/*------------------------------------------------------------------------ * * geqo_main.c * solution to the query optimization problem * by means of a Genetic Algorithm (GA) * * Portions Copyright (c) 1996-2021, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * src/backend/optimizer/geqo/geqo_main.c * *------------------------------------------------------------------------- */ /* contributed by: =*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*= * Martin Utesch * Institute of Automatic Control * = = University of Mining and Technology = * utesch@aut.tu-freiberg.de * Freiberg, Germany * =*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*=*= */ /* -- parts of this are adapted from D. Whitley's Genitor algorithm -- */ #include "postgres.h" #include #include "optimizer/geqo_misc.h" #include "optimizer/geqo_mutation.h" #include "optimizer/geqo_pool.h" #include "optimizer/geqo_random.h" #include "optimizer/geqo_selection.h" /* * Configuration options */ int Geqo_effort; int Geqo_pool_size; int Geqo_generations; double Geqo_selection_bias; double Geqo_seed; static int gimme_pool_size(int nr_rel); static int gimme_number_generations(int pool_size); /* complain if no recombination mechanism is #define'd */ #if !defined(ERX) && \ !defined(PMX) && \ !defined(CX) && \ !defined(PX) && \ !defined(OX1) && \ !defined(OX2) #error "must choose one GEQO recombination mechanism in geqo.h" #endif /* * geqo * solution of the query optimization problem * similar to a constrained Traveling Salesman Problem (TSP) */ RelOptInfo * geqo(PlannerInfo *root, int number_of_rels, List *initial_rels) { GeqoPrivateData private; int generation; Chromosome *momma; Chromosome *daddy; Chromosome *kid; Pool *pool; int pool_size, number_generations; #ifdef GEQO_DEBUG int status_interval; #endif Gene *best_tour; RelOptInfo *best_rel; #if defined(ERX) Edge *edge_table; /* list of edges */ int edge_failures = 0; #endif #if defined(CX) || defined(PX) || defined(OX1) || defined(OX2) City *city_table; /* list of cities */ #endif #if defined(CX) int cycle_diffs = 0; int mutations = 0; #endif /* set up private information */ root->join_search_private = (void *) &private; private.initial_rels = initial_rels; /* initialize private number generator */ geqo_set_seed(root, Geqo_seed); /* set GA parameters */ pool_size = gimme_pool_size(number_of_rels); number_generations = gimme_number_generations(pool_size); #ifdef GEQO_DEBUG status_interval = 10; #endif /* allocate genetic pool memory */ pool = alloc_pool(root, pool_size, number_of_rels); /* random initialization of the pool */ random_init_pool(root, pool); /* sort the pool according to cheapest path as fitness */ sort_pool(root, pool); /* we have to do it only one time, since all * kids replace the worst individuals in * future (-> geqo_pool.c:spread_chromo ) */ #ifdef GEQO_DEBUG elog(DEBUG1, "GEQO selected %d pool entries, best %.2f, worst %.2f", pool_size, pool->data[0].worth, pool->data[pool_size - 1].worth); #endif /* allocate chromosome momma and daddy memory */ momma = alloc_chromo(root, pool->string_length); daddy = alloc_chromo(root, pool->string_length); #if defined (ERX) #ifdef GEQO_DEBUG elog(DEBUG2, "using edge recombination crossover [ERX]"); #endif /* allocate edge table memory */ edge_table = alloc_edge_table(root, pool->string_length); #elif defined(PMX) #ifdef GEQO_DEBUG elog(DEBUG2, "using partially matched crossover [PMX]"); #endif /* allocate chromosome kid memory */ kid = alloc_chromo(root, pool->string_length); #elif defined(CX) #ifdef GEQO_DEBUG elog(DEBUG2, "using cycle crossover [CX]"); #endif /* allocate city table memory */ kid = alloc_chromo(root, pool->string_length); city_table = alloc_city_table(root, pool->string_length); #elif defined(PX) #ifdef GEQO_DEBUG elog(DEBUG2, "using position crossover [PX]"); #endif /* allocate city table memory */ kid = alloc_chromo(root, pool->string_length); city_table = alloc_city_table(root, pool->string_length); #elif defined(OX1) #ifdef GEQO_DEBUG elog(DEBUG2, "using order crossover [OX1]"); #endif /* allocate city table memory */ kid = alloc_chromo(root, pool->string_length); city_table = alloc_city_table(root, pool->string_length); #elif defined(OX2) #ifdef GEQO_DEBUG elog(DEBUG2, "using order crossover [OX2]"); #endif /* allocate city table memory */ kid = alloc_chromo(root, pool->string_length); city_table = alloc_city_table(root, pool->string_length); #endif /* my pain main part: */ /* iterative optimization */ for (generation = 0; generation < number_generations; generation++) { /* SELECTION: using linear bias function */ geqo_selection(root, momma, daddy, pool, Geqo_selection_bias); #if defined (ERX) /* EDGE RECOMBINATION CROSSOVER */ gimme_edge_table(root, momma->string, daddy->string, pool->string_length, edge_table); kid = momma; /* are there any edge failures ? */ edge_failures += gimme_tour(root, edge_table, kid->string, pool->string_length); #elif defined(PMX) /* PARTIALLY MATCHED CROSSOVER */ pmx(root, momma->string, daddy->string, kid->string, pool->string_length); #elif defined(CX) /* CYCLE CROSSOVER */ cycle_diffs = cx(root, momma->string, daddy->string, kid->string, pool->string_length, city_table); /* mutate the child */ if (cycle_diffs == 0) { mutations++; geqo_mutation(root, kid->string, pool->string_length); } #elif defined(PX) /* POSITION CROSSOVER */ px(root, momma->string, daddy->string, kid->string, pool->string_length, city_table); #elif defined(OX1) /* ORDER CROSSOVER */ ox1(root, momma->string, daddy->string, kid->string, pool->string_length, city_table); #elif defined(OX2) /* ORDER CROSSOVER */ ox2(root, momma->string, daddy->string, kid->string, pool->string_length, city_table); #endif /* EVALUATE FITNESS */ kid->worth = geqo_eval(root, kid->string, pool->string_length); /* push the kid into the wilderness of life according to its worth */ spread_chromo(root, kid, pool); #ifdef GEQO_DEBUG if (status_interval && !(generation % status_interval)) print_gen(stdout, pool, generation); #endif } #if defined(ERX) #if defined(GEQO_DEBUG) if (edge_failures != 0) elog(LOG, "[GEQO] failures: %d, average: %d", edge_failures, (int) number_generations / edge_failures); else elog(LOG, "[GEQO] no edge failures detected"); #else /* suppress variable-set-but-not-used warnings from some compilers */ (void) edge_failures; #endif #endif #if defined(CX) && defined(GEQO_DEBUG) if (mutations != 0) elog(LOG, "[GEQO] mutations: %d, generations: %d", mutations, number_generations); else elog(LOG, "[GEQO] no mutations processed"); #endif #ifdef GEQO_DEBUG print_pool(stdout, pool, 0, pool_size - 1); #endif #ifdef GEQO_DEBUG elog(DEBUG1, "GEQO best is %.2f after %d generations", pool->data[0].worth, number_generations); #endif /* * got the cheapest query tree processed by geqo; first element of the * population indicates the best query tree */ best_tour = (Gene *) pool->data[0].string; best_rel = gimme_tree(root, best_tour, pool->string_length); if (best_rel == NULL) elog(ERROR, "geqo failed to make a valid plan"); /* DBG: show the query plan */ #ifdef NOT_USED print_plan(best_plan, root); #endif /* ... free memory stuff */ free_chromo(root, momma); free_chromo(root, daddy); #if defined (ERX) free_edge_table(root, edge_table); #elif defined(PMX) free_chromo(root, kid); #elif defined(CX) free_chromo(root, kid); free_city_table(root, city_table); #elif defined(PX) free_chromo(root, kid); free_city_table(root, city_table); #elif defined(OX1) free_chromo(root, kid); free_city_table(root, city_table); #elif defined(OX2) free_chromo(root, kid); free_city_table(root, city_table); #endif free_pool(root, pool); /* ... clear root pointer to our private storage */ root->join_search_private = NULL; return best_rel; } /* * Return either configured pool size or a good default * * The default is based on query size (no. of relations) = 2^(QS+1), * but constrained to a range based on the effort value. */ static int gimme_pool_size(int nr_rel) { double size; int minsize; int maxsize; /* Legal pool size *must* be at least 2, so ignore attempt to select 1 */ if (Geqo_pool_size >= 2) return Geqo_pool_size; size = pow(2.0, nr_rel + 1.0); maxsize = 50 * Geqo_effort; /* 50 to 500 individuals */ if (size > maxsize) return maxsize; minsize = 10 * Geqo_effort; /* 10 to 100 individuals */ if (size < minsize) return minsize; return (int) ceil(size); } /* * Return either configured number of generations or a good default * * The default is the same as the pool size, which allows us to be * sure that less-fit individuals get pushed out of the breeding * population before the run finishes. */ static int gimme_number_generations(int pool_size) { if (Geqo_generations > 0) return Geqo_generations; return pool_size; }