/* Copyright 2011-2016 David Robillard Permission to use, copy, modify, and/or distribute this software for any purpose with or without fee is hereby granted, provided that the above copyright notice and this permission notice appear in all copies. THIS SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ // C99 #include #include #include #include #include #include #define ZIX_INLINE #include "zix/digest.c" #include "zix/hash.c" #include "zix/btree.c" #include "sord_config.h" #include "sord_internal.h" #define SORD_LOG(prefix, ...) fprintf(stderr, "[Sord::" prefix "] " __VA_ARGS__) #ifdef SORD_DEBUG_ITER # define SORD_ITER_LOG(...) SORD_LOG("iter", __VA_ARGS__) #else # define SORD_ITER_LOG(...) #endif #ifdef SORD_DEBUG_SEARCH # define SORD_FIND_LOG(...) SORD_LOG("search", __VA_ARGS__) #else # define SORD_FIND_LOG(...) #endif #ifdef SORD_DEBUG_WRITE # define SORD_WRITE_LOG(...) SORD_LOG("write", __VA_ARGS__) #else # define SORD_WRITE_LOG(...) #endif #define NUM_ORDERS 12 #define STATEMENT_LEN 3 #define TUP_LEN STATEMENT_LEN + 1 #define DEFAULT_ORDER SPO #define DEFAULT_GRAPH_ORDER GSPO #define TUP_FMT "(%s %s %s %s)" #define TUP_FMT_ELEM(e) ((e) ? sord_node_get_string(e) : (const uint8_t*)"*") #define TUP_FMT_ARGS(t) \ TUP_FMT_ELEM((t)[0]), \ TUP_FMT_ELEM((t)[1]), \ TUP_FMT_ELEM((t)[2]), \ TUP_FMT_ELEM((t)[3]) #define TUP_S 0 #define TUP_P 1 #define TUP_O 2 #define TUP_G 3 /** Triple ordering */ typedef enum { SPO, ///< Subject, Predicate, Object SOP, ///< Subject, Object, Predicate OPS, ///< Object, Predicate, Subject OSP, ///< Object, Subject, Predicate PSO, ///< Predicate, Subject, Object POS, ///< Predicate, Object, Subject GSPO, ///< Graph, Subject, Predicate, Object GSOP, ///< Graph, Subject, Object, Predicate GOPS, ///< Graph, Object, Predicate, Subject GOSP, ///< Graph, Object, Subject, Predicate GPSO, ///< Graph, Predicate, Subject, Object GPOS, ///< Graph, Predicate, Object, Subject } SordOrder; #ifdef SORD_DEBUG_SEARCH /** String name of each ordering (array indexed by SordOrder) */ static const char* const order_names[NUM_ORDERS] = { "spo", "sop", "ops", "osp", "pso", "pos", "gspo", "gsop", "gops", "gosp", "gpso", "gpos" }; #endif /** Quads of indices for each order, from most to least significant (array indexed by SordOrder) */ static const int orderings[NUM_ORDERS][TUP_LEN] = { { 0, 1, 2, 3 }, { 0, 2, 1, 3 }, // SPO, SOP { 2, 1, 0, 3 }, { 2, 0, 1, 3 }, // OPS, OSP { 1, 0, 2, 3 }, { 1, 2, 0, 3 }, // PSO, POS { 3, 0, 1, 2 }, { 3, 0, 2, 1 }, // GSPO, GSOP { 3, 2, 1, 0 }, { 3, 2, 0, 1 }, // GOPS, GOSP { 3, 1, 0, 2 }, { 3, 1, 2, 0 } // GPSO, GPOS }; /** World */ struct SordWorldImpl { ZixHash* nodes; SerdErrorSink error_sink; void* error_handle; }; /** Store */ struct SordModelImpl { SordWorld* world; /** Index for each possible triple ordering (may or may not exist). * Each index is a tree of SordQuad with the appropriate ordering. */ ZixBTree* indices[NUM_ORDERS]; size_t n_quads; size_t n_iters; }; /** Mode for searching or iteration */ typedef enum { ALL, ///< Iterate over entire store SINGLE, ///< Iteration over a single element (exact search) RANGE, ///< Iterate over range with equal prefix FILTER_RANGE, ///< Iterate over range with equal prefix, filtering FILTER_ALL ///< Iterate to end of store, filtering } SearchMode; /** Iterator over some range of a store */ struct SordIterImpl { const SordModel* sord; ///< Model being iterated over ZixBTreeIter* cur; ///< Current DB cursor SordQuad pat; ///< Pattern (in ordering order) SordOrder order; ///< Store order (which index) SearchMode mode; ///< Iteration mode int n_prefix; ///< Prefix for RANGE and FILTER_RANGE bool end; ///< True iff reached end bool skip_graphs; ///< Iteration should ignore graphs }; static uint32_t sord_node_hash(const void* n) { const SordNode* node = (const SordNode*)n; uint32_t hash = zix_digest_start(); hash = zix_digest_add(hash, node->node.buf, node->node.n_bytes); hash = zix_digest_add(hash, &node->node.type, sizeof(node->node.type)); if (node->node.type == SERD_LITERAL) { hash = zix_digest_add(hash, &node->meta.lit, sizeof(node->meta.lit)); } return hash; } static bool sord_node_hash_equal(const void* a, const void* b) { const SordNode* a_node = (const SordNode*)a; const SordNode* b_node = (const SordNode*)b; return (a_node == b_node) || ((a_node->node.type == b_node->node.type) && (a_node->node.type != SERD_LITERAL || (a_node->meta.lit.datatype == b_node->meta.lit.datatype && !strncmp(a_node->meta.lit.lang, b_node->meta.lit.lang, sizeof(a_node->meta.lit.lang)))) && (serd_node_equals(&a_node->node, &b_node->node))); } static void error(SordWorld* world, SerdStatus st, const char* fmt, ...) { va_list args; va_start(args, fmt); const SerdError e = { st, NULL, 0, 0, fmt, &args }; if (world->error_sink) { world->error_sink(world->error_handle, &e); } else { fprintf(stderr, "error: "); vfprintf(stderr, fmt, args); } va_end(args); } SordWorld* sord_world_new(void) { SordWorld* world = (SordWorld*)malloc(sizeof(SordWorld)); world->error_sink = NULL; world->error_handle = NULL; world->nodes = zix_hash_new( sord_node_hash, sord_node_hash_equal, sizeof(SordNode)); return world; } static void free_node_entry(void* value, void* user_data) { SordNode* node = (SordNode*)value; if (node->node.type == SERD_LITERAL) { sord_node_free((SordWorld*)user_data, node->meta.lit.datatype); } free((uint8_t*)node->node.buf); } void sord_world_free(SordWorld* world) { zix_hash_foreach(world->nodes, free_node_entry, world); zix_hash_free(world->nodes); free(world); } void sord_world_set_error_sink(SordWorld* world, SerdErrorSink error_sink, void* handle) { world->error_sink = error_sink; world->error_handle = handle; } /** Compare nodes, considering NULL a wildcard match. */ static inline int sord_node_compare(const SordNode* a, const SordNode* b) { if (a == b || !a || !b) { return 0; // Exact or wildcard match } else if (a->node.type != b->node.type) { return a->node.type - b->node.type; } int cmp = 0; switch (a->node.type) { case SERD_URI: case SERD_BLANK: return strcmp((const char*)a->node.buf, (const char*)b->node.buf); case SERD_LITERAL: cmp = strcmp((const char*)sord_node_get_string(a), (const char*)sord_node_get_string(b)); if (cmp == 0) { // Note: Can't use sord_node_compare here since it does wildcards if (!a->meta.lit.datatype || !b->meta.lit.datatype) { cmp = a->meta.lit.datatype - b->meta.lit.datatype; } else { cmp = strcmp((const char*)a->meta.lit.datatype->node.buf, (const char*)b->meta.lit.datatype->node.buf); } } if (cmp == 0) { cmp = strcmp(a->meta.lit.lang, b->meta.lit.lang); } default: break; } return cmp; } bool sord_node_equals(const SordNode* a, const SordNode* b) { return a == b; // Nodes are interned } /** Return true iff IDs are equivalent, or one is a wildcard */ static inline bool sord_id_match(const SordNode* a, const SordNode* b) { return !a || !b || (a == b); } static inline bool sord_quad_match_inline(const SordQuad x, const SordQuad y) { return sord_id_match(x[0], y[0]) && sord_id_match(x[1], y[1]) && sord_id_match(x[2], y[2]) && sord_id_match(x[3], y[3]); } bool sord_quad_match(const SordQuad x, const SordQuad y) { return sord_quad_match_inline(x, y); } /** Compare two quad IDs lexicographically. NULL IDs (equal to 0) are treated as wildcards, always less than every other possible ID, except itself. */ static int sord_quad_compare(const void* x_ptr, const void* y_ptr, void* user_data) { const int* const ordering = (const int*)user_data; const SordNode*const*const x = (const SordNode*const*)x_ptr; const SordNode*const*const y = (const SordNode*const*)y_ptr; for (int i = 0; i < TUP_LEN; ++i) { const int idx = ordering[i]; const int cmp = sord_node_compare(x[idx], y[idx]); if (cmp) { return cmp; } } return 0; } static inline bool sord_iter_forward(SordIter* iter) { if (!iter->skip_graphs) { zix_btree_iter_increment(iter->cur); return zix_btree_iter_is_end(iter->cur); } SordNode** key = (SordNode**)zix_btree_get(iter->cur); const SordQuad initial = { key[0], key[1], key[2], key[3] }; zix_btree_iter_increment(iter->cur); while (!zix_btree_iter_is_end(iter->cur)) { key = (SordNode**)zix_btree_get(iter->cur); for (int i = 0; i < 3; ++i) if (key[i] != initial[i]) return false; zix_btree_iter_increment(iter->cur); } return true; } /** Seek forward as necessary until `iter` points at a match. @return true iff iterator reached end of valid range. */ static inline bool sord_iter_seek_match(SordIter* iter) { for (iter->end = true; !zix_btree_iter_is_end(iter->cur); sord_iter_forward(iter)) { const SordNode** const key = (const SordNode**)zix_btree_get(iter->cur); if (sord_quad_match_inline(key, iter->pat)) return (iter->end = false); } return true; } /** Seek forward as necessary until `iter` points at a match, or the prefix no longer matches iter->pat. @return true iff iterator reached end of valid range. */ static inline bool sord_iter_seek_match_range(SordIter* iter) { assert(!iter->end); do { const SordNode** key = (const SordNode**)zix_btree_get(iter->cur); if (sord_quad_match_inline(key, iter->pat)) return false; // Found match for (int i = 0; i < iter->n_prefix; ++i) { const int idx = orderings[iter->order][i]; if (!sord_id_match(key[idx], iter->pat[idx])) { iter->end = true; // Reached end of valid range return true; } } } while (!sord_iter_forward(iter)); return (iter->end = true); // Reached end } static SordIter* sord_iter_new(const SordModel* sord, ZixBTreeIter* cur, const SordQuad pat, SordOrder order, SearchMode mode, int n_prefix) { SordIter* iter = (SordIter*)malloc(sizeof(SordIter)); iter->sord = sord; iter->cur = cur; iter->order = order; iter->mode = mode; iter->n_prefix = n_prefix; iter->end = false; iter->skip_graphs = order < GSPO; for (int i = 0; i < TUP_LEN; ++i) { iter->pat[i] = pat[i]; } switch (iter->mode) { case ALL: case SINGLE: case RANGE: assert( sord_quad_match_inline((const SordNode**)zix_btree_get(iter->cur), iter->pat)); break; case FILTER_RANGE: sord_iter_seek_match_range(iter); break; case FILTER_ALL: sord_iter_seek_match(iter); break; } #ifdef SORD_DEBUG_ITER SordQuad value; sord_iter_get(iter, value); SORD_ITER_LOG("New %p pat=" TUP_FMT " cur=" TUP_FMT " end=%d skip=%d\n", (void*)iter, TUP_FMT_ARGS(pat), TUP_FMT_ARGS(value), iter->end, iter->skip_graphs); #endif ++((SordModel*)sord)->n_iters; return iter; } const SordModel* sord_iter_get_model(SordIter* iter) { return iter->sord; } void sord_iter_get(const SordIter* iter, SordQuad id) { SordNode** key = (SordNode**)zix_btree_get(iter->cur); for (int i = 0; i < TUP_LEN; ++i) { id[i] = key[i]; } } const SordNode* sord_iter_get_node(const SordIter* iter, SordQuadIndex index) { return (!sord_iter_end(iter) ? ((SordNode**)zix_btree_get(iter->cur))[index] : NULL); } static bool sord_iter_scan_next(SordIter* iter) { if (iter->end) { return true; } const SordNode** key; if (!iter->end) { switch (iter->mode) { case ALL: // At the end if the cursor is (assigned above) break; case SINGLE: iter->end = true; SORD_ITER_LOG("%p reached single end\n", (void*)iter); break; case RANGE: SORD_ITER_LOG("%p range next\n", (void*)iter); // At the end if the MSNs no longer match key = (const SordNode**)zix_btree_get(iter->cur); assert(key); for (int i = 0; i < iter->n_prefix; ++i) { const int idx = orderings[iter->order][i]; if (!sord_id_match(key[idx], iter->pat[idx])) { iter->end = true; SORD_ITER_LOG("%p reached non-match end\n", (void*)iter); break; } } break; case FILTER_RANGE: // Seek forward to next match, stopping if prefix changes sord_iter_seek_match_range(iter); break; case FILTER_ALL: // Seek forward to next match sord_iter_seek_match(iter); break; } } else { SORD_ITER_LOG("%p reached index end\n", (void*)iter); } if (iter->end) { SORD_ITER_LOG("%p Reached end\n", (void*)iter); return true; } else { #ifdef SORD_DEBUG_ITER SordQuad tup; sord_iter_get(iter, tup); SORD_ITER_LOG("%p Increment to " TUP_FMT "\n", (void*)iter, TUP_FMT_ARGS(tup)); #endif return false; } } bool sord_iter_next(SordIter* iter) { if (iter->end) { return true; } iter->end = sord_iter_forward(iter); return sord_iter_scan_next(iter); } bool sord_iter_end(const SordIter* iter) { return !iter || iter->end; } void sord_iter_free(SordIter* iter) { SORD_ITER_LOG("%p Free\n", (void*)iter); if (iter) { --((SordModel*)iter->sord)->n_iters; zix_btree_iter_free(iter->cur); free(iter); } } /** Return true iff `sord` has an index for `order`. If `graphs` is true, `order` will be modified to be the corresponding order with a G prepended (so G will be the MSN). */ static inline bool sord_has_index(SordModel* sord, SordOrder* order, int* n_prefix, bool graphs) { if (graphs) { *order = (SordOrder)(*order + GSPO); *n_prefix += 1; } return sord->indices[*order]; } /** Return the best available index for a pattern. @param pat Pattern in standard (S P O G) order @param mode Set to the (best) iteration mode for iterating over results @param n_prefix Set to the length of the range prefix (for `mode` == RANGE and `mode` == FILTER_RANGE) */ static inline SordOrder sord_best_index(SordModel* sord, const SordQuad pat, SearchMode* mode, int* n_prefix) { const bool graph_search = (pat[TUP_G] != 0); const unsigned sig = (pat[0] ? 1 : 0) * 0x100 + (pat[1] ? 1 : 0) * 0x010 + (pat[2] ? 1 : 0) * 0x001; SordOrder good[2] = { (SordOrder)-1, (SordOrder)-1 }; #define PAT_CASE(sig, m, g0, g1, np) \ case sig: \ *mode = m; \ good[0] = g0; \ good[1] = g1; \ *n_prefix = np; \ break // Good orderings that don't require filtering *mode = RANGE; *n_prefix = 0; switch (sig) { case 0x000: assert(graph_search); *mode = RANGE; *n_prefix = 1; return DEFAULT_GRAPH_ORDER; case 0x111: *mode = SINGLE; return graph_search ? DEFAULT_GRAPH_ORDER : DEFAULT_ORDER; PAT_CASE(0x001, RANGE, OPS, OSP, 1); PAT_CASE(0x010, RANGE, POS, PSO, 1); PAT_CASE(0x011, RANGE, OPS, POS, 2); PAT_CASE(0x100, RANGE, SPO, SOP, 1); PAT_CASE(0x101, RANGE, SOP, OSP, 2); PAT_CASE(0x110, RANGE, SPO, PSO, 2); } if (*mode == RANGE) { if (sord_has_index(sord, &good[0], n_prefix, graph_search)) { return good[0]; } else if (sord_has_index(sord, &good[1], n_prefix, graph_search)) { return good[1]; } } // Not so good orderings that require filtering, but can // still be constrained to a range switch (sig) { PAT_CASE(0x011, FILTER_RANGE, OSP, PSO, 1); PAT_CASE(0x101, FILTER_RANGE, SPO, OPS, 1); // SPO is always present, so 0x110 is never reached here default: break; } if (*mode == FILTER_RANGE) { if (sord_has_index(sord, &good[0], n_prefix, graph_search)) { return good[0]; } else if (sord_has_index(sord, &good[1], n_prefix, graph_search)) { return good[1]; } } if (graph_search) { *mode = FILTER_RANGE; *n_prefix = 1; return DEFAULT_GRAPH_ORDER; } else { *mode = FILTER_ALL; return DEFAULT_ORDER; } } SordModel* sord_new(SordWorld* world, unsigned indices, bool graphs) { SordModel* sord = (SordModel*)malloc(sizeof(struct SordModelImpl)); sord->world = world; sord->n_quads = 0; sord->n_iters = 0; for (unsigned i = 0; i < (NUM_ORDERS / 2); ++i) { const int* const ordering = orderings[i]; const int* const g_ordering = orderings[i + (NUM_ORDERS / 2)]; if (indices & (1 << i)) { sord->indices[i] = zix_btree_new( sord_quad_compare, (void*)ordering, NULL); if (graphs) { sord->indices[i + (NUM_ORDERS / 2)] = zix_btree_new( sord_quad_compare, (void*)g_ordering, NULL); } else { sord->indices[i + (NUM_ORDERS / 2)] = NULL; } } else { sord->indices[i] = NULL; sord->indices[i + (NUM_ORDERS / 2)] = NULL; } } if (!sord->indices[DEFAULT_ORDER]) { sord->indices[DEFAULT_ORDER] = zix_btree_new( sord_quad_compare, (void*)orderings[DEFAULT_ORDER], NULL); } if (graphs && !sord->indices[DEFAULT_GRAPH_ORDER]) { sord->indices[DEFAULT_GRAPH_ORDER] = zix_btree_new( sord_quad_compare, (void*)orderings[DEFAULT_GRAPH_ORDER], NULL); } return sord; } static void sord_node_free_internal(SordWorld* world, SordNode* node) { assert(node->refs == 0); // Cache pointer to buffer to free after node removal and destruction const uint8_t* const buf = node->node.buf; // Remove node from hash (which frees the node) if (zix_hash_remove(world->nodes, node)) { error(world, SERD_ERR_INTERNAL, "failed to remove node from hash\n"); } // Free buffer free((uint8_t*)buf); } static void sord_add_quad_ref(SordModel* sord, const SordNode* node, SordQuadIndex i) { if (node) { assert(node->refs > 0); ++((SordNode*)node)->refs; if (node->node.type != SERD_LITERAL && i == SORD_OBJECT) { ++((SordNode*)node)->meta.res.refs_as_obj; } } } static void sord_drop_quad_ref(SordModel* sord, const SordNode* node, SordQuadIndex i) { if (!node) { return; } assert(node->refs > 0); if (node->node.type != SERD_LITERAL && i == SORD_OBJECT) { assert(node->meta.res.refs_as_obj > 0); --((SordNode*)node)->meta.res.refs_as_obj; } if (--((SordNode*)node)->refs == 0) { sord_node_free_internal(sord_get_world(sord), (SordNode*)node); } } void sord_free(SordModel* sord) { if (!sord) return; // Free nodes SordQuad tup; SordIter* i = sord_begin(sord); for (; !sord_iter_end(i); sord_iter_next(i)) { sord_iter_get(i, tup); for (int t = 0; t < TUP_LEN; ++t) { sord_drop_quad_ref(sord, tup[t], (SordQuadIndex)t); } } sord_iter_free(i); // Free quads ZixBTreeIter* t = zix_btree_begin(sord->indices[DEFAULT_ORDER]); for (; !zix_btree_iter_is_end(t); zix_btree_iter_increment(t)) { free(zix_btree_get(t)); } zix_btree_iter_free(t); // Free indices for (unsigned o = 0; o < NUM_ORDERS; ++o) if (sord->indices[o]) zix_btree_free(sord->indices[o]); free(sord); } SordWorld* sord_get_world(SordModel* sord) { return sord->world; } size_t sord_num_quads(const SordModel* sord) { return sord->n_quads; } size_t sord_num_nodes(const SordWorld* world) { return zix_hash_size(world->nodes); } SordIter* sord_begin(const SordModel* sord) { if (sord_num_quads(sord) == 0) { return NULL; } else { ZixBTreeIter* cur = zix_btree_begin(sord->indices[DEFAULT_ORDER]); SordQuad pat = { 0, 0, 0, 0 }; return sord_iter_new(sord, cur, pat, DEFAULT_ORDER, ALL, 0); } } SordIter* sord_find(SordModel* sord, const SordQuad pat) { if (!pat[0] && !pat[1] && !pat[2] && !pat[3]) return sord_begin(sord); SearchMode mode; int n_prefix; const SordOrder index_order = sord_best_index(sord, pat, &mode, &n_prefix); SORD_FIND_LOG("Find " TUP_FMT " index=%s mode=%d n_prefix=%d\n", TUP_FMT_ARGS(pat), order_names[index_order], mode, n_prefix); if (pat[0] && pat[1] && pat[2] && pat[3]) mode = SINGLE; // No duplicate quads (Sord is a set) ZixBTree* const db = sord->indices[index_order]; ZixBTreeIter* cur = NULL; zix_btree_lower_bound(db, pat, &cur); if (zix_btree_iter_is_end(cur)) { SORD_FIND_LOG("No match found\n"); zix_btree_iter_free(cur); return NULL; } const SordNode** const key = (const SordNode**)zix_btree_get(cur); if (!key || ( (mode == RANGE || mode == SINGLE) && !sord_quad_match_inline(pat, key) )) { SORD_FIND_LOG("No match found\n"); zix_btree_iter_free(cur); return NULL; } return sord_iter_new(sord, cur, pat, index_order, mode, n_prefix); } SordIter* sord_search(SordModel* model, const SordNode* s, const SordNode* p, const SordNode* o, const SordNode* g) { SordQuad pat = { s, p, o, g }; return sord_find(model, pat); } SordNode* sord_get(SordModel* model, const SordNode* s, const SordNode* p, const SordNode* o, const SordNode* g) { if ((bool)s + (bool)p + (bool)o != 2) { return NULL; } SordIter* i = sord_search(model, s, p, o, g); SordNode* ret = NULL; if (!s) { ret = sord_node_copy(sord_iter_get_node(i, SORD_SUBJECT)); } else if (!p) { ret = sord_node_copy(sord_iter_get_node(i, SORD_PREDICATE)); } else if (!o) { ret = sord_node_copy(sord_iter_get_node(i, SORD_OBJECT)); } sord_iter_free(i); return ret; } bool sord_ask(SordModel* model, const SordNode* s, const SordNode* p, const SordNode* o, const SordNode* g) { SordQuad pat = { s, p, o, g }; return sord_contains(model, pat); } uint64_t sord_count(SordModel* model, const SordNode* s, const SordNode* p, const SordNode* o, const SordNode* g) { SordIter* i = sord_search(model, s, p, o, g); uint64_t n = 0; for (; !sord_iter_end(i); sord_iter_next(i)) { ++n; } sord_iter_free(i); return n; } bool sord_contains(SordModel* sord, const SordQuad pat) { SordIter* iter = sord_find(sord, pat); bool ret = (iter != NULL); sord_iter_free(iter); return ret; } static uint8_t* sord_strndup(const uint8_t* str, size_t len) { uint8_t* dup = (uint8_t*)malloc(len + 1); memcpy(dup, str, len + 1); return dup; } SordNodeType sord_node_get_type(const SordNode* node) { switch (node->node.type) { case SERD_URI: return SORD_URI; case SERD_BLANK: return SORD_BLANK; default: return SORD_LITERAL; } SORD_UNREACHABLE(); } const uint8_t* sord_node_get_string(const SordNode* node) { return node->node.buf; } const uint8_t* sord_node_get_string_counted(const SordNode* node, size_t* bytes) { *bytes = node->node.n_bytes; return node->node.buf; } const uint8_t* sord_node_get_string_measured(const SordNode* node, size_t* bytes, size_t* chars) { *bytes = node->node.n_bytes; *chars = node->node.n_chars; return node->node.buf; } const char* sord_node_get_language(const SordNode* node) { if (node->node.type != SERD_LITERAL || !node->meta.lit.lang[0]) { return NULL; } return node->meta.lit.lang; } SordNode* sord_node_get_datatype(const SordNode* node) { return (node->node.type == SERD_LITERAL) ? node->meta.lit.datatype : NULL; } SerdNodeFlags sord_node_get_flags(const SordNode* node) { return node->node.flags; } bool sord_node_is_inline_object(const SordNode* node) { return (node->node.type == SERD_BLANK) && (node->meta.res.refs_as_obj == 1); } static SordNode* sord_insert_node(SordWorld* world, const SordNode* key, bool copy) { SordNode* node = NULL; ZixStatus st = zix_hash_insert(world->nodes, key, (const void**)&node); switch (st) { case ZIX_STATUS_EXISTS: ++node->refs; break; case ZIX_STATUS_SUCCESS: assert(node->refs == 1); if (copy) { node->node.buf = sord_strndup(node->node.buf, node->node.n_bytes); } if (node->node.type == SERD_LITERAL) { node->meta.lit.datatype = sord_node_copy(node->meta.lit.datatype); } return node; default: error(world, SERD_ERR_INTERNAL, "error inserting node `%s'\n", key->node.buf); } if (!copy) { // Free the buffer we would have copied if a new node was created free((uint8_t*)key->node.buf); } return node; } static SordNode* sord_new_uri_counted(SordWorld* world, const uint8_t* str, size_t n_bytes, size_t n_chars, bool copy) { if (!serd_uri_string_has_scheme(str)) { error(world, SERD_ERR_BAD_ARG, "attempt to map invalid URI `%s'\n", str); return NULL; // Can't intern relative URIs } const SordNode key = { { str, n_bytes, n_chars, 0, SERD_URI }, 1, { { 0 } } }; return sord_insert_node(world, &key, copy); } SordNode* sord_new_uri(SordWorld* world, const uint8_t* str) { const SerdNode node = serd_node_from_string(SERD_URI, str); return sord_new_uri_counted(world, str, node.n_bytes, node.n_chars, true); } SordNode* sord_new_relative_uri(SordWorld* world, const uint8_t* str, const uint8_t* base_str) { if (serd_uri_string_has_scheme(str)) { return sord_new_uri(world, str); } SerdURI buri = SERD_URI_NULL; SerdNode base = serd_node_new_uri_from_string(base_str, NULL, &buri); SerdNode node = serd_node_new_uri_from_string(str, &buri, NULL); SordNode* ret = sord_new_uri_counted( world, node.buf, node.n_bytes, node.n_chars, false); serd_node_free(&base); return ret; } static SordNode* sord_new_blank_counted(SordWorld* world, const uint8_t* str, size_t n_bytes, size_t n_chars) { const SordNode key = { { str, n_bytes, n_chars, 0, SERD_BLANK }, 1, { { 0 } } }; return sord_insert_node(world, &key, true); } SordNode* sord_new_blank(SordWorld* world, const uint8_t* str) { const SerdNode node = serd_node_from_string(SERD_URI, str); return sord_new_blank_counted(world, str, node.n_bytes, node.n_chars); } static SordNode* sord_new_literal_counted(SordWorld* world, SordNode* datatype, const uint8_t* str, size_t n_bytes, size_t n_chars, SerdNodeFlags flags, const char* lang) { SordNode key = { { str, n_bytes, n_chars, flags, SERD_LITERAL }, 1, { { 0 } } }; key.meta.lit.datatype = sord_node_copy(datatype); memset(key.meta.lit.lang, 0, sizeof(key.meta.lit.lang)); if (lang) { strncpy(key.meta.lit.lang, lang, sizeof(key.meta.lit.lang)); } return sord_insert_node(world, &key, true); } SordNode* sord_new_literal(SordWorld* world, SordNode* datatype, const uint8_t* str, const char* lang) { SerdNodeFlags flags = 0; size_t n_bytes = 0; size_t n_chars = serd_strlen(str, &n_bytes, &flags); return sord_new_literal_counted(world, datatype, str, n_bytes, n_chars, flags, lang); } SordNode* sord_node_from_serd_node(SordWorld* world, SerdEnv* env, const SerdNode* sn, const SerdNode* datatype, const SerdNode* lang) { if (!sn) { return NULL; } SordNode* datatype_node = NULL; SordNode* ret = NULL; switch (sn->type) { case SERD_NOTHING: return NULL; case SERD_LITERAL: datatype_node = sord_node_from_serd_node( world, env, datatype, NULL, NULL), ret = sord_new_literal_counted( world, datatype_node, sn->buf, sn->n_bytes, sn->n_chars, sn->flags, lang ? (const char*)lang->buf : NULL); sord_node_free(world, datatype_node); return ret; case SERD_URI: if (serd_uri_string_has_scheme(sn->buf)) { return sord_new_uri_counted( world, sn->buf, sn->n_bytes, sn->n_chars, true); } else { SerdURI base_uri; serd_env_get_base_uri(env, &base_uri); SerdURI abs_uri; SerdNode abs_uri_node = serd_node_new_uri_from_node( sn, &base_uri, &abs_uri); ret = sord_new_uri_counted(world, abs_uri_node.buf, abs_uri_node.n_bytes, abs_uri_node.n_chars, true); serd_node_free(&abs_uri_node); return ret; } case SERD_CURIE: { SerdChunk uri_prefix; SerdChunk uri_suffix; if (serd_env_expand(env, sn, &uri_prefix, &uri_suffix)) { error(world, SERD_ERR_BAD_CURIE, "failed to expand CURIE `%s'\n", sn->buf); return NULL; } const size_t uri_len = uri_prefix.len + uri_suffix.len; uint8_t* buf = (uint8_t*)malloc(uri_len + 1); memcpy(buf, uri_prefix.buf, uri_prefix.len); memcpy(buf + uri_prefix.len, uri_suffix.buf, uri_suffix.len); buf[uri_len] = '\0'; ret = sord_new_uri_counted( world, buf, uri_len, serd_strlen(buf, NULL, NULL), false); return ret; } case SERD_BLANK: return sord_new_blank_counted(world, sn->buf, sn->n_bytes, sn->n_chars); } return NULL; } const SerdNode* sord_node_to_serd_node(const SordNode* node) { return node ? &node->node : &SERD_NODE_NULL; } void sord_node_free(SordWorld* world, SordNode* node) { if (!node) { return; } else if (node->refs == 0) { error(world, SERD_ERR_BAD_ARG, "attempt to free garbage node\n"); } else if (--node->refs == 0) { sord_node_free_internal(world, node); } } SordNode* sord_node_copy(const SordNode* node) { SordNode* copy = (SordNode*)node; if (copy) { ++copy->refs; } return copy; } static inline bool sord_add_to_index(SordModel* sord, const SordNode** tup, SordOrder order) { return !zix_btree_insert(sord->indices[order], tup); } bool sord_add(SordModel* sord, const SordQuad tup) { SORD_WRITE_LOG("Add " TUP_FMT "\n", TUP_FMT_ARGS(tup)); if (!tup[0] || !tup[1] || !tup[2]) { error(sord->world, SERD_ERR_BAD_ARG, "attempt to add quad with NULL field\n"); return false; } else if (sord->n_iters > 0) { error(sord->world, SERD_ERR_BAD_ARG, "added tuple during iteration\n"); } const SordNode** quad = (const SordNode**)malloc(sizeof(SordQuad)); memcpy(quad, tup, sizeof(SordQuad)); for (unsigned i = 0; i < NUM_ORDERS; ++i) { if (sord->indices[i] && (i < GSPO || tup[3])) { if (!sord_add_to_index(sord, quad, (SordOrder)i)) { assert(i == 0); // Assuming index coherency free(quad); return false; // Quad already stored, do nothing } } } for (int i = 0; i < TUP_LEN; ++i) sord_add_quad_ref(sord, tup[i], (SordQuadIndex)i); ++sord->n_quads; return true; } void sord_remove(SordModel* sord, const SordQuad tup) { SORD_WRITE_LOG("Remove " TUP_FMT "\n", TUP_FMT_ARGS(tup)); if (sord->n_iters > 0) { error(sord->world, SERD_ERR_BAD_ARG, "remove with iterator\n"); } SordNode* quad = NULL; for (unsigned i = 0; i < NUM_ORDERS; ++i) { if (sord->indices[i] && (i < GSPO || tup[3])) { if (zix_btree_remove(sord->indices[i], tup, (void**)&quad, NULL)) { assert(i == 0); // Assuming index coherency return; // Quad not found, do nothing } } } free(quad); for (int i = 0; i < TUP_LEN; ++i) sord_drop_quad_ref(sord, tup[i], (SordQuadIndex)i); --sord->n_quads; } SerdStatus sord_erase(SordModel* sord, SordIter* iter) { if (sord->n_iters > 1) { error(sord->world, SERD_ERR_BAD_ARG, "erased with many iterators\n"); return SERD_ERR_BAD_ARG; } SordQuad tup; sord_iter_get(iter, tup); SORD_WRITE_LOG("Remove " TUP_FMT "\n", TUP_FMT_ARGS(tup)); SordNode* quad = NULL; for (unsigned i = 0; i < NUM_ORDERS; ++i) { if (sord->indices[i]) { if (zix_btree_remove(sord->indices[i], tup, (void**)&quad, i == iter->order ? &iter->cur : NULL)) { return (i == 0) ? SERD_ERR_NOT_FOUND : SERD_ERR_INTERNAL; } } } iter->end = zix_btree_iter_is_end(iter->cur); sord_iter_scan_next(iter); free(quad); for (int i = 0; i < TUP_LEN; ++i) sord_drop_quad_ref(sord, tup[i], (SordQuadIndex)i); --sord->n_quads; return SERD_SUCCESS; }