/* Sequential list data type implemented by a circular array. Copyright (C) 2006-2023 Free Software Foundation, Inc. Written by Bruno Haible , 2006. 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_carray_list.h" #include #include /* Get memcpy. */ #include /* Checked size_t computations. */ #include "xsize.h" /* -------------------------- gl_list_t Data Type -------------------------- */ /* Concrete gl_list_impl type, valid for this file only. */ struct gl_list_impl { struct gl_list_impl_base base; /* An array of ALLOCATED elements, of which the elements OFFSET, (OFFSET + 1) % ALLOCATED, ..., (OFFSET + COUNT - 1) % ALLOCATED are used. 0 <= COUNT <= ALLOCATED. Either OFFSET = ALLOCATED = 0 or 0 <= OFFSET < ALLOCATED. */ const void **elements; size_t offset; size_t count; size_t allocated; }; /* struct gl_list_node_impl doesn't exist here. The pointers are actually indices + 1. */ #define INDEX_TO_NODE(index) (gl_list_node_t)(uintptr_t)(size_t)((index) + 1) #define NODE_TO_INDEX(node) ((uintptr_t)(node) - 1) static gl_list_t gl_carray_nx_create_empty (gl_list_implementation_t implementation, gl_listelement_equals_fn equals_fn, gl_listelement_hashcode_fn hashcode_fn, gl_listelement_dispose_fn dispose_fn, bool allow_duplicates) { struct gl_list_impl *list = (struct gl_list_impl *) malloc (sizeof (struct gl_list_impl)); if (list == NULL) return NULL; list->base.vtable = implementation; list->base.equals_fn = equals_fn; list->base.hashcode_fn = hashcode_fn; list->base.dispose_fn = dispose_fn; list->base.allow_duplicates = allow_duplicates; list->elements = NULL; list->offset = 0; list->count = 0; list->allocated = 0; return list; } static gl_list_t gl_carray_nx_create (gl_list_implementation_t implementation, gl_listelement_equals_fn equals_fn, gl_listelement_hashcode_fn hashcode_fn, gl_listelement_dispose_fn dispose_fn, bool allow_duplicates, size_t count, const void **contents) { struct gl_list_impl *list = (struct gl_list_impl *) malloc (sizeof (struct gl_list_impl)); if (list == NULL) return NULL; list->base.vtable = implementation; list->base.equals_fn = equals_fn; list->base.hashcode_fn = hashcode_fn; list->base.dispose_fn = dispose_fn; list->base.allow_duplicates = allow_duplicates; if (count > 0) { if (size_overflow_p (xtimes (count, sizeof (const void *)))) goto fail; list->elements = (const void **) malloc (count * sizeof (const void *)); if (list->elements == NULL) goto fail; memcpy (list->elements, contents, count * sizeof (const void *)); } else list->elements = NULL; list->offset = 0; list->count = count; list->allocated = count; return list; fail: free (list); return NULL; } static size_t _GL_ATTRIBUTE_PURE gl_carray_size (gl_list_t list) { return list->count; } static const void * _GL_ATTRIBUTE_PURE gl_carray_node_value (gl_list_t list, gl_list_node_t node) { uintptr_t index = NODE_TO_INDEX (node); size_t i; if (!(index < list->count)) /* Invalid argument. */ abort (); i = list->offset + index; if (i >= list->allocated) i -= list->allocated; return list->elements[i]; } static int gl_carray_node_nx_set_value (gl_list_t list, gl_list_node_t node, const void *elt) { uintptr_t index = NODE_TO_INDEX (node); size_t i; if (!(index < list->count)) /* Invalid argument. */ abort (); i = list->offset + index; if (i >= list->allocated) i -= list->allocated; list->elements[i] = elt; return 0; } static gl_list_node_t _GL_ATTRIBUTE_PURE gl_carray_next_node (gl_list_t list, gl_list_node_t node) { uintptr_t index = NODE_TO_INDEX (node); if (!(index < list->count)) /* Invalid argument. */ abort (); index++; if (index < list->count) return INDEX_TO_NODE (index); else return NULL; } static gl_list_node_t _GL_ATTRIBUTE_PURE gl_carray_previous_node (gl_list_t list, gl_list_node_t node) { uintptr_t index = NODE_TO_INDEX (node); if (!(index < list->count)) /* Invalid argument. */ abort (); if (index > 0) return INDEX_TO_NODE (index - 1); else return NULL; } static gl_list_node_t _GL_ATTRIBUTE_PURE gl_carray_first_node (gl_list_t list) { if (list->count > 0) return INDEX_TO_NODE (0); else return NULL; } static gl_list_node_t _GL_ATTRIBUTE_PURE gl_carray_last_node (gl_list_t list) { if (list->count > 0) return INDEX_TO_NODE (list->count - 1); else return NULL; } static const void * _GL_ATTRIBUTE_PURE gl_carray_get_at (gl_list_t list, size_t position) { size_t count = list->count; size_t i; if (!(position < count)) /* Invalid argument. */ abort (); i = list->offset + position; if (i >= list->allocated) i -= list->allocated; return list->elements[i]; } static gl_list_node_t gl_carray_nx_set_at (gl_list_t list, size_t position, const void *elt) { size_t count = list->count; size_t i; if (!(position < count)) /* Invalid argument. */ abort (); i = list->offset + position; if (i >= list->allocated) i -= list->allocated; list->elements[i] = elt; return INDEX_TO_NODE (position); } static size_t _GL_ATTRIBUTE_PURE gl_carray_indexof_from_to (gl_list_t list, size_t start_index, size_t end_index, const void *elt) { size_t count = list->count; if (!(start_index <= end_index && end_index <= count)) /* Invalid arguments. */ abort (); if (start_index < end_index) { gl_listelement_equals_fn equals = list->base.equals_fn; size_t allocated = list->allocated; size_t i_end; i_end = list->offset + end_index; if (i_end >= allocated) i_end -= allocated; if (equals != NULL) { size_t i; i = list->offset + start_index; if (i >= allocated) /* can only happen if start_index > 0 */ i -= allocated; for (;;) { if (equals (elt, list->elements[i])) return (i >= list->offset ? i : i + allocated) - list->offset; i++; if (i == allocated) i = 0; if (i == i_end) break; } } else { size_t i; i = list->offset + start_index; if (i >= allocated) /* can only happen if start_index > 0 */ i -= allocated; for (;;) { if (elt == list->elements[i]) return (i >= list->offset ? i : i + allocated) - list->offset; i++; if (i == allocated) i = 0; if (i == i_end) break; } } } return (size_t)(-1); } static gl_list_node_t _GL_ATTRIBUTE_PURE gl_carray_search_from_to (gl_list_t list, size_t start_index, size_t end_index, const void *elt) { size_t index = gl_carray_indexof_from_to (list, start_index, end_index, elt); return INDEX_TO_NODE (index); } /* Ensure that list->allocated > list->count. Return 0 upon success, -1 upon out-of-memory. */ static int grow (gl_list_t list) { size_t new_allocated; size_t memory_size; const void **memory; new_allocated = xtimes (list->allocated, 2); new_allocated = xsum (new_allocated, 1); memory_size = xtimes (new_allocated, sizeof (const void *)); if (size_overflow_p (memory_size)) /* Overflow, would lead to out of memory. */ return -1; if (list->offset > 0 && list->count > 0) { memory = (const void **) malloc (memory_size); if (memory == NULL) /* Out of memory. */ return -1; if (list->offset + list->count > list->allocated) { memcpy (memory, &list->elements[list->offset], (list->allocated - list->offset) * sizeof (const void *)); memcpy (memory + (list->allocated - list->offset), list->elements, (list->offset + list->count - list->allocated) * sizeof (const void *)); } else memcpy (memory, &list->elements[list->offset], list->count * sizeof (const void *)); if (list->elements != NULL) free (list->elements); } else { memory = (const void **) realloc (list->elements, memory_size); if (memory == NULL) /* Out of memory. */ return -1; } list->elements = memory; list->offset = 0; list->allocated = new_allocated; return 0; } static gl_list_node_t gl_carray_nx_add_first (gl_list_t list, const void *elt) { size_t count = list->count; if (count == list->allocated) if (grow (list) < 0) return NULL; list->offset = (list->offset == 0 ? list->allocated : list->offset) - 1; list->elements[list->offset] = elt; list->count = count + 1; return INDEX_TO_NODE (0); } static gl_list_node_t gl_carray_nx_add_last (gl_list_t list, const void *elt) { size_t count = list->count; size_t i; if (count == list->allocated) if (grow (list) < 0) return NULL; i = list->offset + count; if (i >= list->allocated) i -= list->allocated; list->elements[i] = elt; list->count = count + 1; return INDEX_TO_NODE (count); } static gl_list_node_t gl_carray_nx_add_at (gl_list_t list, size_t position, const void *elt) { size_t count = list->count; const void **elements; if (!(position <= count)) /* Invalid argument. */ abort (); if (count == list->allocated) if (grow (list) < 0) return NULL; elements = list->elements; if (position <= (count / 2)) { /* Shift at most count/2 elements to the left. */ size_t i2, i; list->offset = (list->offset == 0 ? list->allocated : list->offset) - 1; i2 = list->offset + position; if (i2 >= list->allocated) { /* Here we must have list->offset > 0, hence list->allocated > 0. */ size_t i1 = list->allocated - 1; i2 -= list->allocated; for (i = list->offset; i < i1; i++) elements[i] = elements[i + 1]; elements[i1] = elements[0]; for (i = 0; i < i2; i++) elements[i] = elements[i + 1]; } else { for (i = list->offset; i < i2; i++) elements[i] = elements[i + 1]; } elements[i2] = elt; } else { /* Shift at most (count+1)/2 elements to the right. */ size_t i1, i3, i; i1 = list->offset + position; i3 = list->offset + count; if (i1 >= list->allocated) { i1 -= list->allocated; i3 -= list->allocated; for (i = i3; i > i1; i--) elements[i] = elements[i - 1]; } else if (i3 >= list->allocated) { /* Here we must have list->offset > 0, hence list->allocated > 0. */ size_t i2 = list->allocated - 1; i3 -= list->allocated; for (i = i3; i > 0; i--) elements[i] = elements[i - 1]; elements[0] = elements[i2]; for (i = i2; i > i1; i--) elements[i] = elements[i - 1]; } else { for (i = i3; i > i1; i--) elements[i] = elements[i - 1]; } elements[i1] = elt; } list->count = count + 1; return INDEX_TO_NODE (position); } static gl_list_node_t gl_carray_nx_add_before (gl_list_t list, gl_list_node_t node, const void *elt) { size_t count = list->count; uintptr_t index = NODE_TO_INDEX (node); if (!(index < count)) /* Invalid argument. */ abort (); return gl_carray_nx_add_at (list, index, elt); } static gl_list_node_t gl_carray_nx_add_after (gl_list_t list, gl_list_node_t node, const void *elt) { size_t count = list->count; uintptr_t index = NODE_TO_INDEX (node); if (!(index < count)) /* Invalid argument. */ abort (); return gl_carray_nx_add_at (list, index + 1, elt); } static bool gl_carray_remove_at (gl_list_t list, size_t position) { size_t count = list->count; const void **elements; if (!(position < count)) /* Invalid argument. */ abort (); /* Here we know count > 0. */ elements = list->elements; if (position <= ((count - 1) / 2)) { /* Shift at most (count-1)/2 elements to the right. */ size_t i0, i2, i; i0 = list->offset; i2 = list->offset + position; if (i2 >= list->allocated) { /* Here we must have list->offset > 0, hence list->allocated > 0. */ size_t i1 = list->allocated - 1; i2 -= list->allocated; if (list->base.dispose_fn != NULL) list->base.dispose_fn (elements[i2]); for (i = i2; i > 0; i--) elements[i] = elements[i - 1]; elements[0] = elements[i1]; for (i = i1; i > i0; i--) elements[i] = elements[i - 1]; } else { if (list->base.dispose_fn != NULL) list->base.dispose_fn (elements[i2]); for (i = i2; i > i0; i--) elements[i] = elements[i - 1]; } i0++; list->offset = (i0 == list->allocated ? 0 : i0); } else { /* Shift at most count/2 elements to the left. */ size_t i1, i3, i; i1 = list->offset + position; i3 = list->offset + count - 1; if (i1 >= list->allocated) { i1 -= list->allocated; i3 -= list->allocated; if (list->base.dispose_fn != NULL) list->base.dispose_fn (elements[i1]); for (i = i1; i < i3; i++) elements[i] = elements[i + 1]; } else if (i3 >= list->allocated) { /* Here we must have list->offset > 0, hence list->allocated > 0. */ size_t i2 = list->allocated - 1; i3 -= list->allocated; if (list->base.dispose_fn != NULL) list->base.dispose_fn (elements[i1]); for (i = i1; i < i2; i++) elements[i] = elements[i + 1]; elements[i2] = elements[0]; for (i = 0; i < i3; i++) elements[i] = elements[i + 1]; } else { if (list->base.dispose_fn != NULL) list->base.dispose_fn (elements[i1]); for (i = i1; i < i3; i++) elements[i] = elements[i + 1]; } } list->count = count - 1; return true; } static bool gl_carray_remove_node (gl_list_t list, gl_list_node_t node) { size_t count = list->count; uintptr_t index = NODE_TO_INDEX (node); if (!(index < count)) /* Invalid argument. */ abort (); return gl_carray_remove_at (list, index); } static bool gl_carray_remove (gl_list_t list, const void *elt) { size_t position = gl_carray_indexof_from_to (list, 0, list->count, elt); if (position == (size_t)(-1)) return false; else return gl_carray_remove_at (list, position); } static void gl_carray_list_free (gl_list_t list) { if (list->elements != NULL) { if (list->base.dispose_fn != NULL) { size_t count = list->count; if (count > 0) { gl_listelement_dispose_fn dispose = list->base.dispose_fn; const void **elements = list->elements; size_t i1 = list->offset; size_t i3 = list->offset + count - 1; if (i3 >= list->allocated) { /* Here we must have list->offset > 0, hence list->allocated > 0. */ size_t i2 = list->allocated - 1; size_t i; i3 -= list->allocated; for (i = i1; i <= i2; i++) dispose (elements[i]); for (i = 0; i <= i3; i++) dispose (elements[i]); } else { size_t i; for (i = i1; i <= i3; i++) dispose (elements[i]); } } } free (list->elements); } free (list); } /* --------------------- gl_list_iterator_t Data Type --------------------- */ static gl_list_iterator_t _GL_ATTRIBUTE_PURE gl_carray_iterator (gl_list_t list) { gl_list_iterator_t result; result.vtable = list->base.vtable; result.list = list; result.count = list->count; result.i = 0; result.j = list->count; #if defined GCC_LINT || defined lint result.p = 0; result.q = 0; #endif return result; } static gl_list_iterator_t _GL_ATTRIBUTE_PURE gl_carray_iterator_from_to (gl_list_t list, size_t start_index, size_t end_index) { gl_list_iterator_t result; if (!(start_index <= end_index && end_index <= list->count)) /* Invalid arguments. */ abort (); result.vtable = list->base.vtable; result.list = list; result.count = list->count; result.i = start_index; result.j = end_index; #if defined GCC_LINT || defined lint result.p = 0; result.q = 0; #endif return result; } static bool gl_carray_iterator_next (gl_list_iterator_t *iterator, const void **eltp, gl_list_node_t *nodep) { gl_list_t list = iterator->list; if (iterator->count != list->count) { if (iterator->count != list->count + 1) /* Concurrent modifications were done on the list. */ abort (); /* The last returned element was removed. */ iterator->count--; iterator->i--; iterator->j--; } if (iterator->i < iterator->j) { size_t i = list->offset + iterator->i; if (i >= list->allocated) i -= list->allocated; *eltp = list->elements[i]; if (nodep != NULL) *nodep = INDEX_TO_NODE (iterator->i); iterator->i++; return true; } else return false; } static void gl_carray_iterator_free (_GL_ATTRIBUTE_MAYBE_UNUSED gl_list_iterator_t *iterator) { } /* ---------------------- Sorted gl_list_t Data Type ---------------------- */ static size_t _GL_ATTRIBUTE_PURE gl_carray_sortedlist_indexof_from_to (gl_list_t list, gl_listelement_compar_fn compar, size_t low, size_t high, const void *elt) { if (!(low <= high && high <= list->count)) /* Invalid arguments. */ abort (); if (low < high) { /* At each loop iteration, low < high; for indices < low the values are smaller than ELT; for indices >= high the values are greater than ELT. So, if the element occurs in the list, it is at low <= position < high. */ do { size_t mid = low + (high - low) / 2; /* low <= mid < high */ size_t i_mid; int cmp; i_mid = list->offset + mid; if (i_mid >= list->allocated) i_mid -= list->allocated; cmp = compar (list->elements[i_mid], elt); if (cmp < 0) low = mid + 1; else if (cmp > 0) high = mid; else /* cmp == 0 */ { /* We have an element equal to ELT at index MID. But we need the minimal such index. */ high = mid; /* At each loop iteration, low <= high and compar (list->elements[i_high], elt) == 0, and we know that the first occurrence of the element is at low <= position <= high. */ while (low < high) { size_t mid2 = low + (high - low) / 2; /* low <= mid2 < high */ size_t i_mid2; int cmp2; i_mid2 = list->offset + mid2; if (i_mid2 >= list->allocated) i_mid2 -= list->allocated; cmp2 = compar (list->elements[i_mid2], elt); if (cmp2 < 0) low = mid2 + 1; else if (cmp2 > 0) /* The list was not sorted. */ abort (); else /* cmp2 == 0 */ { if (mid2 == low) break; high = mid2 - 1; } } return low; } } while (low < high); /* Here low == high. */ } return (size_t)(-1); } static size_t _GL_ATTRIBUTE_PURE gl_carray_sortedlist_indexof (gl_list_t list, gl_listelement_compar_fn compar, const void *elt) { return gl_carray_sortedlist_indexof_from_to (list, compar, 0, list->count, elt); } static gl_list_node_t _GL_ATTRIBUTE_PURE gl_carray_sortedlist_search_from_to (gl_list_t list, gl_listelement_compar_fn compar, size_t low, size_t high, const void *elt) { size_t index = gl_carray_sortedlist_indexof_from_to (list, compar, low, high, elt); return INDEX_TO_NODE (index); } static gl_list_node_t _GL_ATTRIBUTE_PURE gl_carray_sortedlist_search (gl_list_t list, gl_listelement_compar_fn compar, const void *elt) { size_t index = gl_carray_sortedlist_indexof_from_to (list, compar, 0, list->count, elt); return INDEX_TO_NODE (index); } static gl_list_node_t gl_carray_sortedlist_nx_add (gl_list_t list, gl_listelement_compar_fn compar, const void *elt) { size_t count = list->count; size_t low = 0; size_t high = count; /* At each loop iteration, low <= high; for indices < low the values are smaller than ELT; for indices >= high the values are greater than ELT. */ while (low < high) { size_t mid = low + (high - low) / 2; /* low <= mid < high */ size_t i_mid; int cmp; i_mid = list->offset + mid; if (i_mid >= list->allocated) i_mid -= list->allocated; cmp = compar (list->elements[i_mid], elt); if (cmp < 0) low = mid + 1; else if (cmp > 0) high = mid; else /* cmp == 0 */ { low = mid; break; } } return gl_carray_nx_add_at (list, low, elt); } static bool gl_carray_sortedlist_remove (gl_list_t list, gl_listelement_compar_fn compar, const void *elt) { size_t index = gl_carray_sortedlist_indexof (list, compar, elt); if (index == (size_t)(-1)) return false; else return gl_carray_remove_at (list, index); } const struct gl_list_implementation gl_carray_list_implementation = { gl_carray_nx_create_empty, gl_carray_nx_create, gl_carray_size, gl_carray_node_value, gl_carray_node_nx_set_value, gl_carray_next_node, gl_carray_previous_node, gl_carray_first_node, gl_carray_last_node, gl_carray_get_at, gl_carray_nx_set_at, gl_carray_search_from_to, gl_carray_indexof_from_to, gl_carray_nx_add_first, gl_carray_nx_add_last, gl_carray_nx_add_before, gl_carray_nx_add_after, gl_carray_nx_add_at, gl_carray_remove_node, gl_carray_remove_at, gl_carray_remove, gl_carray_list_free, gl_carray_iterator, gl_carray_iterator_from_to, gl_carray_iterator_next, gl_carray_iterator_free, gl_carray_sortedlist_search, gl_carray_sortedlist_search_from_to, gl_carray_sortedlist_indexof, gl_carray_sortedlist_indexof_from_to, gl_carray_sortedlist_nx_add, gl_carray_sortedlist_remove };