/*%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % $Date: 2010-06-30 17:05:24 +0200 (Wed, 30 Jun 2010) $ % $Revision: 1 $ % % This file is part of YAP & ProbLog % http://www.dcc.fc.up.pt/~vsc/Yap/index.html % http://dtai.cs.kuleuven.be/problog % % ProbLog was developed at Katholieke Universiteit Leuven & % University of Porto % % Copyright 2010 Katholieke Universiteit Leuven & University of Porto % % Main authors of this file: Mantadelis Theofrastos, Ricardo Rocha % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Artistic License 2.0 % % Copyright (c) 2000-2006, The Perl Foundation. % % Everyone is permitted to copy and distribute verbatim copies of this % license document, but changing it is not allowed. Preamble % % This license establishes the terms under which a given free software % Package may be copied, modified, distributed, and/or % redistributed. The intent is that the Copyright Holder maintains some % artistic control over the development of that Package while still % keeping the Package available as open source and free software. % % You are always permitted to make arrangements wholly outside of this % license directly with the Copyright Holder of a given Package. If the % terms of this license do not permit the full use that you propose to % make of the Package, you should contact the Copyright Holder and seek % a different licensing arrangement. Definitions % % "Copyright Holder" means the individual(s) or organization(s) named in % the copyright notice for the entire Package. % % "Contributor" means any party that has contributed code or other % material to the Package, in accordance with the Copyright Holder's % procedures. % % "You" and "your" means any person who would like to copy, distribute, % or modify the Package. % % "Package" means the collection of files distributed by the Copyright % Holder, and derivatives of that collection and/or of those files. A % given Package may consist of either the Standard Version, or a % Modified Version. % % "Distribute" means providing a copy of the Package or making it % accessible to anyone else, or in the case of a company or % organization, to others outside of your company or organization. % % "Distributor Fee" means any fee that you charge for Distributing this % Package or providing support for this Package to another party. It % does not mean licensing fees. % % "Standard Version" refers to the Package if it has not been modified, % or has been modified only in ways explicitly requested by the % Copyright Holder. % % "Modified Version" means the Package, if it has been changed, and such % changes were not explicitly requested by the Copyright Holder. % % "Original License" means this Artistic License as Distributed with the % Standard Version of the Package, in its current version or as it may % be modified by The Perl Foundation in the future. % % "Source" form means the source code, documentation source, and % configuration files for the Package. % % "Compiled" form means the compiled bytecode, object code, binary, or % any other form resulting from mechanical transformation or translation % of the Source form. % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Permission for Use and Modification Without Distribution % % (1) You are permitted to use the Standard Version and create and use % Modified Versions for any purpose without restriction, provided that % you do not Distribute the Modified Version. % % Permissions for Redistribution of the Standard Version % % (2) You may Distribute verbatim copies of the Source form of the % Standard Version of this Package in any medium without restriction, % either gratis or for a Distributor Fee, provided that you duplicate % all of the original copyright notices and associated disclaimers. At % your discretion, such verbatim copies may or may not include a % Compiled form of the Package. % % (3) You may apply any bug fixes, portability changes, and other % modifications made available from the Copyright Holder. The resulting % Package will still be considered the Standard Version, and as such % will be subject to the Original License. % % Distribution of Modified Versions of the Package as Source % % (4) You may Distribute your Modified Version as Source (either gratis % or for a Distributor Fee, and with or without a Compiled form of the % Modified Version) provided that you clearly document how it differs % from the Standard Version, including, but not limited to, documenting % any non-standard features, executables, or modules, and provided that % you do at least ONE of the following: % % (a) make the Modified Version available to the Copyright Holder of the % Standard Version, under the Original License, so that the Copyright % Holder may include your modifications in the Standard Version. (b) % ensure that installation of your Modified Version does not prevent the % user installing or running the Standard Version. In addition, the % modified Version must bear a name that is different from the name of % the Standard Version. (c) allow anyone who receives a copy of the % Modified Version to make the Source form of the Modified Version % available to others under (i) the Original License or (ii) a license % that permits the licensee to freely copy, modify and redistribute the % Modified Version using the same licensing terms that apply to the copy % that the licensee received, and requires that the Source form of the % Modified Version, and of any works derived from it, be made freely % available in that license fees are prohibited but Distributor Fees are % allowed. % % Distribution of Compiled Forms of the Standard Version or % Modified Versions without the Source % % (5) You may Distribute Compiled forms of the Standard Version without % the Source, provided that you include complete instructions on how to % get the Source of the Standard Version. Such instructions must be % valid at the time of your distribution. If these instructions, at any % time while you are carrying out such distribution, become invalid, you % must provide new instructions on demand or cease further % distribution. If you provide valid instructions or cease distribution % within thirty days after you become aware that the instructions are % invalid, then you do not forfeit any of your rights under this % license. % % (6) You may Distribute a Modified Version in Compiled form without the % Source, provided that you comply with Section 4 with respect to the % Source of the Modified Version. % % Aggregating or Linking the Package % % (7) You may aggregate the Package (either the Standard Version or % Modified Version) with other packages and Distribute the resulting % aggregation provided that you do not charge a licensing fee for the % Package. Distributor Fees are permitted, and licensing fees for other % components in the aggregation are permitted. The terms of this license % apply to the use and Distribution of the Standard or Modified Versions % as included in the aggregation. % % (8) You are permitted to link Modified and Standard Versions with % other works, to embed the Package in a larger work of your own, or to % build stand-alone binary or bytecode versions of applications that % include the Package, and Distribute the result without restriction, % provided the result does not expose a direct interface to the Package. % % Items That are Not Considered Part of a Modified Version % % (9) Works (including, but not limited to, modules and scripts) that % merely extend or make use of the Package, do not, by themselves, cause % the Package to be a Modified Version. In addition, such works are not % considered parts of the Package itself, and are not subject to the % terms of this license. % % General Provisions % % (10) Any use, modification, and distribution of the Standard or % Modified Versions is governed by this Artistic License. By using, % modifying or distributing the Package, you accept this license. Do not % use, modify, or distribute the Package, if you do not accept this % license. % % (11) If your Modified Version has been derived from a Modified Version % made by someone other than you, you are nevertheless required to % ensure that your Modified Version complies with the requirements of % this license. % % (12) This license does not grant you the right to use any trademark, % service mark, tradename, or logo of the Copyright Holder. % % (13) This license includes the non-exclusive, worldwide, % free-of-charge patent license to make, have made, use, offer to sell, % sell, import and otherwise transfer the Package with respect to any % patent claims licensable by the Copyright Holder that are necessarily % infringed by the Package. If you institute patent litigation % (including a cross-claim or counterclaim) against any party alleging % that the Package constitutes direct or contributory patent % infringement, then this Artistic License to you shall terminate on the % date that such litigation is filed. % % (14) Disclaimer of Warranty: THE PACKAGE IS PROVIDED BY THE COPYRIGHT % HOLDER AND CONTRIBUTORS "AS IS' AND WITHOUT ANY EXPRESS OR IMPLIED % WARRANTIES. THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A % PARTICULAR PURPOSE, OR NON-INFRINGEMENT ARE DISCLAIMED TO THE EXTENT % PERMITTED BY YOUR LOCAL LAW. UNLESS REQUIRED BY LAW, NO COPYRIGHT % HOLDER OR CONTRIBUTOR WILL BE LIABLE FOR ANY DIRECT, INDIRECT, % INCIDENTAL, OR CONSEQUENTIAL DAMAGES ARISING IN ANY WAY OUT OF THE USE % OF THE PACKAGE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%*/ /* -------------------------- */ /* Local Procedures */ /* -------------------------- */ inline void displaynode(TrNode node); inline int traverse_get_counter(TrNode node); inline YAP_Term generate_label(YAP_Int Index); inline YAP_Term update_depth_breadth_trie(TrEngine engine, TrNode root, YAP_Int opt_level, void (*construct_function)(TrNode), void (*destruct_function)(TrNode), void (*copy_function)(TrNode, TrNode), void (*correct_order_function)(void)); inline YAP_Term get_return_node_term(TrNode node); inline void traverse_and_replace_nested_trie(TrNode node, YAP_Int nested_trie_id, YAP_Term new_term); inline TrNode replace_nested_trie(TrNode node, TrNode child, YAP_Term new_term); /* -------------------------- */ /* Local Variables */ /* -------------------------- */ static YAP_Int LABEL_COUNTER; static YAP_Term TRIE_DEPTH_BREADTH_RETURN_TERM; static YAP_Int TRIE_DEPTH_BREADTH_MIN_PREFIX = 2; static YAP_Int TRIE_DEPTH_BREADTH_OPT_COUNT[3]; /* -------------------------- */ /* depth-breadth Trie */ /* -------------------------- */ inline YAP_Int core_get_trie_db_opt_min_prefix(void) { return TRIE_DEPTH_BREADTH_MIN_PREFIX; } inline void core_set_trie_db_opt_min_prefix(YAP_Int min_prefix) { TRIE_DEPTH_BREADTH_MIN_PREFIX = min_prefix; return; } inline void core_depth_breadth_trie_replace_nested_trie(TrNode node, YAP_Int nested_trie_id, YAP_Term new_term) { traverse_and_replace_nested_trie(node, nested_trie_id, new_term); return; } inline void displaynode(TrNode node) { if (node != NULL) { /* printf("hi\n"); if (IS_HASH_NODE(node)) {printf("1\n");} else {printf("2\n");} printf("bye\n");*/ if (IS_HASH_NODE(node)) printf("HASH n%i, b%i, p%li\n", TrHash_num_nodes((TrHash) node), TrHash_num_buckets((TrHash) node), (long) node); else if (TrNode_entry(node) == PairInitTag) printf("PairInitTag\n"); else if (TrNode_entry(node) == PairEndTag) printf("PairEndTag\n"); else if (IS_FUNCTOR_NODE(node)) {printf("2\n"); printf("FUNCTOR %s\n", YAP_AtomName(YAP_NameOfFunctor((YAP_Functor)( ~ApplTag & TrNode_entry(node)))));} else if (YAP_IsIntTerm(TrNode_entry(node))) {printf("3\n"); printf("%ld\n", YAP_IntOfTerm(TrNode_entry(node)));} else if (YAP_IsAtomTerm(TrNode_entry(node))) {printf("4\n"); printf("%s\n", YAP_AtomName(YAP_AtomOfTerm(TrNode_entry(node))));} else printf("What?\n"); } else printf("null\n"); return; } inline void traverse_and_replace_nested_trie(TrNode node, YAP_Int nested_trie_id, YAP_Term new_term) { TrNode child, temp; if (TrNode_entry(node) == PairEndTag) { if (TrNode_next(node)) traverse_and_replace_nested_trie(TrNode_next(node), nested_trie_id, new_term); return; } else if (IS_HASH_NODE(node)) { abort(); TrNode *first_bucket, *bucket; TrHash hash = (TrHash) node; first_bucket = TrHash_buckets(hash); bucket = first_bucket + TrHash_num_buckets(hash); do { if ((node = *--bucket)) { do { traverse_and_replace_nested_trie(node, nested_trie_id, new_term); node = TrNode_next(node); } while(node); } } while (bucket != first_bucket); } else { if (IS_FUNCTOR_NODE(node)) { YAP_Functor f = (YAP_Functor) (~ApplTag & TrNode_entry(node)); YAP_Int arity = YAP_ArityOfFunctor(f); if (arity == 1 && strcmp(YAP_AtomName(YAP_NameOfFunctor(f)), NESTED_TRIE_TERM) == 0) { child = TrNode_child(node); if (IS_HASH_NODE(child)) { abort(); TrNode *first_bucket, *bucket; TrHash hash = (TrHash) child; first_bucket = TrHash_buckets(hash); bucket = first_bucket + TrHash_num_buckets(hash); do { if ((child = *--bucket)) { do { if (YAP_IntOfTerm(TrNode_entry(child)) == nested_trie_id) { temp = TrNode_previous(node); node = replace_nested_trie(node, child, new_term); if (temp) { temp = TrNode_next(node); if (temp) node = temp; } else { traverse_and_replace_nested_trie(TrNode_child(node), nested_trie_id, new_term); return; } } child = TrNode_next(child); } while(child); } } while (bucket != first_bucket); } else { do { if (YAP_IntOfTerm(TrNode_entry(child)) == nested_trie_id) { temp = TrNode_next(node); node = replace_nested_trie(node, child, new_term); traverse_and_replace_nested_trie(TrNode_child(node), nested_trie_id, new_term); if(temp) traverse_and_replace_nested_trie(temp, nested_trie_id, new_term); return; } child = TrNode_next(child); } while(child); } } } traverse_and_replace_nested_trie(TrNode_child(node), nested_trie_id, new_term); if (TrNode_next(node)) traverse_and_replace_nested_trie(TrNode_next(node), nested_trie_id, new_term); } return; } /* fixmeeee */ inline TrNode replace_nested_trie(TrNode node, TrNode child, YAP_Term new_term) { TrNode newnode, temp, newnodef = NULL; if (YAP_IsApplTerm(new_term)) { YAP_Term new_term_functor = ApplTag | ((YAP_Term) YAP_FunctorOfTerm(new_term)); YAP_Int arity = YAP_ArityOfFunctor(YAP_FunctorOfTerm(new_term)); if (arity != 1) abort(); YAP_Term new_term_arg = YAP_ArgOfTerm(1, new_term); temp = TrNode_child(TrNode_parent(node)); while (temp) { if (TrNode_entry(temp) == new_term_functor) { printf("Warning - non tested code, please report the example to Theo to test it!\n"); newnodef = temp; temp = NULL; } else { temp = TrNode_next(temp); } } if (newnodef == NULL) { new_trie_node(newnodef, new_term_functor, TrNode_parent(node), NULL, TrNode_child(TrNode_parent(node)), NULL); TrNode_previous(TrNode_child(TrNode_parent(node))) = newnodef; TrNode_child(TrNode_parent(node)) = newnodef; } new_trie_node(newnode, new_term_arg, newnodef, TrNode_child(child), TrNode_child(newnodef), NULL); if (TrNode_child(newnodef)) TrNode_previous(TrNode_child(newnodef)) = newnode; TrNode_child(newnodef) = newnode; } else { new_trie_node(newnode, new_term, TrNode_parent(node), TrNode_child(child), TrNode_child(TrNode_parent(node)), NULL); TrNode_previous(TrNode_child(TrNode_parent(node))) = newnode; TrNode_child(TrNode_parent(node)) = newnode; } temp = TrNode_child(child); if (IS_HASH_NODE(temp)) { abort(); TrNode *first_bucket, *bucket; TrHash hash = (TrHash) temp; first_bucket = TrHash_buckets(hash); bucket = first_bucket + TrHash_num_buckets(hash); do { if ((temp = *--bucket)) { do { TrNode_parent(temp) = newnode; temp = TrNode_next(temp); } while(temp); } } while (bucket != first_bucket); } else { while (temp) { TrNode_parent(temp) = newnode; temp = TrNode_next(temp); } } TrNode_child(child) = NULL; remove_entry(child); return newnode; } inline YAP_Term core_get_trie_db_return_term(void) { return TRIE_DEPTH_BREADTH_RETURN_TERM; } inline void core_set_trie_db_return_term(YAP_Term return_value){ TRIE_DEPTH_BREADTH_RETURN_TERM = return_value; return; } inline void core_set_label_counter(YAP_Int value) { LABEL_COUNTER = value; // Initialize the counter return; } inline YAP_Int core_get_label_counter(void) { return LABEL_COUNTER; } inline void core_initialize_depth_breadth_trie(TrNode node, TrNode *depth_node, TrNode *breadth_node) { TrNode root = node; YAP_Functor f; f = YAP_MkFunctor(YAP_LookupAtom("depth"),2); node = trie_node_check_insert(root, ApplTag | ((YAP_Term) f)); *depth_node = trie_node_check_insert(node, PairInitTag); f = YAP_MkFunctor(YAP_LookupAtom("breadth"),2); node = trie_node_check_insert(root, ApplTag | ((YAP_Term) f)); *breadth_node = trie_node_check_insert(node, PairInitTag); TRIE_DEPTH_BREADTH_OPT_COUNT[0] = 0; TRIE_DEPTH_BREADTH_OPT_COUNT[1] = 0; TRIE_DEPTH_BREADTH_OPT_COUNT[2] = 0; return; } inline void core_finalize_depth_breadth_trie(TrNode depth_node, TrNode breadth_node) { depth_node = trie_node_check_insert(depth_node, YAP_MkIntTerm(1)); depth_node = trie_node_check_insert(depth_node, PairEndTag); depth_node = trie_node_check_insert(depth_node, YAP_MkIntTerm(1)); remove_entry(depth_node); breadth_node = trie_node_check_insert(breadth_node, YAP_MkIntTerm(1)); breadth_node = trie_node_check_insert(breadth_node, PairEndTag); breadth_node = trie_node_check_insert(breadth_node, YAP_MkIntTerm(1)); remove_entry(breadth_node); return; } inline TrNode core_depth_reduction(TrEngine engine, TrNode node, TrNode depth_node, YAP_Int opt_level, void (*construct_function)(TrNode), void (*destruct_function)(TrNode), void (*copy_function)(TrNode, TrNode), void (*correct_order_function)(void)) { TrNode leaf = node; YAP_Term t, *stack_top; int count = -1; /* collect depth nodes */ stack_args_base = stack_args = AUXILIARY_TERM_STACK; stack_top = AUXILIARY_TERM_STACK + CURRENT_AUXILIARY_TERM_STACK_SIZE - 1; do { node = TrNode_parent(node); if (TrNode_entry(node) == PairInitTag) { node = TrNode_child(node); break; } //Nested Trie code if (IS_FUNCTOR_NODE(TrNode_parent(node)) && (strcmp(YAP_AtomName(YAP_NameOfFunctor((YAP_Functor)(~ApplTag & TrNode_entry(TrNode_parent(node))))), NESTED_TRIE_TERM) == 0)) { /* nested trie: stop procedure and return nested trie node */ return node; } PUSH_DOWN(stack_args, TrNode_entry(node), stack_top); if (!IS_FUNCTOR_NODE(node)) count++; } while (TrNode_next(node) == NULL && TrNode_child(TrNode_parent(node)) == node); if (!count) return NULL; while (IS_FUNCTOR_NODE(TrNode_parent(node))) { node = TrNode_parent(node); PUSH_DOWN(stack_args, TrNode_entry(node), stack_top); } TrNode temp = TrNode_child(TrNode_parent(node)); if (IS_HASH_NODE(temp)) { TrNode *first_bucket, *bucket; TrHash hash = (TrHash) temp; first_bucket = TrHash_buckets(hash); bucket = first_bucket + TrHash_num_buckets(hash); do { if ((temp = *--bucket)) { while(TrNode_next(temp) != NULL) { if (TrNode_entry(temp) == PairEndTag) return NULL; temp = TrNode_next(temp); } } } while (bucket != first_bucket); } else { while(TrNode_next(temp) != NULL) { if (TrNode_entry(temp) == PairEndTag) return NULL; temp = TrNode_next(temp); } } t = update_depth_breadth_trie(engine, depth_node, opt_level, construct_function, destruct_function, copy_function, correct_order_function); /* do depth reduction */ DATA_DESTRUCT_FUNCTION = destruct_function; node = trie_node_check_insert(TrNode_parent(node), t); node = trie_node_check_insert(node, PairEndTag); INCREMENT_ENTRIES(CURRENT_TRIE_ENGINE); temp = TrNode_parent(leaf); remove_child_nodes(TrNode_child(temp)); remove_entry(temp); return node; } inline TrNode core_breadth_reduction(TrEngine engine, TrNode node, TrNode breadth_node, YAP_Int opt_level, void (*construct_function)(TrNode), void (*destruct_function)(TrNode), void (*copy_function)(TrNode, TrNode), void (*correct_order_function)(void)) { YAP_Term t, *stack_top; int count = -1; TrNode child; /* collect breadth nodes */ stack_args_base = stack_args = AUXILIARY_TERM_STACK; stack_top = AUXILIARY_TERM_STACK + CURRENT_AUXILIARY_TERM_STACK_SIZE - 1; node = TrNode_parent(TrNode_parent(node)); // printf("1\n"); // printf("start node: "); displaynode(node); if (IS_FUNCTOR_NODE(node)) { // printf("2\n"); while(IS_FUNCTOR_NODE(node)) node = TrNode_parent(node); child = TrNode_child(node); while((TrNode_next(child) == NULL) && (TrNode_child(TrNode_parent(child)) == child) && (TrNode_entry(TrNode_child(child)) != PairEndTag)) child = TrNode_child(child); } else child = TrNode_child(node); /* printf("start node: "); displaynode(child);*/ if (IS_HASH_NODE(child)) { printf("warning\n"); TrNode *first_bucket, *bucket; TrHash hash = (TrHash) child; first_bucket = TrHash_buckets(hash); bucket = first_bucket + TrHash_num_buckets(hash); do { if ((child = *--bucket)) { do { if (TrNode_entry(child) == PairEndTag) return core_breadth_reduction(engine, child, breadth_node, opt_level, construct_function, destruct_function, copy_function, correct_order_function); while (IS_FUNCTOR_NODE(child)) { child = TrNode_child(child); if (IS_HASH_NODE(child)) { // gets first child in the hash TrNode *first_bucket2, *bucket2; TrHash hash2 = (TrHash) child; first_bucket2 = TrHash_buckets(hash2); bucket2 = first_bucket2 + TrHash_num_buckets(hash2); while(!(child = *--bucket2)); } } TrNode temp = TrNode_child(child); if (IS_HASH_NODE(temp)) { TrNode *first_bucket2, *bucket2; TrHash hash2 = (TrHash) temp; first_bucket2 = TrHash_buckets(hash2); bucket2 = first_bucket2 + TrHash_num_buckets(hash2); do { if ((temp = *--bucket2)) { while((temp != NULL) && (TrNode_entry(temp) != PairEndTag)) temp = TrNode_next(temp); } } while (bucket2 != first_bucket2 && temp == NULL); } else { while((temp != NULL) && (TrNode_entry(temp) != PairEndTag)) temp = TrNode_next(temp); } if (temp == NULL) return NULL; //Nested Trie code if (IS_FUNCTOR_NODE(TrNode_parent(child)) && (strcmp(YAP_AtomName(YAP_NameOfFunctor((YAP_Functor)(~ApplTag & TrNode_entry(TrNode_parent(child))))), NESTED_TRIE_TERM) == 0)) { /* nested trie: stop procedure and return nested trie node */ return child; } PUSH_DOWN(stack_args, TrNode_entry(child), stack_top); count++; if (IS_FUNCTOR_NODE(TrNode_parent(child))) { temp = TrNode_parent(child); while (IS_FUNCTOR_NODE(temp)) { PUSH_DOWN(stack_args, TrNode_entry(temp), stack_top); temp = TrNode_parent(temp); } while ((TrNode_next(child) == NULL) && IS_FUNCTOR_NODE(TrNode_parent(child)) && (bucket == first_bucket)) child = TrNode_parent(child); } child = TrNode_next(child); } while (child); } } while (bucket != first_bucket); } else { do { if (TrNode_entry(child) == PairEndTag) return core_breadth_reduction(engine, child, breadth_node, opt_level, construct_function, destruct_function, copy_function, correct_order_function); while (IS_FUNCTOR_NODE(child)) { child = TrNode_child(child); if (IS_HASH_NODE(child)) { // gets first child in the hash TrNode *first_bucket, *bucket; TrHash hash = (TrHash) child; first_bucket = TrHash_buckets(hash); bucket = first_bucket + TrHash_num_buckets(hash); while(!(child = *--bucket)); } } TrNode temp = TrNode_child(child); if (IS_HASH_NODE(temp)) { TrNode *first_bucket, *bucket; TrHash hash = (TrHash) temp; first_bucket = TrHash_buckets(hash); bucket = first_bucket + TrHash_num_buckets(hash); do { if ((temp = *--bucket)) { while((temp != NULL) && (TrNode_entry(temp) != PairEndTag)) { temp = TrNode_next(temp); } } } while (bucket != first_bucket && temp == NULL); } else { while((temp != NULL) && (TrNode_entry(temp) != PairEndTag)) temp = TrNode_next(temp); } if (temp == NULL) return NULL; //Nested Trie code if (IS_FUNCTOR_NODE(TrNode_parent(child)) && (strcmp(YAP_AtomName(YAP_NameOfFunctor((YAP_Functor)(~ApplTag & TrNode_entry(TrNode_parent(child))))), NESTED_TRIE_TERM) == 0)) { /* nested trie: stop procedure and return nested trie node */ return child; } PUSH_DOWN(stack_args, TrNode_entry(child), stack_top); count++; if (IS_FUNCTOR_NODE(TrNode_parent(child))) { temp = TrNode_parent(child); while (IS_FUNCTOR_NODE(temp)) { PUSH_DOWN(stack_args, TrNode_entry(temp), stack_top); temp = TrNode_parent(temp); } while ((TrNode_next(child) == NULL) && IS_FUNCTOR_NODE(TrNode_parent(child))) child = TrNode_parent(child); } child = TrNode_next(child); } while (child); // printf("pass through\n"); } if (!count) { /* termination condition */ core_set_trie_db_return_term(get_return_node_term(TrNode_child(node))); node = TrNode_parent(node); remove_child_nodes(TrNode_child(node)); TrNode_child(node) = NULL; return NULL; } t = update_depth_breadth_trie(engine, breadth_node, opt_level, construct_function, destruct_function, copy_function, correct_order_function); /* do breadth reduction */ DATA_DESTRUCT_FUNCTION = destruct_function; remove_child_nodes(TrNode_child(node)); TrNode_child(node) = NULL; node = trie_node_check_insert(node, t); node = trie_node_check_insert(node, PairEndTag); INCREMENT_ENTRIES(CURRENT_TRIE_ENGINE); // printf("end node: "); displaynode(node); return node; } inline YAP_Term get_return_node_term(TrNode node) { YAP_Term args[1], t; if (IS_HASH_NODE(node)) { TrNode *first_bucket, *bucket; TrHash hash = (TrHash) node; first_bucket = TrHash_buckets(hash); bucket = first_bucket + TrHash_num_buckets(hash); while(!(node = *--bucket)); t = TrNode_entry(node); } else if (IS_FUNCTOR_NODE(node)) { args[0] = get_return_node_term(TrNode_child(node)); t = YAP_MkApplTerm((YAP_Functor)(~ApplTag & TrNode_entry(node)), 1, args); } else { t = TrNode_entry(node); } return t; } inline int traverse_get_counter(TrNode node) { int count = -1; while (TrNode_entry(node) != PairEndTag) { if (!IS_FUNCTOR_NODE(node)) count++; node = TrNode_child(node); if (IS_HASH_NODE(node)) { TrNode *first_bucket, *bucket; TrHash hash = (TrHash) node; first_bucket = TrHash_buckets(hash); bucket = first_bucket + TrHash_num_buckets(hash); do { if ((node = *--bucket)) { while(TrNode_next(node) != NULL) node = TrNode_next(node); } } while (bucket != first_bucket); } else { while(TrNode_next(node) != NULL) node = TrNode_next(node); } } return atoi(YAP_AtomName(YAP_AtomOfTerm(TrNode_entry(TrNode_child(node)))) + 1) - count; } inline YAP_Term generate_label(YAP_Int Index) { char label[20]; sprintf(label,"L%ld", Index); return YAP_MkAtomTerm(YAP_LookupAtom(label)); } inline YAP_Term update_depth_breadth_trie(TrEngine engine, TrNode root, YAP_Int opt_level, void (*construct_function)(TrNode), void (*destruct_function)(TrNode), void (*copy_function)(TrNode, TrNode), void (*correct_order_function)(void)) { TrNode node = root, remember = NULL; int count = -1, cnt = -1, c_cnt = 0, f_cnt = 0; YAP_Int BAK_CURRENT_TRIE_MODE = CURRENT_TRIE_MODE; YAP_Term t, tt, ret_t = PairEndTag; if (opt_level > 0) CURRENT_TRIE_MODE = TRIE_MODE_MINIMAL; else CURRENT_TRIE_MODE = TRIE_MODE_STANDARD; CURRENT_TRIE_ENGINE = engine; DATA_DESTRUCT_FUNCTION = destruct_function; DATA_COPY_FUNCTION = copy_function; do { t = POP_UP(stack_args); node = trie_node_check_insert(node, t); if (!IS_FUNCTOR_NODE(node)) count++; if (opt_level > 0) { // Optimization 1: when asserting a non-minimal you can reuse minimal. if (TrNode_entry(node) == PairEndTag) { // Check to find the longest re-usage TrNode c_node = trie_node_check(TrNode_parent(node), t), end_node; c_cnt = 0; f_cnt = 0; while (c_node != NULL) { if (stack_args_base != stack_args) { c_cnt++; tt = POP_UP(stack_args); end_node = trie_node_check(c_node, PairEndTag); c_node = trie_node_check(c_node, tt); if ((c_node!= NULL) && !IS_FUNCTOR_NODE(c_node)) f_cnt++; if ((end_node != NULL)) { count += f_cnt; f_cnt = 0; c_cnt = 0; t = tt; node = end_node; } } else { // reached the end node = c_node; c_node = NULL; count += f_cnt; f_cnt = 0; c_cnt = 0; } } stack_args += c_cnt; } if (TrNode_entry(node) == PairEndTag) { if (count > TRIE_DEPTH_BREADTH_MIN_PREFIX - 2) { TRIE_DEPTH_BREADTH_OPT_COUNT[0]++; cnt = -1; // reset optimization 3 counter count = 0; node = trie_node_check_insert(root, TrNode_entry(TrNode_child(node))); if (TrNode_child(node) != NULL) cnt++; node = trie_node_check_insert(node, t); if (!IS_FUNCTOR_NODE(node)) { count++; if (TrNode_child(node) != NULL) cnt++; } } else { CURRENT_TRIE_MODE = TRIE_MODE_STANDARD; node = trie_node_check_insert(TrNode_parent(node), t); CURRENT_TRIE_MODE = TRIE_MODE_MINIMAL; } } } if (opt_level > 2) { // Optimization 3: when asserting common prefix of size 2 or longer. // 1) remember last node and count // 2) after normal assertion ends go to remembered node, count // 3) assert PairEndTag to triger optimization 2 if (TrNode_child(node) != NULL) { if (!IS_FUNCTOR_NODE(node)) cnt++; } else { if ((remember == NULL) && (cnt > 0) && (cnt > TRIE_DEPTH_BREADTH_MIN_PREFIX - 2)) { TRIE_DEPTH_BREADTH_OPT_COUNT[1]--; TRIE_DEPTH_BREADTH_OPT_COUNT[2]++; remember = node; do { remember = TrNode_parent(remember); } while(IS_FUNCTOR_NODE(remember)); } } } } while (stack_args_base != stack_args); do { t = PairEndTag; if (opt_level > 1) { // Optimization 2: when asserting a more minimal you can reuse it // a) Traverse and find the lowest L and the length of branch LN = (L? - (length - 1) + count) // b) insert LN // c) copy childs of node // d) remove childs of node // e) insert ] // f) insert LN // g) REORDER Entries if ((TrNode_child(node) != NULL) && (TrNode_entry(TrNode_child(node)) != PairEndTag) && (count > TRIE_DEPTH_BREADTH_MIN_PREFIX - 2)) { TRIE_DEPTH_BREADTH_OPT_COUNT[1]++; t = generate_label(traverse_get_counter(node)); root = trie_node_check_insert(root, t); TrNode_child(root) = copy_child_nodes(root, TrNode_child(node)); remove_child_nodes(TrNode_child(node)); TrNode_child(node) = NULL; } } node = trie_node_check_insert(node, PairEndTag); if (t == PairEndTag) { if (TrNode_child(node)) { t = TrNode_entry(TrNode_child(node)); } else { LABEL_COUNTER += count; t = generate_label(LABEL_COUNTER); node = trie_node_check_insert(node, t); INCREMENT_ENTRIES(CURRENT_TRIE_ENGINE); (*construct_function)(node); } } else { node = trie_node_check_insert(node, t); INCREMENT_ENTRIES(CURRENT_TRIE_ENGINE); (*construct_function)(node); (*correct_order_function)(); } // Optimization 3: part 2 node = remember; count = cnt; remember = NULL; if (ret_t == PairEndTag) ret_t = t; } while(node != NULL); CURRENT_TRIE_MODE = BAK_CURRENT_TRIE_MODE; return ret_t; } inline YAP_Int core_db_trie_get_optimization_level_count(YAP_Int opt_level) { return TRIE_DEPTH_BREADTH_OPT_COUNT[opt_level - 1]; }