/************************************************************ * Copyright (c) 1994 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. * ********************************************************/ /* * Copyright © 2012 Intel Corporation * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. * * Author: Daniel Stone */ #include "xkbcomp-priv.h" #include "text.h" #define BUF_CHUNK_SIZE 4096 struct buf { char *buf; size_t size; size_t alloc; }; static bool do_realloc(struct buf *buf, size_t at_least) { char *new; buf->alloc += BUF_CHUNK_SIZE; if (at_least >= BUF_CHUNK_SIZE) buf->alloc += at_least; new = realloc(buf->buf, buf->alloc); if (!new) return false; buf->buf = new; return true; } ATTR_PRINTF(2, 3) static bool check_write_buf(struct buf *buf, const char *fmt, ...) { va_list args; int printed; size_t available; available = buf->alloc - buf->size; va_start(args, fmt); printed = vsnprintf(buf->buf + buf->size, available, fmt, args); va_end(args); if (printed < 0) goto err; if (printed >= available) if (!do_realloc(buf, printed)) goto err; /* The buffer has enough space now. */ available = buf->alloc - buf->size; va_start(args, fmt); printed = vsnprintf(buf->buf + buf->size, available, fmt, args); va_end(args); if (printed >= available || printed < 0) goto err; buf->size += printed; return true; err: free(buf->buf); buf->buf = NULL; return false; } #define write_buf(buf, ...) do { \ if (!check_write_buf(buf, __VA_ARGS__)) \ return false; \ } while (0) static bool write_vmods(struct xkb_keymap *keymap, struct buf *buf) { const struct xkb_mod *mod; xkb_mod_index_t num_vmods = 0; darray_foreach(mod, keymap->mods) { if (mod->type != MOD_VIRT) continue; if (num_vmods == 0) write_buf(buf, "\tvirtual_modifiers "); else write_buf(buf, ","); write_buf(buf, "%s", xkb_atom_text(keymap->ctx, mod->name)); num_vmods++; } if (num_vmods > 0) write_buf(buf, ";\n\n"); return true; } static bool write_keycodes(struct xkb_keymap *keymap, struct buf *buf) { const struct xkb_key *key; xkb_led_index_t idx; const struct xkb_led *led; if (keymap->keycodes_section_name) write_buf(buf, "xkb_keycodes \"%s\" {\n", keymap->keycodes_section_name); else write_buf(buf, "xkb_keycodes {\n"); xkb_foreach_key(key, keymap) { if (key->name == XKB_ATOM_NONE) continue; write_buf(buf, "\t%-20s = %d;\n", KeyNameText(keymap->ctx, key->name), key->keycode); } darray_enumerate(idx, led, keymap->leds) if (led->name != XKB_ATOM_NONE) write_buf(buf, "\tindicator %d = \"%s\";\n", idx + 1, xkb_atom_text(keymap->ctx, led->name)); for (unsigned i = 0; i < keymap->num_key_aliases; i++) write_buf(buf, "\talias %-14s = %s;\n", KeyNameText(keymap->ctx, keymap->key_aliases[i].alias), KeyNameText(keymap->ctx, keymap->key_aliases[i].real)); write_buf(buf, "};\n\n"); return true; } static bool write_types(struct xkb_keymap *keymap, struct buf *buf) { if (keymap->types_section_name) write_buf(buf, "xkb_types \"%s\" {\n", keymap->types_section_name); else write_buf(buf, "xkb_types {\n"); write_vmods(keymap, buf); for (unsigned i = 0; i < keymap->num_types; i++) { const struct xkb_key_type *type = &keymap->types[i]; write_buf(buf, "\ttype \"%s\" {\n", xkb_atom_text(keymap->ctx, type->name)); write_buf(buf, "\t\tmodifiers= %s;\n", ModMaskText(keymap, type->mods.mods)); for (unsigned j = 0; j < type->num_entries; j++) { const char *str; const struct xkb_key_type_entry *entry = &type->entries[j]; /* * Printing level 1 entries is redundant, it's the default, * unless there's preserve info. */ if (entry->level == 0 && entry->preserve.mods == 0) continue; str = ModMaskText(keymap, entry->mods.mods); write_buf(buf, "\t\tmap[%s]= Level%d;\n", str, entry->level + 1); if (entry->preserve.mods) write_buf(buf, "\t\tpreserve[%s]= %s;\n", str, ModMaskText(keymap, entry->preserve.mods)); } for (xkb_level_index_t n = 0; n < type->num_levels; n++) if (type->level_names[n]) write_buf(buf, "\t\tlevel_name[Level%d]= \"%s\";\n", n + 1, xkb_atom_text(keymap->ctx, type->level_names[n])); write_buf(buf, "\t};\n"); } write_buf(buf, "};\n\n"); return true; } static bool write_led_map(struct xkb_keymap *keymap, struct buf *buf, const struct xkb_led *led) { write_buf(buf, "\tindicator \"%s\" {\n", xkb_atom_text(keymap->ctx, led->name)); if (led->which_groups) { if (led->which_groups != XKB_STATE_LAYOUT_EFFECTIVE) { write_buf(buf, "\t\twhichGroupState= %s;\n", LedStateMaskText(keymap->ctx, led->which_groups)); } write_buf(buf, "\t\tgroups= 0x%02x;\n", led->groups); } if (led->which_mods) { if (led->which_mods != XKB_STATE_MODS_EFFECTIVE) { write_buf(buf, "\t\twhichModState= %s;\n", LedStateMaskText(keymap->ctx, led->which_mods)); } write_buf(buf, "\t\tmodifiers= %s;\n", ModMaskText(keymap, led->mods.mods)); } if (led->ctrls) { write_buf(buf, "\t\tcontrols= %s;\n", ControlMaskText(keymap->ctx, led->ctrls)); } write_buf(buf, "\t};\n"); return true; } static bool write_action(struct xkb_keymap *keymap, struct buf *buf, const union xkb_action *action, const char *prefix, const char *suffix) { const char *type; const char *args = NULL; if (!prefix) prefix = ""; if (!suffix) suffix = ""; type = ActionTypeText(action->type); switch (action->type) { case ACTION_TYPE_MOD_SET: case ACTION_TYPE_MOD_LATCH: case ACTION_TYPE_MOD_LOCK: if (action->mods.flags & ACTION_MODS_LOOKUP_MODMAP) args = "modMapMods"; else args = ModMaskText(keymap, action->mods.mods.mods); write_buf(buf, "%s%s(modifiers=%s%s%s)%s", prefix, type, args, (action->type != ACTION_TYPE_MOD_LOCK && (action->mods.flags & ACTION_LOCK_CLEAR)) ? ",clearLocks" : "", (action->type != ACTION_TYPE_MOD_LOCK && (action->mods.flags & ACTION_LATCH_TO_LOCK)) ? ",latchToLock" : "", suffix); break; case ACTION_TYPE_GROUP_SET: case ACTION_TYPE_GROUP_LATCH: case ACTION_TYPE_GROUP_LOCK: write_buf(buf, "%s%s(group=%s%d%s%s)%s", prefix, type, (!(action->group.flags & ACTION_ABSOLUTE_SWITCH) && action->group.group > 0) ? "+" : "", (action->group.flags & ACTION_ABSOLUTE_SWITCH) ? action->group.group + 1 : action->group.group, (action->type != ACTION_TYPE_GROUP_LOCK && (action->group.flags & ACTION_LOCK_CLEAR)) ? ",clearLocks" : "", (action->type != ACTION_TYPE_GROUP_LOCK && (action->group.flags & ACTION_LATCH_TO_LOCK)) ? ",latchToLock" : "", suffix); break; case ACTION_TYPE_TERMINATE: write_buf(buf, "%s%s()%s", prefix, type, suffix); break; case ACTION_TYPE_PTR_MOVE: write_buf(buf, "%s%s(x=%s%d,y=%s%d%s)%s", prefix, type, (!(action->ptr.flags & ACTION_ABSOLUTE_X) && action->ptr.x >= 0) ? "+" : "", action->ptr.x, (!(action->ptr.flags & ACTION_ABSOLUTE_Y) && action->ptr.y >= 0) ? "+" : "", action->ptr.y, (action->ptr.flags & ACTION_NO_ACCEL) ? ",!accel" : "", suffix); break; case ACTION_TYPE_PTR_LOCK: switch (action->btn.flags & (ACTION_LOCK_NO_LOCK | ACTION_LOCK_NO_UNLOCK)) { case ACTION_LOCK_NO_UNLOCK: args = ",affect=lock"; break; case ACTION_LOCK_NO_LOCK: args = ",affect=unlock"; break; case ACTION_LOCK_NO_LOCK | ACTION_LOCK_NO_UNLOCK: args = ",affect=neither"; break; default: args = ",affect=both"; break; } case ACTION_TYPE_PTR_BUTTON: write_buf(buf, "%s%s(button=", prefix, type); if (action->btn.button > 0 && action->btn.button <= 5) write_buf(buf, "%d", action->btn.button); else write_buf(buf, "default"); if (action->btn.count) write_buf(buf, ",count=%d", action->btn.count); if (args) write_buf(buf, "%s", args); write_buf(buf, ")%s", suffix); break; case ACTION_TYPE_PTR_DEFAULT: write_buf(buf, "%s%s(", prefix, type); write_buf(buf, "affect=button,button=%s%d", (!(action->dflt.flags & ACTION_ABSOLUTE_SWITCH) && action->dflt.value >= 0) ? "+" : "", action->dflt.value); write_buf(buf, ")%s", suffix); break; case ACTION_TYPE_SWITCH_VT: write_buf(buf, "%s%s(screen=%s%d,%ssame)%s", prefix, type, (!(action->screen.flags & ACTION_ABSOLUTE_SWITCH) && action->screen.screen >= 0) ? "+" : "", action->screen.screen, (action->screen.flags & ACTION_SAME_SCREEN) ? "!" : "", suffix); break; case ACTION_TYPE_CTRL_SET: case ACTION_TYPE_CTRL_LOCK: write_buf(buf, "%s%s(controls=%s)%s", prefix, type, ControlMaskText(keymap->ctx, action->ctrls.ctrls), suffix); break; case ACTION_TYPE_NONE: write_buf(buf, "%sNoAction()%s", prefix, suffix); break; default: write_buf(buf, "%s%s(type=0x%02x,data[0]=0x%02x,data[1]=0x%02x,data[2]=0x%02x,data[3]=0x%02x,data[4]=0x%02x,data[5]=0x%02x,data[6]=0x%02x)%s", prefix, type, action->type, action->priv.data[0], action->priv.data[1], action->priv.data[2], action->priv.data[3], action->priv.data[4], action->priv.data[5], action->priv.data[6], suffix); break; } return true; } static bool write_compat(struct xkb_keymap *keymap, struct buf *buf) { const struct xkb_sym_interpret *si; const struct xkb_led *led; if (keymap->compat_section_name) write_buf(buf, "xkb_compatibility \"%s\" {\n", keymap->compat_section_name); else write_buf(buf, "xkb_compatibility {\n"); write_vmods(keymap, buf); write_buf(buf, "\tinterpret.useModMapMods= AnyLevel;\n"); write_buf(buf, "\tinterpret.repeat= False;\n"); darray_foreach(si, keymap->sym_interprets) { write_buf(buf, "\tinterpret %s+%s(%s) {\n", si->sym ? KeysymText(keymap->ctx, si->sym) : "Any", SIMatchText(si->match), ModMaskText(keymap, si->mods)); if (si->virtual_mod != XKB_MOD_INVALID) write_buf(buf, "\t\tvirtualModifier= %s;\n", ModIndexText(keymap, si->virtual_mod)); if (si->level_one_only) write_buf(buf, "\t\tuseModMapMods=level1;\n"); if (si->repeat) write_buf(buf, "\t\trepeat= True;\n"); write_action(keymap, buf, &si->action, "\t\taction= ", ";\n"); write_buf(buf, "\t};\n"); } darray_foreach(led, keymap->leds) if (led->which_groups || led->groups || led->which_mods || led->mods.mods || led->ctrls) write_led_map(keymap, buf, led); write_buf(buf, "};\n\n"); return true; } static bool write_keysyms(struct xkb_keymap *keymap, struct buf *buf, const struct xkb_key *key, xkb_layout_index_t group) { for (xkb_level_index_t level = 0; level < XkbKeyGroupWidth(key, group); level++) { const xkb_keysym_t *syms; int num_syms; if (level != 0) write_buf(buf, ", "); num_syms = xkb_keymap_key_get_syms_by_level(keymap, key->keycode, group, level, &syms); if (num_syms == 0) { write_buf(buf, "%15s", "NoSymbol"); } else if (num_syms == 1) { write_buf(buf, "%15s", KeysymText(keymap->ctx, syms[0])); } else { write_buf(buf, "{ "); for (int s = 0; s < num_syms; s++) { if (s != 0) write_buf(buf, ", "); write_buf(buf, "%s", KeysymText(keymap->ctx, syms[s])); } write_buf(buf, " }"); } } return true; } static bool write_key(struct xkb_keymap *keymap, struct buf *buf, const struct xkb_key *key) { xkb_layout_index_t group; bool simple = true; bool explicit_types = false; bool multi_type = false; bool show_actions; write_buf(buf, "\tkey %-20s {", KeyNameText(keymap->ctx, key->name)); for (group = 0; group < key->num_groups; group++) { if (key->groups[group].explicit_type) explicit_types = true; if (group != 0 && key->groups[group].type != key->groups[0].type) multi_type = true; } if (explicit_types) { const struct xkb_key_type *type; simple = false; if (multi_type) { for (group = 0; group < key->num_groups; group++) { if (!key->groups[group].explicit_type) continue; type = key->groups[group].type; write_buf(buf, "\n\t\ttype[group%u]= \"%s\",", group + 1, xkb_atom_text(keymap->ctx, type->name)); } } else { type = key->groups[0].type; write_buf(buf, "\n\t\ttype= \"%s\",", xkb_atom_text(keymap->ctx, type->name)); } } if (key->explicit & EXPLICIT_REPEAT) { if (key->repeats) write_buf(buf, "\n\t\trepeat= Yes,"); else write_buf(buf, "\n\t\trepeat= No,"); simple = false; } if (key->vmodmap && (key->explicit & EXPLICIT_VMODMAP)) write_buf(buf, "\n\t\tvirtualMods= %s,", ModMaskText(keymap, key->vmodmap)); switch (key->out_of_range_group_action) { case RANGE_SATURATE: write_buf(buf, "\n\t\tgroupsClamp,"); break; case RANGE_REDIRECT: write_buf(buf, "\n\t\tgroupsRedirect= Group%u,", key->out_of_range_group_number + 1); break; default: break; } show_actions = !!(key->explicit & EXPLICIT_INTERP); if (key->num_groups > 1 || show_actions) simple = false; if (simple) { write_buf(buf, "\t[ "); if (!write_keysyms(keymap, buf, key, 0)) return false; write_buf(buf, " ] };\n"); } else { xkb_level_index_t level; for (group = 0; group < key->num_groups; group++) { if (group != 0) write_buf(buf, ","); write_buf(buf, "\n\t\tsymbols[Group%u]= [ ", group + 1); if (!write_keysyms(keymap, buf, key, group)) return false; write_buf(buf, " ]"); if (show_actions) { write_buf(buf, ",\n\t\tactions[Group%u]= [ ", group + 1); for (level = 0; level < XkbKeyGroupWidth(key, group); level++) { if (level != 0) write_buf(buf, ", "); write_action(keymap, buf, &key->groups[group].levels[level].action, NULL, NULL); } write_buf(buf, " ]"); } } write_buf(buf, "\n\t};\n"); } return true; } static bool write_symbols(struct xkb_keymap *keymap, struct buf *buf) { const struct xkb_key *key; xkb_layout_index_t group; if (keymap->symbols_section_name) write_buf(buf, "xkb_symbols \"%s\" {\n", keymap->symbols_section_name); else write_buf(buf, "xkb_symbols {\n"); for (group = 0; group < keymap->num_group_names; group++) if (keymap->group_names[group]) write_buf(buf, "\tname[group%d]=\"%s\";\n", group + 1, xkb_atom_text(keymap->ctx, keymap->group_names[group])); if (group > 0) write_buf(buf, "\n"); xkb_foreach_key(key, keymap) if (key->num_groups > 0) write_key(keymap, buf, key); xkb_foreach_key(key, keymap) { xkb_mod_index_t i; const struct xkb_mod *mod; if (key->modmap == 0) continue; darray_enumerate(i, mod, keymap->mods) if (key->modmap & (1 << i)) write_buf(buf, "\tmodifier_map %s { %s };\n", xkb_atom_text(keymap->ctx, mod->name), KeyNameText(keymap->ctx, key->name)); } write_buf(buf, "};\n\n"); return true; } static bool write_keymap(struct xkb_keymap *keymap, struct buf *buf) { return (check_write_buf(buf, "xkb_keymap {\n") && write_keycodes(keymap, buf) && write_types(keymap, buf) && write_compat(keymap, buf) && write_symbols(keymap, buf) && check_write_buf(buf, "};\n")); } char * text_v1_keymap_get_as_string(struct xkb_keymap *keymap) { struct buf buf = { NULL, 0, 0 }; if (!write_keymap(keymap, &buf)) { free(buf.buf); return NULL; } return buf.buf; }