#undef I3__FILE__ #define I3__FILE__ "commands_parser.c" /* * vim:ts=4:sw=4:expandtab * * i3 - an improved dynamic tiling window manager * © 2009-2012 Michael Stapelberg and contributors (see also: LICENSE) * * commands_parser.c: hand-written parser to parse commands (commands are what * you bind on keys and what you can send to i3 using the IPC interface, like * 'move left' or 'workspace 4'). * * We use a hand-written parser instead of lex/yacc because our commands are * easy for humans, not for computers. Thus, it’s quite hard to specify a * context-free grammar for the commands. A PEG grammar would be easier, but * there’s downsides to every PEG parser generator I have come across so far. * * This parser is basically a state machine which looks for literals or strings * and can push either on a stack. After identifying a literal or string, it * will either transition to the current state, to a different state, or call a * function (like cmd_move()). * * Special care has been taken that error messages are useful and the code is * well testable (when compiled with -DTEST_PARSER it will output to stdout * instead of actually calling any function). * */ #include #include #include #include #include #include #include "all.h" // Macros to make the YAJL API a bit easier to use. #define y(x, ...) yajl_gen_ ## x (command_output.json_gen, ##__VA_ARGS__) #define ystr(str) yajl_gen_string(command_output.json_gen, (unsigned char*)str, strlen(str)) /******************************************************************************* * The data structures used for parsing. Essentially the current state and a * list of tokens for that state. * * The GENERATED_* files are generated by generate-commands-parser.pl with the * input parser-specs/commands.spec. ******************************************************************************/ #include "GENERATED_command_enums.h" typedef struct token { char *name; char *identifier; /* This might be __CALL */ cmdp_state next_state; union { uint16_t call_identifier; } extra; } cmdp_token; typedef struct tokenptr { cmdp_token *array; int n; } cmdp_token_ptr; #include "GENERATED_command_tokens.h" /******************************************************************************* * The (small) stack where identified literals are stored during the parsing * of a single command (like $workspace). ******************************************************************************/ struct stack_entry { /* Just a pointer, not dynamically allocated. */ const char *identifier; char *str; }; /* 10 entries should be enough for everybody. */ static struct stack_entry stack[10]; /* * Pushes a string (identified by 'identifier') on the stack. We simply use a * single array, since the number of entries we have to store is very small. * */ static void push_string(const char *identifier, char *str) { for (int c = 0; c < 10; c++) { if (stack[c].identifier != NULL) continue; /* Found a free slot, let’s store it here. */ stack[c].identifier = identifier; stack[c].str = str; return; } /* When we arrive here, the stack is full. This should not happen and * means there’s either a bug in this parser or the specification * contains a command with more than 10 identified tokens. */ fprintf(stderr, "BUG: commands_parser stack full. This means either a bug " "in the code, or a new command which contains more than " "10 identified tokens.\n"); exit(1); } // XXX: ideally, this would be const char. need to check if that works with all // called functions. static char *get_string(const char *identifier) { for (int c = 0; c < 10; c++) { if (stack[c].identifier == NULL) break; if (strcmp(identifier, stack[c].identifier) == 0) return stack[c].str; } return NULL; } static void clear_stack(void) { for (int c = 0; c < 10; c++) { if (stack[c].str != NULL) free(stack[c].str); stack[c].identifier = NULL; stack[c].str = NULL; } } // TODO: remove this if it turns out we don’t need it for testing. #if 0 /******************************************************************************* * A dynamically growing linked list which holds the criteria for the current * command. ******************************************************************************/ typedef struct criterion { char *type; char *value; TAILQ_ENTRY(criterion) criteria; } criterion; static TAILQ_HEAD(criteria_head, criterion) criteria = TAILQ_HEAD_INITIALIZER(criteria); /* * Stores the given type/value in the list of criteria. * Accepts a pointer as first argument, since it is 'call'ed by the parser. * */ static void push_criterion(void *unused_criteria, const char *type, const char *value) { struct criterion *criterion = malloc(sizeof(struct criterion)); criterion->type = strdup(type); criterion->value = strdup(value); TAILQ_INSERT_TAIL(&criteria, criterion, criteria); } /* * Clears the criteria linked list. * Accepts a pointer as first argument, since it is 'call'ed by the parser. * */ static void clear_criteria(void *unused_criteria) { struct criterion *criterion; while (!TAILQ_EMPTY(&criteria)) { criterion = TAILQ_FIRST(&criteria); free(criterion->type); free(criterion->value); TAILQ_REMOVE(&criteria, criterion, criteria); free(criterion); } } #endif /******************************************************************************* * The parser itself. ******************************************************************************/ static cmdp_state state; #ifndef TEST_PARSER static Match current_match; #endif static struct CommandResult subcommand_output; static struct CommandResult command_output; #include "GENERATED_command_call.h" static void next_state(const cmdp_token *token) { if (token->next_state == __CALL) { subcommand_output.json_gen = command_output.json_gen; subcommand_output.needs_tree_render = false; GENERATED_call(token->extra.call_identifier, &subcommand_output); state = subcommand_output.next_state; /* If any subcommand requires a tree_render(), we need to make the * whole parser result request a tree_render(). */ if (subcommand_output.needs_tree_render) command_output.needs_tree_render = true; clear_stack(); return; } state = token->next_state; if (state == INITIAL) { clear_stack(); } } struct CommandResult *parse_command(const char *input) { DLOG("COMMAND: *%s*\n", input); state = INITIAL; /* A YAJL JSON generator used for formatting replies. */ #if YAJL_MAJOR >= 2 command_output.json_gen = yajl_gen_alloc(NULL); #else command_output.json_gen = yajl_gen_alloc(NULL, NULL); #endif y(array_open); command_output.needs_tree_render = false; const char *walk = input; const size_t len = strlen(input); int c; const cmdp_token *token; bool token_handled; // TODO: make this testable #ifndef TEST_PARSER cmd_criteria_init(¤t_match, &subcommand_output); #endif /* The "<=" operator is intentional: We also handle the terminating 0-byte * explicitly by looking for an 'end' token. */ while ((size_t)(walk - input) <= len) { /* skip whitespace and newlines before every token */ while ((*walk == ' ' || *walk == '\t' || *walk == '\r' || *walk == '\n') && *walk != '\0') walk++; cmdp_token_ptr *ptr = &(tokens[state]); token_handled = false; for (c = 0; c < ptr->n; c++) { token = &(ptr->array[c]); /* A literal. */ if (token->name[0] == '\'') { if (strncasecmp(walk, token->name + 1, strlen(token->name) - 1) == 0) { if (token->identifier != NULL) push_string(token->identifier, sstrdup(token->name + 1)); walk += strlen(token->name) - 1; next_state(token); token_handled = true; break; } continue; } if (strcmp(token->name, "string") == 0 || strcmp(token->name, "word") == 0) { const char *beginning = walk; /* Handle quoted strings (or words). */ if (*walk == '"') { beginning++; walk++; while (*walk != '\0' && (*walk != '"' || *(walk-1) == '\\')) walk++; } else { if (token->name[0] == 's') { /* For a string (starting with 's'), the delimiters are * comma (,) and semicolon (;) which introduce a new * operation or command, respectively. Also, newlines * end a command. */ while (*walk != ';' && *walk != ',' && *walk != '\0' && *walk != '\r' && *walk != '\n') walk++; } else { /* For a word, the delimiters are white space (' ' or * '\t'), closing square bracket (]), comma (,) and * semicolon (;). */ while (*walk != ' ' && *walk != '\t' && *walk != ']' && *walk != ',' && *walk != ';' && *walk != '\r' && *walk != '\n' && *walk != '\0') walk++; } } if (walk != beginning) { char *str = scalloc(walk-beginning + 1); /* We copy manually to handle escaping of characters. */ int inpos, outpos; for (inpos = 0, outpos = 0; inpos < (walk-beginning); inpos++, outpos++) { /* We only handle escaped double quotes to not break * backwards compatibility with people using \w in * regular expressions etc. */ if (beginning[inpos] == '\\' && beginning[inpos+1] == '"') inpos++; str[outpos] = beginning[inpos]; } if (token->identifier) push_string(token->identifier, str); /* If we are at the end of a quoted string, skip the ending * double quote. */ if (*walk == '"') walk++; next_state(token); token_handled = true; break; } } if (strcmp(token->name, "end") == 0) { if (*walk == '\0' || *walk == ',' || *walk == ';') { next_state(token); token_handled = true; /* To make sure we start with an appropriate matching * datastructure for commands which do *not* specify any * criteria, we re-initialize the criteria system after * every command. */ // TODO: make this testable #ifndef TEST_PARSER if (*walk == '\0' || *walk == ';') cmd_criteria_init(¤t_match, &subcommand_output); #endif walk++; break; } } } if (!token_handled) { /* Figure out how much memory we will need to fill in the names of * all tokens afterwards. */ int tokenlen = 0; for (c = 0; c < ptr->n; c++) tokenlen += strlen(ptr->array[c].name) + strlen("'', "); /* Build up a decent error message. We include the problem, the * full input, and underline the position where the parser * currently is. */ char *errormessage; char *possible_tokens = smalloc(tokenlen + 1); char *tokenwalk = possible_tokens; for (c = 0; c < ptr->n; c++) { token = &(ptr->array[c]); if (token->name[0] == '\'') { /* A literal is copied to the error message enclosed with * single quotes. */ *tokenwalk++ = '\''; strcpy(tokenwalk, token->name + 1); tokenwalk += strlen(token->name + 1); *tokenwalk++ = '\''; } else { /* Any other token is copied to the error message enclosed * with angle brackets. */ *tokenwalk++ = '<'; strcpy(tokenwalk, token->name); tokenwalk += strlen(token->name); *tokenwalk++ = '>'; } if (c < (ptr->n - 1)) { *tokenwalk++ = ','; *tokenwalk++ = ' '; } } *tokenwalk = '\0'; sasprintf(&errormessage, "Expected one of these tokens: %s", possible_tokens); free(possible_tokens); /* Contains the same amount of characters as 'input' has, but with * the unparseable part highlighted using ^ characters. */ char *position = smalloc(len + 1); for (const char *copywalk = input; *copywalk != '\0'; copywalk++) position[(copywalk - input)] = (copywalk >= walk ? '^' : ' '); position[len] = '\0'; ELOG("%s\n", errormessage); ELOG("Your command: %s\n", input); ELOG(" %s\n", position); /* Format this error message as a JSON reply. */ y(map_open); ystr("success"); y(bool, false); /* We set parse_error to true to distinguish this from other * errors. i3-nagbar is spawned upon keypresses only for parser * errors. */ ystr("parse_error"); y(bool, true); ystr("error"); ystr(errormessage); ystr("input"); ystr(input); ystr("errorposition"); ystr(position); y(map_close); free(position); free(errormessage); clear_stack(); break; } } y(array_close); return &command_output; } /******************************************************************************* * Code for building the stand-alone binary test.commands_parser which is used * by t/187-commands-parser.t. ******************************************************************************/ #ifdef TEST_PARSER /* * Logs the given message to stdout while prefixing the current time to it, * but only if debug logging was activated. * This is to be called by DLOG() which includes filename/linenumber * */ void debuglog(char *fmt, ...) { va_list args; va_start(args, fmt); fprintf(stdout, "# "); vfprintf(stdout, fmt, args); va_end(args); } void errorlog(char *fmt, ...) { va_list args; va_start(args, fmt); vfprintf(stderr, fmt, args); va_end(args); } int main(int argc, char *argv[]) { if (argc < 2) { fprintf(stderr, "Syntax: %s \n", argv[0]); return 1; } parse_command(argv[1]); } #endif