Documentation/libtracefs-sql.txt - platform/external/libtracefs - Git at Google

 libtracefs(3)
 =============

 NAME
 ----
 tracefs_sql - Create a synthetic event via an SQL statement

 SYNOPSIS
 --------
 [verse]
 --
 *#include <tracefs.h>*

 struct tracefs_synth pass:[*]*tracefs_sql*(struct tep_handle pass:[*]_tep_, const char pass:[*]_name_,
 					const char pass:[*]_sql_buffer_, char pass:[**]_err_);
 --

 DESCRIPTION
 -----------
 Synthetic events are dynamically created events that attach two existing events
 together via one or more matching fields between the two events. It can be used
 to find the latency between the events, or to simply pass fields of the first event
 on to the second event to display as one event.

 The Linux kernel interface to create synthetic events is complex, and there needs
 to be a better way to create synthetic events that is easy and can be understood
 via existing technology.

 If you think of each event as a table, where the fields are the column of the table
 and each instance of the event as a row, you can understand how SQL can be used
 to attach two events together and form another event (table). Utilizing the
 SQL *SELECT* *FROM* *JOIN* *ON* [ *WHERE* ] syntax, a synthetic event can easily
 be created from two different events.

 For simple SQL queries to make a histogram instead of a synthetic event, see
 HISTOGRAMS below.

 *tracefs_sql*() takes in a _tep_ handler (See _tep_local_events_(3)) that is used to
 verify the events within the _sql_buffer_ expression. The _name_ is the name of the
 synthetic event to create. If _err_ points to an address of a string, it will be filled
 with a detailed message on any type of parsing error, including fields that do not belong
 to an event, or if the events or fields are not properly compared.

 The example program below is a fully functional parser where it will create a synthetic
 event from a SQL syntax passed in via the command line or a file.

 The SQL format is as follows:

 *SELECT* <fields> *FROM* <start-event> *JOIN* <end-event> *ON* <matching-fields> *WHERE* <filter>

 Note, although the examples show the SQL commands in uppercase, they are not required to
 be so. That is, you can use "SELECT" or "select" or "sElEct".

 For example:
 [source,c]
 --
 SELECT syscalls.sys_enter_read.fd, syscalls.sys_exit_read.ret FROM syscalls.sys_enter_read
    JOIN syscalls.sys_exit_read
    ON syscalls.sys_enter_read.common_pid = syscalls.sys_exit_write.common_pid
 --

 Will create a synthetic event that with the fields:

   u64 fd; s64 ret;

 Because the function takes a _tep_ handle, and usually all event names are unique, you can
 leave off the system (group) name of the event, and *tracefs_sql*() will discover the
 system for you.

 That is, the above statement would work with:

 [source,c]
 --
 SELECT sys_enter_read.fd, sys_exit_read.ret FROM sys_enter_read JOIN sys_exit_read
    ON sys_enter_read.common_pid = sys_exit_write.common_pid
 --

 The *AS* keyword can be used to name the fields as well as to give an alias to the
 events, such that the above can be simplified even more as:

 [source,c]
 --
 SELECT start.fd, end.ret FROM sys_enter_read AS start JOIN sys_exit_read AS end ON start.common_pid = end.common_pid
 --

 The above aliases _sys_enter_read_ as *start* and _sys_exit_read_ as *end* and uses
 those aliases to reference the event throughout the statement.

 Using the *AS* keyword in the selection portion of the SQL statement will define what
 those fields will be called in the synthetic event.

 [source,c]
 --
 SELECT start.fd AS filed, end.ret AS return FROM sys_enter_read AS start JOIN sys_exit_read AS end
    ON start.common_pid = end.common_pid
 --

 The above labels the _fd_ of _start_ as *filed* and the _ret_ of _end_ as *return* where
 the synthetic event that is created will now have the fields:

   u64 filed; s64 return;

 The fields can also be calculated with results passed to the synthetic event:

 [source,c]
 --
 select start.truesize, end.len, (start.truesize - end.len) as diff from napi_gro_receive_entry as start
    JOIN netif_receive_skb as end ON start.skbaddr = end.skbaddr
 --

 Which would show the *truesize* of the _napi_gro_receive_entry_ event, the actual
 _len_ of the content, shown by the _netif_receive_skb_, and the delta between
 the two and expressed by the field *diff*.

 The code also supports recording the timestamps at either event, and performing calculations
 on them. For wakeup latency, you have:

 [source,c]
 --
 select start.pid, (end.TIMESTAMP_USECS - start.TIMESTAMP_USECS) as lat from sched_waking as start
    JOIN sched_switch as end ON start.pid = end.next_pid
 --

 The above will create a synthetic event that records the _pid_ of the task being woken up,
 and the time difference between the _sched_waking_ event and the _sched_switch_ event.
 The *TIMESTAMP_USECS* will truncate the time down to microseconds as the timestamp usually
 recorded in the tracing buffer has nanosecond resolution. If you do not want that
 truncation, use *TIMESTAMP* instead of *TIMESTAMP_USECS*.

 Finally, the *WHERE* clause can be added, that will let you add filters on either or both events.

 [source,c]
 --
 select start.pid, (end.TIMESTAMP_USECS - start.TIMESTAMP_USECS) as lat from sched_waking as start
    JOIN sched_switch as end ON start.pid = end.next_pid
    WHERE start.prio < 100 && (!(end.prev_pid < 1 || end.prev_prio > 100) || end.prev_pid == 0)
 --

 *NOTE*

 Although both events can be used together in the *WHERE* clause, they must not be mixed outside
 the top most "&&" statements. You can not OR (||) the events together, where a filter of one
 event is OR'd to a filter of the other event. This does not make sense, as the synthetic event
 requires both events to take place to be recorded. If one is filtered out, then the synthetic
 event does not execute.

 [source,c]
 --
 select start.pid, (end.TIMESTAMP_USECS - start.TIMESTAMP_USECS) as lat from sched_waking as start
    JOIN sched_switch as end ON start.pid = end.next_pid
    WHERE start.prio < 100 && end.prev_prio < 100
 --

 The above is valid.

 Where as the below is not.

 [source,c]
 --
 select start.pid, (end.TIMESTAMP_USECS - start.TIMESTAMP_USECS) as lat from sched_waking as start
    JOIN sched_switch as end ON start.pid = end.next_pid
    WHERE start.prio < 100 || end.prev_prio < 100
 --


 KEYWORDS AS EVENT FIELDS
 ------------------------

 In some cases, an event may have a keyword. For example, regcache_drop_region has "from"
 as a field and the following will not work

 [source,c]
 --
   select from from regcache_drop_region
 --

 In such cases, add a backslash to the conflicting field, and this will tell the parser
 that the "from" is a field and not a keyword:

 [source,c]
 --
   select \from from regcache_drop_region
 --

 HISTOGRAMS
 ----------

 Simple SQL statements without the *JOIN* *ON* may also be used, which will create a histogram
 instead. When doing this, the struct tracefs_hist descriptor can be retrieved from the
 returned synthetic event descriptor via the *tracefs_synth_get_start_hist*(3).

 In order to utilize the histogram types (see xxx) the CAST command of SQL can be used.

 That is:

 [source,c]
 --
   select CAST(common_pid AS comm), CAST(id AS syscall) FROM sys_enter
 --

 Which produces:

 [source,c]
 --
  # echo 'hist:keys=common_pid.execname,id.syscall' > events/raw_syscalls/sys_enter/trigger

  # cat events/raw_syscalls/sys_enter/hist

 { common_pid: bash            [     18248], id: sys_setpgid                   [109] } hitcount:          1
 { common_pid: sendmail        [      1812], id: sys_read                      [  0] } hitcount:          1
 { common_pid: bash            [     18247], id: sys_getpid                    [ 39] } hitcount:          1
 { common_pid: bash            [     18247], id: sys_dup2                      [ 33] } hitcount:          1
 { common_pid: gmain           [     13684], id: sys_inotify_add_watch         [254] } hitcount:          1
 { common_pid: cat             [     18247], id: sys_access                    [ 21] } hitcount:          1
 { common_pid: bash            [     18248], id: sys_getpid                    [ 39] } hitcount:          1
 { common_pid: cat             [     18247], id: sys_fadvise64                 [221] } hitcount:          1
 { common_pid: sendmail        [      1812], id: sys_openat                    [257] } hitcount:          1
 { common_pid: less            [     18248], id: sys_munmap                    [ 11] } hitcount:          1
 { common_pid: sendmail        [      1812], id: sys_close                     [  3] } hitcount:          1
 { common_pid: gmain           [      1534], id: sys_poll                      [  7] } hitcount:          1
 { common_pid: bash            [     18247], id: sys_execve                    [ 59] } hitcount:          1
 --

 Note, string fields may not be cast.

 The possible types to cast to are:

 *HEX* - convert the value to use hex and not decimal

 *SYM* - convert a pointer to symbolic (kallsyms values)

 *SYM-OFFSET* - convert a pointer to symbolic and include the offset.

 *SYSCALL* - convert the number to the mapped system call name

 *EXECNAME* or *COMM* - can only be used with the common_pid field. Will show the task
 name of the process.

 *LOG* or *LOG2* - bucket the key values in a log 2 values (1, 2, 3-4, 5-8, 9-16, 17-32, ...)

 The above fields are not case sensitive, and "LOG2" works as good as "log".

 A special CAST to _COUNTER_ or __COUNTER__ will make the field a value and not
 a key. For example:

 [source,c]
 --
   SELECT common_pid, CAST(bytes_req AS _COUNTER_) FROM kmalloc
 --

 Which will create

 [source,c]
 --
   echo 'hist:keys=common_pid:vals=bytes_req' > events/kmem/kmalloc/trigger

   cat events/kmem/kmalloc/hist

 { common_pid:       1812 } hitcount:          1  bytes_req:         32
 { common_pid:       9111 } hitcount:          2  bytes_req:        272
 { common_pid:       1768 } hitcount:          3  bytes_req:       1112
 { common_pid:          0 } hitcount:          4  bytes_req:        512
 { common_pid:      18297 } hitcount:         11  bytes_req:       2004
 --

 RETURN VALUE
 ------------
 Returns 0 on success and -1 on failure. On failure, if _err_ is defined, it will be
 allocated to hold a detailed description of what went wrong if it the error was caused
 by a parsing error, or that an event, field does not exist or is not compatible with
 what it was combined with.

 CREATE A TOOL
 -------------

 The below example is a functional program that can be used to parse SQL commands into
 synthetic events.

 [source, c]
 --
    man tracefs_sql | sed -ne '/^EXAMPLE/,/FILES/ { /EXAMPLE/d ; /FILES/d ; p}' > sqlhist.c
    gcc -o sqlhist sqlhist.c `pkg-config --cflags --libs libtracefs`
 --

 Then you can run the above examples:

 [source, c]
 --
   sudo ./sqlhist 'select start.pid, (end.TIMESTAMP_USECS - start.TIMESTAMP_USECS) as lat from sched_waking as start
                   JOIN sched_switch as end ON start.pid = end.next_pid
                   WHERE start.prio < 100 || end.prev_prio < 100'
 --
 EXAMPLE
 -------
 [source,c]
 --
 #include <stdio.h>
 #include <stdlib.h>
 #include <stdarg.h>
 #include <string.h>
 #include <errno.h>
 #include <unistd.h>
 #include <tracefs.h>

 static void usage(char **argv)
 {
 	fprintf(stderr, "usage: %s [-ed][-n name][-s][-S fields][-m var][-c var][-T][-t dir][-f file | sql-command-line]\n"
 		"  -n name - name of synthetic event 'Anonymous' if left off\n"
 		"  -t dir - use dir instead of /sys/kernel/tracing\n"
 		"  -e - execute the commands to create the synthetic event\n"
 		"  -m - trigger the action when var is a new max.\n"
 		"  -c - trigger the action when var changes.\n"
 		"  -s - used with -m or -c to do a snapshot of the tracing buffer\n"
 		"  -S - used with -m or -c to save fields of the end event (comma deliminated)\n"
 		"  -T - used with -m or -c to do both a snapshot and a trace\n"
 		"  -f file - read sql lines from file otherwise from the command line\n"
 		"            if file is '-' then read from standard input.\n",
 		argv[0]);
 	exit(-1);
 }

 enum action {
 	ACTION_DEFAULT		= 0,
 	ACTION_SNAPSHOT		= (1 << 0),
 	ACTION_TRACE		= (1 << 1),
 	ACTION_SAVE		= (1 << 2),
 	ACTION_MAX		= (1 << 3),
 	ACTION_CHANGE		= (1 << 4),
 };

 #define ACTIONS ((ACTION_MAX - 1))

 static int do_sql(const char *instance_name,
 		  const char *buffer, const char *name, const char *var,
 		  const char *trace_dir, bool execute, int action,
 		  char **save_fields)
 {
 	struct tracefs_synth *synth;
 	struct tep_handle *tep;
 	struct trace_seq seq;
 	enum tracefs_synth_handler handler;
 	char *err;
 	int ret;

 	if ((action & ACTIONS) && !var) {
 		fprintf(stderr, "Error: -s, -S and -T not supported without -m or -c");
 		exit(-1);
 	}

 	if (!name)
 		name = "Anonymous";

 	trace_seq_init(&seq);
 	tep = tracefs_local_events(trace_dir);
 	if (!tep) {
 		if (!trace_dir)
 			trace_dir = "tracefs directory";
 		perror(trace_dir);
 		exit(-1);
 	}

 	synth = tracefs_sql(tep, name, buffer, &err);
 	if (!synth) {
 		perror("Failed creating synthetic event!");
 		if (err)
 			fprintf(stderr, "%s", err);
 		free(err);
 		exit(-1);
 	}

 	if (tracefs_synth_complete(synth)) {
 		if (var) {
 			if (action & ACTION_MAX)
 				handler = TRACEFS_SYNTH_HANDLE_MAX;
 			else
 				handler = TRACEFS_SYNTH_HANDLE_CHANGE;

 			if (action & ACTION_SAVE) {
 				ret = tracefs_synth_save(synth, handler, var, save_fields);
 				if (ret < 0) {
 					err = "adding save";
 					goto failed_action;
 				}
 			}
 			if (action & ACTION_TRACE) {
 				/*
 				 * By doing the trace before snapshot, it will be included
 				 * in the snapshot.
 				 */
 				ret = tracefs_synth_trace(synth, handler, var);
 				if (ret < 0) {
 					err = "adding trace";
 					goto failed_action;
 				}
 			}
 			if (action & ACTION_SNAPSHOT) {
 				ret = tracefs_synth_snapshot(synth, handler, var);
 				if (ret < 0) {
 					err = "adding snapshot";
  failed_action:
 					perror(err);
 					if (errno == ENODEV)
 						fprintf(stderr, "ERROR: '%s' is not a variable\n",
 							var);
 					exit(-1);
 				}
 			}
 		}
 		tracefs_synth_echo_cmd(&seq, synth);
 		if (execute) {
 			ret = tracefs_synth_create(synth);
 			if (ret < 0) {
 				fprintf(stderr, "%s\n", tracefs_error_last(NULL));
 				exit(-1);
 			}
 		}
 	} else {
 		struct tracefs_instance *instance = NULL;
 		struct tracefs_hist *hist;

 		hist = tracefs_synth_get_start_hist(synth);
 		if (!hist) {
 			perror("get_start_hist");
 			exit(-1);
 		}
 		if (instance_name) {
 			if (execute)
 				instance = tracefs_instance_create(instance_name);
 			else
 				instance = tracefs_instance_alloc(trace_dir,
 								  instance_name);
 			if (!instance) {
 				perror("Failed to create instance");
 				exit(-1);
 			}
 		}
 		tracefs_hist_echo_cmd(&seq, instance, hist, 0);
 		if (execute) {
 			ret = tracefs_hist_start(instance, hist);
 			if (ret < 0) {
 				fprintf(stderr, "%s\n", tracefs_error_last(instance));
 				exit(-1);
 			}
 		}
 	}

 	tracefs_synth_free(synth);

 	trace_seq_do_printf(&seq);
 	trace_seq_destroy(&seq);
 	return 0;
 }

 int main (int argc, char **argv)
 {
 	char *trace_dir = NULL;
 	char *buffer = NULL;
 	char buf[BUFSIZ];
 	int buffer_size = 0;
 	const char *file = NULL;
 	const char *instance = NULL;
 	bool execute = false;
 	char **save_fields = NULL;
 	const char *name;
 	const char *var;
 	int action = 0;
 	char *tok;
 	FILE *fp;
 	size_t r;
 	int c;
 	int i;

 	for (;;) {
 		c = getopt(argc, argv, "ht:f:en:m:c:sS:TB:");
 		if (c == -1)
 			break;

 		switch(c) {
 		case 'h':
 			usage(argv);
 		case 't':
 			trace_dir = optarg;
 			break;
 		case 'f':
 			file = optarg;
 			break;
 		case 'e':
 			execute = true;
 			break;
 		case 'm':
 			action |= ACTION_MAX;
 			var = optarg;
 			break;
 		case 'c':
 			action |= ACTION_CHANGE;
 			var = optarg;
 			break;
 		case 's':
 			action |= ACTION_SNAPSHOT;
 			break;
 		case 'S':
 			action |= ACTION_SAVE;
 			tok = strtok(optarg, ",");
 			while (tok) {
 				save_fields = tracefs_list_add(save_fields, tok);
 				tok = strtok(NULL, ",");
 			}
 			if (!save_fields) {
 				perror(optarg);
 				exit(-1);
 			}
 			break;
 		case 'T':
 			action |= ACTION_TRACE | ACTION_SNAPSHOT;
 			break;
 		case 'B':
 			instance = optarg;
 			break;
 		case 'n':
 			name = optarg;
 			break;
 		}
 	}

 	if ((action & (ACTION_MAX|ACTION_CHANGE)) == (ACTION_MAX|ACTION_CHANGE)) {
 		fprintf(stderr, "Can not use both -m and -c together\n");
 		exit(-1);
 	}
 	if (file) {
 		if (!strcmp(file, "-"))
 			fp = stdin;
 		else
 			fp = fopen(file, "r");
 		if (!fp) {
 			perror(file);
 			exit(-1);
 		}
 		while ((r = fread(buf, 1, BUFSIZ, fp)) > 0) {
 			buffer = realloc(buffer, buffer_size + r + 1);
 			strncpy(buffer + buffer_size, buf, r);
 			buffer_size += r;
 		}
 		fclose(fp);
 		if (buffer_size)
 			buffer[buffer_size] = '\0';
 	} else if (argc == optind) {
 		usage(argv);
 	} else {
 		for (i = optind; i < argc; i++) {
 			r = strlen(argv[i]);
 			buffer = realloc(buffer, buffer_size + r + 2);
 			if (i != optind)
 				buffer[buffer_size++] = ' ';
 			strcpy(buffer + buffer_size, argv[i]);
 			buffer_size += r;
 		}
 	}

 	do_sql(instance, buffer, name, var, trace_dir, execute, action, save_fields);
 	free(buffer);

 	return 0;
 }
 --

 FILES
 -----
 [verse]
 --
 *tracefs.h*
 	Header file to include in order to have access to the library APIs.
 *-ltracefs*
 	Linker switch to add when building a program that uses the library.
 --

 SEE ALSO
 --------
 *sqlhist*(1),
 *libtracefs*(3),
 *libtraceevent*(3),
 *trace-cmd*(1),
 *tracefs_synth_init*(3),
 *tracefs_synth_add_match_field*(3),
 *tracefs_synth_add_compare_field*(3),
 *tracefs_synth_add_start_field*(3),
 *tracefs_synth_add_end_field*(3),
 *tracefs_synth_append_start_filter*(3),
 *tracefs_synth_append_end_filter*(3),
 *tracefs_synth_create*(3),
 *tracefs_synth_destroy*(3),
 *tracefs_synth_free*(3),
 *tracefs_synth_echo_cmd*(3),
 *tracefs_hist_alloc*(3),
 *tracefs_hist_alloc_2d*(3),
 *tracefs_hist_alloc_nd*(3),
 *tracefs_hist_free*(3),
 *tracefs_hist_add_key*(3),
 *tracefs_hist_add_value*(3),
 *tracefs_hist_add_name*(3),
 *tracefs_hist_start*(3),
 *tracefs_hist_destory*(3),
 *tracefs_hist_add_sort_key*(3),
 *tracefs_hist_sort_key_direction*(3)

 AUTHOR
 ------
 [verse]
 --
 *Steven Rostedt* <rostedt@goodmis.org>
 *Tzvetomir Stoyanov* <tz.stoyanov@gmail.com>
 *sameeruddin shaik* <sameeruddin.shaik8@gmail.com>
 --
 REPORTING BUGS
 --------------
 Report bugs to  <linux-trace-devel@vger.kernel.org>

 LICENSE
 -------
 libtracefs is Free Software licensed under the GNU LGPL 2.1

 RESOURCES
 ---------
 https://git.kernel.org/pub/scm/libs/libtrace/libtracefs.git/

 COPYING
 -------
 Copyright \(C) 2020 VMware, Inc. Free use of this software is granted under
 the terms of the GNU Public License (GPL).
	libtracefs(3)
	=============

	NAME
	----
	tracefs_sql - Create a synthetic event via an SQL statement

	SYNOPSIS
	--------
	[verse]
	--
	#include <tracefs.h>

	struct tracefs_synth pass:[]tracefs_sql(struct tep_handle pass:[]_tep_, const char pass:[*]_name_,
	const char pass:[]_sql_buffer_, char pass:[*]_err_);
	--

	DESCRIPTION
	-----------
	Synthetic events are dynamically created events that attach two existing events
	together via one or more matching fields between the two events. It can be used
	to find the latency between the events, or to simply pass fields of the first event
	on to the second event to display as one event.

	The Linux kernel interface to create synthetic events is complex, and there needs
	to be a better way to create synthetic events that is easy and can be understood
	via existing technology.

	If you think of each event as a table, where the fields are the column of the table
	and each instance of the event as a row, you can understand how SQL can be used
	to attach two events together and form another event (table). Utilizing the
	SQL SELECT FROM JOIN ON [ WHERE ] syntax, a synthetic event can easily
	be created from two different events.

	For simple SQL queries to make a histogram instead of a synthetic event, see
	HISTOGRAMS below.

	tracefs_sql() takes in a _tep_ handler (See _tep_local_events_(3)) that is used to
	verify the events within the _sql_buffer_ expression. The _name_ is the name of the
	synthetic event to create. If _err_ points to an address of a string, it will be filled
	with a detailed message on any type of parsing error, including fields that do not belong
	to an event, or if the events or fields are not properly compared.

	The example program below is a fully functional parser where it will create a synthetic
	event from a SQL syntax passed in via the command line or a file.

	The SQL format is as follows:

	SELECT <fields> FROM <start-event> JOIN <end-event> ON <matching-fields> WHERE <filter>

	Note, although the examples show the SQL commands in uppercase, they are not required to
	be so. That is, you can use "SELECT" or "select" or "sElEct".

	For example:
	[source,c]
	--
	SELECT syscalls.sys_enter_read.fd, syscalls.sys_exit_read.ret FROM syscalls.sys_enter_read
	JOIN syscalls.sys_exit_read
	ON syscalls.sys_enter_read.common_pid = syscalls.sys_exit_write.common_pid
	--

	Will create a synthetic event that with the fields:

	u64 fd; s64 ret;

	Because the function takes a _tep_ handle, and usually all event names are unique, you can
	leave off the system (group) name of the event, and tracefs_sql() will discover the
	system for you.

	That is, the above statement would work with:

	[source,c]
	--
	SELECT sys_enter_read.fd, sys_exit_read.ret FROM sys_enter_read JOIN sys_exit_read
	ON sys_enter_read.common_pid = sys_exit_write.common_pid
	--

	The AS keyword can be used to name the fields as well as to give an alias to the
	events, such that the above can be simplified even more as:

	[source,c]
	--
	SELECT start.fd, end.ret FROM sys_enter_read AS start JOIN sys_exit_read AS end ON start.common_pid = end.common_pid
	--

	The above aliases _sys_enter_read_ as start and _sys_exit_read_ as end and uses
	those aliases to reference the event throughout the statement.

	Using the AS keyword in the selection portion of the SQL statement will define what
	those fields will be called in the synthetic event.

	[source,c]
	--
	SELECT start.fd AS filed, end.ret AS return FROM sys_enter_read AS start JOIN sys_exit_read AS end
	ON start.common_pid = end.common_pid
	--

	The above labels the _fd_ of _start_ as filed and the _ret_ of _end_ as return where
	the synthetic event that is created will now have the fields:

	u64 filed; s64 return;

	The fields can also be calculated with results passed to the synthetic event:

	[source,c]
	--
	select start.truesize, end.len, (start.truesize - end.len) as diff from napi_gro_receive_entry as start
	JOIN netif_receive_skb as end ON start.skbaddr = end.skbaddr
	--

	Which would show the truesize of the _napi_gro_receive_entry_ event, the actual
	_len_ of the content, shown by the _netif_receive_skb_, and the delta between
	the two and expressed by the field diff.

	The code also supports recording the timestamps at either event, and performing calculations
	on them. For wakeup latency, you have:

	[source,c]
	--
	select start.pid, (end.TIMESTAMP_USECS - start.TIMESTAMP_USECS) as lat from sched_waking as start
	JOIN sched_switch as end ON start.pid = end.next_pid
	--

	The above will create a synthetic event that records the _pid_ of the task being woken up,
	and the time difference between the _sched_waking_ event and the _sched_switch_ event.
	The TIMESTAMP_USECS will truncate the time down to microseconds as the timestamp usually
	recorded in the tracing buffer has nanosecond resolution. If you do not want that
	truncation, use TIMESTAMP instead of TIMESTAMP_USECS.

	Finally, the WHERE clause can be added, that will let you add filters on either or both events.

	[source,c]
	--
	select start.pid, (end.TIMESTAMP_USECS - start.TIMESTAMP_USECS) as lat from sched_waking as start
	JOIN sched_switch as end ON start.pid = end.next_pid
	WHERE start.prio < 100 && (!(end.prev_pid < 1 \|\| end.prev_prio > 100) \|\| end.prev_pid == 0)
	--

	NOTE

	Although both events can be used together in the WHERE clause, they must not be mixed outside
	the top most "&&" statements. You can not OR (\|\|) the events together, where a filter of one
	event is OR'd to a filter of the other event. This does not make sense, as the synthetic event
	requires both events to take place to be recorded. If one is filtered out, then the synthetic
	event does not execute.

	[source,c]
	--
	select start.pid, (end.TIMESTAMP_USECS - start.TIMESTAMP_USECS) as lat from sched_waking as start
	JOIN sched_switch as end ON start.pid = end.next_pid
	WHERE start.prio < 100 && end.prev_prio < 100
	--

	The above is valid.

	Where as the below is not.

	[source,c]
	--
	select start.pid, (end.TIMESTAMP_USECS - start.TIMESTAMP_USECS) as lat from sched_waking as start
	JOIN sched_switch as end ON start.pid = end.next_pid
	WHERE start.prio < 100 \|\| end.prev_prio < 100
	--


	KEYWORDS AS EVENT FIELDS
	------------------------

	In some cases, an event may have a keyword. For example, regcache_drop_region has "from"
	as a field and the following will not work

	[source,c]
	--
	select from from regcache_drop_region
	--

	In such cases, add a backslash to the conflicting field, and this will tell the parser
	that the "from" is a field and not a keyword:

	[source,c]
	--
	select \from from regcache_drop_region
	--

	HISTOGRAMS
	----------

	Simple SQL statements without the JOIN ON may also be used, which will create a histogram
	instead. When doing this, the struct tracefs_hist descriptor can be retrieved from the
	returned synthetic event descriptor via the tracefs_synth_get_start_hist(3).

	In order to utilize the histogram types (see xxx) the CAST command of SQL can be used.

	That is:

	[source,c]
	--
	select CAST(common_pid AS comm), CAST(id AS syscall) FROM sys_enter
	--

	Which produces:

	[source,c]
	--
	# echo 'hist:keys=common_pid.execname,id.syscall' > events/raw_syscalls/sys_enter/trigger

	# cat events/raw_syscalls/sys_enter/hist

	{ common_pid: bash [ 18248], id: sys_setpgid [109] } hitcount: 1
	{ common_pid: sendmail [ 1812], id: sys_read [ 0] } hitcount: 1
	{ common_pid: bash [ 18247], id: sys_getpid [ 39] } hitcount: 1
	{ common_pid: bash [ 18247], id: sys_dup2 [ 33] } hitcount: 1
	{ common_pid: gmain [ 13684], id: sys_inotify_add_watch [254] } hitcount: 1
	{ common_pid: cat [ 18247], id: sys_access [ 21] } hitcount: 1
	{ common_pid: bash [ 18248], id: sys_getpid [ 39] } hitcount: 1
	{ common_pid: cat [ 18247], id: sys_fadvise64 [221] } hitcount: 1
	{ common_pid: sendmail [ 1812], id: sys_openat [257] } hitcount: 1
	{ common_pid: less [ 18248], id: sys_munmap [ 11] } hitcount: 1
	{ common_pid: sendmail [ 1812], id: sys_close [ 3] } hitcount: 1
	{ common_pid: gmain [ 1534], id: sys_poll [ 7] } hitcount: 1
	{ common_pid: bash [ 18247], id: sys_execve [ 59] } hitcount: 1
	--

	Note, string fields may not be cast.

	The possible types to cast to are:

	HEX - convert the value to use hex and not decimal

	SYM - convert a pointer to symbolic (kallsyms values)

	SYM-OFFSET - convert a pointer to symbolic and include the offset.

	SYSCALL - convert the number to the mapped system call name

	EXECNAME or COMM - can only be used with the common_pid field. Will show the task
	name of the process.

	LOG or LOG2 - bucket the key values in a log 2 values (1, 2, 3-4, 5-8, 9-16, 17-32, ...)

	The above fields are not case sensitive, and "LOG2" works as good as "log".

	A special CAST to _COUNTER_ or __COUNTER__ will make the field a value and not
	a key. For example:

	[source,c]
	--
	SELECT common_pid, CAST(bytes_req AS _COUNTER_) FROM kmalloc
	--

	Which will create

	[source,c]
	--
	echo 'hist:keys=common_pid:vals=bytes_req' > events/kmem/kmalloc/trigger

	cat events/kmem/kmalloc/hist

	{ common_pid: 1812 } hitcount: 1 bytes_req: 32
	{ common_pid: 9111 } hitcount: 2 bytes_req: 272
	{ common_pid: 1768 } hitcount: 3 bytes_req: 1112
	{ common_pid: 0 } hitcount: 4 bytes_req: 512
	{ common_pid: 18297 } hitcount: 11 bytes_req: 2004
	--

	RETURN VALUE
	------------
	Returns 0 on success and -1 on failure. On failure, if _err_ is defined, it will be
	allocated to hold a detailed description of what went wrong if it the error was caused
	by a parsing error, or that an event, field does not exist or is not compatible with
	what it was combined with.

	CREATE A TOOL
	-------------

	The below example is a functional program that can be used to parse SQL commands into
	synthetic events.

	[source, c]
	--
	man tracefs_sql \| sed -ne '/^EXAMPLE/,/FILES/ { /EXAMPLE/d ; /FILES/d ; p}' > sqlhist.c
	gcc -o sqlhist sqlhist.c `pkg-config --cflags --libs libtracefs`
	--

	Then you can run the above examples:

	[source, c]
	--
	sudo ./sqlhist 'select start.pid, (end.TIMESTAMP_USECS - start.TIMESTAMP_USECS) as lat from sched_waking as start
	JOIN sched_switch as end ON start.pid = end.next_pid
	WHERE start.prio < 100 \|\| end.prev_prio < 100'
	--
	EXAMPLE
	-------
	[source,c]
	--
	#include <stdio.h>
	#include <stdlib.h>
	#include <stdarg.h>
	#include <string.h>
	#include <errno.h>
	#include <unistd.h>
	#include <tracefs.h>

	static void usage(char **argv)
	{
	fprintf(stderr, "usage: %s [-ed][-n name][-s][-S fields][-m var][-c var][-T][-t dir][-f file \| sql-command-line]\n"
	" -n name - name of synthetic event 'Anonymous' if left off\n"
	" -t dir - use dir instead of /sys/kernel/tracing\n"
	" -e - execute the commands to create the synthetic event\n"
	" -m - trigger the action when var is a new max.\n"
	" -c - trigger the action when var changes.\n"
	" -s - used with -m or -c to do a snapshot of the tracing buffer\n"
	" -S - used with -m or -c to save fields of the end event (comma deliminated)\n"
	" -T - used with -m or -c to do both a snapshot and a trace\n"
	" -f file - read sql lines from file otherwise from the command line\n"
	" if file is '-' then read from standard input.\n",
	argv[0]);
	exit(-1);
	}

	enum action {
	ACTION_DEFAULT = 0,
	ACTION_SNAPSHOT = (1 << 0),
	ACTION_TRACE = (1 << 1),
	ACTION_SAVE = (1 << 2),
	ACTION_MAX = (1 << 3),
	ACTION_CHANGE = (1 << 4),
	};

	#define ACTIONS ((ACTION_MAX - 1))

	static int do_sql(const char *instance_name,
	const char buffer, const char name, const char *var,
	const char *trace_dir, bool execute, int action,
	char **save_fields)
	{
	struct tracefs_synth *synth;
	struct tep_handle *tep;
	struct trace_seq seq;
	enum tracefs_synth_handler handler;
	char *err;
	int ret;

	if ((action & ACTIONS) && !var) {
	fprintf(stderr, "Error: -s, -S and -T not supported without -m or -c");
	exit(-1);
	}

	if (!name)
	name = "Anonymous";

	trace_seq_init(&seq);
	tep = tracefs_local_events(trace_dir);
	if (!tep) {
	if (!trace_dir)
	trace_dir = "tracefs directory";
	perror(trace_dir);
	exit(-1);
	}

	synth = tracefs_sql(tep, name, buffer, &err);
	if (!synth) {
	perror("Failed creating synthetic event!");
	if (err)
	fprintf(stderr, "%s", err);
	free(err);
	exit(-1);
	}

	if (tracefs_synth_complete(synth)) {
	if (var) {
	if (action & ACTION_MAX)
	handler = TRACEFS_SYNTH_HANDLE_MAX;
	else
	handler = TRACEFS_SYNTH_HANDLE_CHANGE;

	if (action & ACTION_SAVE) {
	ret = tracefs_synth_save(synth, handler, var, save_fields);
	if (ret < 0) {
	err = "adding save";
	goto failed_action;
	}
	}
	if (action & ACTION_TRACE) {
	/*
	* By doing the trace before snapshot, it will be included
	* in the snapshot.
	*/
	ret = tracefs_synth_trace(synth, handler, var);
	if (ret < 0) {
	err = "adding trace";
	goto failed_action;
	}
	}
	if (action & ACTION_SNAPSHOT) {
	ret = tracefs_synth_snapshot(synth, handler, var);
	if (ret < 0) {
	err = "adding snapshot";
	failed_action:
	perror(err);
	if (errno == ENODEV)
	fprintf(stderr, "ERROR: '%s' is not a variable\n",
	var);
	exit(-1);
	}
	}
	}
	tracefs_synth_echo_cmd(&seq, synth);
	if (execute) {
	ret = tracefs_synth_create(synth);
	if (ret < 0) {
	fprintf(stderr, "%s\n", tracefs_error_last(NULL));
	exit(-1);
	}
	}
	} else {
	struct tracefs_instance *instance = NULL;
	struct tracefs_hist *hist;

	hist = tracefs_synth_get_start_hist(synth);
	if (!hist) {
	perror("get_start_hist");
	exit(-1);
	}
	if (instance_name) {
	if (execute)
	instance = tracefs_instance_create(instance_name);
	else
	instance = tracefs_instance_alloc(trace_dir,
	instance_name);
	if (!instance) {
	perror("Failed to create instance");
	exit(-1);
	}
	}
	tracefs_hist_echo_cmd(&seq, instance, hist, 0);
	if (execute) {
	ret = tracefs_hist_start(instance, hist);
	if (ret < 0) {
	fprintf(stderr, "%s\n", tracefs_error_last(instance));
	exit(-1);
	}
	}
	}

	tracefs_synth_free(synth);

	trace_seq_do_printf(&seq);
	trace_seq_destroy(&seq);
	return 0;
	}

	int main (int argc, char **argv)
	{
	char *trace_dir = NULL;
	char *buffer = NULL;
	char buf[BUFSIZ];
	int buffer_size = 0;
	const char *file = NULL;
	const char *instance = NULL;
	bool execute = false;
	char **save_fields = NULL;
	const char *name;
	const char *var;
	int action = 0;
	char *tok;
	FILE *fp;
	size_t r;
	int c;
	int i;

	for (;;) {
	c = getopt(argc, argv, "ht:f:en:m:c:sS:TB:");
	if (c == -1)
	break;

	switch(c) {
	case 'h':
	usage(argv);
	case 't':
	trace_dir = optarg;
	break;
	case 'f':
	file = optarg;
	break;
	case 'e':
	execute = true;
	break;
	case 'm':
	action \|= ACTION_MAX;
	var = optarg;
	break;
	case 'c':
	action \|= ACTION_CHANGE;
	var = optarg;
	break;
	case 's':
	action \|= ACTION_SNAPSHOT;
	break;
	case 'S':
	action \|= ACTION_SAVE;
	tok = strtok(optarg, ",");
	while (tok) {
	save_fields = tracefs_list_add(save_fields, tok);
	tok = strtok(NULL, ",");
	}
	if (!save_fields) {
	perror(optarg);
	exit(-1);
	}
	break;
	case 'T':
	action \|= ACTION_TRACE \| ACTION_SNAPSHOT;
	break;
	case 'B':
	instance = optarg;
	break;
	case 'n':
	name = optarg;
	break;
	}
	}

	if ((action & (ACTION_MAX\|ACTION_CHANGE)) == (ACTION_MAX\|ACTION_CHANGE)) {
	fprintf(stderr, "Can not use both -m and -c together\n");
	exit(-1);
	}
	if (file) {
	if (!strcmp(file, "-"))
	fp = stdin;
	else
	fp = fopen(file, "r");
	if (!fp) {
	perror(file);
	exit(-1);
	}
	while ((r = fread(buf, 1, BUFSIZ, fp)) > 0) {
	buffer = realloc(buffer, buffer_size + r + 1);
	strncpy(buffer + buffer_size, buf, r);
	buffer_size += r;
	}
	fclose(fp);
	if (buffer_size)
	buffer[buffer_size] = '\0';
	} else if (argc == optind) {
	usage(argv);
	} else {
	for (i = optind; i < argc; i++) {
	r = strlen(argv[i]);
	buffer = realloc(buffer, buffer_size + r + 2);
	if (i != optind)
	buffer[buffer_size++] = ' ';
	strcpy(buffer + buffer_size, argv[i]);
	buffer_size += r;
	}
	}

	do_sql(instance, buffer, name, var, trace_dir, execute, action, save_fields);
	free(buffer);

	return 0;
	}
	--

	FILES
	-----
	[verse]
	--
	tracefs.h
	Header file to include in order to have access to the library APIs.
	-ltracefs
	Linker switch to add when building a program that uses the library.
	--

	SEE ALSO
	--------
	sqlhist(1),
	libtracefs(3),
	libtraceevent(3),
	trace-cmd(1),
	tracefs_synth_init(3),
	tracefs_synth_add_match_field(3),
	tracefs_synth_add_compare_field(3),
	tracefs_synth_add_start_field(3),
	tracefs_synth_add_end_field(3),
	tracefs_synth_append_start_filter(3),
	tracefs_synth_append_end_filter(3),
	tracefs_synth_create(3),
	tracefs_synth_destroy(3),
	tracefs_synth_free(3),
	tracefs_synth_echo_cmd(3),
	tracefs_hist_alloc(3),
	tracefs_hist_alloc_2d(3),
	tracefs_hist_alloc_nd(3),
	tracefs_hist_free(3),
	tracefs_hist_add_key(3),
	tracefs_hist_add_value(3),
	tracefs_hist_add_name(3),
	tracefs_hist_start(3),
	tracefs_hist_destory(3),
	tracefs_hist_add_sort_key(3),
	tracefs_hist_sort_key_direction(3)

	AUTHOR
	------
	[verse]
	--
	Steven Rostedt <rostedt@goodmis.org>
	Tzvetomir Stoyanov <tz.stoyanov@gmail.com>
	sameeruddin shaik <sameeruddin.shaik8@gmail.com>
	--
	REPORTING BUGS
	--------------
	Report bugs to <linux-trace-devel@vger.kernel.org>

	LICENSE
	-------
	libtracefs is Free Software licensed under the GNU LGPL 2.1

	RESOURCES
	---------
	https://git.kernel.org/pub/scm/libs/libtrace/libtracefs.git/

	COPYING
	-------
	Copyright \(C) 2020 VMware, Inc. Free use of this software is granted under
	the terms of the GNU Public License (GPL).