/* Provides high-level routines to manipulate the keywork list structures the code generation output. Copyright (C) 1989 Free Software Foundation, Inc. written by Douglas C. Schmidt (schmidt@ics.uci.edu) This file is part of GNU GPERF. GNU GPERF is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 1, or (at your option) any later version. GNU GPERF is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GNU GPERF; see the file COPYING. If not, write to the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. */ #include #include #include #include #include "options.h" #include "gen-perf.h" #include "trace.h" /* Current release version. */ extern char *version_string; /* Efficiently returns the least power of two greater than or equal to X! */ #define POW(X) ((!X)?1:(X-=1,X|=X>>1,X|=X>>2,X|=X>>4,X|=X>>8,X|=X>>16,(++X))) #ifdef USG #define srandom srand #define random rand #endif /* Reads input keys, possibly applies the reordering heuristic, sets the maximum associated value size (rounded up to the nearest power of 2), may initialize the associated values array, and determines the maximum hash table size. Note: using the random numbers is often helpful, though not as deterministic, of course! */ Gen_Perf::Gen_Perf (void) { T (Trace t ("Gen_Perf::Gen_Perf");) int asso_value_max; int non_linked_length; Key_List::read_keys (); if (option[ORDER]) reorder (); asso_value_max = option.get_asso_max (); non_linked_length = Key_List::keyword_list_length (); num_done = 1; fewest_collisions = 0; if (asso_value_max == 0) asso_value_max = non_linked_length; else if (asso_value_max > 0) asso_value_max *= non_linked_length; else /* if (asso_value_max < 0) */ asso_value_max = non_linked_length / -asso_value_max; option.set_asso_max (POW (asso_value_max)); if (option[RANDOM]) { srandom (time (0)); for (int i = 0; i < ALPHA_SIZE; i++) asso_values[i] = (random () & asso_value_max - 1); } else { int asso_value = option.initial_value (); if (asso_value) /* Initialize array if user requests non-zero default. */ for (int i = ALPHA_SIZE - 1; i >= 0; i--) asso_values[i] = asso_value & option.get_asso_max () - 1; } max_hash_value = Key_List::max_key_length () + option.get_asso_max () * option.get_max_keysig_size (); printf ("/* "); if (option[C]) printf ("C"); else if (option[CPLUSPLUS]) printf ("C++"); printf (" code produced by gperf version %s */\n", version_string); Options::print_options (); if (option[DEBUG]) fprintf (stderr, "total non-linked keys = %d\nmaximum associated value is %d" "\nmaximum size of generated hash table is %d\n", non_linked_length, asso_value_max, max_hash_value); } /* Merge two disjoint hash key multisets to form the ordered disjoint union of the sets. (In a multiset, an element can occur multiple times). Precondition: both set_1 and set_2 must be ordered. Returns the length of the combined set. */ static inline int Gen_Perf::compute_disjoint_union (char *set_1, char *set_2, char *set_3) { T (Trace t ("Gen_Perf::compute_disjoint_union");) char *base = set_3; while (*set_1 && *set_2) if (*set_1 == *set_2) set_1++, set_2++; else { *set_3 = *set_1 < *set_2 ? *set_1++ : *set_2++; if (set_3 == base || *set_3 != *(set_3-1)) set_3++; } while (*set_1) { *set_3 = *set_1++; if (set_3 == base || *set_3 != *(set_3-1)) set_3++; } while (*set_2) { *set_3 = *set_2++; if (set_3 == base || *set_3 != *(set_3-1)) set_3++; } *set_3 = '\0'; return set_3 - base; } /* Sort the UNION_SET in increasing frequency of occurrence. This speeds up later processing since we may assume the resulting set (Set_3, in this case), is ordered. Uses insertion sort, since the UNION_SET is typically short. */ static inline void Gen_Perf::sort_set (char *union_set, int len) { T (Trace t ("Gen_Perf::sort_set");) int i, j; for (i = 0, j = len - 1; i < j; i++) { char curr, tmp; for (curr = i + 1, tmp = union_set[curr]; curr > 0 && occurrences[tmp] < occurrences[union_set[curr-1]]; curr--) union_set[curr] = union_set[curr - 1]; union_set[curr] = tmp; } } /* Generate a key set's hash value. */ static inline int Gen_Perf::hash (List_Node *key_node) { T (Trace t ("Gen_Perf::hash");) int sum = option[NOLENGTH] ? 0 : key_node->length; for (char *ptr = key_node->char_set; *ptr; ptr++) sum += asso_values[*ptr]; return key_node->hash_value = sum; } /* Find out how character value change affects successfully hashed items. Returns FALSE if no other hash values are affected, else returns TRUE. Note that because Option.Get_Asso_Max is a power of two we can guarantee that all legal Asso_Values are visited without repetition since Option.Get_Jump was forced to be an odd value! */ static inline int Gen_Perf::affects_prev (char c, List_Node *curr) { T (Trace t ("Gen_Perf::affects_prev");) int original_char = asso_values[c]; int total_iterations = !option[FAST] ? option.get_asso_max () : option.get_iterations () ? /* Elided! */ : keyword_list_length (); /* Try all legal associated values. */ for (int i = total_iterations - 1; i >= 0; i--) { int collisions = 0; asso_values[c] = asso_values[c] + (option.get_jump () ? /* Elided! */ : random ()) & option.get_asso_max () - 1; /* Iteration Number array is a win, O(1) intialization time! */ reset (); /* See how this asso_value change affects previous keywords. If it does better than before we'll take it! */ for (List_Node *ptr = head; !Bool_Array::find (hash (ptr)) || ++collisions < fewest_collisions; ptr = ptr->next) if (ptr == curr) { fewest_collisions = collisions; if (option[DEBUG]) fprintf (stderr, "- resolved after %d iterations", total_iterations - i); return 0; } } /* Restore original values, no more tries. */ asso_values[c] = original_char; /* If we're this far it's time to try the next character.... */ return 1; } /* Change a character value, try least-used characters first. */ static void Gen_Perf::change (List_Node *prior, List_Node *curr) { T (Trace t ("Gen_Perf::change");) static char *union_set; if (!union_set) union_set = new char [2 * option.get_max_keysig_size () + 1]; if (option[DEBUG]) { fprintf (stderr, "collision on keyword #%d, prior = \"%s\", curr = \"%s\" hash = %d\n", num_done, prior->key, curr->key, curr->hash_value); fflush (stderr); } sort_set (union_set, compute_disjoint_union (prior->char_set, curr->char_set, union_set)); /* Try changing some values, if change doesn't alter other values continue normal action. */ fewest_collisions++; for (char *temp = union_set; *temp; temp++) if (!affects_prev (*temp, curr)) { if (option[DEBUG]) { fprintf (stderr, " by changing asso_value['%c'] (char #%d) to %d\n", *temp, temp - union_set + 1, asso_values[*temp]); fflush (stderr); } return; /* Good, doesn't affect previous hash values, we'll take it. */ } for (List_Node *ptr = head; ptr != curr; ptr = ptr->next) hash (ptr); hash (curr); if (option[DEBUG]) { fprintf (stderr, "** collision not resolved after %d iterations, %d duplicates remain, continuing...\n", !option[FAST] ? option.get_asso_max () : option.get_iterations () ? /* Elided! */ : keyword_list_length (), fewest_collisions + total_duplicates); fflush (stderr); } } /* Does the hard stuff.... Initializes the Iteration Number array, and attempts to find a perfect function that will hash all the key words without getting any duplications. This is made much easier since we aren't attempting to generate *minimum* functions, only perfect ones. If we can't generate a perfect function in one pass *and* the user hasn't enabled the DUP option, we'll inform the user to try the randomization option, use -D, or choose alternative key positions. The alternatives (e.g., back-tracking) are too time-consuming, i.e, exponential in the number of keys. */ int Gen_Perf::operator() (void) { T (Trace t ("Gen_Perf::operator()");) STORAGE_TYPE buffer[max_hash_value + 1]; Bool_Array::init (buffer, max_hash_value + 1); for (List_Node *curr = head; curr; curr = curr->next) { hash (curr); for (List_Node *ptr = head; ptr != curr; ptr = ptr->next) if (ptr->hash_value == curr->hash_value) { change (ptr, curr); break; } num_done++; } /* Make one final check, just to make sure nothing weird happened.... */ Bool_Array::reset (); for (curr = head; curr; curr = curr->next) if (Bool_Array::find (hash (curr))) if (option[DUP]) /* Keep track of this number... */ total_duplicates++; else /* Yow, big problems. we're outta here! */ { report_error ("\nInternal error, duplicate value %d:\n" "try options -D or -r, or use new key positions.\n\n", hash (curr)); return 1; } /* Sorts the key word list by hash value, and then outputs the list. The generated hash table code is only output if the early stage of processing turned out O.K. */ sort (); output (); return 0; } /* Prints out some diagnostics upon completion. */ Gen_Perf::~Gen_Perf (void) { T (Trace t ("Gen_Perf::~Gen_Perf");) if (option[DEBUG]) { fprintf (stderr, "\ndumping occurrence and associated values tables\n"); for (int i = 0; i < ALPHA_SIZE; i++) if (occurrences[i]) fprintf (stderr, "asso_values[%c] = %6d, occurrences[%c] = %6d\n", i, asso_values[i], i, occurrences[i]); fprintf (stderr, "end table dumping\n"); } }