eptr,range)) return eptr; return NULL; } /* Move to previous element by moving to the score of previous element. * When this returns NULL, we know there also is no element. */ sptr = ziplistPrev(zl,eptr); if (sptr != NULL) serverAssert((eptr = ziplistPrev(zl,sptr)) != NULL); else eptr = NULL; } return NULL; } unsigned char *zzlFind(unsigned char *zl, sds ele, double *score) { unsigned char *eptr = ziplistIndex(zl,0), *sptr; while (eptr != NULL) { sptr = ziplistNext(zl,eptr); serverAssert(sptr != NULL); if (ziplistCompare(eptr,(unsigned char*)ele,sdslen(ele))) { /* Matching element, pull out score. */ if (score != NULL) *score = zzlGetScore(sptr); return eptr; } /* Move to next element. */ eptr = ziplistNext(zl,sptr); } return NULL; } /* Delete (element,score) pair from ziplist. Use local copy of eptr because we * don't want to modify the one given as argument. */ unsigned char *zzlDelete(unsigned char *zl, unsigned char *eptr) { unsigned char *p = eptr; /* TODO: add function to ziplist API to delete N elements from offset. */ zl = ziplistDelete(zl,&p); zl = ziplistDelete(zl,&p); return zl; } unsigned char *zzlInsertAt(unsigned char *zl, unsigned char *eptr, sds ele, double score) { unsigned char *sptr; char scorebuf[128]; int scorelen; size_t offset; scorelen = d2string(scorebuf,sizeof(scorebuf),score); if (eptr == NULL) { zl = ziplistPush(zl,(unsigned char*)ele,sdslen(ele),ZIPLIST_TAIL); zl = ziplistPush(zl,(unsigned char*)scorebuf,scorelen,ZIPLIST_TAIL); } else { /* Keep offset relative to zl, as it might be re-allocated. */ offset = eptr-zl; zl = ziplistInsert(zl,eptr,(unsigned char*)ele,sdslen(ele)); eptr = zl+offset; /* Insert score after the element. */ serverAssert((sptr = ziplistNext(zl,eptr)) != NULL); zl = ziplistInsert(zl,sptr,(unsigned char*)scorebuf,scorelen); } return zl; } /* Insert (element,score) pair in ziplist. This function assumes the element is * not yet present in the list. */ unsigned char *zzlInsert(unsigned char *zl, sds ele, double score) { unsigned char *eptr = ziplistIndex(zl,0), *sptr; double s; while (eptr != NULL) { sptr = ziplistNext(zl,eptr); serverAssert(sptr != NULL); s = zzlGetScore(sptr); if (s > score) { /* First element with score larger than score for element to be * inserted. This means we should take its spot in the list to * maintain ordering. */ zl = zzlInsertAt(zl,eptr,ele,score); break; } else if (s == score) { /* Ensure lexicographical ordering for elements. */ if (zzlCompareElements(eptr,(unsigned char*)ele,sdslen(ele)) > 0) { zl = zzlInsertAt(zl,eptr,ele,score); break; } } /* Move to next element. */ eptr = ziplistNext(zl,sptr); } /* Push on tail of list when it was not yet inserted. */ if (eptr == NULL) zl = zzlInsertAt(zl,NULL,ele,score); return zl; } unsigned char *zzlDeleteRangeByScore(unsigned char *zl, zrangespec *range, unsigned long *deleted) { unsigned char *eptr, *sptr; double score; unsigned long num = 0; if (deleted != NULL) *deleted = 0; eptr = zzlFirstInRange(zl,range); if (eptr == NULL) return zl; /* When the tail of the ziplist is deleted, eptr will point to the sentinel * byte and ziplistNext will return NULL. */ while ((sptr = ziplistNext(zl,eptr)) != NULL) { score = zzlGetScore(sptr); if (zslValueLteMax(score,range)) { /* Delete both the element and the score. */ zl = ziplistDelete(zl,&eptr); zl = ziplistDelete(zl,&eptr); num++; } else { /* No longer in range. */ break; } } if (deleted != NULL) *deleted = num; return zl; } unsigned char *zzlDeleteRangeByLex(unsigned char *zl, zlexrangespec *range, unsigned long *deleted) { unsigned char *eptr, *sptr; unsigned long num = 0; if (deleted != NULL) *deleted = 0; eptr = zzlFirstInLexRange(zl,range); if (eptr == NULL) return zl; /* When the tail of the ziplist is deleted, eptr will point to the sentinel * byte and ziplistNext will return NULL. */ while ((sptr = ziplistNext(zl,eptr)) != NULL) { if (zzlLexValueLteMax(eptr,range)) { /* Delete both the element and the score. */ zl = ziplistDelete(zl,&eptr); zl = ziplistDelete(zl,&eptr); num++; } else { /* No longer in range. */ break; } } if (deleted != NULL) *deleted = num; return zl; } /* Delete all the elements with rank between start and end from the skiplist. * Start and end are inclusive. Note that start and end need to be 1-based */ unsigned char *zzlDeleteRangeByRank(unsigned char *zl, unsigned int start, unsigned int end, unsigned long *deleted) { unsigned int num = (end-start)+1; if (deleted) *deleted = num; zl = ziplistDeleteRange(zl,2*(start-1),2*num); return zl; } /*----------------------------------------------------------------------------- * Common sorted set API *----------------------------------------------------------------------------*/ unsigned int zsetLength(robj *zobj) { int length = -1; if (zobj->encoding == OBJ_ENCODING_ZIPLIST) { length = zzlLength(zobj->ptr); } else if (zobj->encoding == OBJ_ENCODING_SKIPLIST) { length = ((zset*)zobj->ptr)->zsl->length; } else { serverPanic("Unknown sorted set encoding"); } return length; } void zsetConvert(robj *zobj, int encoding) { zset *zs; zskiplistNode *node, *next; sds ele; double score; if (zobj->encoding == encoding) return; if (zobj->encoding == OBJ_ENCODING_ZIPLIST) { unsigned char *zl = zobj->ptr; unsigned char *eptr, *sptr; unsigned char *vstr; unsigned int vlen; long long vlong; if (encoding != OBJ_ENCODING_SKIPLIST) serverPanic("Unknown target encoding"); zs = zmalloc(sizeof(*zs)); zs->dict = dictCreate(&zsetDictType,NULL); zs->zsl = zslCreate(); eptr = ziplistIndex(zl,0); serverAssertWithInfo(NULL,zobj,eptr != NULL); sptr = ziplistNext(zl,eptr); serverAssertWithInfo(NULL,zobj,sptr != NULL); while (eptr != NULL) { score = zzlGetScore(sptr); serverAssertWithInfo(NULL,zobj,ziplistGet(eptr,&vstr,&vlen,&vlong)); if (vstr == NULL) ele = sdsfromlonglong(vlong); else ele = sdsnewlen((char*)vstr,vlen); node = zslInsert(zs->zsl,score,ele); serverAssert(dictAdd(zs->dict,ele,&node->score) == DICT_OK); zzlNext(zl,&eptr,&sptr); } zfree(zobj->ptr); zobj->ptr = zs; zobj->encoding = OBJ_ENCODING_SKIPLIST; } else if (zobj->encoding == OBJ_ENCODING_SKIPLIST) { unsigned char *zl = ziplistNew(); if (encoding != OBJ_ENCODING_ZIPLIST) serverPanic("Unknown target encoding"); /* Approach similar to zslFree(), since we want to free the skiplist at * the same time as creating the ziplist. */ zs = zobj->ptr; dictRelease(zs->dict); node = zs->zsl->header->level[0].forward; zfree(zs->zsl->header); zfree(zs->zsl); while (node) { zl = zzlInsertAt(zl,NULL,node->ele,node->score); next = node->level[0].forward; zslFreeNode(node); node = next; } zfree(zs); zobj->ptr = zl; zobj->encoding = OBJ_ENCODING_ZIPLIST; } else { serverPanic("Unknown sorted set encoding"); } } /* Return (by reference) the score of the specified member of the sorted set * storing it into *score. If the element does not exist C_ERR is returned * otherwise C_OK is returned and *score is correctly populated. * If 'zobj' or 'member' is NULL, C_ERR is returned. */ int zsetScore(robj *zobj, sds member, double *score) { if (!zobj || !member) return C_ERR; if (zobj->encoding == OBJ_ENCODING_ZIPLIST) { if (zzlFind(zobj->ptr, member, score) == NULL) return C_ERR; } else if (zobj->encoding == OBJ_ENCODING_SKIPLIST) { zset *zs = zobj->ptr; dictEntry *de = dictFind(zs->dict, member); if (de == NULL) return C_ERR; *score = *(double*)dictGetVal(de); } else { serverPanic("Unknown sorted set encoding"); } return C_OK; } /*----------------------------------------------------------------------------- * Sorted set commands *----------------------------------------------------------------------------*/ /* This generic command implements both ZADD and ZINCRBY. */ #define ZADD_NONE 0 #define ZADD_INCR (1<<0) /* Increment the score instead of setting it. */ #define ZADD_NX (1<<1) /* Don't touch elements not already existing. */ #define ZADD_XX (1<<2) /* Only touch elements already exisitng. */ #define ZADD_CH (1<<3) /* Return num of elements added or updated. */ void zaddGenericCommand(client *c, int flags) { static char *nanerr = "resulting score is not a number (NaN)"; robj *key = c->argv[1]; robj *zobj; sds ele; double score = 0, *scores = NULL, curscore = 0.0; int j, elements; int scoreidx = 0; /* The following vars are used in order to track what the command actually * did during the execution, to reply to the client and to trigger the * notification of keyspace change. */ int added = 0; /* Number of new elements added. */ int updated = 0; /* Number of elements with updated score. */ int processed = 0; /* Number of elements processed, may remain zero with options like XX. */ /* Parse options. At the end 'scoreidx' is set to the argument position * of the score of the first score-element pair. */ scoreidx = 2; while(scoreidx < c->argc) { char *opt = c->argv[scoreidx]->ptr; if (!strcasecmp(opt,"nx")) flags |= ZADD_NX; else if (!strcasecmp(opt,"xx")) flags |= ZADD_XX; else if (!strcasecmp(opt,"ch")) flags |= ZADD_CH; else if (!strcasecmp(opt,"incr")) flags |= ZADD_INCR; else break; scoreidx++; } /* Turn options into simple to check vars. */ int incr = (flags & ZADD_INCR) != 0; int nx = (flags & ZADD_NX) != 0; int xx = (flags & ZADD_XX) != 0; int ch = (flags & ZADD_CH) != 0; /* After the options, we expect to have an even number of args, since * we expect any number of score-element pairs. */ elements = c->argc-scoreidx; if (elements % 2) { addReply(c,shared.syntaxerr); return; } elements /= 2; /* Now this holds the number of score-element pairs. */ /* Check for incompatible options. */ if (nx && xx) { addReplyError(c, "XX and NX options at the same time are not compatible"); return; } if (incr && elements > 1) { addReplyError(c, "INCR option supports a single increment-element pair"); return; } /* Start parsing all the scores, we need to emit any syntax error * before executing additions to the sorted set, as the command should * either execute fully or nothing at all. */ scores = zmalloc(sizeof(double)*elements); for (j = 0; j < elements; j++) { if (getDoubleFromObjectOrReply(c,c->argv[scoreidx+j*2],&scores[j],NULL) != C_OK) goto cleanup; } /* Lookup the key and create the sorted set if does not exist. */ zobj = lookupKeyWrite(c->db,key); if (zobj == NULL) { if (xx) goto reply_to_client; /* No key + XX option: nothing to do. */ if (server.zset_max_ziplist_entries == 0 || server.zset_max_ziplist_value < sdslen(c->argv[scoreidx+1]->ptr)) { zobj = createZsetObject(); } else { zobj = createZsetZiplistObject(); } dbAdd(c->db,key,zobj); } else { if (zobj->type != OBJ_ZSET) { addReply(c,shared.wrongtypeerr); goto cleanup; } } for (j = 0; j < elements; j++) { score = scores[j]; ele = c->argv[scoreidx+1+j*2]->ptr; if (zobj->encoding == OBJ_ENCODING_ZIPLIST) { unsigned char *eptr; if ((eptr = zzlFind(zobj->ptr,ele,&curscore)) != NULL) { if (nx) continue; if (incr) { score += curscore; if (isnan(score)) { addReplyError(c,nanerr); goto cleanup; } } /* Remove and re-insert when score changed. */ if (score != curscore) { zobj->ptr = zzlDelete(zobj->ptr,eptr); zobj->ptr = zzlInsert(zobj->ptr,ele,score); server.dirty++; updated++; } processed++; } else if (!xx) { /* Optimize: check if the element is too large or the list * becomes too long *before* executing zzlInsert. */ zobj->ptr = zzlInsert(zobj->ptr,ele,score); if (zzlLength(zobj->ptr) > server.zset_max_ziplist_entries) zsetConvert(zobj,OBJ_ENCODING_SKIPLIST); if (sdslen(ele) > server.zset_max_ziplist_value) zsetConvert(zobj,OBJ_ENCODING_SKIPLIST); server.dirty++; added++; processed++; } } else if (zobj->encoding == OBJ_ENCODING_SKIPLIST) { zset *zs = zobj->ptr; zskiplistNode *znode; dictEntry *de; de = dictFind(zs->dict,ele); if (de != NULL) { if (nx) continue; curscore = *(double*)dictGetVal(de); if (incr) { score += curscore; if (isnan(score)) { addReplyError(c,nanerr); /* Don't need to check if the sorted set is empty * because we know it has at least one element. */ goto cleanup; } } /* Remove and re-insert when score changes. */ if (score != curscore) { zskiplistNode *node; serverAssert(zslDelete(zs->zsl,curscore,ele,&node)); znode = zslInsert(zs->zsl,score,node->ele); /* We reused the node->ele SDS string, free the node now * since zslInsert created a new one. */ node->ele = NULL; zslFreeNode(node); /* Note that we did not removed the original element from * the hash table representing the sorted set, so we just * update the score. */ dictGetVal(de) = &znode->score; /* Update score ptr. */ server.dirty++; updated++; } processed++; } else if (!xx) { ele = sdsdup(ele); znode = zslInsert(zs->zsl,score,ele); serverAssert(dictAdd(zs->dict,ele,&znode->score) == DICT_OK); server.dirty++; added++; processed++; } } else { serverPanic("Unknown sorted set encoding"); } } reply_to_client: if (incr) { /* ZINCRBY or INCR option. */ if (processed) addReplyDouble(c,score); else addReply(c,shared.nullbulk); } else { /* ZADD. */ addReplyLongLong(c,ch ? added+updated : added); } cleanup: zfree(scores); if (added || updated) { signalModifiedKey(c->db,key); notifyKeyspaceEvent(NOTIFY_ZSET, incr ? "zincr" : "zadd", key, c->db->id); } } void zaddCommand(client *c) { zaddGenericCommand(c,ZADD_NONE); } void zincrbyCommand(client *c) { zaddGenericCommand(c,ZADD_INCR); } void zremCommand(client *c) { robj *key = c->argv[1]; robj *zobj; int deleted = 0, keyremoved = 0, j; if ((zobj = lookupKeyWriteOrReply(c,key,shared.czero)) == NULL || checkType(c,zobj,OBJ_ZSET)) return; if (zobj->encoding == OBJ_ENCODING_ZIPLIST) { unsigned char *eptr; for (j = 2; j < c->argc; j++) { if ((eptr = zzlFind(zobj->ptr,c->argv[j]->ptr,NULL)) != NULL) { deleted++; zobj->ptr = zzlDelete(zobj->ptr,eptr); if (zzlLength(zobj->ptr) == 0) { dbDelete(c->db,key); keyremoved = 1; break; } } } } else if (zobj->encoding == OBJ_ENCODING_SKIPLIST) { zset *zs = zobj->ptr; dictEntry *de; double score; for (j = 2; j < c->argc; j++) { de = dictFind(zs->dict,c->argv[j]->ptr); if (de != NULL) { deleted++; /* Get the score in order to delete from the skiplist later. */ score = *(double*)dictGetVal(de); /* Delete from the hash table and later from the skiplist. * Note that the order is important: deleting from the skiplist * actually releases the SDS string representing the element, * which is shared between the skiplist and the hash table, so * we need to delete from the skiplist as the final step. */ int retval1 = dictDelete(zs->dict,c->argv[j]->ptr); /* Delete from skiplist. */ int retval2 = zslDelete(zs->zsl,score,c->argv[j]->ptr,NULL); serverAssertWithInfo(c,c->argv[j], retval1 == DICT_OK && retval2); if (htNeedsResize(zs->dict)) dictResize(zs->dict); if (dictSize(zs->dict) == 0) { dbDelete(c->db,key); keyremoved = 1; break; } } } } else { serverPanic("Unknown sorted set encoding"); } if (deleted) { notifyKeyspaceEvent(NOTIFY_ZSET,"zrem",key,c->db->id); if (keyremoved) notifyKeyspaceEvent(NOTIFY_GENERIC,"del",key,c->db->id); signalModifiedKey(c->db,key); server.dirty += deleted; } addReplyLongLong(c,deleted); } /* Implements ZREMRANGEBYRANK, ZREMRANGEBYSCORE, ZREMRANGEBYLEX commands. */ #define ZRANGE_RANK 0 #define ZRANGE_SCORE 1 #define ZRANGE_LEX 2 void zremrangeGenericCommand(client *c, int rangetype) { robj *key = c->argv[1]; robj *zobj; int keyremoved = 0; unsigned long deleted = 0; zrangespec range; zlexrangespec lexrange; long start, end, llen; /* Step 1: Parse the range. */ if (rangetype == ZRANGE_RANK) { if ((getLongFromObjectOrReply(c,c->argv[2],&start,NULL) != C_OK) || (getLongFromObjectOrReply(c,c->argv[3],&end,NULL) != C_OK)) return; } else if (rangetype == ZRANGE_SCORE) { if (zslParseRange(c->argv[2],c->argv[3],&range) != C_OK) { addReplyError(c,"min or max is not a float"); return; } } else if (rangetype == ZRANGE_LEX) { if (zslParseLexRange(c->argv[2],c->argv[3],&lexrange) != C_OK) { addReplyError(c,"min or max not valid string range item"); return; } } /* Step 2: Lookup & range sanity checks if needed. */ if ((zobj = lookupKeyWriteOrReply(c,key,shared.czero)) == NULL || checkType(c,zobj,OBJ_ZSET)) goto cleanup; if (rangetype == ZRANGE_RANK) { /* Sanitize indexes. */ llen = zsetLength(zobj); if (start < 0) start = llen+start; if (end < 0) end = llen+end; if (start < 0) start = 0; /* Invariant: start >= 0, so this test will be true when end < 0. * The range is empty when start > end or start >= length. */ if (start > end || start >= llen) { addReply(c,shared.czero); goto cleanup; } if (end >= llen) end = llen-1; } /* Step 3: Perform the range deletion operation. */ if (zobj->encoding == OBJ_ENCODING_ZIPLIST) { switch(rangetype) { case ZRANGE_RANK: zobj->ptr = zzlDeleteRangeByRank(zobj->ptr,start+1,end+1,&deleted); break; case ZRANGE_SCORE: zobj->ptr = zzlDeleteRangeByScore(zobj->ptr,&range,&deleted); break; case ZRANGE_LEX: zobj->ptr = zzlDeleteRangeByLex(zobj->ptr,&lexrange,&deleted); break; } if (zzlLength(zobj->ptr) == 0) { dbDelete(c->db,key); keyremoved = 1; } } else if (zobj->encoding == OBJ_ENCODING_SKIPLIST) { zset *zs = zobj->ptr; switch(rangetype) { case ZRANGE_RANK: deleted = zslDeleteRangeByRank(zs->zsl,start+1,end+1,zs->dict); break; case ZRANGE_SCORE: deleted = zslDeleteRangeByScore(zs->zsl,&range,zs->dict); break; case ZRANGE_LEX: deleted = zslDeleteRangeByLex(zs->zsl,&lexrange,zs->dict); break; } if (htNeedsResize(zs->dict)) dictResize(zs->dict); if (dictSize(zs->dict) == 0) { dbDelete(c->db,key); keyremoved = 1; } } else { serverPanic("Unknown sorted set encoding"); } /* Step 4: Notifications and reply. */ if (deleted) { char *event[3] = {"zremrangebyrank","zremrangebyscore","zremrangebylex"}; signalModifiedKey(c->db,key); notifyKeyspaceEvent(NOTIFY_ZSET,event[rangetype],key,c->db->id); if (keyremoved) notifyKeyspaceEvent(NOTIFY_GENERIC,"del",key,c->db->id); } server.dirty += deleted; addReplyLongLong(c,deleted); cleanup: if (rangetype == ZRANGE_LEX) zslFreeLexRange(&lexrange); } void zremrangebyrankCommand(client *c) { zremrangeGenericCommand(c,ZRANGE_RANK); } void zremrangebyscoreCommand(client *c) { zremrangeGenericCommand(c,ZRANGE_SCORE); } void zremrangebylexCommand(client *c) { zremrangeGenericCommand(c,ZRANGE_LEX); } typedef struct { robj *subject; int type; /* Set, sorted set */ int encoding; double weight; union { /* Set iterators. */ union _iterset { struct { intset *is; int ii; } is; struct { dict *dict; dictIterator *di; dictEntry *de; } ht; } set; /* Sorted set iterators. */ union _iterzset { struct { unsigned char *zl; unsigned char *eptr, *sptr; } zl; struct { zset *zs; zskiplistNode *node; } sl; } zset; } iter; } zsetopsrc; /* Use dirty flags for pointers that need to be cleaned up in the next * iteration over the zsetopval. The dirty flag for the long long value is * special, since long long values don't need cleanup. Instead, it means that * we already checked that "ell" holds a long long, or tried to convert another * representation into a long long value. When this was successful, * OPVAL_VALID_LL is set as well. */ #define OPVAL_DIRTY_SDS 1 #define OPVAL_DIRTY_LL 2 #define OPVAL_VALID_LL 4 /* Store value retrieved from the iterator. */ typedef struct { int flags; unsigned char _buf[32]; /* Private buffer. */ sds ele; unsigned char *estr; unsigned int elen; long long ell; double score; } zsetopval; typedef union _iterset iterset; typedef union _iterzset iterzset; void zuiInitIterator(zsetopsrc *op) { if (op->subject == NULL) return; if (op->type == OBJ_SET) { iterset *it = &op->iter.set; if (op->encoding == OBJ_ENCODING_INTSET) { it->is.is = op->subject->ptr; it->is.ii = 0; } else if (op->encoding == OBJ_ENCODING_HT) { it->ht.dict = op->subject->ptr; it->ht.di = dictGetIterator(op->subject->ptr); it->ht.de = dictNext(it->ht.di); } else { serverPanic("Unknown set encoding"); } } else if (op->type == OBJ_ZSET) { iterzset *it = &op->iter.zset; if (op->encoding == OBJ_ENCODING_ZIPLIST) { it->zl.zl = op->subject->ptr; it->zl.eptr = ziplistIndex(it->zl.zl,0); if (it->zl.eptr != NULL) { it->zl.sptr = ziplistNext(it->zl.zl,it->zl.eptr); serverAssert(it->zl.sptr != NULL); } } else if (op->encoding == OBJ_ENCODING_SKIPLIST) { it->sl.zs = op->subject->ptr; it->sl.node = it->sl.zs->zsl->header->level[0].forward; } else { serverPanic("Unknown sorted set encoding"); } } else { serverPanic("Unsupported type"); } } void zuiClearIterator(zsetopsrc *op) { if (op->subject == NULL) return; if (op->type == OBJ_SET) { iterset *it = &op->iter.set; if (op->encoding == OBJ_ENCODING_INTSET) { UNUSED(it); /* skip */ } else if (op->encoding == OBJ_ENCODING_HT) { dictReleaseIterator(it->ht.di); } else { serverPanic("Unknown set encoding"); } } else if (op->type == OBJ_ZSET) { iterzset *it = &op->iter.zset; if (op->encoding == OBJ_ENCODING_ZIPLIST) { UNUSED(it); /* skip */ } else if (op->encoding == OBJ_ENCODING_SKIPLIST) { UNUSED(it); /* skip */ } else { serverPanic("Unknown sorted set encoding"); } } else { serverPanic("Unsupported type"); } } int zuiLength(zsetopsrc *op) { if (op->subject == NULL) return 0; if (op->type == OBJ_SET) { if (op->encoding == OBJ_ENCODING_INTSET) { return intsetLen(op->subject->ptr); } else if (op->encoding == OBJ_ENCODING_HT) { dict *ht = op->subject->ptr; return dictSize(ht); } else { serverPanic("Unknown set encoding"); } } else if (op->type == OBJ_ZSET) { if (op->encoding == OBJ_ENCODING_ZIPLIST) { return zzlLength(op->subject->ptr); } else if (op->encoding == OBJ_ENCODING_SKIPLIST) { zset *zs = op->subject->ptr; return zs->zsl->length; } else { serverPanic("Unknown sorted set encoding"); } } else { serverPanic("Unsupported type"); } } /* Check if the current value is valid. If so, store it in the passed structure * and move to the next element. If not valid, this means we have reached the * end of the structure and can abort. */ int zuiNext(zsetopsrc *op, zsetopval *val) { if (op->subject == NULL) return 0; if (val->flags & OPVAL_DIRTY_SDS) sdsfree(val->ele); memset(val,0,sizeof(zsetopval)); if (op->type == OBJ_SET) { iterset *it = &op->iter.set; if (op->encoding == OBJ_ENCODING_INTSET) { int64_t ell; if (!intsetGet(it->is.is,it->is.ii,&ell)) return 0; val->ell = ell; val->score = 1.0; /* Move to next element. */ it->is.ii++; } else if (op->encoding == OBJ_ENCODING_HT) { if (it->ht.de == NULL) return 0; val->ele = dictGetKey(it->ht.de); val->score = 1.0; /* Move to next element. */ it->ht.de = dictNext(it->ht.di); } else { serverPanic("Unknown set encoding"); } } else if (op->type == OBJ_ZSET) { iterzset *it = &op->iter.zset; if (op->encoding == OBJ_ENCODING_ZIPLIST) { /* No need to check both, but better be explicit. */ if (it->zl.eptr == NULL || it->zl.sptr == NULL) return 0; serverAssert(ziplistGet(it->zl.eptr,&val->estr,&val->elen,&val->ell)); val->score = zzlGetScore(it->zl.sptr); /* Move to next element. */ zzlNext(it->zl.zl,&it->zl.eptr,&it->zl.sptr); } else if (op->encoding == OBJ_ENCODING_SKIPLIST) { if (it->sl.node == NULL) return 0; val->ele = it->sl.node->ele; val->score = it->sl.node->score; /* Move to next element. */ it->sl.node = it->sl.node->level[0].forward; } else { serverPanic("Unknown sorted set encoding"); } } else { serverPanic("Unsupported type"); } return 1; } int zuiLongLongFromValue(zsetopval *val) { if (!(val->flags & OPVAL_DIRTY_LL)) { val->flags |= OPVAL_DIRTY_LL; if (val->ele != NULL) { if (string2ll(val->ele,sdslen(val->ele),&val->ell)) val->flags |= OPVAL_VALID_LL; } else if (val->estr != NULL) { if (string2ll((char*)val->estr,val->elen,&val->ell)) val->flags |= OPVAL_VALID_LL; } else { /* The long long was already set, flag as valid. */ val->flags |= OPVAL_VALID_LL; } } return val->flags & OPVAL_VALID_LL; } sds zuiSdsFromValue(zsetopval *val) { if (val->ele == NULL) { if (val->estr != NULL) { val->ele = sdsnewlen((char*)val->estr,val->elen); } else { val->ele = sdsfromlonglong(val->ell); } val->flags |= OPVAL_DIRTY_SDS; } return val->ele; } /* This is different from zuiSdsFromValue since returns a new SDS string * which is up to the caller to free. */ sds zuiNewSdsFromValue(zsetopval *val) { if (val->flags & OPVAL_DIRTY_SDS) { /* We have already one to return! */ sds ele = val->ele; val->flags &= ~OPVAL_DIRTY_SDS; val->ele = NULL; return ele; } else if (val->ele) { return sdsdup(val->ele); } else if (val->estr) { return sdsnewlen((char*)val->estr,val->elen); } else { return sdsfromlonglong(val->ell); } } int zuiBufferFromValue(zsetopval *val) { if (val->estr == NULL) { if (val->ele != NULL) { val->elen = sdslen(val->ele); val->estr = (unsigned char*)val->ele; } else { val->elen = ll2string((char*)val->_buf,sizeof(val->_buf),val->ell); val->estr = val->_buf; } } return 1; } /* Find value pointed to by val in the source pointer to by op. When found, * return 1 and store its score in target. Return 0 otherwise. */ int zuiFind(zsetopsrc *op, zsetopval *val, double *score) { if (op->subject == NULL) return 0; if (op->type == OBJ_SET) { if (op->encoding == OBJ_ENCODING_INTSET) { if (zuiLongLongFromValue(val) && intsetFind(op->subject->ptr,val->ell)) { *score = 1.0; return 1; } else { return 0; } } else if (op->encoding == OBJ_ENCODING_HT) { dict *ht = op->subject->ptr; zuiSdsFromValue(val); if (dictFind(ht,val->ele) != NULL) { *score = 1.0; return 1; } else { return 0; } } else { serverPanic("Unknown set encoding"); } } else if (op->type == OBJ_ZSET) { zuiSdsFromValue(val); if (op->encoding == OBJ_ENCODING_ZIPLIST) { if (zzlFind(op->subject->ptr,val->ele,score) != NULL) { /* Score is already set by zzlFind. */ return 1; } else { return 0; } } else if (op->encoding == OBJ_ENCODING_SKIPLIST) { zset *zs = op->subject->ptr; dictEntry *de; if ((de = dictFind(zs->dict,val->ele)) != NULL) { *score = *(double*)dictGetVal(de); return 1; } else { return 0; } } else { serverPanic("Unknown sorted set encoding"); } } else { serverPanic("Unsupported type"); } } int zuiCompareByCardinality(const void *s1, const void *s2) { return zuiLength((zsetopsrc*)s1) - zuiLength((zsetopsrc*)s2); } #define REDIS_AGGR_SUM 1 #define REDIS_AGGR_MIN 2 #define REDIS_AGGR_MAX 3 #define zunionInterDictValue(_e) (dictGetVal(_e) == NULL ? 1.0 : *(double*)dictGetVal(_e)) inline static void zunionInterAggregate(double *target, double val, int aggregate) { if (aggregate == REDIS_AGGR_SUM) { *target = *target + val; /* The result of adding two doubles is NaN when one variable * is +inf and the other is -inf. When these numbers are added, * we maintain the convention of the result being 0.0. */ if (isnan(*target)) *target = 0.0; } else if (aggregate == REDIS_AGGR_MIN) { *target = val < *target ? val : *target; } else if (aggregate == REDIS_AGGR_MAX) { *target = val > *target ? val : *target; } else { /* safety net */ serverPanic("Unknown ZUNION/INTER aggregate type"); } } unsigned int dictSdsHash(const void *key); int dictSdsKeyCompare(void *privdata, const void *key1, const void *key2); dictType setAccumulatorDictType = { dictSdsHash, /* hash function */ NULL, /* key dup */ NULL, /* val dup */ dictSdsKeyCompare, /* key compare */ NULL, /* key destructor */ NULL /* val destructor */ }; void zunionInterGenericCommand(client *c, robj *dstkey, int op) { int i, j; long setnum; int aggregate = REDIS_AGGR_SUM; zsetopsrc *src; zsetopval zval; sds tmp; unsigned int maxelelen = 0; robj *dstobj; zset *dstzset; zskiplistNode *znode; int touched = 0; /* expect setnum input keys to be given */ if ((getLongFromObjectOrReply(c, c->argv[2], &setnum, NULL) != C_OK)) return; if (setnum < 1) { addReplyError(c, "at least 1 input key is needed for ZUNIONSTORE/ZINTERSTORE"); return; } /* test if the expected number of keys would overflow */ if (setnum > c->argc-3) { addReply(c,shared.syntaxerr); return; } /* read keys to be used for input */ src = zcalloc(sizeof(zsetopsrc) * setnum); for (i = 0, j = 3; i < setnum; i++, j++) { robj *obj = lookupKeyWrite(c->db,c->argv[j]); if (obj != NULL) { if (obj->type != OBJ_ZSET && obj->type != OBJ_SET) { zfree(src); addReply(c,shared.wrongtypeerr); return; } src[i].subject = obj; src[i].type = obj->type; src[i].encoding = obj->encoding; } else { src[i].subject = NULL; } /* Default all weights to 1. */ src[i].weight = 1.0; } /* parse optional extra arguments */ if (j < c->argc) { int remaining = c->argc - j; while (remaining) { if (remaining >= (setnum + 1) && !strcasecmp(c->argv[j]->ptr,"weights")) { j++; remaining--; for (i = 0; i < setnum; i++, j++, remaining--) { if (getDoubleFromObjectOrReply(c,c->argv[j],&src[i].weight, "weight value is not a float") != C_OK) { zfree(src); return; } } } else if (remaining >= 2 && !strcasecmp(c->argv[j]->ptr,"aggregate")) { j++; remaining--; if (!strcasecmp(c->argv[j]->ptr,"sum")) { aggregate = REDIS_AGGR_SUM; } else if (!strcasecmp(c->argv[j]->ptr,"min")) { aggregate = REDIS_AGGR_MIN; } else if (!strcasecmp(c->argv[j]->ptr,"max")) { aggregate = REDIS_AGGR_MAX; } else { zfree(src); addReply(c,shared.syntaxerr); return; } j++; remaining--; } else { zfree(src); addReply(c,shared.syntaxerr); return; } } } /* sort sets from the smallest to largest, this will improve our * algorithm's performance */ qsort(src,setnum,sizeof(zsetopsrc),zuiCompareByCardinality); dstobj = createZsetObject(); dstzset = dstobj->ptr; memset(&zval, 0, sizeof(zval)); if (op == SET_OP_INTER) { /* Skip everything if the smallest input is empty. */ if (zuiLength(&src[0]) > 0) { /* Precondition: as src[0] is non-empty and the inputs are ordered * by size, all src[i > 0] are non-empty too. */ zuiInitIterator(&src[0]); while (zuiNext(&src[0],&zval)) { double score, value; score = src[0].weight * zval.score; if (isnan(score)) score = 0; for (j = 1; j < setnum; j++) { /* It is not safe to access the zset we are * iterating, so explicitly check for equal object. */ if (src[j].subject == src[0].subject) { value = zval.score*src[j].weight; zunionInterAggregate(&score,value,aggregate); } else if (zuiFind(&src[j],&zval,&value)) { value *= src[j].weight; zunionInterAggregate(&score,value,aggregate); } else { break; } } /* Only continue when present in every input. */ if (j == setnum) { tmp = zuiNewSdsFromValue(&zval); znode = zslInsert(dstzset->zsl,score,tmp); dictAdd(dstzset->dict,tmp,&znode->score); if (sdslen(tmp) > maxelelen) maxelelen = sdslen(tmp); } } zuiClearIterator(&src[0]); } } else if (op == SET_OP_UNION) { dict *accumulator = dictCreate(&setAccumulatorDictType,NULL); dictIterator *di; dictEntry *de; double score; if (setnum) { /* Our union is at least as large as the largest set. * Resize the dictionary ASAP to avoid useless rehashing. */ dictExpand(accumulator,zuiLength(&src[setnum-1])); } /* Step 1: Create a dictionary of elements -> aggregated-scores * by iterating one sorted set after the other. */ for (i = 0; i < setnum; i++) { if (zuiLength(&src[i]) == 0) continue; zuiInitIterator(&src[i]); while (zuiNext(&src[i],&zval)) { /* Initialize value */ score = src[i].weight * zval.score; if (isnan(score)) score = 0; /* Search for this element in the accumulating dictionary. */ de = dictFind(accumulator,zuiSdsFromValue(&zval)); /* If we don't have it, we need to create a new entry. */ if (de == NULL) { tmp = zuiNewSdsFromValue(&zval); /* Remember the longest single element encountered, * to understand if it's possible to convert to ziplist * at the end. */ if (sdslen(tmp) > maxelelen) maxelelen = sdslen(tmp); /* Add the element with its initial score. */ de = dictAddRaw(accumulator,tmp); dictSetDoubleVal(de,score); } else { /* Update the score with the score of the new instance * of the element found in the current sorted set. * * Here we access directly the dictEntry double * value inside the union as it is a big speedup * compared to using the getDouble/setDouble API. */ zunionInterAggregate(&de->v.d,score,aggregate); } } zuiClearIterator(&src[i]); } /* Step 2: convert the dictionary into the final sorted set. */ di = dictGetIterator(accumulator); /* We now are aware of the final size of the resulting sorted set, * let's resize the dictionary embedded inside the sorted set to the * right size, in order to save rehashing time. */ dictExpand(dstzset->dict,dictSize(accumulator)); while((de = dictNext(di)) != NULL) { sds ele = dictGetKey(de); score = dictGetDoubleVal(de); znode = zslInsert(dstzset->zsl,score,ele); dictAdd(dstzset->dict,ele,&znode->score); } dictReleaseIterator(di); dictRelease(accumulator); } else { serverPanic("Unknown operator"); } if (dbDelete(c->db,dstkey)) { signalModifiedKey(c->db,dstkey); touched = 1; server.dirty++; } if (dstzset->zsl->length) { /* Convert to ziplist when in limits. */ if (dstzset->zsl->length <= server.zset_max_ziplist_entries && maxelelen <= server.zset_max_ziplist_value) zsetConvert(dstobj,OBJ_ENCODING_ZIPLIST); dbAdd(c->db,dstkey,dstobj); addReplyLongLong(c,zsetLength(dstobj)); if (!touched) signalModifiedKey(c->db,dstkey); notifyKeyspaceEvent(NOTIFY_ZSET, (op == SET_OP_UNION) ? "zunionstore" : "zinterstore", dstkey,c->db->id); server.dirty++; } else { decrRefCount(dstobj); addReply(c,shared.czero); if (touched) notifyKeyspaceEvent(NOTIFY_GENERIC,"del",dstkey,c->db->id); } zfree(src); } void zunionstoreCommand(client *c) { zunionInterGenericCommand(c,c->argv[1], SET_OP_UNION); } void zinterstoreCommand(client *c) { zunionInterGenericCommand(c,c->argv[1], SET_OP_INTER); } void zrangeGenericCommand(client *c, int reverse) { robj *key = c->argv[1]; robj *zobj; int withscores = 0; long start; long end; int llen; int rangelen; if ((getLongFromObjectOrReply(c, c->argv[2], &start, NULL) != C_OK) || (getLongFromObjectOrReply(c, c->argv[3], &end, NULL) != C_OK)) return; if (c->argc == 5 && !strcasecmp(c->argv[4]->ptr,"withscores")) { withscores = 1; } else if (c->argc >= 5) { addReply(c,shared.syntaxerr); return; } if ((zobj = lookupKeyReadOrReply(c,key,shared.emptymultibulk)) == NULL || checkType(c,zobj,OBJ_ZSET)) return; /* Sanitize indexes. */ llen = zsetLength(zobj); if (start < 0) start = llen+start; if (end < 0) end = llen+end; if (start < 0) start = 0; /* Invariant: start >= 0, so this test will be true when end < 0. * The range is empty when start > end or start >= length. */ if (start > end || start >= llen) { addReply(c,shared.emptymultibulk); return; } if (end >= llen) end = llen-1; rangelen = (end-start)+1; /* Return the result in form of a multi-bulk reply */ addReplyMultiBulkLen(c, withscores ? (rangelen*2) : rangelen); if (zobj->encoding == OBJ_ENCODING_ZIPLIST) { unsigned char *zl = zobj->ptr; unsigned char *eptr, *sptr; unsigned char *vstr; unsigned int vlen; long long vlong; if (reverse) eptr = ziplistIndex(zl,-2-(2*start)); else eptr = ziplistIndex(zl,2*start); serverAssertWithInfo(c,zobj,eptr != NULL); sptr = ziplistNext(zl,eptr); while (rangelen--) { serverAssertWithInfo(c,zobj,eptr != NULL && sptr != NULL); serverAssertWithInfo(c,zobj,ziplistGet(eptr,&vstr,&vlen,&vlong)); if (vstr == NULL) addReplyBulkLongLong(c,vlong); else addReplyBulkCBuffer(c,vstr,vlen); if (withscores) addReplyDouble(c,zzlGetScore(sptr)); if (reverse) zzlPrev(zl,&eptr,&sptr); else zzlNext(zl,&eptr,&sptr); } } else if (zobj->encoding == OBJ_ENCODING_SKIPLIST) { zset *zs = zobj->ptr; zskiplist *zsl = zs->zsl; zskiplistNode *ln; sds ele; /* Check if starting point is trivial, before doing log(N) lookup. */ if (reverse) { ln = zsl->tail; if (start > 0) ln = zslGetElementByRank(zsl,llen-start); } else { ln = zsl->header->level[0].forward; if (start > 0) ln = zslGetElementByRank(zsl,start+1); } while(rangelen--) { serverAssertWithInfo(c,zobj,ln != NULL); ele = ln->ele; addReplyBulkCBuffer(c,ele,sdslen(ele)); if (withscores) addReplyDouble(c,ln->score); ln = reverse ? ln->backward : ln->level[0].forward; } } else { serverPanic("Unknown sorted set encoding"); } } void zrangeCommand(client *c) { zrangeGenericCommand(c,0); } void zrevrangeCommand(client *c) { zrangeGenericCommand(c,1); } /* This command implements ZRANGEBYSCORE, ZREVRANGEBYSCORE. */ void genericZrangebyscoreCommand(client *c, int reverse) { zrangespec range; robj *key = c->argv[1]; robj *zobj; long offset = 0, limit = -1; int withscores = 0; unsigned long rangelen = 0; void *replylen = NULL; int minidx, maxidx; /* Parse the range arguments. */ if (reverse) { /* Range is given as [max,min] */ maxidx = 2; minidx = 3; } else { /* Range is given as [min,max] */ minidx = 2; maxidx = 3; } if (zslParseRange(c->argv[minidx],c->argv[maxidx],&range) != C_OK) { addReplyError(c,"min or max is not a float"); return; } /* Parse optional extra arguments. Note that ZCOUNT will exactly have * 4 arguments, so we'll never enter the following code path. */ if (c->argc > 4) { int remaining = c->argc - 4; int pos = 4; while (remaining) { if (remaining >= 1 && !strcasecmp(c->argv[pos]->ptr,"withscores")) { pos++; remaining--; withscores = 1; } else if (remaining >= 3 && !strcasecmp(c->argv[pos]->ptr,"limit")) { if ((getLongFromObjectOrReply(c, c->argv[pos+1], &offset, NULL) != C_OK) || (getLongFromObjectOrReply(c, c->argv[pos+2], &limit, NULL) != C_OK)) { return; } pos += 3; remaining -= 3; } else { addReply(c,shared.syntaxerr); return; } } } /* Ok, lookup the key and get the range */ if ((zobj = lookupKeyReadOrReply(c,key,shared.emptymultibulk)) == NULL || checkType(c,zobj,OBJ_ZSET)) return; if (zobj->encoding == OBJ_ENCODING_ZIPLIST) { unsigned char *zl = zobj->ptr; unsigned char *eptr, *sptr; unsigned char *vstr; unsigned int vlen; long long vlong; double score; /* If reversed, get the last node in range as starting point. */ if (reverse) { eptr = zzlLastInRange(zl,&range); } else { eptr = zzlFirstInRange(zl,&range); } /* No "first" element in the specified interval. */ if (eptr == NULL) { addReply(c, shared.emptymultibulk); return; } /* Get score pointer for the first element. */ serverAssertWithInfo(c,zobj,eptr != NULL); sptr = ziplistNext(zl,eptr); /* We don't know in advance how many matching elements there are in the * list, so we push this object that will represent the multi-bulk * length in the output buffer, and will "fix" it later */ replylen = addDeferredMultiBulkLength(c); /* If there is an offset, just traverse the number of elements without * checking the score because that is done in the next loop. */ while (eptr && offset--) { if (reverse) { zzlPrev(zl,&eptr,&sptr); } else { zzlNext(zl,&eptr,&sptr); } } while (eptr && limit--) { score = zzlGetScore(sptr); /* Abort when the node is no longer in range. */ if (reverse) { if (!zslValueGteMin(score,&range)) break; } else { if (!zslValueLteMax(score,&range)) break; } /* We know the element exists, so ziplistGet should always succeed */ serverAssertWithInfo(c,zobj,ziplistGet(eptr,&vstr,&vlen,&vlong)); rangelen++; if (vstr == NULL) { addReplyBulkLongLong(c,vlong); } else { addReplyBulkCBuffer(c,vstr,vlen); } if (withscores) { addReplyDouble(c,score); } /* Move to next node */ if (reverse) { zzlPrev(zl,&eptr,&sptr); } else { zzlNext(zl,&eptr,&sptr); } } } else if (zobj->encoding == OBJ_ENCODING_SKIPLIST) { zset *zs = zobj->ptr; zskiplist *zsl = zs->zsl; zskiplistNode *ln; /* If reversed, get the last node in range as starting point. */ if (reverse) { ln = zslLastInRange(zsl,&range); } else { ln = zslFirstInRange(zsl,&range); } /* No "first" element in the specified interval. */ if (ln == NULL) { addReply(c, shared.emptymultibulk); return; } /* We don't know in advance how many matching elements there are in the * list, so we push this object that will represent the multi-bulk * length in the output buffer, and will "fix" it later */ replylen = addDeferredMultiBulkLength(c); /* If there is an offset, just traverse the number of elements without * checking the score because that is done in the next loop. */ while (ln && offset--) { if (reverse) { ln = ln->backward; } else { ln = ln->level[0].forward; } } while (ln && limit--) { /* Abort when the node is no longer in range. */ if (reverse) { if (!zslValueGteMin(ln->score,&range)) break; } else { if (!zslValueLteMax(ln->score,&range)) break; } rangelen++; addReplyBulkCBuffer(c,ln->ele,sdslen(ln->ele)); if (withscores) { addReplyDouble(c,ln->score); } /* Move to next node */ if (reverse) { ln = ln->backward; } else { ln = ln->level[0].forward; } } } else { serverPanic("Unknown sorted set encoding"); } if (withscores) { rangelen *= 2; } setDeferredMultiBulkLength(c, replylen, rangelen); } void zrangebyscoreCommand(client *c) { genericZrangebyscoreCommand(c,0); } void zrevrangebyscoreCommand(client *c) { genericZrangebyscoreCommand(c,1); } void zcountCommand(client *c) { robj *key = c->argv[1]; robj *zobj; zrangespec range; int count = 0; /* Parse the range arguments */ if (zslParseRange(c->argv[2],c->argv[3],&range) != C_OK) { addReplyError(c,"min or max is not a float"); return; } /* Lookup the sorted set */ if ((zobj = lookupKeyReadOrReply(c, key, shared.czero)) == NULL || checkType(c, zobj, OBJ_ZSET)) return; if (zobj->encoding == OBJ_ENCODING_ZIPLIST) { unsigned char *zl = zobj->ptr; unsigned char *eptr, *sptr; double score; /* Use the first element in range as the starting point */ eptr = zzlFirstInRange(zl,&range); /* No "first" element */ if (eptr == NULL) { addReply(c, shared.czero); return; } /* First element is in range */ sptr = ziplistNext(zl,eptr); score = zzlGetScore(sptr); serverAssertWithInfo(c,zobj,zslValueLteMax(score,&range)); /* Iterate over elements in range */ while (eptr) { score = zzlGetScore(sptr); /* Abort when the node is no longer in range. */ if (!zslValueLteMax(score,&range)) { break; } else { count++; zzlNext(zl,&eptr,&sptr); } } } else if (zobj->encoding == OBJ_ENCODING_SKIPLIST) { zset *zs = zobj->ptr; zskiplist *zsl = zs->zsl; zskiplistNode *zn; unsigned long rank; /* Find first element in range */ zn = zslFirstInRange(zsl, &range); /* Use rank of first element, if any, to determine preliminary count */ if (zn != NULL) { rank = zslGetRank(zsl, zn->score, zn->ele); count = (zsl->length - (rank - 1)); /* Find last element in range */ zn = zslLastInRange(zsl, &range); /* Use rank of last element, if any, to determine the actual count */ if (zn != NULL) { rank = zslGetRank(zsl, zn->score, zn->ele); count -= (zsl->length - rank); } } } else { serverPanic("Unknown sorted set encoding"); } addReplyLongLong(c, count); } void zlexcountCommand(client *c) { robj *key = c->argv[1]; robj *zobj; zlexrangespec range; int count = 0; /* Parse the range arguments */ if (zslParseLexRange(c->argv[2],c->argv[3],&range) != C_OK) { addReplyError(c,"min or max not valid string range item"); return; } /* Lookup the sorted set */ if ((zobj = lookupKeyReadOrReply(c, key, shared.czero)) == NULL || checkType(c, zobj, OBJ_ZSET)) { zslFreeLexRange(&range); return; } if (zobj->encoding == OBJ_ENCODING_ZIPLIST) { unsigned char *zl = zobj->ptr; unsigned char *eptr, *sptr; /* Use the first element in range as the starting point */ eptr = zzlFirstInLexRange(zl,&range); /* No "first" element */ if (eptr == NULL) { zslFreeLexRange(&range); addReply(c, shared.czero); return; } /* First element is in range */ sptr = ziplistNext(zl,eptr); serverAssertWithInfo(c,zobj,zzlLexValueLteMax(eptr,&range)); /* Iterate over elements in range */ while (eptr) { /* Abort when the node is no longer in range. */ if (!zzlLexValueLteMax(eptr,&range)) { break; } else { count++; zzlNext(zl,&eptr,&sptr); } } } else if (zobj->encoding == OBJ_ENCODING_SKIPLIST) { zset *zs = zobj->ptr; zskiplist *zsl = zs->zsl; zskiplistNode *zn; unsigned long rank; /* Find first element in range */ zn = zslFirstInLexRange(zsl, &range); /* Use rank of first element, if any, to determine preliminary count */ if (zn != NULL) { rank = zslGetRank(zsl, zn->score, zn->ele); count = (zsl->length - (rank - 1)); /* Find last element in range */ zn = zslLastInLexRange(zsl, &range); /* Use rank of last element, if any, to determine the actual count */ if (zn != NULL) { rank = zslGetRank(zsl, zn->score, zn->ele); count -= (zsl->length - rank); } } } else { serverPanic("Unknown sorted set encoding"); } zslFreeLexRange(&range); addReplyLongLong(c, count); } /* This command implements ZRANGEBYLEX, ZREVRANGEBYLEX. */ void genericZrangebylexCommand(client *c, int reverse) { zlexrangespec range; robj *key = c->argv[1]; robj *zobj; long offset = 0, limit = -1; unsigned long rangelen = 0; void *replylen = NULL; int minidx, maxidx; /* Parse the range arguments. */ if (reverse) { /* Range is given as [max,min] */ maxidx = 2; minidx = 3; } else { /* Range is given as [min,max] */ minidx = 2; maxidx = 3; } if (zslParseLexRange(c->argv[minidx],c->argv[maxidx],&range) != C_OK) { addReplyError(c,"min or max not valid string range item"); return; } /* Parse optional extra arguments. Note that ZCOUNT will exactly have * 4 arguments, so we'll never enter the following code path. */ if (c->argc > 4) { int remaining = c->argc - 4; int pos = 4; while (remaining) { if (remaining >= 3 && !strcasecmp(c->argv[pos]->ptr,"limit")) { if ((getLongFromObjectOrReply(c, c->argv[pos+1], &offset, NULL) != C_OK) || (getLongFromObjectOrReply(c, c->argv[pos+2], &limit, NULL) != C_OK)) return; pos += 3; remaining -= 3; } else { zslFreeLexRange(&range); addReply(c,shared.syntaxerr); return; } } } /* Ok, lookup the key and get the range */ if ((zobj = lookupKeyReadOrReply(c,key,shared.emptymultibulk)) == NULL || checkType(c,zobj,OBJ_ZSET)) { zslFreeLexRange(&range); return; } if (zobj->encoding == OBJ_ENCODING_ZIPLIST) { unsigned char *zl = zobj->ptr; unsigned char *eptr, *sptr; unsigned char *vstr; unsigned int vlen; long long vlong; /* If reversed, get the last node in range as starting point. */ if (reverse) { eptr = zzlLastInLexRange(zl,&range); } else { eptr = zzlFirstInLexRange(zl,&range); } /* No "first" element in the specified interval. */ if (eptr == NULL) { addReply(c, shared.emptymultibulk); zslFreeLexRange(&range); return; } /* Get score pointer for the first element. */ serverAssertWithInfo(c,zobj,eptr != NULL); sptr = ziplistNext(zl,eptr); /* We don't know in advance how many matching elements there are in the * list, so we push this object that will represent the multi-bulk * length in the output buffer, and will "fix" it later */ replylen = addDeferredMultiBulkLength(c); /* If there is an offset, just traverse the number of elements without * checking the score because that is done in the next loop. */ while (eptr && offset--) { if (reverse) { zzlPrev(zl,&eptr,&sptr); } else { zzlNext(zl,&eptr,&sptr); } } while (eptr && limit--) { /* Abort when the node is no longer in range. */ if (reverse) { if (!zzlLexValueGteMin(eptr,&range)) break; } else { if (!zzlLexValueLteMax(eptr,&range)) break; } /* We know the element exists, so ziplistGet should always * succeed. */ serverAssertWithInfo(c,zobj,ziplistGet(eptr,&vstr,&vlen,&vlong)); rangelen++; if (vstr == NULL) { addReplyBulkLongLong(c,vlong); } else { addReplyBulkCBuffer(c,vstr,vlen); } /* Move to next node */ if (reverse) { zzlPrev(zl,&eptr,&sptr); } else { zzlNext(zl,&eptr,&sptr); } } } else if (zobj->encoding == OBJ_ENCODING_SKIPLIST) { zset *zs = zobj->ptr; zskiplist *zsl = zs->zsl; zskiplistNode *ln; /* If reversed, get the last node in range as starting point. */ if (reverse) { ln = zslLastInLexRange(zsl,&range); } else { ln = zslFirstInLexRange(zsl,&range); } /* No "first" element in the specified interval. */ if (ln == NULL) { addReply(c, shared.emptymultibulk); zslFreeLexRange(&range); return; } /* We don't know in advance how many matching elements there are in the * list, so we push this object that will represent the multi-bulk * length in the output buffer, and will "fix" it later */ replylen = addDeferredMultiBulkLength(c); /* If there is an offset, just traverse the number of elements without * checking the score because that is done in the next loop. */ while (ln && offset--) { if (reverse) { ln = ln->backward; } else { ln = ln->level[0].forward; } } while (ln && limit--) { /* Abort when the node is no longer in range. */ if (reverse) { if (!zslLexValueGteMin(ln->ele,&range)) break; } else { if (!zslLexValueLteMax(ln->ele,&range)) break; } rangelen++; addReplyBulkCBuffer(c,ln->ele,sdslen(ln->ele)); /* Move to next node */ if (reverse) { ln = ln->backward; } else { ln = ln->level[0].forward; } } } else { serverPanic("Unknown sorted set encoding"); } zslFreeLexRange(&range); setDeferredMultiBulkLength(c, replylen, rangelen); } void zrangebylexCommand(client *c) { genericZrangebylexCommand(c,0); } void zrevrangebylexCommand(client *c) { genericZrangebylexCommand(c,1); } void zcardCommand(client *c) { robj *key = c->argv[1]; robj *zobj; if ((zobj = lookupKeyReadOrReply(c,key,shared.czero)) == NULL || checkType(c,zobj,OBJ_ZSET)) return; addReplyLongLong(c,zsetLength(zobj)); } void zscoreCommand(client *c) { robj *key = c->argv[1]; robj *zobj; double score; if ((zobj = lookupKeyReadOrReply(c,key,shared.nullbulk)) == NULL || checkType(c,zobj,OBJ_ZSET)) return; if (zsetScore(zobj,c->argv[2]->ptr,&score) == C_ERR) { addReply(c,shared.nullbulk); } else { addReplyDouble(c,score); } } void zrankGenericCommand(client *c, int reverse) { robj *key = c->argv[1]; robj *ele = c->argv[2]; robj *zobj; unsigned long llen; unsigned long rank; if ((zobj = lookupKeyReadOrReply(c,key,shared.nullbulk)) == NULL || checkType(c,zobj,OBJ_ZSET)) return; llen = zsetLength(zobj); serverAssertWithInfo(c,ele,sdsEncodedObject(ele)); if (zobj->encoding == OBJ_ENCODING_ZIPLIST) { unsigned char *zl = zobj->ptr; unsigned char *eptr, *sptr; eptr = ziplistIndex(zl,0); serverAssertWithInfo(c,zobj,eptr != NULL); sptr = ziplistNext(zl,eptr); serverAssertWithInfo(c,zobj,sptr != NULL); rank = 1; while(eptr != NULL) { if (ziplistCompare(eptr,ele->ptr,sdslen(ele->ptr))) break; rank++; zzlNext(zl,&eptr,&sptr); } if (eptr != NULL) { if (reverse) addReplyLongLong(c,llen-rank); else addReplyLongLong(c,rank-1); } else { addReply(c,shared.nullbulk); } } else if (zobj->encoding == OBJ_ENCODING_SKIPLIST) { zset *zs = zobj->ptr; zskiplist *zsl = zs->zsl; dictEntry *de; double score; ele = c->argv[2]; de = dictFind(zs->dict,ele->ptr); if (de != NULL) { score = *(double*)dictGetVal(de); rank = zslGetRank(zsl,score,ele->ptr); /* Existing elements always have a rank. */ serverAssertWithInfo(c,ele,rank); if (reverse) addReplyLongLong(c,llen-rank); else addReplyLongLong(c,rank-1); } else { addReply(c,shared.nullbulk); } } else { serverPanic("Unknown sorted set encoding"); } } void zrankCommand(client *c) { zrankGenericCommand(c, 0); } void zrevrankCommand(client *c) { zrankGenericCommand(c, 1); } void zscanCommand(client *c) { robj *o; unsigned long cursor; if (parseScanCursorOrReply(c,c->argv[2],&cursor) == C_ERR) return; if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.emptyscan)) == NULL || checkType(c,o,OBJ_ZSET)) return; scanGenericCommand(c,o,cursor); }