Edit
kc3-lang/libxkbcommon/src/alloc.c
Branch :
-
Show log
Commit
-
Author :
Ran Benita
Date : 2012-04-11 02:02:45
Hash : 409ec8a1
Message : Merge src/alloc.c and src/malloc.c The two files do exactly the same sort of things, without any discernible reason for splitting them. Signed-off-by: Ran Benita <ran234@gmail.com> [daniels: Updated for xkb_desc -> xkb_keymap changes.]
- src/alloc.c
-
/* Copyright (c) 1993 by Silicon Graphics Computer Systems, Inc. Permission to use, copy, modify, and distribute this software and its documentation for any purpose and without fee is hereby granted, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of Silicon Graphics not be used in advertising or publicity pertaining to distribution of the software without specific prior written permission. Silicon Graphics makes no representation about the suitability of this software for any purpose. It is provided "as is" without any express or implied warranty. SILICON GRAPHICS DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. IN NO EVENT SHALL SILICON GRAPHICS BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include "utils.h" #include "xkballoc.h" #include "xkbcommon/xkbcommon.h" #include "XKBcommonint.h" int XkbcAllocClientMap(struct xkb_keymap * xkb, unsigned which, unsigned nTotalTypes) { struct xkb_client_map * map; if (!xkb || ((nTotalTypes > 0) && (nTotalTypes < XkbNumRequiredTypes))) return BadValue; if ((which & XkbKeySymsMask) && !xkb_keymap_keycode_range_is_legal(xkb)) { #ifdef DEBUG fprintf(stderr, "bad keycode (%d,%d) in XkbAllocClientMap\n", xkb->min_key_code, xkb->max_key_code); #endif return BadValue; } if (!xkb->map) { map = uTypedCalloc(1, struct xkb_client_map); if (!map) return BadAlloc; xkb->map = map; } else map = xkb->map; if ((which & XkbKeyTypesMask) && (nTotalTypes > 0)) { if (!map->types) { map->types = uTypedCalloc(nTotalTypes, struct xkb_key_type); if (!map->types) return BadAlloc; map->num_types = 0; map->size_types = nTotalTypes; } else if (map->size_types < nTotalTypes) { struct xkb_key_type *prev_types = map->types; map->types = uTypedRealloc(map->types, nTotalTypes, struct xkb_key_type); if (!map->types) { free(prev_types); map->num_types = map->size_types = 0; return BadAlloc; } map->size_types = nTotalTypes; memset(&map->types[map->num_types], 0, (map->size_types - map->num_types) * sizeof(struct xkb_key_type)); } } if (which & XkbKeySymsMask) { if (!map->key_sym_map) { map->key_sym_map = uTypedCalloc(xkb->max_key_code + 1, struct xkb_sym_map); if (!map->key_sym_map) return BadAlloc; } } if (which & XkbModifierMapMask) { if (!map->modmap) { map->modmap = uTypedCalloc(xkb->max_key_code + 1, unsigned char); if (!map->modmap) return BadAlloc; } } return Success; } int XkbcAllocServerMap(struct xkb_keymap * xkb, unsigned which, unsigned nNewActions) { unsigned i; struct xkb_server_map * map; if (!xkb) return BadMatch; if (!xkb->server) { map = uTypedCalloc(1, struct xkb_server_map); if (!map) return BadAlloc; for (i = 0; i < XkbNumVirtualMods; i++) map->vmods[i] = XkbNoModifierMask; xkb->server = map; } else map = xkb->server; if (!which) return Success; if (!xkb_keymap_keycode_range_is_legal(xkb)) return BadMatch; if (!map->explicit) { i = xkb->max_key_code + 1; map->explicit = uTypedCalloc(i, unsigned char); if (!map->explicit) return BadAlloc; } if (nNewActions < 1) nNewActions = 1; if (!map->acts) { map->acts = uTypedCalloc(nNewActions + 1, union xkb_action); if (!map->acts) return BadAlloc; map->num_acts = 1; map->size_acts = nNewActions + 1; } else if ((map->size_acts - map->num_acts) < (int)nNewActions) { unsigned need; union xkb_action *prev_acts = map->acts; need = map->num_acts + nNewActions; map->acts = uTypedRealloc(map->acts, need, union xkb_action); if (!map->acts) { free(prev_acts); map->num_acts = map->size_acts = 0; return BadAlloc; } map->size_acts = need; memset(&map->acts[map->num_acts], 0, (map->size_acts - map->num_acts) * sizeof(union xkb_action)); } if (!map->key_acts) { i = xkb->max_key_code + 1; map->key_acts = uTypedCalloc(i, unsigned short); if (!map->key_acts) return BadAlloc; } if (!map->behaviors) { i = xkb->max_key_code + 1; map->behaviors = uTypedCalloc(i, struct xkb_behavior); if (!map->behaviors) return BadAlloc; } if (!map->vmodmap) { i = xkb->max_key_code + 1; map->vmodmap = uTypedCalloc(i, uint32_t); if (!map->vmodmap) return BadAlloc; } return Success; } int XkbcCopyKeyType(struct xkb_key_type * from, struct xkb_key_type * into) { int i; if (!from || !into) return BadMatch; free(into->map); into->map = NULL; free(into->preserve); into->preserve= NULL; for (i = 0; i < into->num_levels; i++) free(UNCONSTIFY(into->level_names[i])); free(into->level_names); into->level_names = NULL; *into = *from; if (from->map && (into->map_count > 0)) { into->map = uTypedCalloc(into->map_count, struct xkb_kt_map_entry); if (!into->map) return BadAlloc; memcpy(into->map, from->map, into->map_count * sizeof(struct xkb_kt_map_entry)); } if (from->preserve && (into->map_count > 0)) { into->preserve = uTypedCalloc(into->map_count, struct xkb_mods); if (!into->preserve) return BadAlloc; memcpy(into->preserve, from->preserve, into->map_count * sizeof(struct xkb_mods)); } if (from->level_names && (into->num_levels > 0)) { into->level_names = uTypedCalloc(into->num_levels, const char *); if (!into->level_names) return BadAlloc; for (i = 0; i < into->num_levels; i++) into->level_names[i] = strdup(from->level_names[i]); } return Success; } bool XkbcResizeKeySyms(struct xkb_keymap * xkb, xkb_keycode_t key, unsigned int needed) { if (xkb->map->key_sym_map[key].size_syms >= needed) return true; xkb->map->key_sym_map[key].syms = uTypedRecalloc(xkb->map->key_sym_map[key].syms, xkb->map->key_sym_map[key].size_syms, needed, xkb_keysym_t); if (!xkb->map->key_sym_map[key].syms) { xkb->map->key_sym_map[key].size_syms = 0; return false; } xkb->map->key_sym_map[key].size_syms = needed; return true; } union xkb_action * XkbcResizeKeyActions(struct xkb_keymap * xkb, xkb_keycode_t key, uint32_t needed) { xkb_keycode_t i, nActs; union xkb_action *newActs; if (needed == 0) { xkb->server->key_acts[key] = 0; return NULL; } if (XkbKeyHasActions(xkb, key) && (XkbKeyGroupsWidth(xkb, key) >= needed)) return XkbKeyActionsPtr(xkb, key); if (xkb->server->size_acts - xkb->server->num_acts >= (int)needed) { xkb->server->key_acts[key] = xkb->server->num_acts; xkb->server->num_acts += needed; return &xkb->server->acts[xkb->server->key_acts[key]]; } xkb->server->size_acts = xkb->server->num_acts + needed + 8; newActs = uTypedCalloc(xkb->server->size_acts, union xkb_action); if (!newActs) return NULL; newActs[0].type = XkbSA_NoAction; nActs = 1; for (i = xkb->min_key_code; i <= xkb->max_key_code; i++) { xkb_keycode_t nKeyActs, nCopy; if ((xkb->server->key_acts[i] == 0) && (i != key)) continue; nCopy = nKeyActs = XkbKeyNumActions(xkb, i); if (i == key) { nKeyActs= needed; if (needed < nCopy) nCopy = needed; } if (nCopy > 0) memcpy(&newActs[nActs], XkbKeyActionsPtr(xkb, i), nCopy * sizeof(union xkb_action)); if (nCopy < nKeyActs) memset(&newActs[nActs + nCopy], 0, (nKeyActs - nCopy) * sizeof(union xkb_action)); xkb->server->key_acts[i] = nActs; nActs += nKeyActs; } free(xkb->server->acts); xkb->server->acts = newActs; xkb->server->num_acts = nActs; return &xkb->server->acts[xkb->server->key_acts[key]]; } void XkbcFreeClientMap(struct xkb_keymap * xkb) { struct xkb_client_map * map; struct xkb_key_type * type; xkb_keycode_t key; int i; if (!xkb || !xkb->map) return; map = xkb->map; for (i = 0, type = map->types; i < map->num_types && type; i++, type++) { int j; free(type->map); free(type->preserve); for (j = 0; j < type->num_levels; j++) free(UNCONSTIFY(type->level_names[j])); free(type->level_names); free(UNCONSTIFY(type->name)); } free(map->types); if (map->key_sym_map) { for (key = xkb->min_key_code; key < xkb->max_key_code; key++) { free(map->key_sym_map[key].sym_index); free(map->key_sym_map[key].num_syms); free(map->key_sym_map[key].syms); } } free(map->key_sym_map); free(map->modmap); free(xkb->map); xkb->map = NULL; } void XkbcFreeServerMap(struct xkb_keymap * xkb) { struct xkb_server_map * map; if (!xkb || !xkb->server) return; map = xkb->server; free(map->explicit); free(map->key_acts); free(map->acts); free(map->behaviors); free(map->vmodmap); free(xkb->server); xkb->server = NULL; } int XkbcAllocCompatMap(struct xkb_keymap *xkb, unsigned nSI) { struct xkb_compat_map * compat; struct xkb_sym_interpret *prev_interpret; if (!xkb) return BadMatch; if (xkb->compat) { if (xkb->compat->size_si >= nSI) return Success; compat = xkb->compat; compat->size_si = nSI; if (!compat->sym_interpret) compat->num_si = 0; prev_interpret = compat->sym_interpret; compat->sym_interpret = uTypedRecalloc(compat->sym_interpret, compat->num_si, nSI, struct xkb_sym_interpret); if (!compat->sym_interpret) { free(prev_interpret); compat->size_si = compat->num_si = 0; return BadAlloc; } return Success; } compat = uTypedCalloc(1, struct xkb_compat_map); if (!compat) return BadAlloc; if (nSI > 0) { compat->sym_interpret = uTypedCalloc(nSI, struct xkb_sym_interpret); if (!compat->sym_interpret) { free(compat); return BadAlloc; } } compat->size_si = nSI; compat->num_si = 0; memset(&compat->groups[0], 0, XkbNumKbdGroups * sizeof(struct xkb_mods)); xkb->compat = compat; return Success; } static void XkbcFreeCompatMap(struct xkb_keymap * xkb) { struct xkb_compat_map * compat; if (!xkb || !xkb->compat) return; compat = xkb->compat; free(compat->sym_interpret); free(compat); xkb->compat = NULL; } int XkbcAllocNames(struct xkb_keymap * xkb, unsigned which, unsigned nTotalAliases) { struct xkb_names * names; if (!xkb) return BadMatch; if (!xkb->names) { xkb->names = uTypedCalloc(1, struct xkb_names); if (!xkb->names) return BadAlloc; } names = xkb->names; if ((which & XkbKTLevelNamesMask) && xkb->map && xkb->map->types) { int i; struct xkb_key_type * type; type = xkb->map->types; for (i = 0; i < xkb->map->num_types; i++, type++) { if (!type->level_names) { type->level_names = uTypedCalloc(type->num_levels, const char *); if (!type->level_names) return BadAlloc; } } } if ((which & XkbKeyNamesMask) && !names->keys) { if (!xkb_keymap_keycode_range_is_legal(xkb)) return BadMatch; names->keys = uTypedCalloc(xkb->max_key_code + 1, struct xkb_key_name); if (!names->keys) return BadAlloc; } if ((which & XkbKeyAliasesMask) && (nTotalAliases > 0)) { if (!names->key_aliases) names->key_aliases = uTypedCalloc(nTotalAliases, struct xkb_key_alias); else if (nTotalAliases > names->num_key_aliases) { struct xkb_key_alias *prev_aliases = names->key_aliases; names->key_aliases = uTypedRecalloc(names->key_aliases, names->num_key_aliases, nTotalAliases, struct xkb_key_alias); if (!names->key_aliases) free(prev_aliases); } if (!names->key_aliases) { names->num_key_aliases = 0; return BadAlloc; } names->num_key_aliases = nTotalAliases; } return Success; } static void XkbcFreeNames(struct xkb_keymap * xkb) { struct xkb_names * names; struct xkb_client_map * map; int i; if (!xkb || !xkb->names) return; names = xkb->names; map = xkb->map; if (map && map->types) { struct xkb_key_type * type = map->types; for (i = 0; i < map->num_types; i++, type++) { int j; for (j = 0; j < type->num_levels; j++) free(UNCONSTIFY(type->level_names[i])); free(type->level_names); type->level_names = NULL; } } for (i = 0; i < XkbNumVirtualMods; i++) free(UNCONSTIFY(names->vmods[i])); for (i = 0; i < XkbNumIndicators; i++) free(UNCONSTIFY(names->indicators[i])); for (i = 0; i < XkbNumKbdGroups; i++) free(UNCONSTIFY(names->groups[i])); free(names->keys); free(names->key_aliases); free(names); xkb->names = NULL; } int XkbcAllocControls(struct xkb_keymap * xkb) { if (!xkb) return BadMatch; if (!xkb->ctrls) { xkb->ctrls = uTypedCalloc(1, struct xkb_controls); if (!xkb->ctrls) return BadAlloc; } xkb->ctrls->per_key_repeat = uTypedCalloc(xkb->max_key_code << 3, unsigned char); if (!xkb->ctrls->per_key_repeat) return BadAlloc; return Success; } static void XkbcFreeControls(struct xkb_keymap * xkb) { if (xkb && xkb->ctrls) { free(xkb->ctrls->per_key_repeat); free(xkb->ctrls); xkb->ctrls = NULL; } } int XkbcAllocIndicatorMaps(struct xkb_keymap * xkb) { if (!xkb) return BadMatch; if (!xkb->indicators) { xkb->indicators = uTypedCalloc(1, struct xkb_indicator); if (!xkb->indicators) return BadAlloc; } return Success; } static void XkbcFreeIndicatorMaps(struct xkb_keymap * xkb) { if (xkb) { free(xkb->indicators); xkb->indicators = NULL; } } struct xkb_keymap * XkbcAllocKeyboard(struct xkb_context *context) { struct xkb_keymap *xkb; xkb = uTypedCalloc(1, struct xkb_keymap); if (!xkb) return NULL; xkb->refcnt = 1; xkb->context = xkb_context_ref(context); return xkb; } void XkbcFreeKeyboard(struct xkb_keymap * xkb) { if (!xkb) return; XkbcFreeClientMap(xkb); XkbcFreeServerMap(xkb); XkbcFreeCompatMap(xkb); XkbcFreeIndicatorMaps(xkb); XkbcFreeNames(xkb); XkbcFreeControls(xkb); xkb_context_unref(xkb->context); free(xkb); }