/* Ordered map data type implemented by an array. Copyright (C) 2006-2007, 2009-2023 Free Software Foundation, Inc. Written by Bruno Haible , 2018. This file is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This file 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this program. If not, see . */ #include /* Specification. */ #include "gl_array_omap.h" #include /* Checked size_t computations. */ #include "xsize.h" /* -------------------------- gl_omap_t Data Type -------------------------- */ struct pair { const void *key; const void *value; }; /* Concrete gl_omap_impl type, valid for this file only. */ struct gl_omap_impl { struct gl_omap_impl_base base; /* An array of ALLOCATED pairs, of which the first COUNT are used. 0 <= COUNT <= ALLOCATED. */ struct pair *pairs; size_t count; size_t allocated; }; static gl_omap_t gl_array_nx_create_empty (gl_omap_implementation_t implementation, gl_mapkey_compar_fn compar_fn, gl_mapkey_dispose_fn kdispose_fn, gl_mapvalue_dispose_fn vdispose_fn) { struct gl_omap_impl *map = (struct gl_omap_impl *) malloc (sizeof (struct gl_omap_impl)); if (map == NULL) return NULL; map->base.vtable = implementation; map->base.compar_fn = compar_fn; map->base.kdispose_fn = kdispose_fn; map->base.vdispose_fn = vdispose_fn; map->pairs = NULL; map->count = 0; map->allocated = 0; return map; } static size_t _GL_ATTRIBUTE_PURE gl_array_size (gl_omap_t map) { return map->count; } static size_t _GL_ATTRIBUTE_PURE gl_array_indexof (gl_omap_t map, const void *key) { size_t count = map->count; if (count > 0) { gl_mapkey_compar_fn compar = map->base.compar_fn; size_t low = 0; size_t high = count; /* At each loop iteration, low < high; for indices < low the values are smaller than KEY; for indices >= high the values are greater than KEY. So, if the key occurs in the map, it is at low <= position < high. */ do { size_t mid = low + (high - low) / 2; /* low <= mid < high */ int cmp = (compar != NULL ? compar (map->pairs[mid].key, key) : (map->pairs[mid].key > key ? 1 : map->pairs[mid].key < key ? -1 : 0)); if (cmp < 0) low = mid + 1; else if (cmp > 0) high = mid; else /* cmp == 0 */ /* We have a key equal to KEY at index MID. */ return mid; } while (low < high); } return (size_t)(-1); } static bool _GL_ATTRIBUTE_PURE gl_array_search (gl_omap_t map, const void *key, const void **valuep) { size_t index = gl_array_indexof (map, key); if (index != (size_t)(-1)) { *valuep = map->pairs[index].value; return true; } else return false; } static bool _GL_ATTRIBUTE_PURE gl_array_search_atleast (gl_omap_t map, gl_mapkey_threshold_fn threshold_fn, const void *threshold, const void **keyp, const void **valuep) { size_t count = map->count; if (count > 0) { size_t low = 0; size_t high = count; /* At each loop iteration, low < high; for indices < low the values are smaller than THRESHOLD; for indices >= high the values are nonexistent. So, if a key >= THRESHOLD occurs in the map, it is at low <= position < high. */ do { size_t mid = low + (high - low) / 2; /* low <= mid < high */ if (! threshold_fn (map->pairs[mid].key, threshold)) low = mid + 1; else { /* We have a key >= THRESHOLD at index MID. But we need the minimal such index. */ high = mid; /* At each loop iteration, low <= high and compar (map->pairs[high].key, value) >= 0, and we know that the first occurrence of the key is at low <= position <= high. */ while (low < high) { size_t mid2 = low + (high - low) / 2; /* low <= mid2 < high */ if (! threshold_fn (map->pairs[mid2].key, threshold)) low = mid2 + 1; else high = mid2; } *keyp = map->pairs[low].key; *valuep = map->pairs[low].value; return true; } } while (low < high); } return false; } /* Ensure that map->allocated > map->count. Return 0 upon success, -1 upon out-of-memory. */ static int grow (gl_omap_t map) { size_t new_allocated; size_t memory_size; struct pair *memory; new_allocated = xtimes (map->allocated, 2); new_allocated = xsum (new_allocated, 1); memory_size = xtimes (new_allocated, sizeof (struct pair)); if (size_overflow_p (memory_size)) /* Overflow, would lead to out of memory. */ return -1; memory = (struct pair *) realloc (map->pairs, memory_size); if (memory == NULL) /* Out of memory. */ return -1; map->pairs = memory; map->allocated = new_allocated; return 0; } /* Add the given pair (KEY, VALUE) at the given position, 0 <= position <= gl_omap_size (map). Return 1 upon success, -1 upon out-of-memory. */ static int gl_array_nx_add_at (gl_omap_t map, size_t position, const void *key, const void *value) { size_t count = map->count; struct pair *pairs; size_t i; if (count == map->allocated) if (grow (map) < 0) return -1; pairs = map->pairs; for (i = count; i > position; i--) pairs[i] = pairs[i - 1]; pairs[position].key = key; pairs[position].value = value; map->count = count + 1; return 1; } static int gl_array_nx_getput (gl_omap_t map, const void *key, const void *value, const void **oldvaluep) { size_t count = map->count; size_t low = 0; if (count > 0) { gl_mapkey_compar_fn compar = map->base.compar_fn; size_t high = count; /* At each loop iteration, low < high; for indices < low the keys are smaller than KEY; for indices >= high the keys are greater than KEY. So, if the key occurs in the map, it is at low <= position < high. */ do { size_t mid = low + (high - low) / 2; /* low <= mid < high */ int cmp = (compar != NULL ? compar (map->pairs[mid].key, key) : (map->pairs[mid].key > key ? 1 : map->pairs[mid].key < key ? -1 : 0)); if (cmp < 0) low = mid + 1; else if (cmp > 0) high = mid; else /* cmp == 0 */ { *oldvaluep = map->pairs[mid].value; map->pairs[mid].value = value; return 0; } } while (low < high); } return gl_array_nx_add_at (map, low, key, value); } /* Remove the pair at the given position, 0 <= position < gl_omap_size (map). */ static void gl_array_remove_at (gl_omap_t map, size_t position) { size_t count = map->count; struct pair *pairs; size_t i; pairs = map->pairs; if (map->base.kdispose_fn != NULL) map->base.kdispose_fn (pairs[position].key); for (i = position + 1; i < count; i++) pairs[i - 1] = pairs[i]; map->count = count - 1; } static bool gl_array_getremove (gl_omap_t map, const void *key, const void **oldvaluep) { size_t index = gl_array_indexof (map, key); if (index != (size_t)(-1)) { *oldvaluep = map->pairs[index].value; gl_array_remove_at (map, index); return true; } else return false; } static void gl_array_free (gl_omap_t map) { if (map->pairs != NULL) { if (map->base.kdispose_fn != NULL || map->base.vdispose_fn != NULL) { size_t count = map->count; if (count > 0) { gl_mapkey_dispose_fn kdispose = map->base.kdispose_fn; gl_mapvalue_dispose_fn vdispose = map->base.vdispose_fn; struct pair *pairs = map->pairs; do { if (vdispose) vdispose (pairs->value); if (kdispose) kdispose (pairs->key); pairs++; } while (--count > 0); } } free (map->pairs); } free (map); } /* ---------------------- gl_omap_iterator_t Data Type ---------------------- */ static gl_omap_iterator_t _GL_ATTRIBUTE_PURE gl_array_iterator (gl_omap_t map) { gl_omap_iterator_t result; result.vtable = map->base.vtable; result.map = map; result.count = map->count; result.p = map->pairs + 0; result.q = map->pairs + map->count; #if defined GCC_LINT || defined lint result.i = 0; result.j = 0; #endif return result; } static bool gl_array_iterator_next (gl_omap_iterator_t *iterator, const void **keyp, const void **valuep) { gl_omap_t map = iterator->map; if (iterator->count != map->count) { if (iterator->count != map->count + 1) /* Concurrent modifications were done on the map. */ abort (); /* The last returned pair was removed. */ iterator->count--; iterator->p = (struct pair *) iterator->p - 1; iterator->q = (struct pair *) iterator->q - 1; } if (iterator->p < iterator->q) { struct pair *p = (struct pair *) iterator->p; *keyp = p->key; *valuep = p->value; iterator->p = p + 1; return true; } else return false; } static void gl_array_iterator_free (_GL_ATTRIBUTE_MAYBE_UNUSED gl_omap_iterator_t *iterator) { } const struct gl_omap_implementation gl_array_omap_implementation = { gl_array_nx_create_empty, gl_array_size, gl_array_search, gl_array_search_atleast, gl_array_nx_getput, gl_array_getremove, gl_array_free, gl_array_iterator, gl_array_iterator_next, gl_array_iterator_free };