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      1 /*
      2  * Copyright (C) 2009, 2010 Red Hat Inc, Steven Rostedt <srostedt (at) redhat.com>
      3  *
      4  * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
      5  * This program is free software; you can redistribute it and/or
      6  * modify it under the terms of the GNU Lesser General Public
      7  * License as published by the Free Software Foundation;
      8  * version 2.1 of the License (not later!)
      9  *
     10  * This program is distributed in the hope that it will be useful,
     11  * but WITHOUT ANY WARRANTY; without even the implied warranty of
     12  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
     13  * GNU Lesser General Public License for more details.
     14  *
     15  * You should have received a copy of the GNU Lesser General Public
     16  * License along with this program; if not,  see <http://www.gnu.org/licenses>
     17  *
     18  * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
     19  *
     20  *  The parts for function graph printing was taken and modified from the
     21  *  Linux Kernel that were written by
     22  *    - Copyright (C) 2009  Frederic Weisbecker,
     23  *  Frederic Weisbecker gave his permission to relicense the code to
     24  *  the Lesser General Public License.
     25  */
     26 #include <stdio.h>
     27 #include <stdlib.h>
     28 #include <string.h>
     29 #include <stdarg.h>
     30 #include <ctype.h>
     31 #include <errno.h>
     32 #include <stdint.h>
     33 #include <limits.h>
     34 
     35 #include "event-parse.h"
     36 #include "event-utils.h"
     37 
     38 static const char *input_buf;
     39 static unsigned long long input_buf_ptr;
     40 static unsigned long long input_buf_siz;
     41 
     42 static int is_flag_field;
     43 static int is_symbolic_field;
     44 
     45 static int show_warning = 1;
     46 
     47 #define do_warning(fmt, ...)				\
     48 	do {						\
     49 		if (show_warning)			\
     50 			warning(fmt, ##__VA_ARGS__);	\
     51 	} while (0)
     52 
     53 static void init_input_buf(const char *buf, unsigned long long size)
     54 {
     55 	input_buf = buf;
     56 	input_buf_siz = size;
     57 	input_buf_ptr = 0;
     58 }
     59 
     60 const char *pevent_get_input_buf(void)
     61 {
     62 	return input_buf;
     63 }
     64 
     65 unsigned long long pevent_get_input_buf_ptr(void)
     66 {
     67 	return input_buf_ptr;
     68 }
     69 
     70 struct event_handler {
     71 	struct event_handler		*next;
     72 	int				id;
     73 	const char			*sys_name;
     74 	const char			*event_name;
     75 	pevent_event_handler_func	func;
     76 	void				*context;
     77 };
     78 
     79 struct pevent_func_params {
     80 	struct pevent_func_params	*next;
     81 	enum pevent_func_arg_type	type;
     82 };
     83 
     84 struct pevent_function_handler {
     85 	struct pevent_function_handler	*next;
     86 	enum pevent_func_arg_type	ret_type;
     87 	char				*name;
     88 	pevent_func_handler		func;
     89 	struct pevent_func_params	*params;
     90 	int				nr_args;
     91 };
     92 
     93 static unsigned long long
     94 process_defined_func(struct trace_seq *s, void *data, int size,
     95 		     struct event_format *event, struct print_arg *arg);
     96 
     97 static void free_func_handle(struct pevent_function_handler *func);
     98 
     99 /**
    100  * pevent_buffer_init - init buffer for parsing
    101  * @buf: buffer to parse
    102  * @size: the size of the buffer
    103  *
    104  * For use with pevent_read_token(), this initializes the internal
    105  * buffer that pevent_read_token() will parse.
    106  */
    107 void pevent_buffer_init(const char *buf, unsigned long long size)
    108 {
    109 	init_input_buf(buf, size);
    110 }
    111 
    112 void breakpoint(void)
    113 {
    114 	static int x;
    115 	x++;
    116 }
    117 
    118 struct print_arg *alloc_arg(void)
    119 {
    120 	return calloc(1, sizeof(struct print_arg));
    121 }
    122 
    123 struct cmdline {
    124 	char *comm;
    125 	int pid;
    126 };
    127 
    128 static int cmdline_cmp(const void *a, const void *b)
    129 {
    130 	const struct cmdline *ca = a;
    131 	const struct cmdline *cb = b;
    132 
    133 	if (ca->pid < cb->pid)
    134 		return -1;
    135 	if (ca->pid > cb->pid)
    136 		return 1;
    137 
    138 	return 0;
    139 }
    140 
    141 struct cmdline_list {
    142 	struct cmdline_list	*next;
    143 	char			*comm;
    144 	int			pid;
    145 };
    146 
    147 static int cmdline_init(struct pevent *pevent)
    148 {
    149 	struct cmdline_list *cmdlist = pevent->cmdlist;
    150 	struct cmdline_list *item;
    151 	struct cmdline *cmdlines;
    152 	int i;
    153 
    154 	cmdlines = malloc(sizeof(*cmdlines) * pevent->cmdline_count);
    155 	if (!cmdlines)
    156 		return -1;
    157 
    158 	i = 0;
    159 	while (cmdlist) {
    160 		cmdlines[i].pid = cmdlist->pid;
    161 		cmdlines[i].comm = cmdlist->comm;
    162 		i++;
    163 		item = cmdlist;
    164 		cmdlist = cmdlist->next;
    165 		free(item);
    166 	}
    167 
    168 	qsort(cmdlines, pevent->cmdline_count, sizeof(*cmdlines), cmdline_cmp);
    169 
    170 	pevent->cmdlines = cmdlines;
    171 	pevent->cmdlist = NULL;
    172 
    173 	return 0;
    174 }
    175 
    176 static const char *find_cmdline(struct pevent *pevent, int pid)
    177 {
    178 	const struct cmdline *comm;
    179 	struct cmdline key;
    180 
    181 	if (!pid)
    182 		return "<idle>";
    183 
    184 	if (!pevent->cmdlines && cmdline_init(pevent))
    185 		return "<not enough memory for cmdlines!>";
    186 
    187 	key.pid = pid;
    188 
    189 	comm = bsearch(&key, pevent->cmdlines, pevent->cmdline_count,
    190 		       sizeof(*pevent->cmdlines), cmdline_cmp);
    191 
    192 	if (comm)
    193 		return comm->comm;
    194 	return "<...>";
    195 }
    196 
    197 /**
    198  * pevent_pid_is_registered - return if a pid has a cmdline registered
    199  * @pevent: handle for the pevent
    200  * @pid: The pid to check if it has a cmdline registered with.
    201  *
    202  * Returns 1 if the pid has a cmdline mapped to it
    203  * 0 otherwise.
    204  */
    205 int pevent_pid_is_registered(struct pevent *pevent, int pid)
    206 {
    207 	const struct cmdline *comm;
    208 	struct cmdline key;
    209 
    210 	if (!pid)
    211 		return 1;
    212 
    213 	if (!pevent->cmdlines && cmdline_init(pevent))
    214 		return 0;
    215 
    216 	key.pid = pid;
    217 
    218 	comm = bsearch(&key, pevent->cmdlines, pevent->cmdline_count,
    219 		       sizeof(*pevent->cmdlines), cmdline_cmp);
    220 
    221 	if (comm)
    222 		return 1;
    223 	return 0;
    224 }
    225 
    226 /*
    227  * If the command lines have been converted to an array, then
    228  * we must add this pid. This is much slower than when cmdlines
    229  * are added before the array is initialized.
    230  */
    231 static int add_new_comm(struct pevent *pevent, const char *comm, int pid)
    232 {
    233 	struct cmdline *cmdlines = pevent->cmdlines;
    234 	const struct cmdline *cmdline;
    235 	struct cmdline key;
    236 
    237 	if (!pid)
    238 		return 0;
    239 
    240 	/* avoid duplicates */
    241 	key.pid = pid;
    242 
    243 	cmdline = bsearch(&key, pevent->cmdlines, pevent->cmdline_count,
    244 		       sizeof(*pevent->cmdlines), cmdline_cmp);
    245 	if (cmdline) {
    246 		errno = EEXIST;
    247 		return -1;
    248 	}
    249 
    250 	cmdlines = realloc(cmdlines, sizeof(*cmdlines) * (pevent->cmdline_count + 1));
    251 	if (!cmdlines) {
    252 		errno = ENOMEM;
    253 		return -1;
    254 	}
    255 
    256 	cmdlines[pevent->cmdline_count].comm = strdup(comm);
    257 	if (!cmdlines[pevent->cmdline_count].comm) {
    258 		free(cmdlines);
    259 		errno = ENOMEM;
    260 		return -1;
    261 	}
    262 
    263 	cmdlines[pevent->cmdline_count].pid = pid;
    264 
    265 	if (cmdlines[pevent->cmdline_count].comm)
    266 		pevent->cmdline_count++;
    267 
    268 	qsort(cmdlines, pevent->cmdline_count, sizeof(*cmdlines), cmdline_cmp);
    269 	pevent->cmdlines = cmdlines;
    270 
    271 	return 0;
    272 }
    273 
    274 /**
    275  * pevent_register_comm - register a pid / comm mapping
    276  * @pevent: handle for the pevent
    277  * @comm: the command line to register
    278  * @pid: the pid to map the command line to
    279  *
    280  * This adds a mapping to search for command line names with
    281  * a given pid. The comm is duplicated.
    282  */
    283 int pevent_register_comm(struct pevent *pevent, const char *comm, int pid)
    284 {
    285 	struct cmdline_list *item;
    286 
    287 	if (pevent->cmdlines)
    288 		return add_new_comm(pevent, comm, pid);
    289 
    290 	item = malloc(sizeof(*item));
    291 	if (!item)
    292 		return -1;
    293 
    294 	item->comm = strdup(comm);
    295 	if (!item->comm) {
    296 		free(item);
    297 		return -1;
    298 	}
    299 	item->pid = pid;
    300 	item->next = pevent->cmdlist;
    301 
    302 	pevent->cmdlist = item;
    303 	pevent->cmdline_count++;
    304 
    305 	return 0;
    306 }
    307 
    308 struct func_map {
    309 	unsigned long long		addr;
    310 	char				*func;
    311 	char				*mod;
    312 };
    313 
    314 struct func_list {
    315 	struct func_list	*next;
    316 	unsigned long long	addr;
    317 	char			*func;
    318 	char			*mod;
    319 };
    320 
    321 static int func_cmp(const void *a, const void *b)
    322 {
    323 	const struct func_map *fa = a;
    324 	const struct func_map *fb = b;
    325 
    326 	if (fa->addr < fb->addr)
    327 		return -1;
    328 	if (fa->addr > fb->addr)
    329 		return 1;
    330 
    331 	return 0;
    332 }
    333 
    334 /*
    335  * We are searching for a record in between, not an exact
    336  * match.
    337  */
    338 static int func_bcmp(const void *a, const void *b)
    339 {
    340 	const struct func_map *fa = a;
    341 	const struct func_map *fb = b;
    342 
    343 	if ((fa->addr == fb->addr) ||
    344 
    345 	    (fa->addr > fb->addr &&
    346 	     fa->addr < (fb+1)->addr))
    347 		return 0;
    348 
    349 	if (fa->addr < fb->addr)
    350 		return -1;
    351 
    352 	return 1;
    353 }
    354 
    355 static int func_map_init(struct pevent *pevent)
    356 {
    357 	struct func_list *funclist;
    358 	struct func_list *item;
    359 	struct func_map *func_map;
    360 	int i;
    361 
    362 	func_map = malloc(sizeof(*func_map) * (pevent->func_count + 1));
    363 	if (!func_map)
    364 		return -1;
    365 
    366 	funclist = pevent->funclist;
    367 
    368 	i = 0;
    369 	while (funclist) {
    370 		func_map[i].func = funclist->func;
    371 		func_map[i].addr = funclist->addr;
    372 		func_map[i].mod = funclist->mod;
    373 		i++;
    374 		item = funclist;
    375 		funclist = funclist->next;
    376 		free(item);
    377 	}
    378 
    379 	qsort(func_map, pevent->func_count, sizeof(*func_map), func_cmp);
    380 
    381 	/*
    382 	 * Add a special record at the end.
    383 	 */
    384 	func_map[pevent->func_count].func = NULL;
    385 	func_map[pevent->func_count].addr = 0;
    386 	func_map[pevent->func_count].mod = NULL;
    387 
    388 	pevent->func_map = func_map;
    389 	pevent->funclist = NULL;
    390 
    391 	return 0;
    392 }
    393 
    394 static struct func_map *
    395 find_func(struct pevent *pevent, unsigned long long addr)
    396 {
    397 	struct func_map *func;
    398 	struct func_map key;
    399 
    400 	if (!pevent->func_map)
    401 		func_map_init(pevent);
    402 
    403 	key.addr = addr;
    404 
    405 	func = bsearch(&key, pevent->func_map, pevent->func_count,
    406 		       sizeof(*pevent->func_map), func_bcmp);
    407 
    408 	return func;
    409 }
    410 
    411 /**
    412  * pevent_find_function - find a function by a given address
    413  * @pevent: handle for the pevent
    414  * @addr: the address to find the function with
    415  *
    416  * Returns a pointer to the function stored that has the given
    417  * address. Note, the address does not have to be exact, it
    418  * will select the function that would contain the address.
    419  */
    420 const char *pevent_find_function(struct pevent *pevent, unsigned long long addr)
    421 {
    422 	struct func_map *map;
    423 
    424 	map = find_func(pevent, addr);
    425 	if (!map)
    426 		return NULL;
    427 
    428 	return map->func;
    429 }
    430 
    431 /**
    432  * pevent_find_function_address - find a function address by a given address
    433  * @pevent: handle for the pevent
    434  * @addr: the address to find the function with
    435  *
    436  * Returns the address the function starts at. This can be used in
    437  * conjunction with pevent_find_function to print both the function
    438  * name and the function offset.
    439  */
    440 unsigned long long
    441 pevent_find_function_address(struct pevent *pevent, unsigned long long addr)
    442 {
    443 	struct func_map *map;
    444 
    445 	map = find_func(pevent, addr);
    446 	if (!map)
    447 		return 0;
    448 
    449 	return map->addr;
    450 }
    451 
    452 /**
    453  * pevent_register_function - register a function with a given address
    454  * @pevent: handle for the pevent
    455  * @function: the function name to register
    456  * @addr: the address the function starts at
    457  * @mod: the kernel module the function may be in (NULL for none)
    458  *
    459  * This registers a function name with an address and module.
    460  * The @func passed in is duplicated.
    461  */
    462 int pevent_register_function(struct pevent *pevent, char *func,
    463 			     unsigned long long addr, char *mod)
    464 {
    465 	struct func_list *item = malloc(sizeof(*item));
    466 
    467 	if (!item)
    468 		return -1;
    469 
    470 	item->next = pevent->funclist;
    471 	item->func = strdup(func);
    472 	if (!item->func)
    473 		goto out_free;
    474 
    475 	if (mod) {
    476 		item->mod = strdup(mod);
    477 		if (!item->mod)
    478 			goto out_free_func;
    479 	} else
    480 		item->mod = NULL;
    481 	item->addr = addr;
    482 
    483 	pevent->funclist = item;
    484 	pevent->func_count++;
    485 
    486 	return 0;
    487 
    488 out_free_func:
    489 	free(item->func);
    490 	item->func = NULL;
    491 out_free:
    492 	free(item);
    493 	errno = ENOMEM;
    494 	return -1;
    495 }
    496 
    497 /**
    498  * pevent_print_funcs - print out the stored functions
    499  * @pevent: handle for the pevent
    500  *
    501  * This prints out the stored functions.
    502  */
    503 void pevent_print_funcs(struct pevent *pevent)
    504 {
    505 	int i;
    506 
    507 	if (!pevent->func_map)
    508 		func_map_init(pevent);
    509 
    510 	for (i = 0; i < (int)pevent->func_count; i++) {
    511 		printf("%016llx %s",
    512 		       pevent->func_map[i].addr,
    513 		       pevent->func_map[i].func);
    514 		if (pevent->func_map[i].mod)
    515 			printf(" [%s]\n", pevent->func_map[i].mod);
    516 		else
    517 			printf("\n");
    518 	}
    519 }
    520 
    521 struct printk_map {
    522 	unsigned long long		addr;
    523 	char				*printk;
    524 };
    525 
    526 struct printk_list {
    527 	struct printk_list	*next;
    528 	unsigned long long	addr;
    529 	char			*printk;
    530 };
    531 
    532 static int printk_cmp(const void *a, const void *b)
    533 {
    534 	const struct printk_map *pa = a;
    535 	const struct printk_map *pb = b;
    536 
    537 	if (pa->addr < pb->addr)
    538 		return -1;
    539 	if (pa->addr > pb->addr)
    540 		return 1;
    541 
    542 	return 0;
    543 }
    544 
    545 static int printk_map_init(struct pevent *pevent)
    546 {
    547 	struct printk_list *printklist;
    548 	struct printk_list *item;
    549 	struct printk_map *printk_map;
    550 	int i;
    551 
    552 	printk_map = malloc(sizeof(*printk_map) * (pevent->printk_count + 1));
    553 	if (!printk_map)
    554 		return -1;
    555 
    556 	printklist = pevent->printklist;
    557 
    558 	i = 0;
    559 	while (printklist) {
    560 		printk_map[i].printk = printklist->printk;
    561 		printk_map[i].addr = printklist->addr;
    562 		i++;
    563 		item = printklist;
    564 		printklist = printklist->next;
    565 		free(item);
    566 	}
    567 
    568 	qsort(printk_map, pevent->printk_count, sizeof(*printk_map), printk_cmp);
    569 
    570 	pevent->printk_map = printk_map;
    571 	pevent->printklist = NULL;
    572 
    573 	return 0;
    574 }
    575 
    576 static struct printk_map *
    577 find_printk(struct pevent *pevent, unsigned long long addr)
    578 {
    579 	struct printk_map *printk;
    580 	struct printk_map key;
    581 
    582 	if (!pevent->printk_map && printk_map_init(pevent))
    583 		return NULL;
    584 
    585 	key.addr = addr;
    586 
    587 	printk = bsearch(&key, pevent->printk_map, pevent->printk_count,
    588 			 sizeof(*pevent->printk_map), printk_cmp);
    589 
    590 	return printk;
    591 }
    592 
    593 /**
    594  * pevent_register_print_string - register a string by its address
    595  * @pevent: handle for the pevent
    596  * @fmt: the string format to register
    597  * @addr: the address the string was located at
    598  *
    599  * This registers a string by the address it was stored in the kernel.
    600  * The @fmt passed in is duplicated.
    601  */
    602 int pevent_register_print_string(struct pevent *pevent, char *fmt,
    603 				 unsigned long long addr)
    604 {
    605 	struct printk_list *item = malloc(sizeof(*item));
    606 
    607 	if (!item)
    608 		return -1;
    609 
    610 	item->next = pevent->printklist;
    611 	item->addr = addr;
    612 
    613 	item->printk = strdup(fmt);
    614 	if (!item->printk)
    615 		goto out_free;
    616 
    617 	pevent->printklist = item;
    618 	pevent->printk_count++;
    619 
    620 	return 0;
    621 
    622 out_free:
    623 	free(item);
    624 	errno = ENOMEM;
    625 	return -1;
    626 }
    627 
    628 /**
    629  * pevent_print_printk - print out the stored strings
    630  * @pevent: handle for the pevent
    631  *
    632  * This prints the string formats that were stored.
    633  */
    634 void pevent_print_printk(struct pevent *pevent)
    635 {
    636 	int i;
    637 
    638 	if (!pevent->printk_map)
    639 		printk_map_init(pevent);
    640 
    641 	for (i = 0; i < (int)pevent->printk_count; i++) {
    642 		printf("%016llx %s\n",
    643 		       pevent->printk_map[i].addr,
    644 		       pevent->printk_map[i].printk);
    645 	}
    646 }
    647 
    648 static struct event_format *alloc_event(void)
    649 {
    650 	return calloc(1, sizeof(struct event_format));
    651 }
    652 
    653 static int add_event(struct pevent *pevent, struct event_format *event)
    654 {
    655 	int i;
    656 	struct event_format **events = realloc(pevent->events, sizeof(event) *
    657 					       (pevent->nr_events + 1));
    658 	if (!events)
    659 		return -1;
    660 
    661 	pevent->events = events;
    662 
    663 	for (i = 0; i < pevent->nr_events; i++) {
    664 		if (pevent->events[i]->id > event->id)
    665 			break;
    666 	}
    667 	if (i < pevent->nr_events)
    668 		memmove(&pevent->events[i + 1],
    669 			&pevent->events[i],
    670 			sizeof(event) * (pevent->nr_events - i));
    671 
    672 	pevent->events[i] = event;
    673 	pevent->nr_events++;
    674 
    675 	event->pevent = pevent;
    676 
    677 	return 0;
    678 }
    679 
    680 static int event_item_type(enum event_type type)
    681 {
    682 	switch (type) {
    683 	case EVENT_ITEM ... EVENT_SQUOTE:
    684 		return 1;
    685 	case EVENT_ERROR ... EVENT_DELIM:
    686 	default:
    687 		return 0;
    688 	}
    689 }
    690 
    691 static void free_flag_sym(struct print_flag_sym *fsym)
    692 {
    693 	struct print_flag_sym *next;
    694 
    695 	while (fsym) {
    696 		next = fsym->next;
    697 		free(fsym->value);
    698 		free(fsym->str);
    699 		free(fsym);
    700 		fsym = next;
    701 	}
    702 }
    703 
    704 static void free_arg(struct print_arg *arg)
    705 {
    706 	struct print_arg *farg;
    707 
    708 	if (!arg)
    709 		return;
    710 
    711 	switch (arg->type) {
    712 	case PRINT_ATOM:
    713 		free(arg->atom.atom);
    714 		break;
    715 	case PRINT_FIELD:
    716 		free(arg->field.name);
    717 		break;
    718 	case PRINT_FLAGS:
    719 		free_arg(arg->flags.field);
    720 		free(arg->flags.delim);
    721 		free_flag_sym(arg->flags.flags);
    722 		break;
    723 	case PRINT_SYMBOL:
    724 		free_arg(arg->symbol.field);
    725 		free_flag_sym(arg->symbol.symbols);
    726 		break;
    727 	case PRINT_HEX:
    728 		free_arg(arg->hex.field);
    729 		free_arg(arg->hex.size);
    730 		break;
    731 	case PRINT_TYPE:
    732 		free(arg->typecast.type);
    733 		free_arg(arg->typecast.item);
    734 		break;
    735 	case PRINT_STRING:
    736 	case PRINT_BSTRING:
    737 		free(arg->string.string);
    738 		break;
    739 	case PRINT_DYNAMIC_ARRAY:
    740 		free(arg->dynarray.index);
    741 		break;
    742 	case PRINT_OP:
    743 		free(arg->op.op);
    744 		free_arg(arg->op.left);
    745 		free_arg(arg->op.right);
    746 		break;
    747 	case PRINT_FUNC:
    748 		while (arg->func.args) {
    749 			farg = arg->func.args;
    750 			arg->func.args = farg->next;
    751 			free_arg(farg);
    752 		}
    753 		break;
    754 
    755 	case PRINT_NULL:
    756 	default:
    757 		break;
    758 	}
    759 
    760 	free(arg);
    761 }
    762 
    763 static enum event_type get_type(int ch)
    764 {
    765 	if (ch == '\n')
    766 		return EVENT_NEWLINE;
    767 	if (isspace(ch))
    768 		return EVENT_SPACE;
    769 	if (isalnum(ch) || ch == '_')
    770 		return EVENT_ITEM;
    771 	if (ch == '\'')
    772 		return EVENT_SQUOTE;
    773 	if (ch == '"')
    774 		return EVENT_DQUOTE;
    775 	if (!isprint(ch))
    776 		return EVENT_NONE;
    777 	if (ch == '(' || ch == ')' || ch == ',')
    778 		return EVENT_DELIM;
    779 
    780 	return EVENT_OP;
    781 }
    782 
    783 static int __read_char(void)
    784 {
    785 	if (input_buf_ptr >= input_buf_siz)
    786 		return -1;
    787 
    788 	return input_buf[input_buf_ptr++];
    789 }
    790 
    791 static int __peek_char(void)
    792 {
    793 	if (input_buf_ptr >= input_buf_siz)
    794 		return -1;
    795 
    796 	return input_buf[input_buf_ptr];
    797 }
    798 
    799 /**
    800  * pevent_peek_char - peek at the next character that will be read
    801  *
    802  * Returns the next character read, or -1 if end of buffer.
    803  */
    804 int pevent_peek_char(void)
    805 {
    806 	return __peek_char();
    807 }
    808 
    809 static int extend_token(char **tok, char *buf, int size)
    810 {
    811 	char *newtok = realloc(*tok, size);
    812 
    813 	if (!newtok) {
    814 		free(*tok);
    815 		*tok = NULL;
    816 		return -1;
    817 	}
    818 
    819 	if (!*tok)
    820 		strcpy(newtok, buf);
    821 	else
    822 		strcat(newtok, buf);
    823 	*tok = newtok;
    824 
    825 	return 0;
    826 }
    827 
    828 static enum event_type force_token(const char *str, char **tok);
    829 
    830 static enum event_type __read_token(char **tok)
    831 {
    832 	char buf[BUFSIZ];
    833 	int ch, last_ch, quote_ch, next_ch;
    834 	int i = 0;
    835 	int tok_size = 0;
    836 	enum event_type type;
    837 
    838 	*tok = NULL;
    839 
    840 
    841 	ch = __read_char();
    842 	if (ch < 0)
    843 		return EVENT_NONE;
    844 
    845 	type = get_type(ch);
    846 	if (type == EVENT_NONE)
    847 		return type;
    848 
    849 	buf[i++] = ch;
    850 
    851 	switch (type) {
    852 	case EVENT_NEWLINE:
    853 	case EVENT_DELIM:
    854 		if (asprintf(tok, "%c", ch) < 0)
    855 			return EVENT_ERROR;
    856 
    857 		return type;
    858 
    859 	case EVENT_OP:
    860 		switch (ch) {
    861 		case '-':
    862 			next_ch = __peek_char();
    863 			if (next_ch == '>') {
    864 				buf[i++] = __read_char();
    865 				break;
    866 			}
    867 			/* fall through */
    868 		case '+':
    869 		case '|':
    870 		case '&':
    871 		case '>':
    872 		case '<':
    873 			last_ch = ch;
    874 			ch = __peek_char();
    875 			if (ch != last_ch)
    876 				goto test_equal;
    877 			buf[i++] = __read_char();
    878 			switch (last_ch) {
    879 			case '>':
    880 			case '<':
    881 				goto test_equal;
    882 			default:
    883 				break;
    884 			}
    885 			break;
    886 		case '!':
    887 		case '=':
    888 			goto test_equal;
    889 		default: /* what should we do instead? */
    890 			break;
    891 		}
    892 		buf[i] = 0;
    893 		*tok = strdup(buf);
    894 		return type;
    895 
    896  test_equal:
    897 		ch = __peek_char();
    898 		if (ch == '=')
    899 			buf[i++] = __read_char();
    900 		goto out;
    901 
    902 	case EVENT_DQUOTE:
    903 	case EVENT_SQUOTE:
    904 		/* don't keep quotes */
    905 		i--;
    906 		quote_ch = ch;
    907 		last_ch = 0;
    908  concat:
    909 		do {
    910 			if (i == (BUFSIZ - 1)) {
    911 				buf[i] = 0;
    912 				tok_size += BUFSIZ;
    913 
    914 				if (extend_token(tok, buf, tok_size) < 0)
    915 					return EVENT_NONE;
    916 				i = 0;
    917 			}
    918 			last_ch = ch;
    919 			ch = __read_char();
    920 			buf[i++] = ch;
    921 			/* the '\' '\' will cancel itself */
    922 			if (ch == '\\' && last_ch == '\\')
    923 				last_ch = 0;
    924 		} while (ch != quote_ch || last_ch == '\\');
    925 		/* remove the last quote */
    926 		i--;
    927 
    928 		/*
    929 		 * For strings (double quotes) check the next token.
    930 		 * If it is another string, concatinate the two.
    931 		 */
    932 		if (type == EVENT_DQUOTE) {
    933 			unsigned long long save_input_buf_ptr = input_buf_ptr;
    934 
    935 			do {
    936 				ch = __read_char();
    937 			} while (isspace(ch));
    938 			if (ch == '"')
    939 				goto concat;
    940 			input_buf_ptr = save_input_buf_ptr;
    941 		}
    942 
    943 		goto out;
    944 
    945 	case EVENT_ERROR ... EVENT_SPACE:
    946 	case EVENT_ITEM:
    947 	default:
    948 		break;
    949 	}
    950 
    951 	while (get_type(__peek_char()) == type) {
    952 		if (i == (BUFSIZ - 1)) {
    953 			buf[i] = 0;
    954 			tok_size += BUFSIZ;
    955 
    956 			if (extend_token(tok, buf, tok_size) < 0)
    957 				return EVENT_NONE;
    958 			i = 0;
    959 		}
    960 		ch = __read_char();
    961 		buf[i++] = ch;
    962 	}
    963 
    964  out:
    965 	buf[i] = 0;
    966 	if (extend_token(tok, buf, tok_size + i + 1) < 0)
    967 		return EVENT_NONE;
    968 
    969 	if (type == EVENT_ITEM) {
    970 		/*
    971 		 * Older versions of the kernel has a bug that
    972 		 * creates invalid symbols and will break the mac80211
    973 		 * parsing. This is a work around to that bug.
    974 		 *
    975 		 * See Linux kernel commit:
    976 		 *  811cb50baf63461ce0bdb234927046131fc7fa8b
    977 		 */
    978 		if (strcmp(*tok, "LOCAL_PR_FMT") == 0) {
    979 			free(*tok);
    980 			*tok = NULL;
    981 			return force_token("\"\%s\" ", tok);
    982 		} else if (strcmp(*tok, "STA_PR_FMT") == 0) {
    983 			free(*tok);
    984 			*tok = NULL;
    985 			return force_token("\" sta:%pM\" ", tok);
    986 		} else if (strcmp(*tok, "VIF_PR_FMT") == 0) {
    987 			free(*tok);
    988 			*tok = NULL;
    989 			return force_token("\" vif:%p(%d)\" ", tok);
    990 		}
    991 	}
    992 
    993 	return type;
    994 }
    995 
    996 static enum event_type force_token(const char *str, char **tok)
    997 {
    998 	const char *save_input_buf;
    999 	unsigned long long save_input_buf_ptr;
   1000 	unsigned long long save_input_buf_siz;
   1001 	enum event_type type;
   1002 
   1003 	/* save off the current input pointers */
   1004 	save_input_buf = input_buf;
   1005 	save_input_buf_ptr = input_buf_ptr;
   1006 	save_input_buf_siz = input_buf_siz;
   1007 
   1008 	init_input_buf(str, strlen(str));
   1009 
   1010 	type = __read_token(tok);
   1011 
   1012 	/* reset back to original token */
   1013 	input_buf = save_input_buf;
   1014 	input_buf_ptr = save_input_buf_ptr;
   1015 	input_buf_siz = save_input_buf_siz;
   1016 
   1017 	return type;
   1018 }
   1019 
   1020 static void free_token(char *tok)
   1021 {
   1022 	if (tok)
   1023 		free(tok);
   1024 }
   1025 
   1026 static enum event_type read_token(char **tok)
   1027 {
   1028 	enum event_type type;
   1029 
   1030 	for (;;) {
   1031 		type = __read_token(tok);
   1032 		if (type != EVENT_SPACE)
   1033 			return type;
   1034 
   1035 		free_token(*tok);
   1036 	}
   1037 
   1038 	/* not reached */
   1039 	*tok = NULL;
   1040 	return EVENT_NONE;
   1041 }
   1042 
   1043 /**
   1044  * pevent_read_token - access to utilites to use the pevent parser
   1045  * @tok: The token to return
   1046  *
   1047  * This will parse tokens from the string given by
   1048  * pevent_init_data().
   1049  *
   1050  * Returns the token type.
   1051  */
   1052 enum event_type pevent_read_token(char **tok)
   1053 {
   1054 	return read_token(tok);
   1055 }
   1056 
   1057 /**
   1058  * pevent_free_token - free a token returned by pevent_read_token
   1059  * @token: the token to free
   1060  */
   1061 void pevent_free_token(char *token)
   1062 {
   1063 	free_token(token);
   1064 }
   1065 
   1066 /* no newline */
   1067 static enum event_type read_token_item(char **tok)
   1068 {
   1069 	enum event_type type;
   1070 
   1071 	for (;;) {
   1072 		type = __read_token(tok);
   1073 		if (type != EVENT_SPACE && type != EVENT_NEWLINE)
   1074 			return type;
   1075 		free_token(*tok);
   1076 		*tok = NULL;
   1077 	}
   1078 
   1079 	/* not reached */
   1080 	*tok = NULL;
   1081 	return EVENT_NONE;
   1082 }
   1083 
   1084 static int test_type(enum event_type type, enum event_type expect)
   1085 {
   1086 	if (type != expect) {
   1087 		do_warning("Error: expected type %d but read %d",
   1088 		    expect, type);
   1089 		return -1;
   1090 	}
   1091 	return 0;
   1092 }
   1093 
   1094 static int test_type_token(enum event_type type, const char *token,
   1095 		    enum event_type expect, const char *expect_tok)
   1096 {
   1097 	if (type != expect) {
   1098 		do_warning("Error: expected type %d but read %d",
   1099 		    expect, type);
   1100 		return -1;
   1101 	}
   1102 
   1103 	if (strcmp(token, expect_tok) != 0) {
   1104 		do_warning("Error: expected '%s' but read '%s'",
   1105 		    expect_tok, token);
   1106 		return -1;
   1107 	}
   1108 	return 0;
   1109 }
   1110 
   1111 static int __read_expect_type(enum event_type expect, char **tok, int newline_ok)
   1112 {
   1113 	enum event_type type;
   1114 
   1115 	if (newline_ok)
   1116 		type = read_token(tok);
   1117 	else
   1118 		type = read_token_item(tok);
   1119 	return test_type(type, expect);
   1120 }
   1121 
   1122 static int read_expect_type(enum event_type expect, char **tok)
   1123 {
   1124 	return __read_expect_type(expect, tok, 1);
   1125 }
   1126 
   1127 static int __read_expected(enum event_type expect, const char *str,
   1128 			   int newline_ok)
   1129 {
   1130 	enum event_type type;
   1131 	char *token;
   1132 	int ret;
   1133 
   1134 	if (newline_ok)
   1135 		type = read_token(&token);
   1136 	else
   1137 		type = read_token_item(&token);
   1138 
   1139 	ret = test_type_token(type, token, expect, str);
   1140 
   1141 	free_token(token);
   1142 
   1143 	return ret;
   1144 }
   1145 
   1146 static int read_expected(enum event_type expect, const char *str)
   1147 {
   1148 	return __read_expected(expect, str, 1);
   1149 }
   1150 
   1151 static int read_expected_item(enum event_type expect, const char *str)
   1152 {
   1153 	return __read_expected(expect, str, 0);
   1154 }
   1155 
   1156 static char *event_read_name(void)
   1157 {
   1158 	char *token;
   1159 
   1160 	if (read_expected(EVENT_ITEM, "name") < 0)
   1161 		return NULL;
   1162 
   1163 	if (read_expected(EVENT_OP, ":") < 0)
   1164 		return NULL;
   1165 
   1166 	if (read_expect_type(EVENT_ITEM, &token) < 0)
   1167 		goto fail;
   1168 
   1169 	return token;
   1170 
   1171  fail:
   1172 	free_token(token);
   1173 	return NULL;
   1174 }
   1175 
   1176 static int event_read_id(void)
   1177 {
   1178 	char *token;
   1179 	int id;
   1180 
   1181 	if (read_expected_item(EVENT_ITEM, "ID") < 0)
   1182 		return -1;
   1183 
   1184 	if (read_expected(EVENT_OP, ":") < 0)
   1185 		return -1;
   1186 
   1187 	if (read_expect_type(EVENT_ITEM, &token) < 0)
   1188 		goto fail;
   1189 
   1190 	id = strtoul(token, NULL, 0);
   1191 	free_token(token);
   1192 	return id;
   1193 
   1194  fail:
   1195 	free_token(token);
   1196 	return -1;
   1197 }
   1198 
   1199 static int field_is_string(struct format_field *field)
   1200 {
   1201 	if ((field->flags & FIELD_IS_ARRAY) &&
   1202 	    (strstr(field->type, "char") || strstr(field->type, "u8") ||
   1203 	     strstr(field->type, "s8")))
   1204 		return 1;
   1205 
   1206 	return 0;
   1207 }
   1208 
   1209 static int field_is_dynamic(struct format_field *field)
   1210 {
   1211 	if (strncmp(field->type, "__data_loc", 10) == 0)
   1212 		return 1;
   1213 
   1214 	return 0;
   1215 }
   1216 
   1217 static int field_is_long(struct format_field *field)
   1218 {
   1219 	/* includes long long */
   1220 	if (strstr(field->type, "long"))
   1221 		return 1;
   1222 
   1223 	return 0;
   1224 }
   1225 
   1226 static unsigned int type_size(const char *name)
   1227 {
   1228 	/* This covers all FIELD_IS_STRING types. */
   1229 	static struct {
   1230 		const char *type;
   1231 		unsigned int size;
   1232 	} table[] = {
   1233 		{ "u8",   1 },
   1234 		{ "u16",  2 },
   1235 		{ "u32",  4 },
   1236 		{ "u64",  8 },
   1237 		{ "s8",   1 },
   1238 		{ "s16",  2 },
   1239 		{ "s32",  4 },
   1240 		{ "s64",  8 },
   1241 		{ "char", 1 },
   1242 		{ },
   1243 	};
   1244 	int i;
   1245 
   1246 	for (i = 0; table[i].type; i++) {
   1247 		if (!strcmp(table[i].type, name))
   1248 			return table[i].size;
   1249 	}
   1250 
   1251 	return 0;
   1252 }
   1253 
   1254 static int event_read_fields(struct event_format *event, struct format_field **fields)
   1255 {
   1256 	struct format_field *field = NULL;
   1257 	enum event_type type;
   1258 	char *token;
   1259 	char *last_token;
   1260 	int count = 0;
   1261 
   1262 	do {
   1263 		unsigned int size_dynamic = 0;
   1264 
   1265 		type = read_token(&token);
   1266 		if (type == EVENT_NEWLINE) {
   1267 			free_token(token);
   1268 			return count;
   1269 		}
   1270 
   1271 		count++;
   1272 
   1273 		if (test_type_token(type, token, EVENT_ITEM, "field"))
   1274 			goto fail;
   1275 		free_token(token);
   1276 
   1277 		type = read_token(&token);
   1278 		/*
   1279 		 * The ftrace fields may still use the "special" name.
   1280 		 * Just ignore it.
   1281 		 */
   1282 		if (event->flags & EVENT_FL_ISFTRACE &&
   1283 		    type == EVENT_ITEM && strcmp(token, "special") == 0) {
   1284 			free_token(token);
   1285 			type = read_token(&token);
   1286 		}
   1287 
   1288 		if (test_type_token(type, token, EVENT_OP, ":") < 0)
   1289 			goto fail;
   1290 
   1291 		free_token(token);
   1292 		if (read_expect_type(EVENT_ITEM, &token) < 0)
   1293 			goto fail;
   1294 
   1295 		last_token = token;
   1296 
   1297 		field = calloc(1, sizeof(*field));
   1298 		if (!field)
   1299 			goto fail;
   1300 
   1301 		field->event = event;
   1302 
   1303 		/* read the rest of the type */
   1304 		for (;;) {
   1305 			type = read_token(&token);
   1306 			if (type == EVENT_ITEM ||
   1307 			    (type == EVENT_OP && strcmp(token, "*") == 0) ||
   1308 			    /*
   1309 			     * Some of the ftrace fields are broken and have
   1310 			     * an illegal "." in them.
   1311 			     */
   1312 			    (event->flags & EVENT_FL_ISFTRACE &&
   1313 			     type == EVENT_OP && strcmp(token, ".") == 0)) {
   1314 
   1315 				if (strcmp(token, "*") == 0)
   1316 					field->flags |= FIELD_IS_POINTER;
   1317 
   1318 				if (field->type) {
   1319 					char *new_type;
   1320 					new_type = realloc(field->type,
   1321 							   strlen(field->type) +
   1322 							   strlen(last_token) + 2);
   1323 					if (!new_type) {
   1324 						free(last_token);
   1325 						goto fail;
   1326 					}
   1327 					field->type = new_type;
   1328 					strcat(field->type, " ");
   1329 					strcat(field->type, last_token);
   1330 					free(last_token);
   1331 				} else
   1332 					field->type = last_token;
   1333 				last_token = token;
   1334 				continue;
   1335 			}
   1336 
   1337 			break;
   1338 		}
   1339 
   1340 		if (!field->type) {
   1341 			do_warning("%s: no type found", __func__);
   1342 			goto fail;
   1343 		}
   1344 		field->name = last_token;
   1345 
   1346 		if (test_type(type, EVENT_OP))
   1347 			goto fail;
   1348 
   1349 		if (strcmp(token, "[") == 0) {
   1350 			enum event_type last_type = type;
   1351 			char *brackets = token;
   1352 			char *new_brackets;
   1353 			int len;
   1354 
   1355 			field->flags |= FIELD_IS_ARRAY;
   1356 
   1357 			type = read_token(&token);
   1358 
   1359 			if (type == EVENT_ITEM)
   1360 				field->arraylen = strtoul(token, NULL, 0);
   1361 			else
   1362 				field->arraylen = 0;
   1363 
   1364 		        while (strcmp(token, "]") != 0) {
   1365 				if (last_type == EVENT_ITEM &&
   1366 				    type == EVENT_ITEM)
   1367 					len = 2;
   1368 				else
   1369 					len = 1;
   1370 				last_type = type;
   1371 
   1372 				new_brackets = realloc(brackets,
   1373 						       strlen(brackets) +
   1374 						       strlen(token) + len);
   1375 				if (!new_brackets) {
   1376 					free(brackets);
   1377 					goto fail;
   1378 				}
   1379 				brackets = new_brackets;
   1380 				if (len == 2)
   1381 					strcat(brackets, " ");
   1382 				strcat(brackets, token);
   1383 				/* We only care about the last token */
   1384 				field->arraylen = strtoul(token, NULL, 0);
   1385 				free_token(token);
   1386 				type = read_token(&token);
   1387 				if (type == EVENT_NONE) {
   1388 					do_warning("failed to find token");
   1389 					goto fail;
   1390 				}
   1391 			}
   1392 
   1393 			free_token(token);
   1394 
   1395 			new_brackets = realloc(brackets, strlen(brackets) + 2);
   1396 			if (!new_brackets) {
   1397 				free(brackets);
   1398 				goto fail;
   1399 			}
   1400 			brackets = new_brackets;
   1401 			strcat(brackets, "]");
   1402 
   1403 			/* add brackets to type */
   1404 
   1405 			type = read_token(&token);
   1406 			/*
   1407 			 * If the next token is not an OP, then it is of
   1408 			 * the format: type [] item;
   1409 			 */
   1410 			if (type == EVENT_ITEM) {
   1411 				char *new_type;
   1412 				new_type = realloc(field->type,
   1413 						   strlen(field->type) +
   1414 						   strlen(field->name) +
   1415 						   strlen(brackets) + 2);
   1416 				if (!new_type) {
   1417 					free(brackets);
   1418 					goto fail;
   1419 				}
   1420 				field->type = new_type;
   1421 				strcat(field->type, " ");
   1422 				strcat(field->type, field->name);
   1423 				size_dynamic = type_size(field->name);
   1424 				free_token(field->name);
   1425 				strcat(field->type, brackets);
   1426 				field->name = token;
   1427 				type = read_token(&token);
   1428 			} else {
   1429 				char *new_type;
   1430 				new_type = realloc(field->type,
   1431 						   strlen(field->type) +
   1432 						   strlen(brackets) + 1);
   1433 				if (!new_type) {
   1434 					free(brackets);
   1435 					goto fail;
   1436 				}
   1437 				field->type = new_type;
   1438 				strcat(field->type, brackets);
   1439 			}
   1440 			free(brackets);
   1441 		}
   1442 
   1443 		if (field_is_string(field))
   1444 			field->flags |= FIELD_IS_STRING;
   1445 		if (field_is_dynamic(field))
   1446 			field->flags |= FIELD_IS_DYNAMIC;
   1447 		if (field_is_long(field))
   1448 			field->flags |= FIELD_IS_LONG;
   1449 
   1450 		if (test_type_token(type, token,  EVENT_OP, ";"))
   1451 			goto fail;
   1452 		free_token(token);
   1453 
   1454 		if (read_expected(EVENT_ITEM, "offset") < 0)
   1455 			goto fail_expect;
   1456 
   1457 		if (read_expected(EVENT_OP, ":") < 0)
   1458 			goto fail_expect;
   1459 
   1460 		if (read_expect_type(EVENT_ITEM, &token))
   1461 			goto fail;
   1462 		field->offset = strtoul(token, NULL, 0);
   1463 		free_token(token);
   1464 
   1465 		if (read_expected(EVENT_OP, ";") < 0)
   1466 			goto fail_expect;
   1467 
   1468 		if (read_expected(EVENT_ITEM, "size") < 0)
   1469 			goto fail_expect;
   1470 
   1471 		if (read_expected(EVENT_OP, ":") < 0)
   1472 			goto fail_expect;
   1473 
   1474 		if (read_expect_type(EVENT_ITEM, &token))
   1475 			goto fail;
   1476 		field->size = strtoul(token, NULL, 0);
   1477 		free_token(token);
   1478 
   1479 		if (read_expected(EVENT_OP, ";") < 0)
   1480 			goto fail_expect;
   1481 
   1482 		type = read_token(&token);
   1483 		if (type != EVENT_NEWLINE) {
   1484 			/* newer versions of the kernel have a "signed" type */
   1485 			if (test_type_token(type, token, EVENT_ITEM, "signed"))
   1486 				goto fail;
   1487 
   1488 			free_token(token);
   1489 
   1490 			if (read_expected(EVENT_OP, ":") < 0)
   1491 				goto fail_expect;
   1492 
   1493 			if (read_expect_type(EVENT_ITEM, &token))
   1494 				goto fail;
   1495 
   1496 			if (strtoul(token, NULL, 0))
   1497 				field->flags |= FIELD_IS_SIGNED;
   1498 
   1499 			free_token(token);
   1500 			if (read_expected(EVENT_OP, ";") < 0)
   1501 				goto fail_expect;
   1502 
   1503 			if (read_expect_type(EVENT_NEWLINE, &token))
   1504 				goto fail;
   1505 		}
   1506 
   1507 		free_token(token);
   1508 
   1509 		if (field->flags & FIELD_IS_ARRAY) {
   1510 			if (field->arraylen)
   1511 				field->elementsize = field->size / field->arraylen;
   1512 			else if (field->flags & FIELD_IS_DYNAMIC)
   1513 				field->elementsize = size_dynamic;
   1514 			else if (field->flags & FIELD_IS_STRING)
   1515 				field->elementsize = 1;
   1516 			else if (field->flags & FIELD_IS_LONG)
   1517 				field->elementsize = event->pevent ?
   1518 						     event->pevent->long_size :
   1519 						     sizeof(long);
   1520 		} else
   1521 			field->elementsize = field->size;
   1522 
   1523 		*fields = field;
   1524 		fields = &field->next;
   1525 
   1526 	} while (1);
   1527 
   1528 	return 0;
   1529 
   1530 fail:
   1531 	free_token(token);
   1532 fail_expect:
   1533 	if (field) {
   1534 		free(field->type);
   1535 		free(field->name);
   1536 		free(field);
   1537 	}
   1538 	return -1;
   1539 }
   1540 
   1541 static int event_read_format(struct event_format *event)
   1542 {
   1543 	char *token;
   1544 	int ret;
   1545 
   1546 	if (read_expected_item(EVENT_ITEM, "format") < 0)
   1547 		return -1;
   1548 
   1549 	if (read_expected(EVENT_OP, ":") < 0)
   1550 		return -1;
   1551 
   1552 	if (read_expect_type(EVENT_NEWLINE, &token))
   1553 		goto fail;
   1554 	free_token(token);
   1555 
   1556 	ret = event_read_fields(event, &event->format.common_fields);
   1557 	if (ret < 0)
   1558 		return ret;
   1559 	event->format.nr_common = ret;
   1560 
   1561 	ret = event_read_fields(event, &event->format.fields);
   1562 	if (ret < 0)
   1563 		return ret;
   1564 	event->format.nr_fields = ret;
   1565 
   1566 	return 0;
   1567 
   1568  fail:
   1569 	free_token(token);
   1570 	return -1;
   1571 }
   1572 
   1573 static enum event_type
   1574 process_arg_token(struct event_format *event, struct print_arg *arg,
   1575 		  char **tok, enum event_type type);
   1576 
   1577 static enum event_type
   1578 process_arg(struct event_format *event, struct print_arg *arg, char **tok)
   1579 {
   1580 	enum event_type type;
   1581 	char *token;
   1582 
   1583 	type = read_token(&token);
   1584 	*tok = token;
   1585 
   1586 	return process_arg_token(event, arg, tok, type);
   1587 }
   1588 
   1589 static enum event_type
   1590 process_op(struct event_format *event, struct print_arg *arg, char **tok);
   1591 
   1592 static enum event_type
   1593 process_cond(struct event_format *event, struct print_arg *top, char **tok)
   1594 {
   1595 	struct print_arg *arg, *left, *right;
   1596 	enum event_type type;
   1597 	char *token = NULL;
   1598 
   1599 	arg = alloc_arg();
   1600 	left = alloc_arg();
   1601 	right = alloc_arg();
   1602 
   1603 	if (!arg || !left || !right) {
   1604 		do_warning("%s: not enough memory!", __func__);
   1605 		/* arg will be freed at out_free */
   1606 		free_arg(left);
   1607 		free_arg(right);
   1608 		goto out_free;
   1609 	}
   1610 
   1611 	arg->type = PRINT_OP;
   1612 	arg->op.left = left;
   1613 	arg->op.right = right;
   1614 
   1615 	*tok = NULL;
   1616 	type = process_arg(event, left, &token);
   1617 
   1618  again:
   1619 	/* Handle other operations in the arguments */
   1620 	if (type == EVENT_OP && strcmp(token, ":") != 0) {
   1621 		type = process_op(event, left, &token);
   1622 		goto again;
   1623 	}
   1624 
   1625 	if (test_type_token(type, token, EVENT_OP, ":"))
   1626 		goto out_free;
   1627 
   1628 	arg->op.op = token;
   1629 
   1630 	type = process_arg(event, right, &token);
   1631 
   1632 	top->op.right = arg;
   1633 
   1634 	*tok = token;
   1635 	return type;
   1636 
   1637 out_free:
   1638 	/* Top may point to itself */
   1639 	top->op.right = NULL;
   1640 	free_token(token);
   1641 	free_arg(arg);
   1642 	return EVENT_ERROR;
   1643 }
   1644 
   1645 static enum event_type
   1646 process_array(struct event_format *event, struct print_arg *top, char **tok)
   1647 {
   1648 	struct print_arg *arg;
   1649 	enum event_type type;
   1650 	char *token = NULL;
   1651 
   1652 	arg = alloc_arg();
   1653 	if (!arg) {
   1654 		do_warning("%s: not enough memory!", __func__);
   1655 		/* '*tok' is set to top->op.op.  No need to free. */
   1656 		*tok = NULL;
   1657 		return EVENT_ERROR;
   1658 	}
   1659 
   1660 	*tok = NULL;
   1661 	type = process_arg(event, arg, &token);
   1662 	if (test_type_token(type, token, EVENT_OP, "]"))
   1663 		goto out_free;
   1664 
   1665 	top->op.right = arg;
   1666 
   1667 	free_token(token);
   1668 	type = read_token_item(&token);
   1669 	*tok = token;
   1670 
   1671 	return type;
   1672 
   1673 out_free:
   1674 	free_token(token);
   1675 	free_arg(arg);
   1676 	return EVENT_ERROR;
   1677 }
   1678 
   1679 static int get_op_prio(char *op)
   1680 {
   1681 	if (!op[1]) {
   1682 		switch (op[0]) {
   1683 		case '~':
   1684 		case '!':
   1685 			return 4;
   1686 		case '*':
   1687 		case '/':
   1688 		case '%':
   1689 			return 6;
   1690 		case '+':
   1691 		case '-':
   1692 			return 7;
   1693 			/* '>>' and '<<' are 8 */
   1694 		case '<':
   1695 		case '>':
   1696 			return 9;
   1697 			/* '==' and '!=' are 10 */
   1698 		case '&':
   1699 			return 11;
   1700 		case '^':
   1701 			return 12;
   1702 		case '|':
   1703 			return 13;
   1704 		case '?':
   1705 			return 16;
   1706 		default:
   1707 			do_warning("unknown op '%c'", op[0]);
   1708 			return -1;
   1709 		}
   1710 	} else {
   1711 		if (strcmp(op, "++") == 0 ||
   1712 		    strcmp(op, "--") == 0) {
   1713 			return 3;
   1714 		} else if (strcmp(op, ">>") == 0 ||
   1715 			   strcmp(op, "<<") == 0) {
   1716 			return 8;
   1717 		} else if (strcmp(op, ">=") == 0 ||
   1718 			   strcmp(op, "<=") == 0) {
   1719 			return 9;
   1720 		} else if (strcmp(op, "==") == 0 ||
   1721 			   strcmp(op, "!=") == 0) {
   1722 			return 10;
   1723 		} else if (strcmp(op, "&&") == 0) {
   1724 			return 14;
   1725 		} else if (strcmp(op, "||") == 0) {
   1726 			return 15;
   1727 		} else {
   1728 			do_warning("unknown op '%s'", op);
   1729 			return -1;
   1730 		}
   1731 	}
   1732 }
   1733 
   1734 static int set_op_prio(struct print_arg *arg)
   1735 {
   1736 
   1737 	/* single ops are the greatest */
   1738 	if (!arg->op.left || arg->op.left->type == PRINT_NULL)
   1739 		arg->op.prio = 0;
   1740 	else
   1741 		arg->op.prio = get_op_prio(arg->op.op);
   1742 
   1743 	return arg->op.prio;
   1744 }
   1745 
   1746 /* Note, *tok does not get freed, but will most likely be saved */
   1747 static enum event_type
   1748 process_op(struct event_format *event, struct print_arg *arg, char **tok)
   1749 {
   1750 	struct print_arg *left, *right = NULL;
   1751 	enum event_type type;
   1752 	char *token;
   1753 
   1754 	/* the op is passed in via tok */
   1755 	token = *tok;
   1756 
   1757 	if (arg->type == PRINT_OP && !arg->op.left) {
   1758 		/* handle single op */
   1759 		if (token[1]) {
   1760 			do_warning("bad op token %s", token);
   1761 			goto out_free;
   1762 		}
   1763 		switch (token[0]) {
   1764 		case '~':
   1765 		case '!':
   1766 		case '+':
   1767 		case '-':
   1768 			break;
   1769 		default:
   1770 			do_warning("bad op token %s", token);
   1771 			goto out_free;
   1772 
   1773 		}
   1774 
   1775 		/* make an empty left */
   1776 		left = alloc_arg();
   1777 		if (!left)
   1778 			goto out_warn_free;
   1779 
   1780 		left->type = PRINT_NULL;
   1781 		arg->op.left = left;
   1782 
   1783 		right = alloc_arg();
   1784 		if (!right)
   1785 			goto out_warn_free;
   1786 
   1787 		arg->op.right = right;
   1788 
   1789 		/* do not free the token, it belongs to an op */
   1790 		*tok = NULL;
   1791 		type = process_arg(event, right, tok);
   1792 
   1793 	} else if (strcmp(token, "?") == 0) {
   1794 
   1795 		left = alloc_arg();
   1796 		if (!left)
   1797 			goto out_warn_free;
   1798 
   1799 		/* copy the top arg to the left */
   1800 		*left = *arg;
   1801 
   1802 		arg->type = PRINT_OP;
   1803 		arg->op.op = token;
   1804 		arg->op.left = left;
   1805 		arg->op.prio = 0;
   1806 
   1807 		/* it will set arg->op.right */
   1808 		type = process_cond(event, arg, tok);
   1809 
   1810 	} else if (strcmp(token, ">>") == 0 ||
   1811 		   strcmp(token, "<<") == 0 ||
   1812 		   strcmp(token, "&") == 0 ||
   1813 		   strcmp(token, "|") == 0 ||
   1814 		   strcmp(token, "&&") == 0 ||
   1815 		   strcmp(token, "||") == 0 ||
   1816 		   strcmp(token, "-") == 0 ||
   1817 		   strcmp(token, "+") == 0 ||
   1818 		   strcmp(token, "*") == 0 ||
   1819 		   strcmp(token, "^") == 0 ||
   1820 		   strcmp(token, "/") == 0 ||
   1821 		   strcmp(token, "<") == 0 ||
   1822 		   strcmp(token, ">") == 0 ||
   1823 		   strcmp(token, "<=") == 0 ||
   1824 		   strcmp(token, ">=") == 0 ||
   1825 		   strcmp(token, "==") == 0 ||
   1826 		   strcmp(token, "!=") == 0) {
   1827 
   1828 		left = alloc_arg();
   1829 		if (!left)
   1830 			goto out_warn_free;
   1831 
   1832 		/* copy the top arg to the left */
   1833 		*left = *arg;
   1834 
   1835 		arg->type = PRINT_OP;
   1836 		arg->op.op = token;
   1837 		arg->op.left = left;
   1838 		arg->op.right = NULL;
   1839 
   1840 		if (set_op_prio(arg) == -1) {
   1841 			event->flags |= EVENT_FL_FAILED;
   1842 			/* arg->op.op (= token) will be freed at out_free */
   1843 			arg->op.op = NULL;
   1844 			goto out_free;
   1845 		}
   1846 
   1847 		type = read_token_item(&token);
   1848 		*tok = token;
   1849 
   1850 		/* could just be a type pointer */
   1851 		if ((strcmp(arg->op.op, "*") == 0) &&
   1852 		    type == EVENT_DELIM && (strcmp(token, ")") == 0)) {
   1853 			char *new_atom;
   1854 
   1855 			if (left->type != PRINT_ATOM) {
   1856 				do_warning("bad pointer type");
   1857 				goto out_free;
   1858 			}
   1859 			new_atom = realloc(left->atom.atom,
   1860 					    strlen(left->atom.atom) + 3);
   1861 			if (!new_atom)
   1862 				goto out_warn_free;
   1863 
   1864 			left->atom.atom = new_atom;
   1865 			strcat(left->atom.atom, " *");
   1866 			free(arg->op.op);
   1867 			*arg = *left;
   1868 			free(left);
   1869 
   1870 			return type;
   1871 		}
   1872 
   1873 		right = alloc_arg();
   1874 		if (!right)
   1875 			goto out_warn_free;
   1876 
   1877 		type = process_arg_token(event, right, tok, type);
   1878 		arg->op.right = right;
   1879 
   1880 	} else if (strcmp(token, "[") == 0) {
   1881 
   1882 		left = alloc_arg();
   1883 		if (!left)
   1884 			goto out_warn_free;
   1885 
   1886 		*left = *arg;
   1887 
   1888 		arg->type = PRINT_OP;
   1889 		arg->op.op = token;
   1890 		arg->op.left = left;
   1891 
   1892 		arg->op.prio = 0;
   1893 
   1894 		/* it will set arg->op.right */
   1895 		type = process_array(event, arg, tok);
   1896 
   1897 	} else {
   1898 		do_warning("unknown op '%s'", token);
   1899 		event->flags |= EVENT_FL_FAILED;
   1900 		/* the arg is now the left side */
   1901 		goto out_free;
   1902 	}
   1903 
   1904 	if (type == EVENT_OP && strcmp(*tok, ":") != 0) {
   1905 		int prio;
   1906 
   1907 		/* higher prios need to be closer to the root */
   1908 		prio = get_op_prio(*tok);
   1909 
   1910 		if (prio > arg->op.prio)
   1911 			return process_op(event, arg, tok);
   1912 
   1913 		return process_op(event, right, tok);
   1914 	}
   1915 
   1916 	return type;
   1917 
   1918 out_warn_free:
   1919 	do_warning("%s: not enough memory!", __func__);
   1920 out_free:
   1921 	free_token(token);
   1922 	*tok = NULL;
   1923 	return EVENT_ERROR;
   1924 }
   1925 
   1926 static enum event_type
   1927 process_entry(struct event_format *event __maybe_unused, struct print_arg *arg,
   1928 	      char **tok)
   1929 {
   1930 	enum event_type type;
   1931 	char *field;
   1932 	char *token;
   1933 
   1934 	if (read_expected(EVENT_OP, "->") < 0)
   1935 		goto out_err;
   1936 
   1937 	if (read_expect_type(EVENT_ITEM, &token) < 0)
   1938 		goto out_free;
   1939 	field = token;
   1940 
   1941 	arg->type = PRINT_FIELD;
   1942 	arg->field.name = field;
   1943 
   1944 	if (is_flag_field) {
   1945 		arg->field.field = pevent_find_any_field(event, arg->field.name);
   1946 		arg->field.field->flags |= FIELD_IS_FLAG;
   1947 		is_flag_field = 0;
   1948 	} else if (is_symbolic_field) {
   1949 		arg->field.field = pevent_find_any_field(event, arg->field.name);
   1950 		arg->field.field->flags |= FIELD_IS_SYMBOLIC;
   1951 		is_symbolic_field = 0;
   1952 	}
   1953 
   1954 	type = read_token(&token);
   1955 	*tok = token;
   1956 
   1957 	return type;
   1958 
   1959  out_free:
   1960 	free_token(token);
   1961  out_err:
   1962 	*tok = NULL;
   1963 	return EVENT_ERROR;
   1964 }
   1965 
   1966 static char *arg_eval (struct print_arg *arg);
   1967 
   1968 static unsigned long long
   1969 eval_type_str(unsigned long long val, const char *type, int pointer)
   1970 {
   1971 	int sign = 0;
   1972 	char *ref;
   1973 	int len;
   1974 
   1975 	len = strlen(type);
   1976 
   1977 	if (pointer) {
   1978 
   1979 		if (type[len-1] != '*') {
   1980 			do_warning("pointer expected with non pointer type");
   1981 			return val;
   1982 		}
   1983 
   1984 		ref = malloc(len);
   1985 		if (!ref) {
   1986 			do_warning("%s: not enough memory!", __func__);
   1987 			return val;
   1988 		}
   1989 		memcpy(ref, type, len);
   1990 
   1991 		/* chop off the " *" */
   1992 		ref[len - 2] = 0;
   1993 
   1994 		val = eval_type_str(val, ref, 0);
   1995 		free(ref);
   1996 		return val;
   1997 	}
   1998 
   1999 	/* check if this is a pointer */
   2000 	if (type[len - 1] == '*')
   2001 		return val;
   2002 
   2003 	/* Try to figure out the arg size*/
   2004 	if (strncmp(type, "struct", 6) == 0)
   2005 		/* all bets off */
   2006 		return val;
   2007 
   2008 	if (strcmp(type, "u8") == 0)
   2009 		return val & 0xff;
   2010 
   2011 	if (strcmp(type, "u16") == 0)
   2012 		return val & 0xffff;
   2013 
   2014 	if (strcmp(type, "u32") == 0)
   2015 		return val & 0xffffffff;
   2016 
   2017 	if (strcmp(type, "u64") == 0 ||
   2018 	    strcmp(type, "s64"))
   2019 		return val;
   2020 
   2021 	if (strcmp(type, "s8") == 0)
   2022 		return (unsigned long long)(char)val & 0xff;
   2023 
   2024 	if (strcmp(type, "s16") == 0)
   2025 		return (unsigned long long)(short)val & 0xffff;
   2026 
   2027 	if (strcmp(type, "s32") == 0)
   2028 		return (unsigned long long)(int)val & 0xffffffff;
   2029 
   2030 	if (strncmp(type, "unsigned ", 9) == 0) {
   2031 		sign = 0;
   2032 		type += 9;
   2033 	}
   2034 
   2035 	if (strcmp(type, "char") == 0) {
   2036 		if (sign)
   2037 			return (unsigned long long)(char)val & 0xff;
   2038 		else
   2039 			return val & 0xff;
   2040 	}
   2041 
   2042 	if (strcmp(type, "short") == 0) {
   2043 		if (sign)
   2044 			return (unsigned long long)(short)val & 0xffff;
   2045 		else
   2046 			return val & 0xffff;
   2047 	}
   2048 
   2049 	if (strcmp(type, "int") == 0) {
   2050 		if (sign)
   2051 			return (unsigned long long)(int)val & 0xffffffff;
   2052 		else
   2053 			return val & 0xffffffff;
   2054 	}
   2055 
   2056 	return val;
   2057 }
   2058 
   2059 /*
   2060  * Try to figure out the type.
   2061  */
   2062 static unsigned long long
   2063 eval_type(unsigned long long val, struct print_arg *arg, int pointer)
   2064 {
   2065 	if (arg->type != PRINT_TYPE) {
   2066 		do_warning("expected type argument");
   2067 		return 0;
   2068 	}
   2069 
   2070 	return eval_type_str(val, arg->typecast.type, pointer);
   2071 }
   2072 
   2073 static int arg_num_eval(struct print_arg *arg, long long *val)
   2074 {
   2075 	long long left, right;
   2076 	int ret = 1;
   2077 
   2078 	switch (arg->type) {
   2079 	case PRINT_ATOM:
   2080 		*val = strtoll(arg->atom.atom, NULL, 0);
   2081 		break;
   2082 	case PRINT_TYPE:
   2083 		ret = arg_num_eval(arg->typecast.item, val);
   2084 		if (!ret)
   2085 			break;
   2086 		*val = eval_type(*val, arg, 0);
   2087 		break;
   2088 	case PRINT_OP:
   2089 		switch (arg->op.op[0]) {
   2090 		case '|':
   2091 			ret = arg_num_eval(arg->op.left, &left);
   2092 			if (!ret)
   2093 				break;
   2094 			ret = arg_num_eval(arg->op.right, &right);
   2095 			if (!ret)
   2096 				break;
   2097 			if (arg->op.op[1])
   2098 				*val = left || right;
   2099 			else
   2100 				*val = left | right;
   2101 			break;
   2102 		case '&':
   2103 			ret = arg_num_eval(arg->op.left, &left);
   2104 			if (!ret)
   2105 				break;
   2106 			ret = arg_num_eval(arg->op.right, &right);
   2107 			if (!ret)
   2108 				break;
   2109 			if (arg->op.op[1])
   2110 				*val = left && right;
   2111 			else
   2112 				*val = left & right;
   2113 			break;
   2114 		case '<':
   2115 			ret = arg_num_eval(arg->op.left, &left);
   2116 			if (!ret)
   2117 				break;
   2118 			ret = arg_num_eval(arg->op.right, &right);
   2119 			if (!ret)
   2120 				break;
   2121 			switch (arg->op.op[1]) {
   2122 			case 0:
   2123 				*val = left < right;
   2124 				break;
   2125 			case '<':
   2126 				*val = left << right;
   2127 				break;
   2128 			case '=':
   2129 				*val = left <= right;
   2130 				break;
   2131 			default:
   2132 				do_warning("unknown op '%s'", arg->op.op);
   2133 				ret = 0;
   2134 			}
   2135 			break;
   2136 		case '>':
   2137 			ret = arg_num_eval(arg->op.left, &left);
   2138 			if (!ret)
   2139 				break;
   2140 			ret = arg_num_eval(arg->op.right, &right);
   2141 			if (!ret)
   2142 				break;
   2143 			switch (arg->op.op[1]) {
   2144 			case 0:
   2145 				*val = left > right;
   2146 				break;
   2147 			case '>':
   2148 				*val = left >> right;
   2149 				break;
   2150 			case '=':
   2151 				*val = left >= right;
   2152 				break;
   2153 			default:
   2154 				do_warning("unknown op '%s'", arg->op.op);
   2155 				ret = 0;
   2156 			}
   2157 			break;
   2158 		case '=':
   2159 			ret = arg_num_eval(arg->op.left, &left);
   2160 			if (!ret)
   2161 				break;
   2162 			ret = arg_num_eval(arg->op.right, &right);
   2163 			if (!ret)
   2164 				break;
   2165 
   2166 			if (arg->op.op[1] != '=') {
   2167 				do_warning("unknown op '%s'", arg->op.op);
   2168 				ret = 0;
   2169 			} else
   2170 				*val = left == right;
   2171 			break;
   2172 		case '!':
   2173 			ret = arg_num_eval(arg->op.left, &left);
   2174 			if (!ret)
   2175 				break;
   2176 			ret = arg_num_eval(arg->op.right, &right);
   2177 			if (!ret)
   2178 				break;
   2179 
   2180 			switch (arg->op.op[1]) {
   2181 			case '=':
   2182 				*val = left != right;
   2183 				break;
   2184 			default:
   2185 				do_warning("unknown op '%s'", arg->op.op);
   2186 				ret = 0;
   2187 			}
   2188 			break;
   2189 		case '-':
   2190 			/* check for negative */
   2191 			if (arg->op.left->type == PRINT_NULL)
   2192 				left = 0;
   2193 			else
   2194 				ret = arg_num_eval(arg->op.left, &left);
   2195 			if (!ret)
   2196 				break;
   2197 			ret = arg_num_eval(arg->op.right, &right);
   2198 			if (!ret)
   2199 				break;
   2200 			*val = left - right;
   2201 			break;
   2202 		case '+':
   2203 			if (arg->op.left->type == PRINT_NULL)
   2204 				left = 0;
   2205 			else
   2206 				ret = arg_num_eval(arg->op.left, &left);
   2207 			if (!ret)
   2208 				break;
   2209 			ret = arg_num_eval(arg->op.right, &right);
   2210 			if (!ret)
   2211 				break;
   2212 			*val = left + right;
   2213 			break;
   2214 		default:
   2215 			do_warning("unknown op '%s'", arg->op.op);
   2216 			ret = 0;
   2217 		}
   2218 		break;
   2219 
   2220 	case PRINT_NULL:
   2221 	case PRINT_FIELD ... PRINT_SYMBOL:
   2222 	case PRINT_STRING:
   2223 	case PRINT_BSTRING:
   2224 	default:
   2225 		do_warning("invalid eval type %d", arg->type);
   2226 		ret = 0;
   2227 
   2228 	}
   2229 	return ret;
   2230 }
   2231 
   2232 static char *arg_eval (struct print_arg *arg)
   2233 {
   2234 	long long val;
   2235 	static char buf[20];
   2236 
   2237 	switch (arg->type) {
   2238 	case PRINT_ATOM:
   2239 		return arg->atom.atom;
   2240 	case PRINT_TYPE:
   2241 		return arg_eval(arg->typecast.item);
   2242 	case PRINT_OP:
   2243 		if (!arg_num_eval(arg, &val))
   2244 			break;
   2245 		sprintf(buf, "%lld", val);
   2246 		return buf;
   2247 
   2248 	case PRINT_NULL:
   2249 	case PRINT_FIELD ... PRINT_SYMBOL:
   2250 	case PRINT_STRING:
   2251 	case PRINT_BSTRING:
   2252 	default:
   2253 		do_warning("invalid eval type %d", arg->type);
   2254 		break;
   2255 	}
   2256 
   2257 	return NULL;
   2258 }
   2259 
   2260 static enum event_type
   2261 process_fields(struct event_format *event, struct print_flag_sym **list, char **tok)
   2262 {
   2263 	enum event_type type;
   2264 	struct print_arg *arg = NULL;
   2265 	struct print_flag_sym *field;
   2266 	char *token = *tok;
   2267 	char *value;
   2268 
   2269 	do {
   2270 		free_token(token);
   2271 		type = read_token_item(&token);
   2272 		if (test_type_token(type, token, EVENT_OP, "{"))
   2273 			break;
   2274 
   2275 		arg = alloc_arg();
   2276 		if (!arg)
   2277 			goto out_free;
   2278 
   2279 		free_token(token);
   2280 		type = process_arg(event, arg, &token);
   2281 
   2282 		if (type == EVENT_OP)
   2283 			type = process_op(event, arg, &token);
   2284 
   2285 		if (type == EVENT_ERROR)
   2286 			goto out_free;
   2287 
   2288 		if (test_type_token(type, token, EVENT_DELIM, ","))
   2289 			goto out_free;
   2290 
   2291 		field = calloc(1, sizeof(*field));
   2292 		if (!field)
   2293 			goto out_free;
   2294 
   2295 		value = arg_eval(arg);
   2296 		if (value == NULL)
   2297 			goto out_free_field;
   2298 		field->value = strdup(value);
   2299 		if (field->value == NULL)
   2300 			goto out_free_field;
   2301 
   2302 		free_arg(arg);
   2303 		arg = alloc_arg();
   2304 		if (!arg)
   2305 			goto out_free;
   2306 
   2307 		free_token(token);
   2308 		type = process_arg(event, arg, &token);
   2309 		if (test_type_token(type, token, EVENT_OP, "}"))
   2310 			goto out_free_field;
   2311 
   2312 		value = arg_eval(arg);
   2313 		if (value == NULL)
   2314 			goto out_free_field;
   2315 		field->str = strdup(value);
   2316 		if (field->str == NULL)
   2317 			goto out_free_field;
   2318 		free_arg(arg);
   2319 		arg = NULL;
   2320 
   2321 		*list = field;
   2322 		list = &field->next;
   2323 
   2324 		free_token(token);
   2325 		type = read_token_item(&token);
   2326 	} while (type == EVENT_DELIM && strcmp(token, ",") == 0);
   2327 
   2328 	*tok = token;
   2329 	return type;
   2330 
   2331 out_free_field:
   2332 	free_flag_sym(field);
   2333 out_free:
   2334 	free_arg(arg);
   2335 	free_token(token);
   2336 	*tok = NULL;
   2337 
   2338 	return EVENT_ERROR;
   2339 }
   2340 
   2341 static enum event_type
   2342 process_flags(struct event_format *event, struct print_arg *arg, char **tok)
   2343 {
   2344 	struct print_arg *field;
   2345 	enum event_type type;
   2346 	char *token;
   2347 
   2348 	memset(arg, 0, sizeof(*arg));
   2349 	arg->type = PRINT_FLAGS;
   2350 
   2351 	field = alloc_arg();
   2352 	if (!field) {
   2353 		do_warning("%s: not enough memory!", __func__);
   2354 		goto out_free;
   2355 	}
   2356 
   2357 	type = process_arg(event, field, &token);
   2358 
   2359 	/* Handle operations in the first argument */
   2360 	while (type == EVENT_OP)
   2361 		type = process_op(event, field, &token);
   2362 
   2363 	if (test_type_token(type, token, EVENT_DELIM, ","))
   2364 		goto out_free_field;
   2365 	free_token(token);
   2366 
   2367 	arg->flags.field = field;
   2368 
   2369 	type = read_token_item(&token);
   2370 	if (event_item_type(type)) {
   2371 		arg->flags.delim = token;
   2372 		type = read_token_item(&token);
   2373 	}
   2374 
   2375 	if (test_type_token(type, token, EVENT_DELIM, ","))
   2376 		goto out_free;
   2377 
   2378 	type = process_fields(event, &arg->flags.flags, &token);
   2379 	if (test_type_token(type, token, EVENT_DELIM, ")"))
   2380 		goto out_free;
   2381 
   2382 	free_token(token);
   2383 	type = read_token_item(tok);
   2384 	return type;
   2385 
   2386 out_free_field:
   2387 	free_arg(field);
   2388 out_free:
   2389 	free_token(token);
   2390 	*tok = NULL;
   2391 	return EVENT_ERROR;
   2392 }
   2393 
   2394 static enum event_type
   2395 process_symbols(struct event_format *event, struct print_arg *arg, char **tok)
   2396 {
   2397 	struct print_arg *field;
   2398 	enum event_type type;
   2399 	char *token;
   2400 
   2401 	memset(arg, 0, sizeof(*arg));
   2402 	arg->type = PRINT_SYMBOL;
   2403 
   2404 	field = alloc_arg();
   2405 	if (!field) {
   2406 		do_warning("%s: not enough memory!", __func__);
   2407 		goto out_free;
   2408 	}
   2409 
   2410 	type = process_arg(event, field, &token);
   2411 	if (test_type_token(type, token, EVENT_DELIM, ","))
   2412 		goto out_free_field;
   2413 
   2414 	arg->symbol.field = field;
   2415 
   2416 	type = process_fields(event, &arg->symbol.symbols, &token);
   2417 	if (test_type_token(type, token, EVENT_DELIM, ")"))
   2418 		goto out_free;
   2419 
   2420 	free_token(token);
   2421 	type = read_token_item(tok);
   2422 	return type;
   2423 
   2424 out_free_field:
   2425 	free_arg(field);
   2426 out_free:
   2427 	free_token(token);
   2428 	*tok = NULL;
   2429 	return EVENT_ERROR;
   2430 }
   2431 
   2432 static enum event_type
   2433 process_hex(struct event_format *event, struct print_arg *arg, char **tok)
   2434 {
   2435 	struct print_arg *field;
   2436 	enum event_type type;
   2437 	char *token;
   2438 
   2439 	memset(arg, 0, sizeof(*arg));
   2440 	arg->type = PRINT_HEX;
   2441 
   2442 	field = alloc_arg();
   2443 	if (!field) {
   2444 		do_warning("%s: not enough memory!", __func__);
   2445 		goto out_free;
   2446 	}
   2447 
   2448 	type = process_arg(event, field, &token);
   2449 
   2450 	if (test_type_token(type, token, EVENT_DELIM, ","))
   2451 		goto out_free;
   2452 
   2453 	arg->hex.field = field;
   2454 
   2455 	free_token(token);
   2456 
   2457 	field = alloc_arg();
   2458 	if (!field) {
   2459 		do_warning("%s: not enough memory!", __func__);
   2460 		*tok = NULL;
   2461 		return EVENT_ERROR;
   2462 	}
   2463 
   2464 	type = process_arg(event, field, &token);
   2465 
   2466 	if (test_type_token(type, token, EVENT_DELIM, ")"))
   2467 		goto out_free;
   2468 
   2469 	arg->hex.size = field;
   2470 
   2471 	free_token(token);
   2472 	type = read_token_item(tok);
   2473 	return type;
   2474 
   2475  out_free:
   2476 	free_arg(field);
   2477 	free_token(token);
   2478 	*tok = NULL;
   2479 	return EVENT_ERROR;
   2480 }
   2481 
   2482 static enum event_type
   2483 process_dynamic_array(struct event_format *event, struct print_arg *arg, char **tok)
   2484 {
   2485 	struct format_field *field;
   2486 	enum event_type type;
   2487 	char *token;
   2488 
   2489 	memset(arg, 0, sizeof(*arg));
   2490 	arg->type = PRINT_DYNAMIC_ARRAY;
   2491 
   2492 	/*
   2493 	 * The item within the parenthesis is another field that holds
   2494 	 * the index into where the array starts.
   2495 	 */
   2496 	type = read_token(&token);
   2497 	*tok = token;
   2498 	if (type != EVENT_ITEM)
   2499 		goto out_free;
   2500 
   2501 	/* Find the field */
   2502 
   2503 	field = pevent_find_field(event, token);
   2504 	if (!field)
   2505 		goto out_free;
   2506 
   2507 	arg->dynarray.field = field;
   2508 	arg->dynarray.index = 0;
   2509 
   2510 	if (read_expected(EVENT_DELIM, ")") < 0)
   2511 		goto out_free;
   2512 
   2513 	free_token(token);
   2514 	type = read_token_item(&token);
   2515 	*tok = token;
   2516 	if (type != EVENT_OP || strcmp(token, "[") != 0)
   2517 		return type;
   2518 
   2519 	free_token(token);
   2520 	arg = alloc_arg();
   2521 	if (!arg) {
   2522 		do_warning("%s: not enough memory!", __func__);
   2523 		*tok = NULL;
   2524 		return EVENT_ERROR;
   2525 	}
   2526 
   2527 	type = process_arg(event, arg, &token);
   2528 	if (type == EVENT_ERROR)
   2529 		goto out_free_arg;
   2530 
   2531 	if (!test_type_token(type, token, EVENT_OP, "]"))
   2532 		goto out_free_arg;
   2533 
   2534 	free_token(token);
   2535 	type = read_token_item(tok);
   2536 	return type;
   2537 
   2538  out_free_arg:
   2539 	free_arg(arg);
   2540  out_free:
   2541 	free_token(token);
   2542 	*tok = NULL;
   2543 	return EVENT_ERROR;
   2544 }
   2545 
   2546 static enum event_type
   2547 process_paren(struct event_format *event, struct print_arg *arg, char **tok)
   2548 {
   2549 	struct print_arg *item_arg;
   2550 	enum event_type type;
   2551 	char *token;
   2552 
   2553 	type = process_arg(event, arg, &token);
   2554 
   2555 	if (type == EVENT_ERROR)
   2556 		goto out_free;
   2557 
   2558 	if (type == EVENT_OP)
   2559 		type = process_op(event, arg, &token);
   2560 
   2561 	if (type == EVENT_ERROR)
   2562 		goto out_free;
   2563 
   2564 	if (test_type_token(type, token, EVENT_DELIM, ")"))
   2565 		goto out_free;
   2566 
   2567 	free_token(token);
   2568 	type = read_token_item(&token);
   2569 
   2570 	/*
   2571 	 * If the next token is an item or another open paren, then
   2572 	 * this was a typecast.
   2573 	 */
   2574 	if (event_item_type(type) ||
   2575 	    (type == EVENT_DELIM && strcmp(token, "(") == 0)) {
   2576 
   2577 		/* make this a typecast and contine */
   2578 
   2579 		/* prevous must be an atom */
   2580 		if (arg->type != PRINT_ATOM) {
   2581 			do_warning("previous needed to be PRINT_ATOM");
   2582 			goto out_free;
   2583 		}
   2584 
   2585 		item_arg = alloc_arg();
   2586 		if (!item_arg) {
   2587 			do_warning("%s: not enough memory!", __func__);
   2588 			goto out_free;
   2589 		}
   2590 
   2591 		arg->type = PRINT_TYPE;
   2592 		arg->typecast.type = arg->atom.atom;
   2593 		arg->typecast.item = item_arg;
   2594 		type = process_arg_token(event, item_arg, &token, type);
   2595 
   2596 	}
   2597 
   2598 	*tok = token;
   2599 	return type;
   2600 
   2601  out_free:
   2602 	free_token(token);
   2603 	*tok = NULL;
   2604 	return EVENT_ERROR;
   2605 }
   2606 
   2607 
   2608 static enum event_type
   2609 process_str(struct event_format *event __maybe_unused, struct print_arg *arg,
   2610 	    char **tok)
   2611 {
   2612 	enum event_type type;
   2613 	char *token;
   2614 
   2615 	if (read_expect_type(EVENT_ITEM, &token) < 0)
   2616 		goto out_free;
   2617 
   2618 	arg->type = PRINT_STRING;
   2619 	arg->string.string = token;
   2620 	arg->string.offset = -1;
   2621 
   2622 	if (read_expected(EVENT_DELIM, ")") < 0)
   2623 		goto out_err;
   2624 
   2625 	type = read_token(&token);
   2626 	*tok = token;
   2627 
   2628 	return type;
   2629 
   2630  out_free:
   2631 	free_token(token);
   2632  out_err:
   2633 	*tok = NULL;
   2634 	return EVENT_ERROR;
   2635 }
   2636 
   2637 static struct pevent_function_handler *
   2638 find_func_handler(struct pevent *pevent, char *func_name)
   2639 {
   2640 	struct pevent_function_handler *func;
   2641 
   2642 	if (!pevent)
   2643 		return NULL;
   2644 
   2645 	for (func = pevent->func_handlers; func; func = func->next) {
   2646 		if (strcmp(func->name, func_name) == 0)
   2647 			break;
   2648 	}
   2649 
   2650 	return func;
   2651 }
   2652 
   2653 static void remove_func_handler(struct pevent *pevent, char *func_name)
   2654 {
   2655 	struct pevent_function_handler *func;
   2656 	struct pevent_function_handler **next;
   2657 
   2658 	next = &pevent->func_handlers;
   2659 	while ((func = *next)) {
   2660 		if (strcmp(func->name, func_name) == 0) {
   2661 			*next = func->next;
   2662 			free_func_handle(func);
   2663 			break;
   2664 		}
   2665 		next = &func->next;
   2666 	}
   2667 }
   2668 
   2669 static enum event_type
   2670 process_func_handler(struct event_format *event, struct pevent_function_handler *func,
   2671 		     struct print_arg *arg, char **tok)
   2672 {
   2673 	struct print_arg **next_arg;
   2674 	struct print_arg *farg;
   2675 	enum event_type type;
   2676 	char *token;
   2677 	const char *test;
   2678 	int i;
   2679 
   2680 	arg->type = PRINT_FUNC;
   2681 	arg->func.func = func;
   2682 
   2683 	*tok = NULL;
   2684 
   2685 	next_arg = &(arg->func.args);
   2686 	for (i = 0; i < func->nr_args; i++) {
   2687 		farg = alloc_arg();
   2688 		if (!farg) {
   2689 			do_warning("%s: not enough memory!", __func__);
   2690 			return EVENT_ERROR;
   2691 		}
   2692 
   2693 		type = process_arg(event, farg, &token);
   2694 		if (i < (func->nr_args - 1))
   2695 			test = ",";
   2696 		else
   2697 			test = ")";
   2698 
   2699 		if (test_type_token(type, token, EVENT_DELIM, test)) {
   2700 			free_arg(farg);
   2701 			free_token(token);
   2702 			return EVENT_ERROR;
   2703 		}
   2704 
   2705 		*next_arg = farg;
   2706 		next_arg = &(farg->next);
   2707 		free_token(token);
   2708 	}
   2709 
   2710 	type = read_token(&token);
   2711 	*tok = token;
   2712 
   2713 	return type;
   2714 }
   2715 
   2716 static enum event_type
   2717 process_function(struct event_format *event, struct print_arg *arg,
   2718 		 char *token, char **tok)
   2719 {
   2720 	struct pevent_function_handler *func;
   2721 
   2722 	if (strcmp(token, "__print_flags") == 0) {
   2723 		free_token(token);
   2724 		is_flag_field = 1;
   2725 		return process_flags(event, arg, tok);
   2726 	}
   2727 	if (strcmp(token, "__print_symbolic") == 0) {
   2728 		free_token(token);
   2729 		is_symbolic_field = 1;
   2730 		return process_symbols(event, arg, tok);
   2731 	}
   2732 	if (strcmp(token, "__print_hex") == 0) {
   2733 		free_token(token);
   2734 		return process_hex(event, arg, tok);
   2735 	}
   2736 	if (strcmp(token, "__get_str") == 0) {
   2737 		free_token(token);
   2738 		return process_str(event, arg, tok);
   2739 	}
   2740 	if (strcmp(token, "__get_dynamic_array") == 0) {
   2741 		free_token(token);
   2742 		return process_dynamic_array(event, arg, tok);
   2743 	}
   2744 
   2745 	func = find_func_handler(event->pevent, token);
   2746 	if (func) {
   2747 		free_token(token);
   2748 		return process_func_handler(event, func, arg, tok);
   2749 	}
   2750 
   2751 	do_warning("function %s not defined", token);
   2752 	free_token(token);
   2753 	return EVENT_ERROR;
   2754 }
   2755 
   2756 static enum event_type
   2757 process_arg_token(struct event_format *event, struct print_arg *arg,
   2758 		  char **tok, enum event_type type)
   2759 {
   2760 	char *token;
   2761 	char *atom;
   2762 
   2763 	token = *tok;
   2764 
   2765 	switch (type) {
   2766 	case EVENT_ITEM:
   2767 		if (strcmp(token, "REC") == 0) {
   2768 			free_token(token);
   2769 			type = process_entry(event, arg, &token);
   2770 			break;
   2771 		}
   2772 		atom = token;
   2773 		/* test the next token */
   2774 		type = read_token_item(&token);
   2775 
   2776 		/*
   2777 		 * If the next token is a parenthesis, then this
   2778 		 * is a function.
   2779 		 */
   2780 		if (type == EVENT_DELIM && strcmp(token, "(") == 0) {
   2781 			free_token(token);
   2782 			token = NULL;
   2783 			/* this will free atom. */
   2784 			type = process_function(event, arg, atom, &token);
   2785 			break;
   2786 		}
   2787 		/* atoms can be more than one token long */
   2788 		while (type == EVENT_ITEM) {
   2789 			char *new_atom;
   2790 			new_atom = realloc(atom,
   2791 					   strlen(atom) + strlen(token) + 2);
   2792 			if (!new_atom) {
   2793 				free(atom);
   2794 				*tok = NULL;
   2795 				free_token(token);
   2796 				return EVENT_ERROR;
   2797 			}
   2798 			atom = new_atom;
   2799 			strcat(atom, " ");
   2800 			strcat(atom, token);
   2801 			free_token(token);
   2802 			type = read_token_item(&token);
   2803 		}
   2804 
   2805 		arg->type = PRINT_ATOM;
   2806 		arg->atom.atom = atom;
   2807 		break;
   2808 
   2809 	case EVENT_DQUOTE:
   2810 	case EVENT_SQUOTE:
   2811 		arg->type = PRINT_ATOM;
   2812 		arg->atom.atom = token;
   2813 		type = read_token_item(&token);
   2814 		break;
   2815 	case EVENT_DELIM:
   2816 		if (strcmp(token, "(") == 0) {
   2817 			free_token(token);
   2818 			type = process_paren(event, arg, &token);
   2819 			break;
   2820 		}
   2821 	case EVENT_OP:
   2822 		/* handle single ops */
   2823 		arg->type = PRINT_OP;
   2824 		arg->op.op = token;
   2825 		arg->op.left = NULL;
   2826 		type = process_op(event, arg, &token);
   2827 
   2828 		/* On error, the op is freed */
   2829 		if (type == EVENT_ERROR)
   2830 			arg->op.op = NULL;
   2831 
   2832 		/* return error type if errored */
   2833 		break;
   2834 
   2835 	case EVENT_ERROR ... EVENT_NEWLINE:
   2836 	default:
   2837 		do_warning("unexpected type %d", type);
   2838 		return EVENT_ERROR;
   2839 	}
   2840 	*tok = token;
   2841 
   2842 	return type;
   2843 }
   2844 
   2845 static int event_read_print_args(struct event_format *event, struct print_arg **list)
   2846 {
   2847 	enum event_type type = EVENT_ERROR;
   2848 	struct print_arg *arg;
   2849 	char *token;
   2850 	int args = 0;
   2851 
   2852 	do {
   2853 		if (type == EVENT_NEWLINE) {
   2854 			type = read_token_item(&token);
   2855 			continue;
   2856 		}
   2857 
   2858 		arg = alloc_arg();
   2859 		if (!arg) {
   2860 			do_warning("%s: not enough memory!", __func__);
   2861 			return -1;
   2862 		}
   2863 
   2864 		type = process_arg(event, arg, &token);
   2865 
   2866 		if (type == EVENT_ERROR) {
   2867 			free_token(token);
   2868 			free_arg(arg);
   2869 			return -1;
   2870 		}
   2871 
   2872 		*list = arg;
   2873 		args++;
   2874 
   2875 		if (type == EVENT_OP) {
   2876 			type = process_op(event, arg, &token);
   2877 			free_token(token);
   2878 			if (type == EVENT_ERROR) {
   2879 				*list = NULL;
   2880 				free_arg(arg);
   2881 				return -1;
   2882 			}
   2883 			list = &arg->next;
   2884 			continue;
   2885 		}
   2886 
   2887 		if (type == EVENT_DELIM && strcmp(token, ",") == 0) {
   2888 			free_token(token);
   2889 			*list = arg;
   2890 			list = &arg->next;
   2891 			continue;
   2892 		}
   2893 		break;
   2894 	} while (type != EVENT_NONE);
   2895 
   2896 	if (type != EVENT_NONE && type != EVENT_ERROR)
   2897 		free_token(token);
   2898 
   2899 	return args;
   2900 }
   2901 
   2902 static int event_read_print(struct event_format *event)
   2903 {
   2904 	enum event_type type;
   2905 	char *token;
   2906 	int ret;
   2907 
   2908 	if (read_expected_item(EVENT_ITEM, "print") < 0)
   2909 		return -1;
   2910 
   2911 	if (read_expected(EVENT_ITEM, "fmt") < 0)
   2912 		return -1;
   2913 
   2914 	if (read_expected(EVENT_OP, ":") < 0)
   2915 		return -1;
   2916 
   2917 	if (read_expect_type(EVENT_DQUOTE, &token) < 0)
   2918 		goto fail;
   2919 
   2920  concat:
   2921 	event->print_fmt.format = token;
   2922 	event->print_fmt.args = NULL;
   2923 
   2924 	/* ok to have no arg */
   2925 	type = read_token_item(&token);
   2926 
   2927 	if (type == EVENT_NONE)
   2928 		return 0;
   2929 
   2930 	/* Handle concatenation of print lines */
   2931 	if (type == EVENT_DQUOTE) {
   2932 		char *cat;
   2933 
   2934 		if (asprintf(&cat, "%s%s", event->print_fmt.format, token) < 0)
   2935 			goto fail;
   2936 		free_token(token);
   2937 		free_token(event->print_fmt.format);
   2938 		event->print_fmt.format = NULL;
   2939 		token = cat;
   2940 		goto concat;
   2941 	}
   2942 
   2943 	if (test_type_token(type, token, EVENT_DELIM, ","))
   2944 		goto fail;
   2945 
   2946 	free_token(token);
   2947 
   2948 	ret = event_read_print_args(event, &event->print_fmt.args);
   2949 	if (ret < 0)
   2950 		return -1;
   2951 
   2952 	return ret;
   2953 
   2954  fail:
   2955 	free_token(token);
   2956 	return -1;
   2957 }
   2958 
   2959 /**
   2960  * pevent_find_common_field - return a common field by event
   2961  * @event: handle for the event
   2962  * @name: the name of the common field to return
   2963  *
   2964  * Returns a common field from the event by the given @name.
   2965  * This only searchs the common fields and not all field.
   2966  */
   2967 struct format_field *
   2968 pevent_find_common_field(struct event_format *event, const char *name)
   2969 {
   2970 	struct format_field *format;
   2971 
   2972 	for (format = event->format.common_fields;
   2973 	     format; format = format->next) {
   2974 		if (strcmp(format->name, name) == 0)
   2975 			break;
   2976 	}
   2977 
   2978 	return format;
   2979 }
   2980 
   2981 /**
   2982  * pevent_find_field - find a non-common field
   2983  * @event: handle for the event
   2984  * @name: the name of the non-common field
   2985  *
   2986  * Returns a non-common field by the given @name.
   2987  * This does not search common fields.
   2988  */
   2989 struct format_field *
   2990 pevent_find_field(struct event_format *event, const char *name)
   2991 {
   2992 	struct format_field *format;
   2993 
   2994 	for (format = event->format.fields;
   2995 	     format; format = format->next) {
   2996 		if (strcmp(format->name, name) == 0)
   2997 			break;
   2998 	}
   2999 
   3000 	return format;
   3001 }
   3002 
   3003 /**
   3004  * pevent_find_any_field - find any field by name
   3005  * @event: handle for the event
   3006  * @name: the name of the field
   3007  *
   3008  * Returns a field by the given @name.
   3009  * This searchs the common field names first, then
   3010  * the non-common ones if a common one was not found.
   3011  */
   3012 struct format_field *
   3013 pevent_find_any_field(struct event_format *event, const char *name)
   3014 {
   3015 	struct format_field *format;
   3016 
   3017 	format = pevent_find_common_field(event, name);
   3018 	if (format)
   3019 		return format;
   3020 	return pevent_find_field(event, name);
   3021 }
   3022 
   3023 /**
   3024  * pevent_read_number - read a number from data
   3025  * @pevent: handle for the pevent
   3026  * @ptr: the raw data
   3027  * @size: the size of the data that holds the number
   3028  *
   3029  * Returns the number (converted to host) from the
   3030  * raw data.
   3031  */
   3032 unsigned long long pevent_read_number(struct pevent *pevent,
   3033 				      const void *ptr, int size)
   3034 {
   3035 	switch (size) {
   3036 	case 1:
   3037 		return *(unsigned char *)ptr;
   3038 	case 2:
   3039 		return data2host2(pevent, ptr);
   3040 	case 4:
   3041 		return data2host4(pevent, ptr);
   3042 	case 8:
   3043 		return data2host8(pevent, ptr);
   3044 	default:
   3045 		/* BUG! */
   3046 		return 0;
   3047 	}
   3048 }
   3049 
   3050 /**
   3051  * pevent_read_number_field - read a number from data
   3052  * @field: a handle to the field
   3053  * @data: the raw data to read
   3054  * @value: the value to place the number in
   3055  *
   3056  * Reads raw data according to a field offset and size,
   3057  * and translates it into @value.
   3058  *
   3059  * Returns 0 on success, -1 otherwise.
   3060  */
   3061 int pevent_read_number_field(struct format_field *field, const void *data,
   3062 			     unsigned long long *value)
   3063 {
   3064 	if (!field)
   3065 		return -1;
   3066 	switch (field->size) {
   3067 	case 1:
   3068 	case 2:
   3069 	case 4:
   3070 	case 8:
   3071 		*value = pevent_read_number(field->event->pevent,
   3072 					    data + field->offset, field->size);
   3073 		return 0;
   3074 	default:
   3075 		return -1;
   3076 	}
   3077 }
   3078 
   3079 static int get_common_info(struct pevent *pevent,
   3080 			   const char *type, int *offset, int *size)
   3081 {
   3082 	struct event_format *event;
   3083 	struct format_field *field;
   3084 
   3085 	/*
   3086 	 * All events should have the same common elements.
   3087 	 * Pick any event to find where the type is;
   3088 	 */
   3089 	if (!pevent->events) {
   3090 		do_warning("no event_list!");
   3091 		return -1;
   3092 	}
   3093 
   3094 	event = pevent->events[0];
   3095 	field = pevent_find_common_field(event, type);
   3096 	if (!field)
   3097 		return -1;
   3098 
   3099 	*offset = field->offset;
   3100 	*size = field->size;
   3101 
   3102 	return 0;
   3103 }
   3104 
   3105 static int __parse_common(struct pevent *pevent, void *data,
   3106 			  int *size, int *offset, const char *name)
   3107 {
   3108 	int ret;
   3109 
   3110 	if (!*size) {
   3111 		ret = get_common_info(pevent, name, offset, size);
   3112 		if (ret < 0)
   3113 			return ret;
   3114 	}
   3115 	return pevent_read_number(pevent, data + *offset, *size);
   3116 }
   3117 
   3118 static int trace_parse_common_type(struct pevent *pevent, void *data)
   3119 {
   3120 	return __parse_common(pevent, data,
   3121 			      &pevent->type_size, &pevent->type_offset,
   3122 			      "common_type");
   3123 }
   3124 
   3125 static int parse_common_pid(struct pevent *pevent, void *data)
   3126 {
   3127 	return __parse_common(pevent, data,
   3128 			      &pevent->pid_size, &pevent->pid_offset,
   3129 			      "common_pid");
   3130 }
   3131 
   3132 static int parse_common_pc(struct pevent *pevent, void *data)
   3133 {
   3134 	return __parse_common(pevent, data,
   3135 			      &pevent->pc_size, &pevent->pc_offset,
   3136 			      "common_preempt_count");
   3137 }
   3138 
   3139 static int parse_common_flags(struct pevent *pevent, void *data)
   3140 {
   3141 	return __parse_common(pevent, data,
   3142 			      &pevent->flags_size, &pevent->flags_offset,
   3143 			      "common_flags");
   3144 }
   3145 
   3146 static int parse_common_lock_depth(struct pevent *pevent, void *data)
   3147 {
   3148 	return __parse_common(pevent, data,
   3149 			      &pevent->ld_size, &pevent->ld_offset,
   3150 			      "common_lock_depth");
   3151 }
   3152 
   3153 static int parse_common_migrate_disable(struct pevent *pevent, void *data)
   3154 {
   3155 	return __parse_common(pevent, data,
   3156 			      &pevent->ld_size, &pevent->ld_offset,
   3157 			      "common_migrate_disable");
   3158 }
   3159 
   3160 static int events_id_cmp(const void *a, const void *b);
   3161 
   3162 /**
   3163  * pevent_find_event - find an event by given id
   3164  * @pevent: a handle to the pevent
   3165  * @id: the id of the event
   3166  *
   3167  * Returns an event that has a given @id.
   3168  */
   3169 struct event_format *pevent_find_event(struct pevent *pevent, int id)
   3170 {
   3171 	struct event_format **eventptr;
   3172 	struct event_format key;
   3173 	struct event_format *pkey = &key;
   3174 
   3175 	/* Check cache first */
   3176 	if (pevent->last_event && pevent->last_event->id == id)
   3177 		return pevent->last_event;
   3178 
   3179 	key.id = id;
   3180 
   3181 	eventptr = bsearch(&pkey, pevent->events, pevent->nr_events,
   3182 			   sizeof(*pevent->events), events_id_cmp);
   3183 
   3184 	if (eventptr) {
   3185 		pevent->last_event = *eventptr;
   3186 		return *eventptr;
   3187 	}
   3188 
   3189 	return NULL;
   3190 }
   3191 
   3192 /**
   3193  * pevent_find_event_by_name - find an event by given name
   3194  * @pevent: a handle to the pevent
   3195  * @sys: the system name to search for
   3196  * @name: the name of the event to search for
   3197  *
   3198  * This returns an event with a given @name and under the system
   3199  * @sys. If @sys is NULL the first event with @name is returned.
   3200  */
   3201 struct event_format *
   3202 pevent_find_event_by_name(struct pevent *pevent,
   3203 			  const char *sys, const char *name)
   3204 {
   3205 	struct event_format *event;
   3206 	int i;
   3207 
   3208 	if (pevent->last_event &&
   3209 	    strcmp(pevent->last_event->name, name) == 0 &&
   3210 	    (!sys || strcmp(pevent->last_event->system, sys) == 0))
   3211 		return pevent->last_event;
   3212 
   3213 	for (i = 0; i < pevent->nr_events; i++) {
   3214 		event = pevent->events[i];
   3215 		if (strcmp(event->name, name) == 0) {
   3216 			if (!sys)
   3217 				break;
   3218 			if (strcmp(event->system, sys) == 0)
   3219 				break;
   3220 		}
   3221 	}
   3222 	if (i == pevent->nr_events)
   3223 		event = NULL;
   3224 
   3225 	pevent->last_event = event;
   3226 	return event;
   3227 }
   3228 
   3229 static unsigned long long
   3230 eval_num_arg(void *data, int size, struct event_format *event, struct print_arg *arg)
   3231 {
   3232 	struct pevent *pevent = event->pevent;
   3233 	unsigned long long val = 0;
   3234 	unsigned long long left, right;
   3235 	struct print_arg *typearg = NULL;
   3236 	struct print_arg *larg;
   3237 	unsigned long offset;
   3238 	unsigned int field_size;
   3239 
   3240 	switch (arg->type) {
   3241 	case PRINT_NULL:
   3242 		/* ?? */
   3243 		return 0;
   3244 	case PRINT_ATOM:
   3245 		return strtoull(arg->atom.atom, NULL, 0);
   3246 	case PRINT_FIELD:
   3247 		if (!arg->field.field) {
   3248 			arg->field.field = pevent_find_any_field(event, arg->field.name);
   3249 			if (!arg->field.field)
   3250 				goto out_warning_field;
   3251 
   3252 		}
   3253 		/* must be a number */
   3254 		val = pevent_read_number(pevent, data + arg->field.field->offset,
   3255 				arg->field.field->size);
   3256 		break;
   3257 	case PRINT_FLAGS:
   3258 	case PRINT_SYMBOL:
   3259 	case PRINT_HEX:
   3260 		break;
   3261 	case PRINT_TYPE:
   3262 		val = eval_num_arg(data, size, event, arg->typecast.item);
   3263 		return eval_type(val, arg, 0);
   3264 	case PRINT_STRING:
   3265 	case PRINT_BSTRING:
   3266 		return 0;
   3267 	case PRINT_FUNC: {
   3268 		struct trace_seq s;
   3269 		trace_seq_init(&s);
   3270 		val = process_defined_func(&s, data, size, event, arg);
   3271 		trace_seq_destroy(&s);
   3272 		return val;
   3273 	}
   3274 	case PRINT_OP:
   3275 		if (strcmp(arg->op.op, "[") == 0) {
   3276 			/*
   3277 			 * Arrays are special, since we don't want
   3278 			 * to read the arg as is.
   3279 			 */
   3280 			right = eval_num_arg(data, size, event, arg->op.right);
   3281 
   3282 			/* handle typecasts */
   3283 			larg = arg->op.left;
   3284 			while (larg->type == PRINT_TYPE) {
   3285 				if (!typearg)
   3286 					typearg = larg;
   3287 				larg = larg->typecast.item;
   3288 			}
   3289 
   3290 			/* Default to long size */
   3291 			field_size = pevent->long_size;
   3292 
   3293 			switch (larg->type) {
   3294 			case PRINT_DYNAMIC_ARRAY:
   3295 				offset = pevent_read_number(pevent,
   3296 						   data + larg->dynarray.field->offset,
   3297 						   larg->dynarray.field->size);
   3298 				if (larg->dynarray.field->elementsize)
   3299 					field_size = larg->dynarray.field->elementsize;
   3300 				/*
   3301 				 * The actual length of the dynamic array is stored
   3302 				 * in the top half of the field, and the offset
   3303 				 * is in the bottom half of the 32 bit field.
   3304 				 */
   3305 				offset &= 0xffff;
   3306 				offset += right;
   3307 				break;
   3308 			case PRINT_FIELD:
   3309 				if (!larg->field.field) {
   3310 					larg->field.field =
   3311 						pevent_find_any_field(event, larg->field.name);
   3312 					if (!larg->field.field) {
   3313 						arg = larg;
   3314 						goto out_warning_field;
   3315 					}
   3316 				}
   3317 				field_size = larg->field.field->elementsize;
   3318 				offset = larg->field.field->offset +
   3319 					right * larg->field.field->elementsize;
   3320 				break;
   3321 			default:
   3322 				goto default_op; /* oops, all bets off */
   3323 			}
   3324 			val = pevent_read_number(pevent,
   3325 						 data + offset, field_size);
   3326 			if (typearg)
   3327 				val = eval_type(val, typearg, 1);
   3328 			break;
   3329 		} else if (strcmp(arg->op.op, "?") == 0) {
   3330 			left = eval_num_arg(data, size, event, arg->op.left);
   3331 			arg = arg->op.right;
   3332 			if (left)
   3333 				val = eval_num_arg(data, size, event, arg->op.left);
   3334 			else
   3335 				val = eval_num_arg(data, size, event, arg->op.right);
   3336 			break;
   3337 		}
   3338  default_op:
   3339 		left = eval_num_arg(data, size, event, arg->op.left);
   3340 		right = eval_num_arg(data, size, event, arg->op.right);
   3341 		switch (arg->op.op[0]) {
   3342 		case '!':
   3343 			switch (arg->op.op[1]) {
   3344 			case 0:
   3345 				val = !right;
   3346 				break;
   3347 			case '=':
   3348 				val = left != right;
   3349 				break;
   3350 			default:
   3351 				goto out_warning_op;
   3352 			}
   3353 			break;
   3354 		case '~':
   3355 			val = ~right;
   3356 			break;
   3357 		case '|':
   3358 			if (arg->op.op[1])
   3359 				val = left || right;
   3360 			else
   3361 				val = left | right;
   3362 			break;
   3363 		case '&':
   3364 			if (arg->op.op[1])
   3365 				val = left && right;
   3366 			else
   3367 				val = left & right;
   3368 			break;
   3369 		case '<':
   3370 			switch (arg->op.op[1]) {
   3371 			case 0:
   3372 				val = left < right;
   3373 				break;
   3374 			case '<':
   3375 				val = left << right;
   3376 				break;
   3377 			case '=':
   3378 				val = left <= right;
   3379 				break;
   3380 			default:
   3381 				goto out_warning_op;
   3382 			}
   3383 			break;
   3384 		case '>':
   3385 			switch (arg->op.op[1]) {
   3386 			case 0:
   3387 				val = left > right;
   3388 				break;
   3389 			case '>':
   3390 				val = left >> right;
   3391 				break;
   3392 			case '=':
   3393 				val = left >= right;
   3394 				break;
   3395 			default:
   3396 				goto out_warning_op;
   3397 			}
   3398 			break;
   3399 		case '=':
   3400 			if (arg->op.op[1] != '=')
   3401 				goto out_warning_op;
   3402 
   3403 			val = left == right;
   3404 			break;
   3405 		case '-':
   3406 			val = left - right;
   3407 			break;
   3408 		case '+':
   3409 			val = left + right;
   3410 			break;
   3411 		case '/':
   3412 			val = left / right;
   3413 			break;
   3414 		case '*':
   3415 			val = left * right;
   3416 			break;
   3417 		default:
   3418 			goto out_warning_op;
   3419 		}
   3420 		break;
   3421 	default: /* not sure what to do there */
   3422 		return 0;
   3423 	}
   3424 	return val;
   3425 
   3426 out_warning_op:
   3427 	do_warning("%s: unknown op '%s'", __func__, arg->op.op);
   3428 	return 0;
   3429 
   3430 out_warning_field:
   3431 	do_warning("%s: field %s not found", __func__, arg->field.name);
   3432 	return 0;
   3433 }
   3434 
   3435 struct flag {
   3436 	const char *name;
   3437 	unsigned long long value;
   3438 };
   3439 
   3440 static const struct flag flags[] = {
   3441 	{ "HI_SOFTIRQ", 0 },
   3442 	{ "TIMER_SOFTIRQ", 1 },
   3443 	{ "NET_TX_SOFTIRQ", 2 },
   3444 	{ "NET_RX_SOFTIRQ", 3 },
   3445 	{ "BLOCK_SOFTIRQ", 4 },
   3446 	{ "BLOCK_IOPOLL_SOFTIRQ", 5 },
   3447 	{ "TASKLET_SOFTIRQ", 6 },
   3448 	{ "SCHED_SOFTIRQ", 7 },
   3449 	{ "HRTIMER_SOFTIRQ", 8 },
   3450 	{ "RCU_SOFTIRQ", 9 },
   3451 
   3452 	{ "HRTIMER_NORESTART", 0 },
   3453 	{ "HRTIMER_RESTART", 1 },
   3454 };
   3455 
   3456 static unsigned long long eval_flag(const char *flag)
   3457 {
   3458 	int i;
   3459 
   3460 	/*
   3461 	 * Some flags in the format files do not get converted.
   3462 	 * If the flag is not numeric, see if it is something that
   3463 	 * we already know about.
   3464 	 */
   3465 	if (isdigit(flag[0]))
   3466 		return strtoull(flag, NULL, 0);
   3467 
   3468 	for (i = 0; i < (int)(sizeof(flags)/sizeof(flags[0])); i++)
   3469 		if (strcmp(flags[i].name, flag) == 0)
   3470 			return flags[i].value;
   3471 
   3472 	return 0;
   3473 }
   3474 
   3475 static void print_str_to_seq(struct trace_seq *s, const char *format,
   3476 			     int len_arg, const char *str)
   3477 {
   3478 	if (len_arg >= 0)
   3479 		trace_seq_printf(s, format, len_arg, str);
   3480 	else
   3481 		trace_seq_printf(s, format, str);
   3482 }
   3483 
   3484 static void print_str_arg(struct trace_seq *s, void *data, int size,
   3485 			  struct event_format *event, const char *format,
   3486 			  int len_arg, struct print_arg *arg)
   3487 {
   3488 	struct pevent *pevent = event->pevent;
   3489 	struct print_flag_sym *flag;
   3490 	struct format_field *field;
   3491 	unsigned long long val, fval;
   3492 	unsigned long addr;
   3493 	char *str;
   3494 	unsigned char *hex;
   3495 	int print;
   3496 	int i, len;
   3497 
   3498 	switch (arg->type) {
   3499 	case PRINT_NULL:
   3500 		/* ?? */
   3501 		return;
   3502 	case PRINT_ATOM:
   3503 		print_str_to_seq(s, format, len_arg, arg->atom.atom);
   3504 		return;
   3505 	case PRINT_FIELD:
   3506 		field = arg->field.field;
   3507 		if (!field) {
   3508 			field = pevent_find_any_field(event, arg->field.name);
   3509 			if (!field) {
   3510 				str = arg->field.name;
   3511 				goto out_warning_field;
   3512 			}
   3513 			arg->field.field = field;
   3514 		}
   3515 		/* Zero sized fields, mean the rest of the data */
   3516 		len = field->size ? : size - field->offset;
   3517 
   3518 		/*
   3519 		 * Some events pass in pointers. If this is not an array
   3520 		 * and the size is the same as long_size, assume that it
   3521 		 * is a pointer.
   3522 		 */
   3523 		if (!(field->flags & FIELD_IS_ARRAY) &&
   3524 		    field->size == pevent->long_size) {
   3525 			addr = *(unsigned long *)(data + field->offset);
   3526 			trace_seq_printf(s, "%lx", addr);
   3527 			break;
   3528 		}
   3529 		str = malloc(len + 1);
   3530 		if (!str) {
   3531 			do_warning("%s: not enough memory!", __func__);
   3532 			return;
   3533 		}
   3534 		memcpy(str, data + field->offset, len);
   3535 		str[len] = 0;
   3536 		print_str_to_seq(s, format, len_arg, str);
   3537 		free(str);
   3538 		break;
   3539 	case PRINT_FLAGS:
   3540 		val = eval_num_arg(data, size, event, arg->flags.field);
   3541 		print = 0;
   3542 		for (flag = arg->flags.flags; flag; flag = flag->next) {
   3543 			fval = eval_flag(flag->value);
   3544 			if (!val && !fval) {
   3545 				print_str_to_seq(s, format, len_arg, flag->str);
   3546 				break;
   3547 			}
   3548 			if (fval && (val & fval) == fval) {
   3549 				if (print && arg->flags.delim)
   3550 					trace_seq_puts(s, arg->flags.delim);
   3551 				print_str_to_seq(s, format, len_arg, flag->str);
   3552 				print = 1;
   3553 				val &= ~fval;
   3554 			}
   3555 		}
   3556 		break;
   3557 	case PRINT_SYMBOL:
   3558 		val = eval_num_arg(data, size, event, arg->symbol.field);
   3559 		for (flag = arg->symbol.symbols; flag; flag = flag->next) {
   3560 			fval = eval_flag(flag->value);
   3561 			if (val == fval) {
   3562 				print_str_to_seq(s, format, len_arg, flag->str);
   3563 				break;
   3564 			}
   3565 		}
   3566 		break;
   3567 	case PRINT_HEX:
   3568 		field = arg->hex.field->field.field;
   3569 		if (!field) {
   3570 			str = arg->hex.field->field.name;
   3571 			field = pevent_find_any_field(event, str);
   3572 			if (!field)
   3573 				goto out_warning_field;
   3574 			arg->hex.field->field.field = field;
   3575 		}
   3576 		hex = data + field->offset;
   3577 		len = eval_num_arg(data, size, event, arg->hex.size);
   3578 		for (i = 0; i < len; i++) {
   3579 			if (i)
   3580 				trace_seq_putc(s, ' ');
   3581 			trace_seq_printf(s, "%02x", hex[i]);
   3582 		}
   3583 		break;
   3584 
   3585 	case PRINT_TYPE:
   3586 		break;
   3587 	case PRINT_STRING: {
   3588 		int str_offset;
   3589 
   3590 		if (arg->string.offset == -1) {
   3591 			struct format_field *f;
   3592 
   3593 			f = pevent_find_any_field(event, arg->string.string);
   3594 			arg->string.offset = f->offset;
   3595 		}
   3596 		str_offset = data2host4(pevent, data + arg->string.offset);
   3597 		str_offset &= 0xffff;
   3598 		print_str_to_seq(s, format, len_arg, ((char *)data) + str_offset);
   3599 		break;
   3600 	}
   3601 	case PRINT_BSTRING:
   3602 		print_str_to_seq(s, format, len_arg, arg->string.string);
   3603 		break;
   3604 	case PRINT_OP:
   3605 		/*
   3606 		 * The only op for string should be ? :
   3607 		 */
   3608 		if (arg->op.op[0] != '?')
   3609 			return;
   3610 		val = eval_num_arg(data, size, event, arg->op.left);
   3611 		if (val)
   3612 			print_str_arg(s, data, size, event,
   3613 				      format, len_arg, arg->op.right->op.left);
   3614 		else
   3615 			print_str_arg(s, data, size, event,
   3616 				      format, len_arg, arg->op.right->op.right);
   3617 		break;
   3618 	case PRINT_FUNC:
   3619 		process_defined_func(s, data, size, event, arg);
   3620 		break;
   3621 	default:
   3622 		/* well... */
   3623 		break;
   3624 	}
   3625 
   3626 	return;
   3627 
   3628 out_warning_field:
   3629 	do_warning("%s: field %s not found", __func__, arg->field.name);
   3630 }
   3631 
   3632 static unsigned long long
   3633 process_defined_func(struct trace_seq *s, void *data, int size,
   3634 		     struct event_format *event, struct print_arg *arg)
   3635 {
   3636 	struct pevent_function_handler *func_handle = arg->func.func;
   3637 	struct pevent_func_params *param;
   3638 	unsigned long long *args;
   3639 	unsigned long long ret;
   3640 	struct print_arg *farg;
   3641 	struct trace_seq str;
   3642 	struct save_str {
   3643 		struct save_str *next;
   3644 		char *str;
   3645 	} *strings = NULL, *string;
   3646 	int i;
   3647 
   3648 	if (!func_handle->nr_args) {
   3649 		ret = (*func_handle->func)(s, NULL);
   3650 		goto out;
   3651 	}
   3652 
   3653 	farg = arg->func.args;
   3654 	param = func_handle->params;
   3655 
   3656 	ret = ULLONG_MAX;
   3657 	args = malloc(sizeof(*args) * func_handle->nr_args);
   3658 	if (!args)
   3659 		goto out;
   3660 
   3661 	for (i = 0; i < func_handle->nr_args; i++) {
   3662 		switch (param->type) {
   3663 		case PEVENT_FUNC_ARG_INT:
   3664 		case PEVENT_FUNC_ARG_LONG:
   3665 		case PEVENT_FUNC_ARG_PTR:
   3666 			args[i] = eval_num_arg(data, size, event, farg);
   3667 			break;
   3668 		case PEVENT_FUNC_ARG_STRING:
   3669 			trace_seq_init(&str);
   3670 			print_str_arg(&str, data, size, event, "%s", -1, farg);
   3671 			trace_seq_terminate(&str);
   3672 			string = malloc(sizeof(*string));
   3673 			if (!string) {
   3674 				do_warning("%s(%d): malloc str", __func__, __LINE__);
   3675 				goto out_free;
   3676 			}
   3677 			string->next = strings;
   3678 			string->str = strdup(str.buffer);
   3679 			if (!string->str) {
   3680 				free(string);
   3681 				do_warning("%s(%d): malloc str", __func__, __LINE__);
   3682 				goto out_free;
   3683 			}
   3684 			args[i] = (uintptr_t)string->str;
   3685 			strings = string;
   3686 			trace_seq_destroy(&str);
   3687 			break;
   3688 		default:
   3689 			/*
   3690 			 * Something went totally wrong, this is not
   3691 			 * an input error, something in this code broke.
   3692 			 */
   3693 			do_warning("Unexpected end of arguments\n");
   3694 			goto out_free;
   3695 		}
   3696 		farg = farg->next;
   3697 		param = param->next;
   3698 	}
   3699 
   3700 	ret = (*func_handle->func)(s, args);
   3701 out_free:
   3702 	free(args);
   3703 	while (strings) {
   3704 		string = strings;
   3705 		strings = string->next;
   3706 		free(string->str);
   3707 		free(string);
   3708 	}
   3709 
   3710  out:
   3711 	/* TBD : handle return type here */
   3712 	return ret;
   3713 }
   3714 
   3715 static void free_args(struct print_arg *args)
   3716 {
   3717 	struct print_arg *next;
   3718 
   3719 	while (args) {
   3720 		next = args->next;
   3721 
   3722 		free_arg(args);
   3723 		args = next;
   3724 	}
   3725 }
   3726 
   3727 static struct print_arg *make_bprint_args(char *fmt, void *data, int size, struct event_format *event)
   3728 {
   3729 	struct pevent *pevent = event->pevent;
   3730 	struct format_field *field, *ip_field;
   3731 	struct print_arg *args, *arg, **next;
   3732 	unsigned long long ip, val;
   3733 	char *ptr;
   3734 	void *bptr;
   3735 	int vsize;
   3736 
   3737 	field = pevent->bprint_buf_field;
   3738 	ip_field = pevent->bprint_ip_field;
   3739 
   3740 	if (!field) {
   3741 		field = pevent_find_field(event, "buf");
   3742 		if (!field) {
   3743 			do_warning("can't find buffer field for binary printk");
   3744 			return NULL;
   3745 		}
   3746 		ip_field = pevent_find_field(event, "ip");
   3747 		if (!ip_field) {
   3748 			do_warning("can't find ip field for binary printk");
   3749 			return NULL;
   3750 		}
   3751 		pevent->bprint_buf_field = field;
   3752 		pevent->bprint_ip_field = ip_field;
   3753 	}
   3754 
   3755 	ip = pevent_read_number(pevent, data + ip_field->offset, ip_field->size);
   3756 
   3757 	/*
   3758 	 * The first arg is the IP pointer.
   3759 	 */
   3760 	args = alloc_arg();
   3761 	if (!args) {
   3762 		do_warning("%s(%d): not enough memory!", __func__, __LINE__);
   3763 		return NULL;
   3764 	}
   3765 	arg = args;
   3766 	arg->next = NULL;
   3767 	next = &arg->next;
   3768 
   3769 	arg->type = PRINT_ATOM;
   3770 
   3771 	if (asprintf(&arg->atom.atom, "%lld", ip) < 0)
   3772 		goto out_free;
   3773 
   3774 	/* skip the first "%pf : " */
   3775 	for (ptr = fmt + 6, bptr = data + field->offset;
   3776 	     bptr < data + size && *ptr; ptr++) {
   3777 		int ls = 0;
   3778 
   3779 		if (*ptr == '%') {
   3780  process_again:
   3781 			ptr++;
   3782 			switch (*ptr) {
   3783 			case '%':
   3784 				break;
   3785 			case 'l':
   3786 				ls++;
   3787 				goto process_again;
   3788 			case 'L':
   3789 				ls = 2;
   3790 				goto process_again;
   3791 			case '0' ... '9':
   3792 				goto process_again;
   3793 			case '.':
   3794 				goto process_again;
   3795 			case 'p':
   3796 				ls = 1;
   3797 				/* fall through */
   3798 			case 'd':
   3799 			case 'u':
   3800 			case 'x':
   3801 			case 'i':
   3802 				switch (ls) {
   3803 				case 0:
   3804 					vsize = 4;
   3805 					break;
   3806 				case 1:
   3807 					vsize = pevent->long_size;
   3808 					break;
   3809 				case 2:
   3810 					vsize = 8;
   3811 					break;
   3812 				default:
   3813 					vsize = ls; /* ? */
   3814 					break;
   3815 				}
   3816 			/* fall through */
   3817 			case '*':
   3818 				if (*ptr == '*')
   3819 					vsize = 4;
   3820 
   3821 				/* the pointers are always 4 bytes aligned */
   3822 				bptr = (void *)(((unsigned long)bptr + 3) &
   3823 						~3);
   3824 				val = pevent_read_number(pevent, bptr, vsize);
   3825 				bptr += vsize;
   3826 				arg = alloc_arg();
   3827 				if (!arg) {
   3828 					do_warning("%s(%d): not enough memory!",
   3829 						   __func__, __LINE__);
   3830 					goto out_free;
   3831 				}
   3832 				arg->next = NULL;
   3833 				arg->type = PRINT_ATOM;
   3834 				if (asprintf(&arg->atom.atom, "%lld", val) < 0) {
   3835 					free(arg);
   3836 					goto out_free;
   3837 				}
   3838 				*next = arg;
   3839 				next = &arg->next;
   3840 				/*
   3841 				 * The '*' case means that an arg is used as the length.
   3842 				 * We need to continue to figure out for what.
   3843 				 */
   3844 				if (*ptr == '*')
   3845 					goto process_again;
   3846 
   3847 				break;
   3848 			case 's':
   3849 				arg = alloc_arg();
   3850 				if (!arg) {
   3851 					do_warning("%s(%d): not enough memory!",
   3852 						   __func__, __LINE__);
   3853 					goto out_free;
   3854 				}
   3855 				arg->next = NULL;
   3856 				arg->type = PRINT_BSTRING;
   3857 				arg->string.string = strdup(bptr);
   3858 				if (!arg->string.string)
   3859 					goto out_free;
   3860 				bptr += strlen(bptr) + 1;
   3861 				*next = arg;
   3862 				next = &arg->next;
   3863 			default:
   3864 				break;
   3865 			}
   3866 		}
   3867 	}
   3868 
   3869 	return args;
   3870 
   3871 out_free:
   3872 	free_args(args);
   3873 	return NULL;
   3874 }
   3875 
   3876 static char *
   3877 get_bprint_format(void *data, int size __maybe_unused,
   3878 		  struct event_format *event)
   3879 {
   3880 	struct pevent *pevent = event->pevent;
   3881 	unsigned long long addr;
   3882 	struct format_field *field;
   3883 	struct printk_map *printk;
   3884 	char *format;
   3885 	char *p;
   3886 
   3887 	field = pevent->bprint_fmt_field;
   3888 
   3889 	if (!field) {
   3890 		field = pevent_find_field(event, "fmt");
   3891 		if (!field) {
   3892 			do_warning("can't find format field for binary printk");
   3893 			return NULL;
   3894 		}
   3895 		pevent->bprint_fmt_field = field;
   3896 	}
   3897 
   3898 	addr = pevent_read_number(pevent, data + field->offset, field->size);
   3899 
   3900 	printk = find_printk(pevent, addr);
   3901 	if (!printk) {
   3902 		if (asprintf(&format, "%%pf : (NO FORMAT FOUND at %llx)\n", addr) < 0)
   3903 			return NULL;
   3904 		return format;
   3905 	}
   3906 
   3907 	p = printk->printk;
   3908 	/* Remove any quotes. */
   3909 	if (*p == '"')
   3910 		p++;
   3911 	if (asprintf(&format, "%s : %s", "%pf", p) < 0)
   3912 		return NULL;
   3913 	/* remove ending quotes and new line since we will add one too */
   3914 	p = format + strlen(format) - 1;
   3915 	if (*p == '"')
   3916 		*p = 0;
   3917 
   3918 	p -= 2;
   3919 	if (strcmp(p, "\\n") == 0)
   3920 		*p = 0;
   3921 
   3922 	return format;
   3923 }
   3924 
   3925 static void print_mac_arg(struct trace_seq *s, int mac, void *data, int size,
   3926 			  struct event_format *event, struct print_arg *arg)
   3927 {
   3928 	unsigned char *buf;
   3929 	const char *fmt = "%.2x:%.2x:%.2x:%.2x:%.2x:%.2x";
   3930 
   3931 	if (arg->type == PRINT_FUNC) {
   3932 		process_defined_func(s, data, size, event, arg);
   3933 		return;
   3934 	}
   3935 
   3936 	if (arg->type != PRINT_FIELD) {
   3937 		trace_seq_printf(s, "ARG TYPE NOT FIELD BUT %d",
   3938 				 arg->type);
   3939 		return;
   3940 	}
   3941 
   3942 	if (mac == 'm')
   3943 		fmt = "%.2x%.2x%.2x%.2x%.2x%.2x";
   3944 	if (!arg->field.field) {
   3945 		arg->field.field =
   3946 			pevent_find_any_field(event, arg->field.name);
   3947 		if (!arg->field.field) {
   3948 			do_warning("%s: field %s not found",
   3949 				   __func__, arg->field.name);
   3950 			return;
   3951 		}
   3952 	}
   3953 	if (arg->field.field->size != 6) {
   3954 		trace_seq_printf(s, "INVALIDMAC");
   3955 		return;
   3956 	}
   3957 	buf = data + arg->field.field->offset;
   3958 	trace_seq_printf(s, fmt, buf[0], buf[1], buf[2], buf[3], buf[4], buf[5]);
   3959 }
   3960 
   3961 static int is_printable_array(char *p, unsigned int len)
   3962 {
   3963 	unsigned int i;
   3964 
   3965 	for (i = 0; i < len && p[i]; i++)
   3966 		if (!isprint(p[i]))
   3967 		    return 0;
   3968 	return 1;
   3969 }
   3970 
   3971 static void print_event_fields(struct trace_seq *s, void *data,
   3972 			       int size __maybe_unused,
   3973 			       struct event_format *event)
   3974 {
   3975 	struct format_field *field;
   3976 	unsigned long long val;
   3977 	unsigned int offset, len, i;
   3978 
   3979 	field = event->format.fields;
   3980 	while (field) {
   3981 		trace_seq_printf(s, " %s=", field->name);
   3982 		if (field->flags & FIELD_IS_ARRAY) {
   3983 			offset = field->offset;
   3984 			len = field->size;
   3985 			if (field->flags & FIELD_IS_DYNAMIC) {
   3986 				val = pevent_read_number(event->pevent, data + offset, len);
   3987 				offset = val;
   3988 				len = offset >> 16;
   3989 				offset &= 0xffff;
   3990 			}
   3991 			if (field->flags & FIELD_IS_STRING &&
   3992 			    is_printable_array(data + offset, len)) {
   3993 				trace_seq_printf(s, "%s", (char *)data + offset);
   3994 			} else {
   3995 				trace_seq_puts(s, "ARRAY[");
   3996 				for (i = 0; i < len; i++) {
   3997 					if (i)
   3998 						trace_seq_puts(s, ", ");
   3999 					trace_seq_printf(s, "%02x",
   4000 							 *((unsigned char *)data + offset + i));
   4001 				}
   4002 				trace_seq_putc(s, ']');
   4003 				field->flags &= ~FIELD_IS_STRING;
   4004 			}
   4005 		} else {
   4006 			val = pevent_read_number(event->pevent, data + field->offset,
   4007 						 field->size);
   4008 			if (field->flags & FIELD_IS_POINTER) {
   4009 				trace_seq_printf(s, "0x%llx", val);
   4010 			} else if (field->flags & FIELD_IS_SIGNED) {
   4011 				switch (field->size) {
   4012 				case 4:
   4013 					/*
   4014 					 * If field is long then print it in hex.
   4015 					 * A long usually stores pointers.
   4016 					 */
   4017 					if (field->flags & FIELD_IS_LONG)
   4018 						trace_seq_printf(s, "0x%x", (int)val);
   4019 					else
   4020 						trace_seq_printf(s, "%d", (int)val);
   4021 					break;
   4022 				case 2:
   4023 					trace_seq_printf(s, "%2d", (short)val);
   4024 					break;
   4025 				case 1:
   4026 					trace_seq_printf(s, "%1d", (char)val);
   4027 					break;
   4028 				default:
   4029 					trace_seq_printf(s, "%lld", val);
   4030 				}
   4031 			} else {
   4032 				if (field->flags & FIELD_IS_LONG)
   4033 					trace_seq_printf(s, "0x%llx", val);
   4034 				else
   4035 					trace_seq_printf(s, "%llu", val);
   4036 			}
   4037 		}
   4038 		field = field->next;
   4039 	}
   4040 }
   4041 
   4042 static void pretty_print(struct trace_seq *s, void *data, int size, struct event_format *event)
   4043 {
   4044 	struct pevent *pevent = event->pevent;
   4045 	struct print_fmt *print_fmt = &event->print_fmt;
   4046 	struct print_arg *arg = print_fmt->args;
   4047 	struct print_arg *args = NULL;
   4048 	const char *ptr = print_fmt->format;
   4049 	unsigned long long val;
   4050 	struct func_map *func;
   4051 	const char *saveptr;
   4052 	char *bprint_fmt = NULL;
   4053 	char format[32];
   4054 	int show_func;
   4055 	int len_as_arg;
   4056 	int len_arg;
   4057 	int len;
   4058 	int ls;
   4059 
   4060 	if (event->flags & EVENT_FL_FAILED) {
   4061 		trace_seq_printf(s, "[FAILED TO PARSE]");
   4062 		print_event_fields(s, data, size, event);
   4063 		return;
   4064 	}
   4065 
   4066 	if (event->flags & EVENT_FL_ISBPRINT) {
   4067 		bprint_fmt = get_bprint_format(data, size, event);
   4068 		args = make_bprint_args(bprint_fmt, data, size, event);
   4069 		arg = args;
   4070 		ptr = bprint_fmt;
   4071 	}
   4072 
   4073 	for (; *ptr; ptr++) {
   4074 		ls = 0;
   4075 		if (*ptr == '\\') {
   4076 			ptr++;
   4077 			switch (*ptr) {
   4078 			case 'n':
   4079 				trace_seq_putc(s, '\n');
   4080 				break;
   4081 			case 't':
   4082 				trace_seq_putc(s, '\t');
   4083 				break;
   4084 			case 'r':
   4085 				trace_seq_putc(s, '\r');
   4086 				break;
   4087 			case '\\':
   4088 				trace_seq_putc(s, '\\');
   4089 				break;
   4090 			default:
   4091 				trace_seq_putc(s, *ptr);
   4092 				break;
   4093 			}
   4094 
   4095 		} else if (*ptr == '%') {
   4096 			saveptr = ptr;
   4097 			show_func = 0;
   4098 			len_as_arg = 0;
   4099  cont_process:
   4100 			ptr++;
   4101 			switch (*ptr) {
   4102 			case '%':
   4103 				trace_seq_putc(s, '%');
   4104 				break;
   4105 			case '#':
   4106 				/* FIXME: need to handle properly */
   4107 				goto cont_process;
   4108 			case 'h':
   4109 				ls--;
   4110 				goto cont_process;
   4111 			case 'l':
   4112 				ls++;
   4113 				goto cont_process;
   4114 			case 'L':
   4115 				ls = 2;
   4116 				goto cont_process;
   4117 			case '*':
   4118 				/* The argument is the length. */
   4119 				if (!arg) {
   4120 					do_warning("no argument match");
   4121 					event->flags |= EVENT_FL_FAILED;
   4122 					goto out_failed;
   4123 				}
   4124 				len_arg = eval_num_arg(data, size, event, arg);
   4125 				len_as_arg = 1;
   4126 				arg = arg->next;
   4127 				goto cont_process;
   4128 			case '.':
   4129 			case 'z':
   4130 			case 'Z':
   4131 			case '0' ... '9':
   4132 				goto cont_process;
   4133 			case 'p':
   4134 				if (pevent->long_size == 4)
   4135 					ls = 1;
   4136 				else
   4137 					ls = 2;
   4138 
   4139 				if (*(ptr+1) == 'F' ||
   4140 				    *(ptr+1) == 'f') {
   4141 					ptr++;
   4142 					show_func = *ptr;
   4143 				} else if (*(ptr+1) == 'M' || *(ptr+1) == 'm') {
   4144 					print_mac_arg(s, *(ptr+1), data, size, event, arg);
   4145 					ptr++;
   4146 					arg = arg->next;
   4147 					break;
   4148 				}
   4149 
   4150 				/* fall through */
   4151 			case 'd':
   4152 			case 'i':
   4153 			case 'x':
   4154 			case 'X':
   4155 			case 'u':
   4156 				if (!arg) {
   4157 					do_warning("no argument match");
   4158 					event->flags |= EVENT_FL_FAILED;
   4159 					goto out_failed;
   4160 				}
   4161 
   4162 				len = ((unsigned long)ptr + 1) -
   4163 					(unsigned long)saveptr;
   4164 
   4165 				/* should never happen */
   4166 				if (len > 31) {
   4167 					do_warning("bad format!");
   4168 					event->flags |= EVENT_FL_FAILED;
   4169 					len = 31;
   4170 				}
   4171 
   4172 				memcpy(format, saveptr, len);
   4173 				format[len] = 0;
   4174 
   4175 				val = eval_num_arg(data, size, event, arg);
   4176 				arg = arg->next;
   4177 
   4178 				if (show_func) {
   4179 					func = find_func(pevent, val);
   4180 					if (func) {
   4181 						trace_seq_puts(s, func->func);
   4182 						if (show_func == 'F')
   4183 							trace_seq_printf(s,
   4184 							       "+0x%llx",
   4185 							       val - func->addr);
   4186 						break;
   4187 					}
   4188 				}
   4189 				if (pevent->long_size == 8 && ls &&
   4190 				    sizeof(long) != 8) {
   4191 					char *p;
   4192 
   4193 					ls = 2;
   4194 					/* make %l into %ll */
   4195 					p = strchr(format, 'l');
   4196 					if (p)
   4197 						memmove(p+1, p, strlen(p)+1);
   4198 					else if (strcmp(format, "%p") == 0)
   4199 						strcpy(format, "0x%llx");
   4200 				}
   4201 				switch (ls) {
   4202 				case -2:
   4203 					if (len_as_arg)
   4204 						trace_seq_printf(s, format, len_arg, (char)val);
   4205 					else
   4206 						trace_seq_printf(s, format, (char)val);
   4207 					break;
   4208 				case -1:
   4209 					if (len_as_arg)
   4210 						trace_seq_printf(s, format, len_arg, (short)val);
   4211 					else
   4212 						trace_seq_printf(s, format, (short)val);
   4213 					break;
   4214 				case 0:
   4215 					if (len_as_arg)
   4216 						trace_seq_printf(s, format, len_arg, (int)val);
   4217 					else
   4218 						trace_seq_printf(s, format, (int)val);
   4219 					break;
   4220 				case 1:
   4221 					if (len_as_arg)
   4222 						trace_seq_printf(s, format, len_arg, (long)val);
   4223 					else
   4224 						trace_seq_printf(s, format, (long)val);
   4225 					break;
   4226 				case 2:
   4227 					if (len_as_arg)
   4228 						trace_seq_printf(s, format, len_arg,
   4229 								 (long long)val);
   4230 					else
   4231 						trace_seq_printf(s, format, (long long)val);
   4232 					break;
   4233 				default:
   4234 					do_warning("bad count (%d)", ls);
   4235 					event->flags |= EVENT_FL_FAILED;
   4236 				}
   4237 				break;
   4238 			case 's':
   4239 				if (!arg) {
   4240 					do_warning("no matching argument");
   4241 					event->flags |= EVENT_FL_FAILED;
   4242 					goto out_failed;
   4243 				}
   4244 
   4245 				len = ((unsigned long)ptr + 1) -
   4246 					(unsigned long)saveptr;
   4247 
   4248 				/* should never happen */
   4249 				if (len > 31) {
   4250 					do_warning("bad format!");
   4251 					event->flags |= EVENT_FL_FAILED;
   4252 					len = 31;
   4253 				}
   4254 
   4255 				memcpy(format, saveptr, len);
   4256 				format[len] = 0;
   4257 				if (!len_as_arg)
   4258 					len_arg = -1;
   4259 				print_str_arg(s, data, size, event,
   4260 					      format, len_arg, arg);
   4261 				arg = arg->next;
   4262 				break;
   4263 			default:
   4264 				trace_seq_printf(s, ">%c<", *ptr);
   4265 
   4266 			}
   4267 		} else
   4268 			trace_seq_putc(s, *ptr);
   4269 	}
   4270 
   4271 	if (event->flags & EVENT_FL_FAILED) {
   4272 out_failed:
   4273 		trace_seq_printf(s, "[FAILED TO PARSE]");
   4274 	}
   4275 
   4276 	if (args) {
   4277 		free_args(args);
   4278 		free(bprint_fmt);
   4279 	}
   4280 }
   4281 
   4282 /**
   4283  * pevent_data_lat_fmt - parse the data for the latency format
   4284  * @pevent: a handle to the pevent
   4285  * @s: the trace_seq to write to
   4286  * @record: the record to read from
   4287  *
   4288  * This parses out the Latency format (interrupts disabled,
   4289  * need rescheduling, in hard/soft interrupt, preempt count
   4290  * and lock depth) and places it into the trace_seq.
   4291  */
   4292 void pevent_data_lat_fmt(struct pevent *pevent,
   4293 			 struct trace_seq *s, struct pevent_record *record)
   4294 {
   4295 	static int check_lock_depth = 1;
   4296 	static int check_migrate_disable = 1;
   4297 	static int lock_depth_exists;
   4298 	static int migrate_disable_exists;
   4299 	unsigned int lat_flags;
   4300 	unsigned int pc;
   4301 	int lock_depth;
   4302 	int migrate_disable;
   4303 	int hardirq;
   4304 	int softirq;
   4305 	void *data = record->data;
   4306 
   4307 	lat_flags = parse_common_flags(pevent, data);
   4308 	pc = parse_common_pc(pevent, data);
   4309 	/* lock_depth may not always exist */
   4310 	if (lock_depth_exists)
   4311 		lock_depth = parse_common_lock_depth(pevent, data);
   4312 	else if (check_lock_depth) {
   4313 		lock_depth = parse_common_lock_depth(pevent, data);
   4314 		if (lock_depth < 0)
   4315 			check_lock_depth = 0;
   4316 		else
   4317 			lock_depth_exists = 1;
   4318 	}
   4319 
   4320 	/* migrate_disable may not always exist */
   4321 	if (migrate_disable_exists)
   4322 		migrate_disable = parse_common_migrate_disable(pevent, data);
   4323 	else if (check_migrate_disable) {
   4324 		migrate_disable = parse_common_migrate_disable(pevent, data);
   4325 		if (migrate_disable < 0)
   4326 			check_migrate_disable = 0;
   4327 		else
   4328 			migrate_disable_exists = 1;
   4329 	}
   4330 
   4331 	hardirq = lat_flags & TRACE_FLAG_HARDIRQ;
   4332 	softirq = lat_flags & TRACE_FLAG_SOFTIRQ;
   4333 
   4334 	trace_seq_printf(s, "%c%c%c",
   4335 	       (lat_flags & TRACE_FLAG_IRQS_OFF) ? 'd' :
   4336 	       (lat_flags & TRACE_FLAG_IRQS_NOSUPPORT) ?
   4337 	       'X' : '.',
   4338 	       (lat_flags & TRACE_FLAG_NEED_RESCHED) ?
   4339 	       'N' : '.',
   4340 	       (hardirq && softirq) ? 'H' :
   4341 	       hardirq ? 'h' : softirq ? 's' : '.');
   4342 
   4343 	if (pc)
   4344 		trace_seq_printf(s, "%x", pc);
   4345 	else
   4346 		trace_seq_putc(s, '.');
   4347 
   4348 	if (migrate_disable_exists) {
   4349 		if (migrate_disable < 0)
   4350 			trace_seq_putc(s, '.');
   4351 		else
   4352 			trace_seq_printf(s, "%d", migrate_disable);
   4353 	}
   4354 
   4355 	if (lock_depth_exists) {
   4356 		if (lock_depth < 0)
   4357 			trace_seq_putc(s, '.');
   4358 		else
   4359 			trace_seq_printf(s, "%d", lock_depth);
   4360 	}
   4361 
   4362 	trace_seq_terminate(s);
   4363 }
   4364 
   4365 /**
   4366  * pevent_data_type - parse out the given event type
   4367  * @pevent: a handle to the pevent
   4368  * @rec: the record to read from
   4369  *
   4370  * This returns the event id from the @rec.
   4371  */
   4372 int pevent_data_type(struct pevent *pevent, struct pevent_record *rec)
   4373 {
   4374 	return trace_parse_common_type(pevent, rec->data);
   4375 }
   4376 
   4377 /**
   4378  * pevent_data_event_from_type - find the event by a given type
   4379  * @pevent: a handle to the pevent
   4380  * @type: the type of the event.
   4381  *
   4382  * This returns the event form a given @type;
   4383  */
   4384 struct event_format *pevent_data_event_from_type(struct pevent *pevent, int type)
   4385 {
   4386 	return pevent_find_event(pevent, type);
   4387 }
   4388 
   4389 /**
   4390  * pevent_data_pid - parse the PID from raw data
   4391  * @pevent: a handle to the pevent
   4392  * @rec: the record to parse
   4393  *
   4394  * This returns the PID from a raw data.
   4395  */
   4396 int pevent_data_pid(struct pevent *pevent, struct pevent_record *rec)
   4397 {
   4398 	return parse_common_pid(pevent, rec->data);
   4399 }
   4400 
   4401 /**
   4402  * pevent_data_comm_from_pid - return the command line from PID
   4403  * @pevent: a handle to the pevent
   4404  * @pid: the PID of the task to search for
   4405  *
   4406  * This returns a pointer to the command line that has the given
   4407  * @pid.
   4408  */
   4409 const char *pevent_data_comm_from_pid(struct pevent *pevent, int pid)
   4410 {
   4411 	const char *comm;
   4412 
   4413 	comm = find_cmdline(pevent, pid);
   4414 	return comm;
   4415 }
   4416 
   4417 /**
   4418  * pevent_data_comm_from_pid - parse the data into the print format
   4419  * @s: the trace_seq to write to
   4420  * @event: the handle to the event
   4421  * @record: the record to read from
   4422  *
   4423  * This parses the raw @data using the given @event information and
   4424  * writes the print format into the trace_seq.
   4425  */
   4426 void pevent_event_info(struct trace_seq *s, struct event_format *event,
   4427 		       struct pevent_record *record)
   4428 {
   4429 	int print_pretty = 1;
   4430 
   4431 	if (event->pevent->print_raw)
   4432 		print_event_fields(s, record->data, record->size, event);
   4433 	else {
   4434 
   4435 		if (event->handler)
   4436 			print_pretty = event->handler(s, record, event,
   4437 						      event->context);
   4438 
   4439 		if (print_pretty)
   4440 			pretty_print(s, record->data, record->size, event);
   4441 	}
   4442 
   4443 	trace_seq_terminate(s);
   4444 }
   4445 
   4446 void pevent_print_event(struct pevent *pevent, struct trace_seq *s,
   4447 			struct pevent_record *record)
   4448 {
   4449 	static const char *spaces = "                    "; /* 20 spaces */
   4450 	struct event_format *event;
   4451 	unsigned long secs;
   4452 	unsigned long usecs;
   4453 	unsigned long nsecs;
   4454 	const char *comm;
   4455 	void *data = record->data;
   4456 	int type;
   4457 	int pid;
   4458 	int len;
   4459 	int p;
   4460 
   4461 	secs = record->ts / NSECS_PER_SEC;
   4462 	nsecs = record->ts - secs * NSECS_PER_SEC;
   4463 
   4464 	if (record->size < 0) {
   4465 		do_warning("ug! negative record size %d", record->size);
   4466 		return;
   4467 	}
   4468 
   4469 	type = trace_parse_common_type(pevent, data);
   4470 
   4471 	event = pevent_find_event(pevent, type);
   4472 	if (!event) {
   4473 		do_warning("ug! no event found for type %d", type);
   4474 		return;
   4475 	}
   4476 
   4477 	pid = parse_common_pid(pevent, data);
   4478 	comm = find_cmdline(pevent, pid);
   4479 
   4480 	if (pevent->latency_format) {
   4481 		trace_seq_printf(s, "%8.8s-%-5d %3d",
   4482 		       comm, pid, record->cpu);
   4483 		pevent_data_lat_fmt(pevent, s, record);
   4484 	} else
   4485 		trace_seq_printf(s, "%16s-%-5d [%03d]", comm, pid, record->cpu);
   4486 
   4487 	if (pevent->flags & PEVENT_NSEC_OUTPUT) {
   4488 		usecs = nsecs;
   4489 		p = 9;
   4490 	} else {
   4491 		usecs = (nsecs + 500) / NSECS_PER_USEC;
   4492 		p = 6;
   4493 	}
   4494 
   4495 	trace_seq_printf(s, " %5lu.%0*lu: %s: ", secs, p, usecs, event->name);
   4496 
   4497 	/* Space out the event names evenly. */
   4498 	len = strlen(event->name);
   4499 	if (len < 20)
   4500 		trace_seq_printf(s, "%.*s", 20 - len, spaces);
   4501 
   4502 	pevent_event_info(s, event, record);
   4503 }
   4504 
   4505 static int events_id_cmp(const void *a, const void *b)
   4506 {
   4507 	struct event_format * const * ea = a;
   4508 	struct event_format * const * eb = b;
   4509 
   4510 	if ((*ea)->id < (*eb)->id)
   4511 		return -1;
   4512 
   4513 	if ((*ea)->id > (*eb)->id)
   4514 		return 1;
   4515 
   4516 	return 0;
   4517 }
   4518 
   4519 static int events_name_cmp(const void *a, const void *b)
   4520 {
   4521 	struct event_format * const * ea = a;
   4522 	struct event_format * const * eb = b;
   4523 	int res;
   4524 
   4525 	res = strcmp((*ea)->name, (*eb)->name);
   4526 	if (res)
   4527 		return res;
   4528 
   4529 	res = strcmp((*ea)->system, (*eb)->system);
   4530 	if (res)
   4531 		return res;
   4532 
   4533 	return events_id_cmp(a, b);
   4534 }
   4535 
   4536 static int events_system_cmp(const void *a, const void *b)
   4537 {
   4538 	struct event_format * const * ea = a;
   4539 	struct event_format * const * eb = b;
   4540 	int res;
   4541 
   4542 	res = strcmp((*ea)->system, (*eb)->system);
   4543 	if (res)
   4544 		return res;
   4545 
   4546 	res = strcmp((*ea)->name, (*eb)->name);
   4547 	if (res)
   4548 		return res;
   4549 
   4550 	return events_id_cmp(a, b);
   4551 }
   4552 
   4553 struct event_format **pevent_list_events(struct pevent *pevent, enum event_sort_type sort_type)
   4554 {
   4555 	struct event_format **events;
   4556 	int (*sort)(const void *a, const void *b);
   4557 
   4558 	events = pevent->sort_events;
   4559 
   4560 	if (events && pevent->last_type == sort_type)
   4561 		return events;
   4562 
   4563 	if (!events) {
   4564 		events = malloc(sizeof(*events) * (pevent->nr_events + 1));
   4565 		if (!events)
   4566 			return NULL;
   4567 
   4568 		memcpy(events, pevent->events, sizeof(*events) * pevent->nr_events);
   4569 		events[pevent->nr_events] = NULL;
   4570 
   4571 		pevent->sort_events = events;
   4572 
   4573 		/* the internal events are sorted by id */
   4574 		if (sort_type == EVENT_SORT_ID) {
   4575 			pevent->last_type = sort_type;
   4576 			return events;
   4577 		}
   4578 	}
   4579 
   4580 	switch (sort_type) {
   4581 	case EVENT_SORT_ID:
   4582 		sort = events_id_cmp;
   4583 		break;
   4584 	case EVENT_SORT_NAME:
   4585 		sort = events_name_cmp;
   4586 		break;
   4587 	case EVENT_SORT_SYSTEM:
   4588 		sort = events_system_cmp;
   4589 		break;
   4590 	default:
   4591 		return events;
   4592 	}
   4593 
   4594 	qsort(events, pevent->nr_events, sizeof(*events), sort);
   4595 	pevent->last_type = sort_type;
   4596 
   4597 	return events;
   4598 }
   4599 
   4600 static struct format_field **
   4601 get_event_fields(const char *type, const char *name,
   4602 		 int count, struct format_field *list)
   4603 {
   4604 	struct format_field **fields;
   4605 	struct format_field *field;
   4606 	int i = 0;
   4607 
   4608 	fields = malloc(sizeof(*fields) * (count + 1));
   4609 	if (!fields)
   4610 		return NULL;
   4611 
   4612 	for (field = list; field; field = field->next) {
   4613 		fields[i++] = field;
   4614 		if (i == count + 1) {
   4615 			do_warning("event %s has more %s fields than specified",
   4616 				name, type);
   4617 			i--;
   4618 			break;
   4619 		}
   4620 	}
   4621 
   4622 	if (i != count)
   4623 		do_warning("event %s has less %s fields than specified",
   4624 			name, type);
   4625 
   4626 	fields[i] = NULL;
   4627 
   4628 	return fields;
   4629 }
   4630 
   4631 /**
   4632  * pevent_event_common_fields - return a list of common fields for an event
   4633  * @event: the event to return the common fields of.
   4634  *
   4635  * Returns an allocated array of fields. The last item in the array is NULL.
   4636  * The array must be freed with free().
   4637  */
   4638 struct format_field **pevent_event_common_fields(struct event_format *event)
   4639 {
   4640 	return get_event_fields("common", event->name,
   4641 				event->format.nr_common,
   4642 				event->format.common_fields);
   4643 }
   4644 
   4645 /**
   4646  * pevent_event_fields - return a list of event specific fields for an event
   4647  * @event: the event to return the fields of.
   4648  *
   4649  * Returns an allocated array of fields. The last item in the array is NULL.
   4650  * The array must be freed with free().
   4651  */
   4652 struct format_field **pevent_event_fields(struct event_format *event)
   4653 {
   4654 	return get_event_fields("event", event->name,
   4655 				event->format.nr_fields,
   4656 				event->format.fields);
   4657 }
   4658 
   4659 static void print_fields(struct trace_seq *s, struct print_flag_sym *field)
   4660 {
   4661 	trace_seq_printf(s, "{ %s, %s }", field->value, field->str);
   4662 	if (field->next) {
   4663 		trace_seq_puts(s, ", ");
   4664 		print_fields(s, field->next);
   4665 	}
   4666 }
   4667 
   4668 /* for debugging */
   4669 static void print_args(struct print_arg *args)
   4670 {
   4671 	int print_paren = 1;
   4672 	struct trace_seq s;
   4673 
   4674 	switch (args->type) {
   4675 	case PRINT_NULL:
   4676 		printf("null");
   4677 		break;
   4678 	case PRINT_ATOM:
   4679 		printf("%s", args->atom.atom);
   4680 		break;
   4681 	case PRINT_FIELD:
   4682 		printf("REC->%s", args->field.name);
   4683 		break;
   4684 	case PRINT_FLAGS:
   4685 		printf("__print_flags(");
   4686 		print_args(args->flags.field);
   4687 		printf(", %s, ", args->flags.delim);
   4688 		trace_seq_init(&s);
   4689 		print_fields(&s, args->flags.flags);
   4690 		trace_seq_do_printf(&s);
   4691 		trace_seq_destroy(&s);
   4692 		printf(")");
   4693 		break;
   4694 	case PRINT_SYMBOL:
   4695 		printf("__print_symbolic(");
   4696 		print_args(args->symbol.field);
   4697 		printf(", ");
   4698 		trace_seq_init(&s);
   4699 		print_fields(&s, args->symbol.symbols);
   4700 		trace_seq_do_printf(&s);
   4701 		trace_seq_destroy(&s);
   4702 		printf(")");
   4703 		break;
   4704 	case PRINT_HEX:
   4705 		printf("__print_hex(");
   4706 		print_args(args->hex.field);
   4707 		printf(", ");
   4708 		print_args(args->hex.size);
   4709 		printf(")");
   4710 		break;
   4711 	case PRINT_STRING:
   4712 	case PRINT_BSTRING:
   4713 		printf("__get_str(%s)", args->string.string);
   4714 		break;
   4715 	case PRINT_TYPE:
   4716 		printf("(%s)", args->typecast.type);
   4717 		print_args(args->typecast.item);
   4718 		break;
   4719 	case PRINT_OP:
   4720 		if (strcmp(args->op.op, ":") == 0)
   4721 			print_paren = 0;
   4722 		if (print_paren)
   4723 			printf("(");
   4724 		print_args(args->op.left);
   4725 		printf(" %s ", args->op.op);
   4726 		print_args(args->op.right);
   4727 		if (print_paren)
   4728 			printf(")");
   4729 		break;
   4730 	default:
   4731 		/* we should warn... */
   4732 		return;
   4733 	}
   4734 	if (args->next) {
   4735 		printf("\n");
   4736 		print_args(args->next);
   4737 	}
   4738 }
   4739 
   4740 static void parse_header_field(const char *field,
   4741 			       int *offset, int *size, int mandatory)
   4742 {
   4743 	unsigned long long save_input_buf_ptr;
   4744 	unsigned long long save_input_buf_siz;
   4745 	char *token;
   4746 	int type;
   4747 
   4748 	save_input_buf_ptr = input_buf_ptr;
   4749 	save_input_buf_siz = input_buf_siz;
   4750 
   4751 	if (read_expected(EVENT_ITEM, "field") < 0)
   4752 		return;
   4753 	if (read_expected(EVENT_OP, ":") < 0)
   4754 		return;
   4755 
   4756 	/* type */
   4757 	if (read_expect_type(EVENT_ITEM, &token) < 0)
   4758 		goto fail;
   4759 	free_token(token);
   4760 
   4761 	/*
   4762 	 * If this is not a mandatory field, then test it first.
   4763 	 */
   4764 	if (mandatory) {
   4765 		if (read_expected(EVENT_ITEM, field) < 0)
   4766 			return;
   4767 	} else {
   4768 		if (read_expect_type(EVENT_ITEM, &token) < 0)
   4769 			goto fail;
   4770 		if (strcmp(token, field) != 0)
   4771 			goto discard;
   4772 		free_token(token);
   4773 	}
   4774 
   4775 	if (read_expected(EVENT_OP, ";") < 0)
   4776 		return;
   4777 	if (read_expected(EVENT_ITEM, "offset") < 0)
   4778 		return;
   4779 	if (read_expected(EVENT_OP, ":") < 0)
   4780 		return;
   4781 	if (read_expect_type(EVENT_ITEM, &token) < 0)
   4782 		goto fail;
   4783 	*offset = atoi(token);
   4784 	free_token(token);
   4785 	if (read_expected(EVENT_OP, ";") < 0)
   4786 		return;
   4787 	if (read_expected(EVENT_ITEM, "size") < 0)
   4788 		return;
   4789 	if (read_expected(EVENT_OP, ":") < 0)
   4790 		return;
   4791 	if (read_expect_type(EVENT_ITEM, &token) < 0)
   4792 		goto fail;
   4793 	*size = atoi(token);
   4794 	free_token(token);
   4795 	if (read_expected(EVENT_OP, ";") < 0)
   4796 		return;
   4797 	type = read_token(&token);
   4798 	if (type != EVENT_NEWLINE) {
   4799 		/* newer versions of the kernel have a "signed" type */
   4800 		if (type != EVENT_ITEM)
   4801 			goto fail;
   4802 
   4803 		if (strcmp(token, "signed") != 0)
   4804 			goto fail;
   4805 
   4806 		free_token(token);
   4807 
   4808 		if (read_expected(EVENT_OP, ":") < 0)
   4809 			return;
   4810 
   4811 		if (read_expect_type(EVENT_ITEM, &token))
   4812 			goto fail;
   4813 
   4814 		free_token(token);
   4815 		if (read_expected(EVENT_OP, ";") < 0)
   4816 			return;
   4817 
   4818 		if (read_expect_type(EVENT_NEWLINE, &token))
   4819 			goto fail;
   4820 	}
   4821  fail:
   4822 	free_token(token);
   4823 	return;
   4824 
   4825  discard:
   4826 	input_buf_ptr = save_input_buf_ptr;
   4827 	input_buf_siz = save_input_buf_siz;
   4828 	*offset = 0;
   4829 	*size = 0;
   4830 	free_token(token);
   4831 }
   4832 
   4833 /**
   4834  * pevent_parse_header_page - parse the data stored in the header page
   4835  * @pevent: the handle to the pevent
   4836  * @buf: the buffer storing the header page format string
   4837  * @size: the size of @buf
   4838  * @long_size: the long size to use if there is no header
   4839  *
   4840  * This parses the header page format for information on the
   4841  * ring buffer used. The @buf should be copied from
   4842  *
   4843  * /sys/kernel/debug/tracing/events/header_page
   4844  */
   4845 int pevent_parse_header_page(struct pevent *pevent, char *buf, unsigned long size,
   4846 			     int long_size)
   4847 {
   4848 	int ignore;
   4849 
   4850 	if (!size) {
   4851 		/*
   4852 		 * Old kernels did not have header page info.
   4853 		 * Sorry but we just use what we find here in user space.
   4854 		 */
   4855 		pevent->header_page_ts_size = sizeof(long long);
   4856 		pevent->header_page_size_size = long_size;
   4857 		pevent->header_page_data_offset = sizeof(long long) + long_size;
   4858 		pevent->old_format = 1;
   4859 		return -1;
   4860 	}
   4861 	init_input_buf(buf, size);
   4862 
   4863 	parse_header_field("timestamp", &pevent->header_page_ts_offset,
   4864 			   &pevent->header_page_ts_size, 1);
   4865 	parse_header_field("commit", &pevent->header_page_size_offset,
   4866 			   &pevent->header_page_size_size, 1);
   4867 	parse_header_field("overwrite", &pevent->header_page_overwrite,
   4868 			   &ignore, 0);
   4869 	parse_header_field("data", &pevent->header_page_data_offset,
   4870 			   &pevent->header_page_data_size, 1);
   4871 
   4872 	return 0;
   4873 }
   4874 
   4875 static int event_matches(struct event_format *event,
   4876 			 int id, const char *sys_name,
   4877 			 const char *event_name)
   4878 {
   4879 	if (id >= 0 && id != event->id)
   4880 		return 0;
   4881 
   4882 	if (event_name && (strcmp(event_name, event->name) != 0))
   4883 		return 0;
   4884 
   4885 	if (sys_name && (strcmp(sys_name, event->system) != 0))
   4886 		return 0;
   4887 
   4888 	return 1;
   4889 }
   4890 
   4891 static void free_handler(struct event_handler *handle)
   4892 {
   4893 	free((void *)handle->sys_name);
   4894 	free((void *)handle->event_name);
   4895 	free(handle);
   4896 }
   4897 
   4898 static int find_event_handle(struct pevent *pevent, struct event_format *event)
   4899 {
   4900 	struct event_handler *handle, **next;
   4901 
   4902 	for (next = &pevent->handlers; *next;
   4903 	     next = &(*next)->next) {
   4904 		handle = *next;
   4905 		if (event_matches(event, handle->id,
   4906 				  handle->sys_name,
   4907 				  handle->event_name))
   4908 			break;
   4909 	}
   4910 
   4911 	if (!(*next))
   4912 		return 0;
   4913 
   4914 	pr_stat("overriding event (%d) %s:%s with new print handler",
   4915 		event->id, event->system, event->name);
   4916 
   4917 	event->handler = handle->func;
   4918 	event->context = handle->context;
   4919 
   4920 	*next = handle->next;
   4921 	free_handler(handle);
   4922 
   4923 	return 1;
   4924 }
   4925 
   4926 /**
   4927  * __pevent_parse_format - parse the event format
   4928  * @buf: the buffer storing the event format string
   4929  * @size: the size of @buf
   4930  * @sys: the system the event belongs to
   4931  *
   4932  * This parses the event format and creates an event structure
   4933  * to quickly parse raw data for a given event.
   4934  *
   4935  * These files currently come from:
   4936  *
   4937  * /sys/kernel/debug/tracing/events/.../.../format
   4938  */
   4939 enum pevent_errno __pevent_parse_format(struct event_format **eventp,
   4940 					struct pevent *pevent, const char *buf,
   4941 					unsigned long size, const char *sys)
   4942 {
   4943 	struct event_format *event;
   4944 	int ret;
   4945 
   4946 	init_input_buf(buf, size);
   4947 
   4948 	*eventp = event = alloc_event();
   4949 	if (!event)
   4950 		return PEVENT_ERRNO__MEM_ALLOC_FAILED;
   4951 
   4952 	event->name = event_read_name();
   4953 	if (!event->name) {
   4954 		/* Bad event? */
   4955 		ret = PEVENT_ERRNO__MEM_ALLOC_FAILED;
   4956 		goto event_alloc_failed;
   4957 	}
   4958 
   4959 	if (strcmp(sys, "ftrace") == 0) {
   4960 		event->flags |= EVENT_FL_ISFTRACE;
   4961 
   4962 		if (strcmp(event->name, "bprint") == 0)
   4963 			event->flags |= EVENT_FL_ISBPRINT;
   4964 	}
   4965 
   4966 	event->id = event_read_id();
   4967 	if (event->id < 0) {
   4968 		ret = PEVENT_ERRNO__READ_ID_FAILED;
   4969 		/*
   4970 		 * This isn't an allocation error actually.
   4971 		 * But as the ID is critical, just bail out.
   4972 		 */
   4973 		goto event_alloc_failed;
   4974 	}
   4975 
   4976 	event->system = strdup(sys);
   4977 	if (!event->system) {
   4978 		ret = PEVENT_ERRNO__MEM_ALLOC_FAILED;
   4979 		goto event_alloc_failed;
   4980 	}
   4981 
   4982 	/* Add pevent to event so that it can be referenced */
   4983 	event->pevent = pevent;
   4984 
   4985 	ret = event_read_format(event);
   4986 	if (ret < 0) {
   4987 		ret = PEVENT_ERRNO__READ_FORMAT_FAILED;
   4988 		goto event_parse_failed;
   4989 	}
   4990 
   4991 	/*
   4992 	 * If the event has an override, don't print warnings if the event
   4993 	 * print format fails to parse.
   4994 	 */
   4995 	if (pevent && find_event_handle(pevent, event))
   4996 		show_warning = 0;
   4997 
   4998 	ret = event_read_print(event);
   4999 	show_warning = 1;
   5000 
   5001 	if (ret < 0) {
   5002 		ret = PEVENT_ERRNO__READ_PRINT_FAILED;
   5003 		goto event_parse_failed;
   5004 	}
   5005 
   5006 	if (!ret && (event->flags & EVENT_FL_ISFTRACE)) {
   5007 		struct format_field *field;
   5008 		struct print_arg *arg, **list;
   5009 
   5010 		/* old ftrace had no args */
   5011 		list = &event->print_fmt.args;
   5012 		for (field = event->format.fields; field; field = field->next) {
   5013 			arg = alloc_arg();
   5014 			if (!arg) {
   5015 				event->flags |= EVENT_FL_FAILED;
   5016 				return PEVENT_ERRNO__OLD_FTRACE_ARG_FAILED;
   5017 			}
   5018 			arg->type = PRINT_FIELD;
   5019 			arg->field.name = strdup(field->name);
   5020 			if (!arg->field.name) {
   5021 				event->flags |= EVENT_FL_FAILED;
   5022 				free_arg(arg);
   5023 				return PEVENT_ERRNO__OLD_FTRACE_ARG_FAILED;
   5024 			}
   5025 			arg->field.field = field;
   5026 			*list = arg;
   5027 			list = &arg->next;
   5028 		}
   5029 		return 0;
   5030 	}
   5031 
   5032 	return 0;
   5033 
   5034  event_parse_failed:
   5035 	event->flags |= EVENT_FL_FAILED;
   5036 	return ret;
   5037 
   5038  event_alloc_failed:
   5039 	free(event->system);
   5040 	free(event->name);
   5041 	free(event);
   5042 	*eventp = NULL;
   5043 	return ret;
   5044 }
   5045 
   5046 /**
   5047  * pevent_parse_format - parse the event format
   5048  * @buf: the buffer storing the event format string
   5049  * @size: the size of @buf
   5050  * @sys: the system the event belongs to
   5051  *
   5052  * This parses the event format and creates an event structure
   5053  * to quickly parse raw data for a given event.
   5054  *
   5055  * These files currently come from:
   5056  *
   5057  * /sys/kernel/debug/tracing/events/.../.../format
   5058  */
   5059 enum pevent_errno pevent_parse_format(struct event_format **eventp, const char *buf,
   5060 				      unsigned long size, const char *sys)
   5061 {
   5062 	return __pevent_parse_format(eventp, NULL, buf, size, sys);
   5063 }
   5064 
   5065 /**
   5066  * pevent_parse_event - parse the event format
   5067  * @pevent: the handle to the pevent
   5068  * @buf: the buffer storing the event format string
   5069  * @size: the size of @buf
   5070  * @sys: the system the event belongs to
   5071  *
   5072  * This parses the event format and creates an event structure
   5073  * to quickly parse raw data for a given event.
   5074  *
   5075  * These files currently come from:
   5076  *
   5077  * /sys/kernel/debug/tracing/events/.../.../format
   5078  */
   5079 enum pevent_errno pevent_parse_event(struct pevent *pevent, const char *buf,
   5080 				     unsigned long size, const char *sys)
   5081 {
   5082 	struct event_format *event = NULL;
   5083 	int ret = __pevent_parse_format(&event, pevent, buf, size, sys);
   5084 
   5085 	if (event == NULL)
   5086 		return ret;
   5087 
   5088 	if (add_event(pevent, event)) {
   5089 		ret = PEVENT_ERRNO__MEM_ALLOC_FAILED;
   5090 		goto event_add_failed;
   5091 	}
   5092 
   5093 #define PRINT_ARGS 0
   5094 	if (PRINT_ARGS && event->print_fmt.args)
   5095 		print_args(event->print_fmt.args);
   5096 
   5097 	return 0;
   5098 
   5099 event_add_failed:
   5100 	pevent_free_format(event);
   5101 	return ret;
   5102 }
   5103 
   5104 #undef _PE
   5105 #define _PE(code, str) str
   5106 static const char * const pevent_error_str[] = {
   5107 	PEVENT_ERRORS
   5108 };
   5109 #undef _PE
   5110 
   5111 int pevent_strerror(struct pevent *pevent __maybe_unused,
   5112 		    enum pevent_errno errnum, char *buf, size_t buflen)
   5113 {
   5114 	int idx;
   5115 	const char *msg;
   5116 
   5117 	if (errnum >= 0) {
   5118 		msg = strerror_r(errnum, buf, buflen);
   5119 		if (msg != buf) {
   5120 			size_t len = strlen(msg);
   5121 			memcpy(buf, msg, min(buflen - 1, len));
   5122 			*(buf + min(buflen - 1, len)) = '\0';
   5123 		}
   5124 		return 0;
   5125 	}
   5126 
   5127 	if (errnum <= __PEVENT_ERRNO__START ||
   5128 	    errnum >= __PEVENT_ERRNO__END)
   5129 		return -1;
   5130 
   5131 	idx = errnum - __PEVENT_ERRNO__START - 1;
   5132 	msg = pevent_error_str[idx];
   5133 
   5134 	switch (errnum) {
   5135 	case PEVENT_ERRNO__MEM_ALLOC_FAILED:
   5136 	case PEVENT_ERRNO__PARSE_EVENT_FAILED:
   5137 	case PEVENT_ERRNO__READ_ID_FAILED:
   5138 	case PEVENT_ERRNO__READ_FORMAT_FAILED:
   5139 	case PEVENT_ERRNO__READ_PRINT_FAILED:
   5140 	case PEVENT_ERRNO__OLD_FTRACE_ARG_FAILED:
   5141 	case PEVENT_ERRNO__INVALID_ARG_TYPE:
   5142 		snprintf(buf, buflen, "%s", msg);
   5143 		break;
   5144 
   5145 	default:
   5146 		/* cannot reach here */
   5147 		break;
   5148 	}
   5149 
   5150 	return 0;
   5151 }
   5152 
   5153 int get_field_val(struct trace_seq *s, struct format_field *field,
   5154 		  const char *name, struct pevent_record *record,
   5155 		  unsigned long long *val, int err)
   5156 {
   5157 	if (!field) {
   5158 		if (err)
   5159 			trace_seq_printf(s, "<CANT FIND FIELD %s>", name);
   5160 		return -1;
   5161 	}
   5162 
   5163 	if (pevent_read_number_field(field, record->data, val)) {
   5164 		if (err)
   5165 			trace_seq_printf(s, " %s=INVALID", name);
   5166 		return -1;
   5167 	}
   5168 
   5169 	return 0;
   5170 }
   5171 
   5172 /**
   5173  * pevent_get_field_raw - return the raw pointer into the data field
   5174  * @s: The seq to print to on error
   5175  * @event: the event that the field is for
   5176  * @name: The name of the field
   5177  * @record: The record with the field name.
   5178  * @len: place to store the field length.
   5179  * @err: print default error if failed.
   5180  *
   5181  * Returns a pointer into record->data of the field and places
   5182  * the length of the field in @len.
   5183  *
   5184  * On failure, it returns NULL.
   5185  */
   5186 void *pevent_get_field_raw(struct trace_seq *s, struct event_format *event,
   5187 			   const char *name, struct pevent_record *record,
   5188 			   int *len, int err)
   5189 {
   5190 	struct format_field *field;
   5191 	void *data = record->data;
   5192 	unsigned offset;
   5193 	int dummy;
   5194 
   5195 	if (!event)
   5196 		return NULL;
   5197 
   5198 	field = pevent_find_field(event, name);
   5199 
   5200 	if (!field) {
   5201 		if (err)
   5202 			trace_seq_printf(s, "<CANT FIND FIELD %s>", name);
   5203 		return NULL;
   5204 	}
   5205 
   5206 	/* Allow @len to be NULL */
   5207 	if (!len)
   5208 		len = &dummy;
   5209 
   5210 	offset = field->offset;
   5211 	if (field->flags & FIELD_IS_DYNAMIC) {
   5212 		offset = pevent_read_number(event->pevent,
   5213 					    data + offset, field->size);
   5214 		*len = offset >> 16;
   5215 		offset &= 0xffff;
   5216 	} else
   5217 		*len = field->size;
   5218 
   5219 	return data + offset;
   5220 }
   5221 
   5222 /**
   5223  * pevent_get_field_val - find a field and return its value
   5224  * @s: The seq to print to on error
   5225  * @event: the event that the field is for
   5226  * @name: The name of the field
   5227  * @record: The record with the field name.
   5228  * @val: place to store the value of the field.
   5229  * @err: print default error if failed.
   5230  *
   5231  * Returns 0 on success -1 on field not found.
   5232  */
   5233 int pevent_get_field_val(struct trace_seq *s, struct event_format *event,
   5234 			 const char *name, struct pevent_record *record,
   5235 			 unsigned long long *val, int err)
   5236 {
   5237 	struct format_field *field;
   5238 
   5239 	if (!event)
   5240 		return -1;
   5241 
   5242 	field = pevent_find_field(event, name);
   5243 
   5244 	return get_field_val(s, field, name, record, val, err);
   5245 }
   5246 
   5247 /**
   5248  * pevent_get_common_field_val - find a common field and return its value
   5249  * @s: The seq to print to on error
   5250  * @event: the event that the field is for
   5251  * @name: The name of the field
   5252  * @record: The record with the field name.
   5253  * @val: place to store the value of the field.
   5254  * @err: print default error if failed.
   5255  *
   5256  * Returns 0 on success -1 on field not found.
   5257  */
   5258 int pevent_get_common_field_val(struct trace_seq *s, struct event_format *event,
   5259 				const char *name, struct pevent_record *record,
   5260 				unsigned long long *val, int err)
   5261 {
   5262 	struct format_field *field;
   5263 
   5264 	if (!event)
   5265 		return -1;
   5266 
   5267 	field = pevent_find_common_field(event, name);
   5268 
   5269 	return get_field_val(s, field, name, record, val, err);
   5270 }
   5271 
   5272 /**
   5273  * pevent_get_any_field_val - find a any field and return its value
   5274  * @s: The seq to print to on error
   5275  * @event: the event that the field is for
   5276  * @name: The name of the field
   5277  * @record: The record with the field name.
   5278  * @val: place to store the value of the field.
   5279  * @err: print default error if failed.
   5280  *
   5281  * Returns 0 on success -1 on field not found.
   5282  */
   5283 int pevent_get_any_field_val(struct trace_seq *s, struct event_format *event,
   5284 			     const char *name, struct pevent_record *record,
   5285 			     unsigned long long *val, int err)
   5286 {
   5287 	struct format_field *field;
   5288 
   5289 	if (!event)
   5290 		return -1;
   5291 
   5292 	field = pevent_find_any_field(event, name);
   5293 
   5294 	return get_field_val(s, field, name, record, val, err);
   5295 }
   5296 
   5297 /**
   5298  * pevent_print_num_field - print a field and a format
   5299  * @s: The seq to print to
   5300  * @fmt: The printf format to print the field with.
   5301  * @event: the event that the field is for
   5302  * @name: The name of the field
   5303  * @record: The record with the field name.
   5304  * @err: print default error if failed.
   5305  *
   5306  * Returns: 0 on success, -1 field not found, or 1 if buffer is full.
   5307  */
   5308 int pevent_print_num_field(struct trace_seq *s, const char *fmt,
   5309 			   struct event_format *event, const char *name,
   5310 			   struct pevent_record *record, int err)
   5311 {
   5312 	struct format_field *field = pevent_find_field(event, name);
   5313 	unsigned long long val;
   5314 
   5315 	if (!field)
   5316 		goto failed;
   5317 
   5318 	if (pevent_read_number_field(field, record->data, &val))
   5319 		goto failed;
   5320 
   5321 	return trace_seq_printf(s, fmt, val);
   5322 
   5323  failed:
   5324 	if (err)
   5325 		trace_seq_printf(s, "CAN'T FIND FIELD \"%s\"", name);
   5326 	return -1;
   5327 }
   5328 
   5329 static void free_func_handle(struct pevent_function_handler *func)
   5330 {
   5331 	struct pevent_func_params *params;
   5332 
   5333 	free(func->name);
   5334 
   5335 	while (func->params) {
   5336 		params = func->params;
   5337 		func->params = params->next;
   5338 		free(params);
   5339 	}
   5340 
   5341 	free(func);
   5342 }
   5343 
   5344 /**
   5345  * pevent_register_print_function - register a helper function
   5346  * @pevent: the handle to the pevent
   5347  * @func: the function to process the helper function
   5348  * @ret_type: the return type of the helper function
   5349  * @name: the name of the helper function
   5350  * @parameters: A list of enum pevent_func_arg_type
   5351  *
   5352  * Some events may have helper functions in the print format arguments.
   5353  * This allows a plugin to dynamically create a way to process one
   5354  * of these functions.
   5355  *
   5356  * The @parameters is a variable list of pevent_func_arg_type enums that
   5357  * must end with PEVENT_FUNC_ARG_VOID.
   5358  */
   5359 int pevent_register_print_function(struct pevent *pevent,
   5360 				   pevent_func_handler func,
   5361 				   enum pevent_func_arg_type ret_type,
   5362 				   char *name, ...)
   5363 {
   5364 	struct pevent_function_handler *func_handle;
   5365 	struct pevent_func_params **next_param;
   5366 	struct pevent_func_params *param;
   5367 	enum pevent_func_arg_type type;
   5368 	va_list ap;
   5369 	int ret;
   5370 
   5371 	func_handle = find_func_handler(pevent, name);
   5372 	if (func_handle) {
   5373 		/*
   5374 		 * This is most like caused by the users own
   5375 		 * plugins updating the function. This overrides the
   5376 		 * system defaults.
   5377 		 */
   5378 		pr_stat("override of function helper '%s'", name);
   5379 		remove_func_handler(pevent, name);
   5380 	}
   5381 
   5382 	func_handle = calloc(1, sizeof(*func_handle));
   5383 	if (!func_handle) {
   5384 		do_warning("Failed to allocate function handler");
   5385 		return PEVENT_ERRNO__MEM_ALLOC_FAILED;
   5386 	}
   5387 
   5388 	func_handle->ret_type = ret_type;
   5389 	func_handle->name = strdup(name);
   5390 	func_handle->func = func;
   5391 	if (!func_handle->name) {
   5392 		do_warning("Failed to allocate function name");
   5393 		free(func_handle);
   5394 		return PEVENT_ERRNO__MEM_ALLOC_FAILED;
   5395 	}
   5396 
   5397 	next_param = &(func_handle->params);
   5398 	va_start(ap, name);
   5399 	for (;;) {
   5400 		type = va_arg(ap, enum pevent_func_arg_type);
   5401 		if (type == PEVENT_FUNC_ARG_VOID)
   5402 			break;
   5403 
   5404 		if (type >= PEVENT_FUNC_ARG_MAX_TYPES) {
   5405 			do_warning("Invalid argument type %d", type);
   5406 			ret = PEVENT_ERRNO__INVALID_ARG_TYPE;
   5407 			goto out_free;
   5408 		}
   5409 
   5410 		param = malloc(sizeof(*param));
   5411 		if (!param) {
   5412 			do_warning("Failed to allocate function param");
   5413 			ret = PEVENT_ERRNO__MEM_ALLOC_FAILED;
   5414 			goto out_free;
   5415 		}
   5416 		param->type = type;
   5417 		param->next = NULL;
   5418 
   5419 		*next_param = param;
   5420 		next_param = &(param->next);
   5421 
   5422 		func_handle->nr_args++;
   5423 	}
   5424 	va_end(ap);
   5425 
   5426 	func_handle->next = pevent->func_handlers;
   5427 	pevent->func_handlers = func_handle;
   5428 
   5429 	return 0;
   5430  out_free:
   5431 	va_end(ap);
   5432 	free_func_handle(func_handle);
   5433 	return ret;
   5434 }
   5435 
   5436 /**
   5437  * pevent_register_event_handler - register a way to parse an event
   5438  * @pevent: the handle to the pevent
   5439  * @id: the id of the event to register
   5440  * @sys_name: the system name the event belongs to
   5441  * @event_name: the name of the event
   5442  * @func: the function to call to parse the event information
   5443  * @context: the data to be passed to @func
   5444  *
   5445  * This function allows a developer to override the parsing of
   5446  * a given event. If for some reason the default print format
   5447  * is not sufficient, this function will register a function
   5448  * for an event to be used to parse the data instead.
   5449  *
   5450  * If @id is >= 0, then it is used to find the event.
   5451  * else @sys_name and @event_name are used.
   5452  */
   5453 int pevent_register_event_handler(struct pevent *pevent, int id,
   5454 				  const char *sys_name, const char *event_name,
   5455 				  pevent_event_handler_func func, void *context)
   5456 {
   5457 	struct event_format *event;
   5458 	struct event_handler *handle;
   5459 
   5460 	if (id >= 0) {
   5461 		/* search by id */
   5462 		event = pevent_find_event(pevent, id);
   5463 		if (!event)
   5464 			goto not_found;
   5465 		if (event_name && (strcmp(event_name, event->name) != 0))
   5466 			goto not_found;
   5467 		if (sys_name && (strcmp(sys_name, event->system) != 0))
   5468 			goto not_found;
   5469 	} else {
   5470 		event = pevent_find_event_by_name(pevent, sys_name, event_name);
   5471 		if (!event)
   5472 			goto not_found;
   5473 	}
   5474 
   5475 	pr_stat("overriding event (%d) %s:%s with new print handler",
   5476 		event->id, event->system, event->name);
   5477 
   5478 	event->handler = func;
   5479 	event->context = context;
   5480 	return 0;
   5481 
   5482  not_found:
   5483 	/* Save for later use. */
   5484 	handle = calloc(1, sizeof(*handle));
   5485 	if (!handle) {
   5486 		do_warning("Failed to allocate event handler");
   5487 		return PEVENT_ERRNO__MEM_ALLOC_FAILED;
   5488 	}
   5489 
   5490 	handle->id = id;
   5491 	if (event_name)
   5492 		handle->event_name = strdup(event_name);
   5493 	if (sys_name)
   5494 		handle->sys_name = strdup(sys_name);
   5495 
   5496 	if ((event_name && !handle->event_name) ||
   5497 	    (sys_name && !handle->sys_name)) {
   5498 		do_warning("Failed to allocate event/sys name");
   5499 		free((void *)handle->event_name);
   5500 		free((void *)handle->sys_name);
   5501 		free(handle);
   5502 		return PEVENT_ERRNO__MEM_ALLOC_FAILED;
   5503 	}
   5504 
   5505 	handle->func = func;
   5506 	handle->next = pevent->handlers;
   5507 	pevent->handlers = handle;
   5508 	handle->context = context;
   5509 
   5510 	return -1;
   5511 }
   5512 
   5513 /**
   5514  * pevent_alloc - create a pevent handle
   5515  */
   5516 struct pevent *pevent_alloc(void)
   5517 {
   5518 	struct pevent *pevent = calloc(1, sizeof(*pevent));
   5519 
   5520 	if (pevent)
   5521 		pevent->ref_count = 1;
   5522 
   5523 	return pevent;
   5524 }
   5525 
   5526 void pevent_ref(struct pevent *pevent)
   5527 {
   5528 	pevent->ref_count++;
   5529 }
   5530 
   5531 static void free_format_fields(struct format_field *field)
   5532 {
   5533 	struct format_field *next;
   5534 
   5535 	while (field) {
   5536 		next = field->next;
   5537 		free(field->type);
   5538 		free(field->name);
   5539 		free(field);
   5540 		field = next;
   5541 	}
   5542 }
   5543 
   5544 static void free_formats(struct format *format)
   5545 {
   5546 	free_format_fields(format->common_fields);
   5547 	free_format_fields(format->fields);
   5548 }
   5549 
   5550 void pevent_free_format(struct event_format *event)
   5551 {
   5552 	free(event->name);
   5553 	free(event->system);
   5554 
   5555 	free_formats(&event->format);
   5556 
   5557 	free(event->print_fmt.format);
   5558 	free_args(event->print_fmt.args);
   5559 
   5560 	free(event);
   5561 }
   5562 
   5563 /**
   5564  * pevent_free - free a pevent handle
   5565  * @pevent: the pevent handle to free
   5566  */
   5567 void pevent_free(struct pevent *pevent)
   5568 {
   5569 	struct cmdline_list *cmdlist, *cmdnext;
   5570 	struct func_list *funclist, *funcnext;
   5571 	struct printk_list *printklist, *printknext;
   5572 	struct pevent_function_handler *func_handler;
   5573 	struct event_handler *handle;
   5574 	int i;
   5575 
   5576 	if (!pevent)
   5577 		return;
   5578 
   5579 	cmdlist = pevent->cmdlist;
   5580 	funclist = pevent->funclist;
   5581 	printklist = pevent->printklist;
   5582 
   5583 	pevent->ref_count--;
   5584 	if (pevent->ref_count)
   5585 		return;
   5586 
   5587 	if (pevent->cmdlines) {
   5588 		for (i = 0; i < pevent->cmdline_count; i++)
   5589 			free(pevent->cmdlines[i].comm);
   5590 		free(pevent->cmdlines);
   5591 	}
   5592 
   5593 	while (cmdlist) {
   5594 		cmdnext = cmdlist->next;
   5595 		free(cmdlist->comm);
   5596 		free(cmdlist);
   5597 		cmdlist = cmdnext;
   5598 	}
   5599 
   5600 	if (pevent->func_map) {
   5601 		for (i = 0; i < (int)pevent->func_count; i++) {
   5602 			free(pevent->func_map[i].func);
   5603 			free(pevent->func_map[i].mod);
   5604 		}
   5605 		free(pevent->func_map);
   5606 	}
   5607 
   5608 	while (funclist) {
   5609 		funcnext = funclist->next;
   5610 		free(funclist->func);
   5611 		free(funclist->mod);
   5612 		free(funclist);
   5613 		funclist = funcnext;
   5614 	}
   5615 
   5616 	while (pevent->func_handlers) {
   5617 		func_handler = pevent->func_handlers;
   5618 		pevent->func_handlers = func_handler->next;
   5619 		free_func_handle(func_handler);
   5620 	}
   5621 
   5622 	if (pevent->printk_map) {
   5623 		for (i = 0; i < (int)pevent->printk_count; i++)
   5624 			free(pevent->printk_map[i].printk);
   5625 		free(pevent->printk_map);
   5626 	}
   5627 
   5628 	while (printklist) {
   5629 		printknext = printklist->next;
   5630 		free(printklist->printk);
   5631 		free(printklist);
   5632 		printklist = printknext;
   5633 	}
   5634 
   5635 	for (i = 0; i < pevent->nr_events; i++)
   5636 		pevent_free_format(pevent->events[i]);
   5637 
   5638 	while (pevent->handlers) {
   5639 		handle = pevent->handlers;
   5640 		pevent->handlers = handle->next;
   5641 		free_handler(handle);
   5642 	}
   5643 
   5644 	free(pevent->events);
   5645 	free(pevent->sort_events);
   5646 
   5647 	free(pevent);
   5648 }
   5649 
   5650 void pevent_unref(struct pevent *pevent)
   5651 {
   5652 	pevent_free(pevent);
   5653 }
   5654