/* * Copyright (C) 2010 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include <ctype.h> #include <errno.h> #include <fcntl.h> #include <inttypes.h> #include <stdarg.h> #include <stddef.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <unistd.h> #include "init.h" #include "parser.h" #include "init_parser.h" #include "log.h" #include "property_service.h" #include "util.h" #include <cutils/iosched_policy.h> #include <cutils/list.h> static list_declare(service_list); static list_declare(action_list); static list_declare(action_queue); struct import { struct listnode list; const char *filename; }; static void *parse_service(struct parse_state *state, int nargs, char **args); static void parse_line_service(struct parse_state *state, int nargs, char **args); static void *parse_action(struct parse_state *state, int nargs, char **args); static void parse_line_action(struct parse_state *state, int nargs, char **args); #define SECTION 0x01 #define COMMAND 0x02 #define OPTION 0x04 #include "keywords.h" #define KEYWORD(symbol, flags, nargs, func) \ [ K_##symbol ] = { #symbol, func, nargs + 1, flags, }, static struct { const char *name; int (*func)(int nargs, char **args); unsigned char nargs; unsigned char flags; } keyword_info[KEYWORD_COUNT] = { [ K_UNKNOWN ] = { "unknown", 0, 0, 0 }, #include "keywords.h" }; #undef KEYWORD #define kw_is(kw, type) (keyword_info[kw].flags & (type)) #define kw_name(kw) (keyword_info[kw].name) #define kw_func(kw) (keyword_info[kw].func) #define kw_nargs(kw) (keyword_info[kw].nargs) void dump_parser_state() { if (false) { struct listnode* node; list_for_each(node, &service_list) { service* svc = node_to_item(node, struct service, slist); INFO("service %s\n", svc->name); INFO(" class '%s'\n", svc->classname); INFO(" exec"); for (int n = 0; n < svc->nargs; n++) { INFO(" '%s'", svc->args[n]); } INFO("\n"); for (socketinfo* si = svc->sockets; si; si = si->next) { INFO(" socket %s %s 0%o\n", si->name, si->type, si->perm); } } list_for_each(node, &action_list) { action* act = node_to_item(node, struct action, alist); INFO("on "); char name_str[256] = ""; build_triggers_string(name_str, sizeof(name_str), act); INFO("%s", name_str); INFO("\n"); struct listnode* node2; list_for_each(node2, &act->commands) { command* cmd = node_to_item(node2, struct command, clist); INFO(" %p", cmd->func); for (int n = 0; n < cmd->nargs; n++) { INFO(" %s", cmd->args[n]); } INFO("\n"); } INFO("\n"); } } } static int lookup_keyword(const char *s) { switch (*s++) { case 'b': if (!strcmp(s, "ootchart_init")) return K_bootchart_init; break; case 'c': if (!strcmp(s, "opy")) return K_copy; if (!strcmp(s, "lass")) return K_class; if (!strcmp(s, "lass_start")) return K_class_start; if (!strcmp(s, "lass_stop")) return K_class_stop; if (!strcmp(s, "lass_reset")) return K_class_reset; if (!strcmp(s, "onsole")) return K_console; if (!strcmp(s, "hown")) return K_chown; if (!strcmp(s, "hmod")) return K_chmod; if (!strcmp(s, "ritical")) return K_critical; break; case 'd': if (!strcmp(s, "isabled")) return K_disabled; if (!strcmp(s, "omainname")) return K_domainname; break; case 'e': if (!strcmp(s, "nable")) return K_enable; if (!strcmp(s, "xec")) return K_exec; if (!strcmp(s, "xport")) return K_export; break; case 'g': if (!strcmp(s, "roup")) return K_group; break; case 'h': if (!strcmp(s, "ostname")) return K_hostname; break; case 'i': if (!strcmp(s, "oprio")) return K_ioprio; if (!strcmp(s, "fup")) return K_ifup; if (!strcmp(s, "nsmod")) return K_insmod; if (!strcmp(s, "mport")) return K_import; if (!strcmp(s, "nstallkey")) return K_installkey; break; case 'k': if (!strcmp(s, "eycodes")) return K_keycodes; break; case 'l': if (!strcmp(s, "oglevel")) return K_loglevel; if (!strcmp(s, "oad_persist_props")) return K_load_persist_props; if (!strcmp(s, "oad_system_props")) return K_load_system_props; break; case 'm': if (!strcmp(s, "kdir")) return K_mkdir; if (!strcmp(s, "ount_all")) return K_mount_all; if (!strcmp(s, "ount")) return K_mount; break; case 'o': if (!strcmp(s, "n")) return K_on; if (!strcmp(s, "neshot")) return K_oneshot; if (!strcmp(s, "nrestart")) return K_onrestart; break; case 'p': if (!strcmp(s, "owerctl")) return K_powerctl; break; case 'r': if (!strcmp(s, "estart")) return K_restart; if (!strcmp(s, "estorecon")) return K_restorecon; if (!strcmp(s, "estorecon_recursive")) return K_restorecon_recursive; if (!strcmp(s, "mdir")) return K_rmdir; if (!strcmp(s, "m")) return K_rm; break; case 's': if (!strcmp(s, "eclabel")) return K_seclabel; if (!strcmp(s, "ervice")) return K_service; if (!strcmp(s, "etenv")) return K_setenv; if (!strcmp(s, "etprop")) return K_setprop; if (!strcmp(s, "etrlimit")) return K_setrlimit; if (!strcmp(s, "etusercryptopolicies")) return K_setusercryptopolicies; if (!strcmp(s, "ocket")) return K_socket; if (!strcmp(s, "tart")) return K_start; if (!strcmp(s, "top")) return K_stop; if (!strcmp(s, "wapon_all")) return K_swapon_all; if (!strcmp(s, "ymlink")) return K_symlink; if (!strcmp(s, "ysclktz")) return K_sysclktz; break; case 't': if (!strcmp(s, "rigger")) return K_trigger; break; case 'u': if (!strcmp(s, "ser")) return K_user; break; case 'v': if (!strcmp(s, "erity_load_state")) return K_verity_load_state; if (!strcmp(s, "erity_update_state")) return K_verity_update_state; break; case 'w': if (!strcmp(s, "rite")) return K_write; if (!strcmp(s, "ritepid")) return K_writepid; if (!strcmp(s, "ait")) return K_wait; break; } return K_UNKNOWN; } static void parse_line_no_op(struct parse_state*, int, char**) { } static int push_chars(char **dst, int *len, const char *chars, int cnt) { if (cnt > *len) return -1; memcpy(*dst, chars, cnt); *dst += cnt; *len -= cnt; return 0; } int expand_props(char *dst, const char *src, int dst_size) { char *dst_ptr = dst; const char *src_ptr = src; int ret = 0; int left = dst_size - 1; if (!src || !dst || dst_size == 0) return -1; /* - variables can either be $x.y or ${x.y}, in case they are only part * of the string. * - will accept $$ as a literal $. * - no nested property expansion, i.e. ${foo.${bar}} is not supported, * bad things will happen */ while (*src_ptr && left > 0) { char *c; char prop[PROP_NAME_MAX + 1]; char prop_val[PROP_VALUE_MAX]; int prop_len = 0; int prop_val_len; c = strchr(src_ptr, '$'); if (!c) { while (left-- > 0 && *src_ptr) *(dst_ptr++) = *(src_ptr++); break; } memset(prop, 0, sizeof(prop)); ret = push_chars(&dst_ptr, &left, src_ptr, c - src_ptr); if (ret < 0) goto err_nospace; c++; if (*c == '$') { *(dst_ptr++) = *(c++); src_ptr = c; left--; continue; } else if (*c == '\0') { break; } if (*c == '{') { c++; while (*c && *c != '}' && prop_len < PROP_NAME_MAX) prop[prop_len++] = *(c++); if (*c != '}') { /* failed to find closing brace, abort. */ if (prop_len == PROP_NAME_MAX) ERROR("prop name too long during expansion of '%s'\n", src); else if (*c == '\0') ERROR("unexpected end of string in '%s', looking for }\n", src); goto err; } prop[prop_len] = '\0'; c++; } else if (*c) { while (*c && prop_len < PROP_NAME_MAX) prop[prop_len++] = *(c++); if (prop_len == PROP_NAME_MAX && *c != '\0') { ERROR("prop name too long in '%s'\n", src); goto err; } prop[prop_len] = '\0'; ERROR("using deprecated syntax for specifying property '%s', use ${name} instead\n", prop); } if (prop_len == 0) { ERROR("invalid zero-length prop name in '%s'\n", src); goto err; } prop_val_len = property_get(prop, prop_val); if (!prop_val_len) { ERROR("property '%s' doesn't exist while expanding '%s'\n", prop, src); goto err; } ret = push_chars(&dst_ptr, &left, prop_val, prop_val_len); if (ret < 0) goto err_nospace; src_ptr = c; continue; } *dst_ptr = '\0'; return 0; err_nospace: ERROR("destination buffer overflow while expanding '%s'\n", src); err: return -1; } static void parse_import(struct parse_state *state, int nargs, char **args) { struct listnode *import_list = (listnode*) state->priv; char conf_file[PATH_MAX]; int ret; if (nargs != 2) { ERROR("single argument needed for import\n"); return; } ret = expand_props(conf_file, args[1], sizeof(conf_file)); if (ret) { ERROR("error while handling import on line '%d' in '%s'\n", state->line, state->filename); return; } struct import* import = (struct import*) calloc(1, sizeof(struct import)); import->filename = strdup(conf_file); list_add_tail(import_list, &import->list); INFO("Added '%s' to import list\n", import->filename); } static void parse_new_section(struct parse_state *state, int kw, int nargs, char **args) { printf("[ %s %s ]\n", args[0], nargs > 1 ? args[1] : ""); switch(kw) { case K_service: state->context = parse_service(state, nargs, args); if (state->context) { state->parse_line = parse_line_service; return; } break; case K_on: state->context = parse_action(state, nargs, args); if (state->context) { state->parse_line = parse_line_action; return; } break; case K_import: parse_import(state, nargs, args); break; } state->parse_line = parse_line_no_op; } static void parse_config(const char *fn, const std::string& data) { struct listnode import_list; struct listnode *node; char *args[INIT_PARSER_MAXARGS]; int nargs = 0; parse_state state; state.filename = fn; state.line = 0; state.ptr = strdup(data.c_str()); // TODO: fix this code! state.nexttoken = 0; state.parse_line = parse_line_no_op; list_init(&import_list); state.priv = &import_list; for (;;) { switch (next_token(&state)) { case T_EOF: state.parse_line(&state, 0, 0); goto parser_done; case T_NEWLINE: state.line++; if (nargs) { int kw = lookup_keyword(args[0]); if (kw_is(kw, SECTION)) { state.parse_line(&state, 0, 0); parse_new_section(&state, kw, nargs, args); } else { state.parse_line(&state, nargs, args); } nargs = 0; } break; case T_TEXT: if (nargs < INIT_PARSER_MAXARGS) { args[nargs++] = state.text; } break; } } parser_done: list_for_each(node, &import_list) { struct import *import = node_to_item(node, struct import, list); int ret; ret = init_parse_config_file(import->filename); if (ret) ERROR("could not import file '%s' from '%s'\n", import->filename, fn); } } int init_parse_config_file(const char* path) { INFO("Parsing %s...\n", path); Timer t; std::string data; if (!read_file(path, &data)) { return -1; } data.push_back('\n'); // TODO: fix parse_config. parse_config(path, data); dump_parser_state(); NOTICE("(Parsing %s took %.2fs.)\n", path, t.duration()); return 0; } static int valid_name(const char *name) { if (strlen(name) > 16) { return 0; } while (*name) { if (!isalnum(*name) && (*name != '_') && (*name != '-')) { return 0; } name++; } return 1; } struct service *service_find_by_name(const char *name) { struct listnode *node; struct service *svc; list_for_each(node, &service_list) { svc = node_to_item(node, struct service, slist); if (!strcmp(svc->name, name)) { return svc; } } return 0; } struct service *service_find_by_pid(pid_t pid) { struct listnode *node; struct service *svc; list_for_each(node, &service_list) { svc = node_to_item(node, struct service, slist); if (svc->pid == pid) { return svc; } } return 0; } struct service *service_find_by_keychord(int keychord_id) { struct listnode *node; struct service *svc; list_for_each(node, &service_list) { svc = node_to_item(node, struct service, slist); if (svc->keychord_id == keychord_id) { return svc; } } return 0; } void service_for_each(void (*func)(struct service *svc)) { struct listnode *node; struct service *svc; list_for_each(node, &service_list) { svc = node_to_item(node, struct service, slist); func(svc); } } void service_for_each_class(const char *classname, void (*func)(struct service *svc)) { struct listnode *node; struct service *svc; list_for_each(node, &service_list) { svc = node_to_item(node, struct service, slist); if (!strcmp(svc->classname, classname)) { func(svc); } } } void service_for_each_flags(unsigned matchflags, void (*func)(struct service *svc)) { struct listnode *node; struct service *svc; list_for_each(node, &service_list) { svc = node_to_item(node, struct service, slist); if (svc->flags & matchflags) { func(svc); } } } void action_for_each_trigger(const char *trigger, void (*func)(struct action *act)) { struct listnode *node, *node2; struct action *act; struct trigger *cur_trigger; list_for_each(node, &action_list) { act = node_to_item(node, struct action, alist); list_for_each(node2, &act->triggers) { cur_trigger = node_to_item(node2, struct trigger, nlist); if (!strcmp(cur_trigger->name, trigger)) { func(act); } } } } void queue_property_triggers(const char *name, const char *value) { struct listnode *node, *node2; struct action *act; struct trigger *cur_trigger; bool match; int name_length; list_for_each(node, &action_list) { act = node_to_item(node, struct action, alist); match = !name; list_for_each(node2, &act->triggers) { cur_trigger = node_to_item(node2, struct trigger, nlist); if (!strncmp(cur_trigger->name, "property:", strlen("property:"))) { const char *test = cur_trigger->name + strlen("property:"); if (!match) { name_length = strlen(name); if (!strncmp(name, test, name_length) && test[name_length] == '=' && (!strcmp(test + name_length + 1, value) || !strcmp(test + name_length + 1, "*"))) { match = true; continue; } } const char* equals = strchr(test, '='); if (equals) { char prop_name[PROP_NAME_MAX + 1]; char value[PROP_VALUE_MAX]; int length = equals - test; if (length <= PROP_NAME_MAX) { int ret; memcpy(prop_name, test, length); prop_name[length] = 0; /* does the property exist, and match the trigger value? */ ret = property_get(prop_name, value); if (ret > 0 && (!strcmp(equals + 1, value) || !strcmp(equals + 1, "*"))) { continue; } } } } match = false; break; } if (match) { action_add_queue_tail(act); } } } void queue_all_property_triggers() { queue_property_triggers(NULL, NULL); } void queue_builtin_action(int (*func)(int nargs, char **args), const char *name) { action* act = (action*) calloc(1, sizeof(*act)); trigger* cur_trigger = (trigger*) calloc(1, sizeof(*cur_trigger)); cur_trigger->name = name; list_init(&act->triggers); list_add_tail(&act->triggers, &cur_trigger->nlist); list_init(&act->commands); list_init(&act->qlist); command* cmd = (command*) calloc(1, sizeof(*cmd)); cmd->func = func; cmd->args[0] = const_cast<char*>(name); cmd->nargs = 1; list_add_tail(&act->commands, &cmd->clist); list_add_tail(&action_list, &act->alist); action_add_queue_tail(act); } void action_add_queue_tail(struct action *act) { if (list_empty(&act->qlist)) { list_add_tail(&action_queue, &act->qlist); } } struct action *action_remove_queue_head(void) { if (list_empty(&action_queue)) { return 0; } else { struct listnode *node = list_head(&action_queue); struct action *act = node_to_item(node, struct action, qlist); list_remove(node); list_init(node); return act; } } int action_queue_empty() { return list_empty(&action_queue); } service* make_exec_oneshot_service(int nargs, char** args) { // Parse the arguments: exec [SECLABEL [UID [GID]*] --] COMMAND ARGS... // SECLABEL can be a - to denote default int command_arg = 1; for (int i = 1; i < nargs; ++i) { if (strcmp(args[i], "--") == 0) { command_arg = i + 1; break; } } if (command_arg > 4 + NR_SVC_SUPP_GIDS) { ERROR("exec called with too many supplementary group ids\n"); return NULL; } int argc = nargs - command_arg; char** argv = (args + command_arg); if (argc < 1) { ERROR("exec called without command\n"); return NULL; } service* svc = (service*) calloc(1, sizeof(*svc) + sizeof(char*) * argc); if (svc == NULL) { ERROR("Couldn't allocate service for exec of '%s': %s", argv[0], strerror(errno)); return NULL; } if ((command_arg > 2) && strcmp(args[1], "-")) { svc->seclabel = args[1]; } if (command_arg > 3) { svc->uid = decode_uid(args[2]); } if (command_arg > 4) { svc->gid = decode_uid(args[3]); svc->nr_supp_gids = command_arg - 1 /* -- */ - 4 /* exec SECLABEL UID GID */; for (size_t i = 0; i < svc->nr_supp_gids; ++i) { svc->supp_gids[i] = decode_uid(args[4 + i]); } } static int exec_count; // Every service needs a unique name. char* name = NULL; asprintf(&name, "exec %d (%s)", exec_count++, argv[0]); if (name == NULL) { ERROR("Couldn't allocate name for exec service '%s'\n", argv[0]); free(svc); return NULL; } svc->name = name; svc->classname = "default"; svc->flags = SVC_EXEC | SVC_ONESHOT; svc->nargs = argc; memcpy(svc->args, argv, sizeof(char*) * svc->nargs); svc->args[argc] = NULL; list_add_tail(&service_list, &svc->slist); return svc; } static void *parse_service(struct parse_state *state, int nargs, char **args) { if (nargs < 3) { parse_error(state, "services must have a name and a program\n"); return 0; } if (!valid_name(args[1])) { parse_error(state, "invalid service name '%s'\n", args[1]); return 0; } service* svc = (service*) service_find_by_name(args[1]); if (svc) { parse_error(state, "ignored duplicate definition of service '%s'\n", args[1]); return 0; } nargs -= 2; svc = (service*) calloc(1, sizeof(*svc) + sizeof(char*) * nargs); if (!svc) { parse_error(state, "out of memory\n"); return 0; } svc->name = strdup(args[1]); svc->classname = "default"; memcpy(svc->args, args + 2, sizeof(char*) * nargs); trigger* cur_trigger = (trigger*) calloc(1, sizeof(*cur_trigger)); svc->args[nargs] = 0; svc->nargs = nargs; list_init(&svc->onrestart.triggers); cur_trigger->name = "onrestart"; list_add_tail(&svc->onrestart.triggers, &cur_trigger->nlist); list_init(&svc->onrestart.commands); list_add_tail(&service_list, &svc->slist); return svc; } static void parse_line_service(struct parse_state *state, int nargs, char **args) { struct service *svc = (service*) state->context; struct command *cmd; int i, kw, kw_nargs; if (nargs == 0) { return; } svc->ioprio_class = IoSchedClass_NONE; kw = lookup_keyword(args[0]); switch (kw) { case K_class: if (nargs != 2) { parse_error(state, "class option requires a classname\n"); } else { svc->classname = args[1]; } break; case K_console: svc->flags |= SVC_CONSOLE; break; case K_disabled: svc->flags |= SVC_DISABLED; svc->flags |= SVC_RC_DISABLED; break; case K_ioprio: if (nargs != 3) { parse_error(state, "ioprio optin usage: ioprio <rt|be|idle> <ioprio 0-7>\n"); } else { svc->ioprio_pri = strtoul(args[2], 0, 8); if (svc->ioprio_pri < 0 || svc->ioprio_pri > 7) { parse_error(state, "priority value must be range 0 - 7\n"); break; } if (!strcmp(args[1], "rt")) { svc->ioprio_class = IoSchedClass_RT; } else if (!strcmp(args[1], "be")) { svc->ioprio_class = IoSchedClass_BE; } else if (!strcmp(args[1], "idle")) { svc->ioprio_class = IoSchedClass_IDLE; } else { parse_error(state, "ioprio option usage: ioprio <rt|be|idle> <0-7>\n"); } } break; case K_group: if (nargs < 2) { parse_error(state, "group option requires a group id\n"); } else if (nargs > NR_SVC_SUPP_GIDS + 2) { parse_error(state, "group option accepts at most %d supp. groups\n", NR_SVC_SUPP_GIDS); } else { int n; svc->gid = decode_uid(args[1]); for (n = 2; n < nargs; n++) { svc->supp_gids[n-2] = decode_uid(args[n]); } svc->nr_supp_gids = n - 2; } break; case K_keycodes: if (nargs < 2) { parse_error(state, "keycodes option requires atleast one keycode\n"); } else { svc->keycodes = (int*) malloc((nargs - 1) * sizeof(svc->keycodes[0])); if (!svc->keycodes) { parse_error(state, "could not allocate keycodes\n"); } else { svc->nkeycodes = nargs - 1; for (i = 1; i < nargs; i++) { svc->keycodes[i - 1] = atoi(args[i]); } } } break; case K_oneshot: svc->flags |= SVC_ONESHOT; break; case K_onrestart: nargs--; args++; kw = lookup_keyword(args[0]); if (!kw_is(kw, COMMAND)) { parse_error(state, "invalid command '%s'\n", args[0]); break; } kw_nargs = kw_nargs(kw); if (nargs < kw_nargs) { parse_error(state, "%s requires %d %s\n", args[0], kw_nargs - 1, kw_nargs > 2 ? "arguments" : "argument"); break; } cmd = (command*) malloc(sizeof(*cmd) + sizeof(char*) * nargs); cmd->func = kw_func(kw); cmd->nargs = nargs; memcpy(cmd->args, args, sizeof(char*) * nargs); list_add_tail(&svc->onrestart.commands, &cmd->clist); break; case K_critical: svc->flags |= SVC_CRITICAL; break; case K_setenv: { /* name value */ if (nargs < 3) { parse_error(state, "setenv option requires name and value arguments\n"); break; } svcenvinfo* ei = (svcenvinfo*) calloc(1, sizeof(*ei)); if (!ei) { parse_error(state, "out of memory\n"); break; } ei->name = args[1]; ei->value = args[2]; ei->next = svc->envvars; svc->envvars = ei; break; } case K_socket: {/* name type perm [ uid gid context ] */ if (nargs < 4) { parse_error(state, "socket option requires name, type, perm arguments\n"); break; } if (strcmp(args[2],"dgram") && strcmp(args[2],"stream") && strcmp(args[2],"seqpacket")) { parse_error(state, "socket type must be 'dgram', 'stream' or 'seqpacket'\n"); break; } socketinfo* si = (socketinfo*) calloc(1, sizeof(*si)); if (!si) { parse_error(state, "out of memory\n"); break; } si->name = args[1]; si->type = args[2]; si->perm = strtoul(args[3], 0, 8); if (nargs > 4) si->uid = decode_uid(args[4]); if (nargs > 5) si->gid = decode_uid(args[5]); if (nargs > 6) si->socketcon = args[6]; si->next = svc->sockets; svc->sockets = si; break; } case K_user: if (nargs != 2) { parse_error(state, "user option requires a user id\n"); } else { svc->uid = decode_uid(args[1]); } break; case K_seclabel: if (nargs != 2) { parse_error(state, "seclabel option requires a label string\n"); } else { svc->seclabel = args[1]; } break; case K_writepid: if (nargs < 2) { parse_error(state, "writepid option requires at least one filename\n"); break; } svc->writepid_files_ = new std::vector<std::string>; for (int i = 1; i < nargs; ++i) { svc->writepid_files_->push_back(args[i]); } break; default: parse_error(state, "invalid option '%s'\n", args[0]); } } static void *parse_action(struct parse_state *state, int nargs, char **args) { struct trigger *cur_trigger; int i; if (nargs < 2) { parse_error(state, "actions must have a trigger\n"); return 0; } action* act = (action*) calloc(1, sizeof(*act)); list_init(&act->triggers); for (i = 1; i < nargs; i++) { if (!(i % 2)) { if (strcmp(args[i], "&&")) { struct listnode *node; struct listnode *node2; parse_error(state, "& is the only symbol allowed to concatenate actions\n"); list_for_each_safe(node, node2, &act->triggers) { struct trigger *trigger = node_to_item(node, struct trigger, nlist); free(trigger); } free(act); return 0; } else continue; } cur_trigger = (trigger*) calloc(1, sizeof(*cur_trigger)); cur_trigger->name = args[i]; list_add_tail(&act->triggers, &cur_trigger->nlist); } list_init(&act->commands); list_init(&act->qlist); list_add_tail(&action_list, &act->alist); /* XXX add to hash */ return act; } static void parse_line_action(struct parse_state* state, int nargs, char **args) { struct action *act = (action*) state->context; int kw, n; if (nargs == 0) { return; } kw = lookup_keyword(args[0]); if (!kw_is(kw, COMMAND)) { parse_error(state, "invalid command '%s'\n", args[0]); return; } n = kw_nargs(kw); if (nargs < n) { parse_error(state, "%s requires %d %s\n", args[0], n - 1, n > 2 ? "arguments" : "argument"); return; } command* cmd = (command*) malloc(sizeof(*cmd) + sizeof(char*) * nargs); cmd->func = kw_func(kw); cmd->line = state->line; cmd->filename = state->filename; cmd->nargs = nargs; memcpy(cmd->args, args, sizeof(char*) * nargs); list_add_tail(&act->commands, &cmd->clist); }