t/helper/test-trace2.c - jrn/git - Git at Google

 #include "test-tool.h"
 #include "strvec.h"
 #include "run-command.h"
 #include "exec-cmd.h"
 #include "config.h"
 #include "repository.h"
 #include "trace2.h"

 typedef int(fn_unit_test)(int argc, const char **argv);

 struct unit_test {
 	fn_unit_test *ut_fn;
 	const char *ut_name;
 	const char *ut_usage;
 };

 #define MyOk 0
 #define MyError 1

 static int get_i(int *p_value, const char *data)
 {
 	char *endptr;

 	if (!data || !*data)
 		return MyError;

 	*p_value = strtol(data, &endptr, 10);
 	if (*endptr || errno == ERANGE)
 		return MyError;

 	return MyOk;
 }

 /*
  * Cause process to exit with the requested value via "return".
  *
  * Rely on test-tool.c:cmd_main() to call trace2_cmd_exit()
  * with our result.
  *
  * Test harness can confirm:
  * [] the process-exit value.
  * [] the "code" field in the "exit" trace2 event.
  * [] the "code" field in the "atexit" trace2 event.
  * [] the "name" field in the "cmd_name" trace2 event.
  * [] "def_param" events for all of the "interesting" pre-defined
  * config settings.
  */
 static int ut_001return(int argc UNUSED, const char **argv)
 {
 	int rc;

 	if (get_i(&rc, argv[0]))
 		die("expect <exit_code>");

 	return rc;
 }

 /*
  * Cause the process to exit with the requested value via "exit()".
  *
  * Test harness can confirm:
  * [] the "code" field in the "exit" trace2 event.
  * [] the "code" field in the "atexit" trace2 event.
  * [] the "name" field in the "cmd_name" trace2 event.
  * [] "def_param" events for all of the "interesting" pre-defined
  * config settings.
  */
 static int ut_002exit(int argc UNUSED, const char **argv)
 {
 	int rc;

 	if (get_i(&rc, argv[0]))
 		die("expect <exit_code>");

 	exit(rc);
 }

 /*
  * Send an "error" event with each value in argv.  Normally, git only issues
  * a single "error" event immediately before issuing an "exit" event (such
  * as in die() or BUG()), but multiple "error" events are allowed.
  *
  * Test harness can confirm:
  * [] a trace2 "error" event for each value in argv.
  * [] the "name" field in the "cmd_name" trace2 event.
  * [] (optional) the file:line in the "exit" event refers to this function.
  */
 static int ut_003error(int argc, const char **argv)
 {
 	int k;

 	if (!argv[0] || !*argv[0])
 		die("expect <error_message>");

 	for (k = 0; k < argc; k++)
 		error("%s", argv[k]);

 	return 0;
 }

 /*
  * Run a child process and wait for it to finish and exit with its return code.
  * test-tool trace2 004child [<child-command-line>]
  *
  * For example:
  * test-tool trace2 004child git version
  * test-tool trace2 004child test-tool trace2 001return 0
  * test-tool trace2 004child test-tool trace2 004child test-tool trace2 004child
  * test-tool trace2 004child git -c alias.xyz=version xyz
  *
  * Test harness can confirm:
  * [] the "name" field in the "cmd_name" trace2 event.
  * [] that the outer process has a single component SID (or depth "d0" in
  *    the PERF stream).
  * [] that "child_start" and "child_exit" events are generated for the child.
  * [] if the child process is an instrumented executable:
  *    [] that "version", "start", ..., "exit", and "atexit" events are
  *       generated by the child process.
  *    [] that the child process events have a multiple component SID (or
  *       depth "dN+1" in the PERF stream).
  * [] that the child exit code is propagated to the parent process "exit"
  *    and "atexit" events..
  * [] (optional) that the "t_abs" field in the child process "atexit" event
  *    is less than the "t_rel" field in the "child_exit" event of the parent
  *    process.
  * [] if the child process is like the alias example above,
  *    [] (optional) the child process attempts to run "git-xyx" as a dashed
  *       command.
  *    [] the child process emits an "alias" event with "xyz" => "version"
  *    [] the child process runs "git version" as a child process.
  *    [] the child process has a 3 component SID (or depth "d2" in the PERF
  *       stream).
  */
 static int ut_004child(int argc, const char **argv)
 {
 	struct child_process cmd = CHILD_PROCESS_INIT;
 	int result;

 	/*
 	 * Allow empty <child_command_line> so we can do arbitrarily deep
 	 * command nesting and let the last one be null.
 	 */
 	if (!argc)
 		return 0;

 	strvec_pushv(&cmd.args, argv);
 	result = run_command(&cmd);
 	exit(result);
 }

 /*
  * Exec a git command.  This may either create a child process (Windows)
  * or replace the existing process.
  * test-tool trace2 005exec <git_command_args>
  *
  * For example:
  * test-tool trace2 005exec version
  *
  * Test harness can confirm (on Windows):
  * [] the "name" field in the "cmd_name" trace2 event.
  * [] that the outer process has a single component SID (or depth "d0" in
  *    the PERF stream).
  * [] that "exec" and "exec_result" events are generated for the child
  *    process (since the Windows compatibility layer fakes an exec() with
  *    a CreateProcess(), WaitForSingleObject(), and exit()).
  * [] that the child process has multiple component SID (or depth "dN+1"
  *    in the PERF stream).
  *
  * Test harness can confirm (on platforms with a real exec() function):
  * [] TODO talk about process replacement and how it affects SID.
  */
 static int ut_005exec(int argc, const char **argv)
 {
 	int result;

 	if (!argc)
 		return 0;

 	result = execv_git_cmd(argv);
 	return result;
 }

 static int ut_006data(int argc, const char **argv)
 {
 	const char *usage_error =
 		"expect <cat0> <k0> <v0> [<cat1> <k1> <v1> [...]]";

 	if (argc % 3 != 0)
 		die("%s", usage_error);

 	while (argc) {
 		if (!argv[0] || !*argv[0] || !argv[1] || !*argv[1] ||
 		    !argv[2] || !*argv[2])
 			die("%s", usage_error);

 		trace2_data_string(argv[0], the_repository, argv[1], argv[2]);
 		argv += 3;
 		argc -= 3;
 	}

 	return 0;
 }

 static int ut_007BUG(int argc UNUSED, const char **argv UNUSED)
 {
 	/*
 	 * Exercise BUG() to ensure that the message is printed to trace2.
 	 */
 	BUG("the bug message");
 }

 static int ut_008bug(int argc UNUSED, const char **argv UNUSED)
 {
 	bug("a bug message");
 	bug("another bug message");
 	BUG_if_bug("an explicit BUG_if_bug() following bug() call(s) is nice, but not required");
 	return 0;
 }

 static int ut_009bug_BUG(int argc UNUSED, const char **argv UNUSED)
 {
 	bug("a bug message");
 	bug("another bug message");
 	/* The BUG_if_bug(...) isn't here, but we'll spot bug() calls on exit()! */
 	return 0;
 }

 static int ut_010bug_BUG(int argc UNUSED, const char **argv UNUSED)
 {
 	bug("a %s message", "bug");
 	BUG("a %s message", "BUG");
 }

 /*
  * Single-threaded timer test.  Create several intervals using the
  * TEST1 timer.  The test script can verify that an aggregate Trace2
  * "timer" event is emitted indicating that we started+stopped the
  * timer the requested number of times.
  */
 static int ut_100timer(int argc, const char **argv)
 {
 	const char *usage_error =
 		"expect <count> <ms_delay>";

 	int count = 0;
 	int delay = 0;
 	int k;

 	if (argc != 2)
 		die("%s", usage_error);
 	if (get_i(&count, argv[0]))
 		die("%s", usage_error);
 	if (get_i(&delay, argv[1]))
 		die("%s", usage_error);

 	for (k = 0; k < count; k++) {
 		trace2_timer_start(TRACE2_TIMER_ID_TEST1);
 		sleep_millisec(delay);
 		trace2_timer_stop(TRACE2_TIMER_ID_TEST1);
 	}

 	return 0;
 }

 struct ut_101_data {
 	int count;
 	int delay;
 };

 static void *ut_101timer_thread_proc(void *_ut_101_data)
 {
 	struct ut_101_data *data = _ut_101_data;
 	int k;

 	trace2_thread_start("ut_101");

 	for (k = 0; k < data->count; k++) {
 		trace2_timer_start(TRACE2_TIMER_ID_TEST2);
 		sleep_millisec(data->delay);
 		trace2_timer_stop(TRACE2_TIMER_ID_TEST2);
 	}

 	trace2_thread_exit();
 	return NULL;
 }

 /*
  * Multi-threaded timer test.  Create several threads that each create
  * several intervals using the TEST2 timer.  The test script can verify
  * that an individual Trace2 "th_timer" events for each thread and an
  * aggregate "timer" event are generated.
  */
 static int ut_101timer(int argc, const char **argv)
 {
 	const char *usage_error =
 		"expect <count> <ms_delay> <threads>";

 	struct ut_101_data data = { 0, 0 };
 	int nr_threads = 0;
 	int k;
 	pthread_t *pids = NULL;

 	if (argc != 3)
 		die("%s", usage_error);
 	if (get_i(&data.count, argv[0]))
 		die("%s", usage_error);
 	if (get_i(&data.delay, argv[1]))
 		die("%s", usage_error);
 	if (get_i(&nr_threads, argv[2]))
 		die("%s", usage_error);

 	CALLOC_ARRAY(pids, nr_threads);

 	for (k = 0; k < nr_threads; k++) {
 		if (pthread_create(&pids[k], NULL, ut_101timer_thread_proc, &data))
 			die("failed to create thread[%d]", k);
 	}

 	for (k = 0; k < nr_threads; k++) {
 		if (pthread_join(pids[k], NULL))
 			die("failed to join thread[%d]", k);
 	}

 	free(pids);

 	return 0;
 }

 /*
  * Single-threaded counter test.  Add several values to the TEST1 counter.
  * The test script can verify that the final sum is reported in the "counter"
  * event.
  */
 static int ut_200counter(int argc, const char **argv)
 {
 	const char *usage_error =
 		"expect <v1> [<v2> [...]]";
 	int value;
 	int k;

 	if (argc < 1)
 		die("%s", usage_error);

 	for (k = 0; k < argc; k++) {
 		if (get_i(&value, argv[k]))
 			die("invalid value[%s] -- %s",
 			    argv[k], usage_error);
 		trace2_counter_add(TRACE2_COUNTER_ID_TEST1, value);
 	}

 	return 0;
 }

 /*
  * Multi-threaded counter test.  Create seveal threads that each increment
  * the TEST2 global counter.  The test script can verify that an individual
  * "th_counter" event is generated with a partial sum for each thread and
  * that a final aggregate "counter" event is generated.
  */

 struct ut_201_data {
 	int v1;
 	int v2;
 };

 static void *ut_201counter_thread_proc(void *_ut_201_data)
 {
 	struct ut_201_data *data = _ut_201_data;

 	trace2_thread_start("ut_201");

 	trace2_counter_add(TRACE2_COUNTER_ID_TEST2, data->v1);
 	trace2_counter_add(TRACE2_COUNTER_ID_TEST2, data->v2);

 	trace2_thread_exit();
 	return NULL;
 }

 static int ut_201counter(int argc, const char **argv)
 {
 	const char *usage_error =
 		"expect <v1> <v2> <threads>";

 	struct ut_201_data data = { 0, 0 };
 	int nr_threads = 0;
 	int k;
 	pthread_t *pids = NULL;

 	if (argc != 3)
 		die("%s", usage_error);
 	if (get_i(&data.v1, argv[0]))
 		die("%s", usage_error);
 	if (get_i(&data.v2, argv[1]))
 		die("%s", usage_error);
 	if (get_i(&nr_threads, argv[2]))
 		die("%s", usage_error);

 	CALLOC_ARRAY(pids, nr_threads);

 	for (k = 0; k < nr_threads; k++) {
 		if (pthread_create(&pids[k], NULL, ut_201counter_thread_proc, &data))
 			die("failed to create thread[%d]", k);
 	}

 	for (k = 0; k < nr_threads; k++) {
 		if (pthread_join(pids[k], NULL))
 			die("failed to join thread[%d]", k);
 	}

 	free(pids);

 	return 0;
 }

 static int ut_300redact_start(int argc, const char **argv)
 {
 	if (!argc)
 		die("expect <argv...>");

 	trace2_cmd_start(argv);

 	return 0;
 }

 static int ut_301redact_child_start(int argc, const char **argv)
 {
 	struct child_process cmd = CHILD_PROCESS_INIT;
 	int k;

 	if (!argc)
 		die("expect <argv...>");

 	for (k = 0; argv[k]; k++)
 		strvec_push(&cmd.args, argv[k]);

 	trace2_child_start(&cmd);

 	strvec_clear(&cmd.args);

 	return 0;
 }

 static int ut_302redact_exec(int argc, const char **argv)
 {
 	if (!argc)
 		die("expect <exe> <argv...>");

 	trace2_exec(argv[0], &argv[1]);

 	return 0;
 }

 static int ut_303redact_def_param(int argc, const char **argv)
 {
 	struct key_value_info kvi = KVI_INIT;

 	if (argc < 2)
 		die("expect <key> <value>");

 	trace2_def_param(argv[0], argv[1], &kvi);

 	return 0;
 }

 /*
  * Usage:
  *     test-tool trace2 <ut_name_1> <ut_usage_1>
  *     test-tool trace2 <ut_name_2> <ut_usage_2>
  *     ...
  */
 #define USAGE_PREFIX "test-tool trace2"

 /* clang-format off */
 static struct unit_test ut_table[] = {
 	{ ut_001return,   "001return", "<exit_code>" },
 	{ ut_002exit,     "002exit",   "<exit_code>" },
 	{ ut_003error,    "003error",  "<error_message>+" },
 	{ ut_004child,    "004child",  "[<child_command_line>]" },
 	{ ut_005exec,     "005exec",   "<git_command_args>" },
 	{ ut_006data,     "006data",   "[<category> <key> <value>]+" },
 	{ ut_007BUG,      "007bug",    "" },
 	{ ut_008bug,      "008bug",    "" },
 	{ ut_009bug_BUG,  "009bug_BUG","" },
 	{ ut_010bug_BUG,  "010bug_BUG","" },

 	{ ut_100timer,    "100timer",  "<count> <ms_delay>" },
 	{ ut_101timer,    "101timer",  "<count> <ms_delay> <threads>" },

 	{ ut_200counter,  "200counter", "<v1> [<v2> [<v3> [...]]]" },
 	{ ut_201counter,  "201counter", "<v1> <v2> <threads>" },

 	{ ut_300redact_start,       "300redact_start",       "<argv...>" },
 	{ ut_301redact_child_start, "301redact_child_start", "<argv...>" },
 	{ ut_302redact_exec,        "302redact_exec",        "<exe> <argv...>" },
 	{ ut_303redact_def_param,   "303redact_def_param",   "<key> <value>" },
 };
 /* clang-format on */

 /* clang-format off */
 #define for_each_ut(k, ut_k)			\
 	for (k = 0, ut_k = &ut_table[k];	\
 	     k < ARRAY_SIZE(ut_table);		\
 	     k++, ut_k = &ut_table[k])
 /* clang-format on */

 static int print_usage(void)
 {
 	int k;
 	struct unit_test *ut_k;

 	fprintf(stderr, "usage:\n");
 	for_each_ut (k, ut_k)
 		fprintf(stderr, "\t%s %s %s\n", USAGE_PREFIX, ut_k->ut_name,
 			ut_k->ut_usage);

 	return 129;
 }

 /*
  * Issue various trace2 events for testing.
  *
  * We assume that these trace2 routines has already been called:
  *    [] trace2_initialize()      [common-main.c:main()]
  *    [] trace2_cmd_start()       [common-main.c:main()]
  *    [] trace2_cmd_name()        [test-tool.c:cmd_main()]
  *    [] tracd2_cmd_list_config() [test-tool.c:cmd_main()]
  * So that:
  *    [] the various trace2 streams are open.
  *    [] the process SID has been created.
  *    [] the "version" event has been generated.
  *    [] the "start" event has been generated.
  *    [] the "cmd_name" event has been generated.
  *    [] this writes various "def_param" events for interesting config values.
  *
  * We return from here and let test-tool.c::cmd_main() pass the exit
  * code to common-main.c::main(), which will use it to call
  * trace2_cmd_exit().
  */
 int cmd__trace2(int argc, const char **argv)
 {
 	int k;
 	struct unit_test *ut_k;

 	argc--; /* skip over "trace2" arg */
 	argv++;

 	if (argc)
 		for_each_ut (k, ut_k)
 			if (!strcmp(argv[0], ut_k->ut_name))
 				return ut_k->ut_fn(argc - 1, argv + 1);

 	return print_usage();
 }
	#include "test-tool.h"
	#include "strvec.h"
	#include "run-command.h"
	#include "exec-cmd.h"
	#include "config.h"
	#include "repository.h"
	#include "trace2.h"

	typedef int(fn_unit_test)(int argc, const char **argv);

	struct unit_test {
	fn_unit_test *ut_fn;
	const char *ut_name;
	const char *ut_usage;
	};

	#define MyOk 0
	#define MyError 1

	static int get_i(int p_value, const char data)
	{
	char *endptr;

	if (!data \|\| !*data)
	return MyError;

	*p_value = strtol(data, &endptr, 10);
	if (*endptr \|\| errno == ERANGE)
	return MyError;

	return MyOk;
	}

	/*
	* Cause process to exit with the requested value via "return".
	*
	* Rely on test-tool.c:cmd_main() to call trace2_cmd_exit()
	* with our result.
	*
	* Test harness can confirm:
	* [] the process-exit value.
	* [] the "code" field in the "exit" trace2 event.
	* [] the "code" field in the "atexit" trace2 event.
	* [] the "name" field in the "cmd_name" trace2 event.
	* [] "def_param" events for all of the "interesting" pre-defined
	* config settings.
	*/
	static int ut_001return(int argc UNUSED, const char **argv)
	{
	int rc;

	if (get_i(&rc, argv[0]))
	die("expect <exit_code>");

	return rc;
	}

	/*
	* Cause the process to exit with the requested value via "exit()".
	*
	* Test harness can confirm:
	* [] the "code" field in the "exit" trace2 event.
	* [] the "code" field in the "atexit" trace2 event.
	* [] the "name" field in the "cmd_name" trace2 event.
	* [] "def_param" events for all of the "interesting" pre-defined
	* config settings.
	*/
	static int ut_002exit(int argc UNUSED, const char **argv)
	{
	int rc;

	if (get_i(&rc, argv[0]))
	die("expect <exit_code>");

	exit(rc);
	}

	/*
	* Send an "error" event with each value in argv. Normally, git only issues
	* a single "error" event immediately before issuing an "exit" event (such
	* as in die() or BUG()), but multiple "error" events are allowed.
	*
	* Test harness can confirm:
	* [] a trace2 "error" event for each value in argv.
	* [] the "name" field in the "cmd_name" trace2 event.
	* [] (optional) the file:line in the "exit" event refers to this function.
	*/
	static int ut_003error(int argc, const char **argv)
	{
	int k;

	if (!argv[0] \|\| !*argv[0])
	die("expect <error_message>");

	for (k = 0; k < argc; k++)
	error("%s", argv[k]);

	return 0;
	}

	/*
	* Run a child process and wait for it to finish and exit with its return code.
	* test-tool trace2 004child [<child-command-line>]
	*
	* For example:
	* test-tool trace2 004child git version
	* test-tool trace2 004child test-tool trace2 001return 0
	* test-tool trace2 004child test-tool trace2 004child test-tool trace2 004child
	* test-tool trace2 004child git -c alias.xyz=version xyz
	*
	* Test harness can confirm:
	* [] the "name" field in the "cmd_name" trace2 event.
	* [] that the outer process has a single component SID (or depth "d0" in
	* the PERF stream).
	* [] that "child_start" and "child_exit" events are generated for the child.
	* [] if the child process is an instrumented executable:
	* [] that "version", "start", ..., "exit", and "atexit" events are
	* generated by the child process.
	* [] that the child process events have a multiple component SID (or
	* depth "dN+1" in the PERF stream).
	* [] that the child exit code is propagated to the parent process "exit"
	* and "atexit" events..
	* [] (optional) that the "t_abs" field in the child process "atexit" event
	* is less than the "t_rel" field in the "child_exit" event of the parent
	* process.
	* [] if the child process is like the alias example above,
	* [] (optional) the child process attempts to run "git-xyx" as a dashed
	* command.
	* [] the child process emits an "alias" event with "xyz" => "version"
	* [] the child process runs "git version" as a child process.
	* [] the child process has a 3 component SID (or depth "d2" in the PERF
	* stream).
	*/
	static int ut_004child(int argc, const char **argv)
	{
	struct child_process cmd = CHILD_PROCESS_INIT;
	int result;

	/*
	* Allow empty <child_command_line> so we can do arbitrarily deep
	* command nesting and let the last one be null.
	*/
	if (!argc)
	return 0;

	strvec_pushv(&cmd.args, argv);
	result = run_command(&cmd);
	exit(result);
	}

	/*
	* Exec a git command. This may either create a child process (Windows)
	* or replace the existing process.
	* test-tool trace2 005exec <git_command_args>
	*
	* For example:
	* test-tool trace2 005exec version
	*
	* Test harness can confirm (on Windows):
	* [] the "name" field in the "cmd_name" trace2 event.
	* [] that the outer process has a single component SID (or depth "d0" in
	* the PERF stream).
	* [] that "exec" and "exec_result" events are generated for the child
	* process (since the Windows compatibility layer fakes an exec() with
	* a CreateProcess(), WaitForSingleObject(), and exit()).
	* [] that the child process has multiple component SID (or depth "dN+1"
	* in the PERF stream).
	*
	* Test harness can confirm (on platforms with a real exec() function):
	* [] TODO talk about process replacement and how it affects SID.
	*/
	static int ut_005exec(int argc, const char **argv)
	{
	int result;

	if (!argc)
	return 0;

	result = execv_git_cmd(argv);
	return result;
	}

	static int ut_006data(int argc, const char **argv)
	{
	const char *usage_error =
	"expect <cat0> <k0> <v0> [<cat1> <k1> <v1> [...]]";

	if (argc % 3 != 0)
	die("%s", usage_error);

	while (argc) {
	if (!argv[0] \|\| !argv[0] \|\| !argv[1] \|\| !argv[1] \|\|
	!argv[2] \|\| !*argv[2])
	die("%s", usage_error);

	trace2_data_string(argv[0], the_repository, argv[1], argv[2]);
	argv += 3;
	argc -= 3;
	}

	return 0;
	}

	static int ut_007BUG(int argc UNUSED, const char **argv UNUSED)
	{
	/*
	* Exercise BUG() to ensure that the message is printed to trace2.
	*/
	BUG("the bug message");
	}

	static int ut_008bug(int argc UNUSED, const char **argv UNUSED)
	{
	bug("a bug message");
	bug("another bug message");
	BUG_if_bug("an explicit BUG_if_bug() following bug() call(s) is nice, but not required");
	return 0;
	}

	static int ut_009bug_BUG(int argc UNUSED, const char **argv UNUSED)
	{
	bug("a bug message");
	bug("another bug message");
	/* The BUG_if_bug(...) isn't here, but we'll spot bug() calls on exit()! */
	return 0;
	}

	static int ut_010bug_BUG(int argc UNUSED, const char **argv UNUSED)
	{
	bug("a %s message", "bug");
	BUG("a %s message", "BUG");
	}

	/*
	* Single-threaded timer test. Create several intervals using the
	* TEST1 timer. The test script can verify that an aggregate Trace2
	* "timer" event is emitted indicating that we started+stopped the
	* timer the requested number of times.
	*/
	static int ut_100timer(int argc, const char **argv)
	{
	const char *usage_error =
	"expect <count> <ms_delay>";

	int count = 0;
	int delay = 0;
	int k;

	if (argc != 2)
	die("%s", usage_error);
	if (get_i(&count, argv[0]))
	die("%s", usage_error);
	if (get_i(&delay, argv[1]))
	die("%s", usage_error);

	for (k = 0; k < count; k++) {
	trace2_timer_start(TRACE2_TIMER_ID_TEST1);
	sleep_millisec(delay);
	trace2_timer_stop(TRACE2_TIMER_ID_TEST1);
	}

	return 0;
	}

	struct ut_101_data {
	int count;
	int delay;
	};

	static void ut_101timer_thread_proc(void _ut_101_data)
	{
	struct ut_101_data *data = _ut_101_data;
	int k;

	trace2_thread_start("ut_101");

	for (k = 0; k < data->count; k++) {
	trace2_timer_start(TRACE2_TIMER_ID_TEST2);
	sleep_millisec(data->delay);
	trace2_timer_stop(TRACE2_TIMER_ID_TEST2);
	}

	trace2_thread_exit();
	return NULL;
	}

	/*
	* Multi-threaded timer test. Create several threads that each create
	* several intervals using the TEST2 timer. The test script can verify
	* that an individual Trace2 "th_timer" events for each thread and an
	* aggregate "timer" event are generated.
	*/
	static int ut_101timer(int argc, const char **argv)
	{
	const char *usage_error =
	"expect <count> <ms_delay> <threads>";

	struct ut_101_data data = { 0, 0 };
	int nr_threads = 0;
	int k;
	pthread_t *pids = NULL;

	if (argc != 3)
	die("%s", usage_error);
	if (get_i(&data.count, argv[0]))
	die("%s", usage_error);
	if (get_i(&data.delay, argv[1]))
	die("%s", usage_error);
	if (get_i(&nr_threads, argv[2]))
	die("%s", usage_error);

	CALLOC_ARRAY(pids, nr_threads);

	for (k = 0; k < nr_threads; k++) {
	if (pthread_create(&pids[k], NULL, ut_101timer_thread_proc, &data))
	die("failed to create thread[%d]", k);
	}

	for (k = 0; k < nr_threads; k++) {
	if (pthread_join(pids[k], NULL))
	die("failed to join thread[%d]", k);
	}

	free(pids);

	return 0;
	}

	/*
	* Single-threaded counter test. Add several values to the TEST1 counter.
	* The test script can verify that the final sum is reported in the "counter"
	* event.
	*/
	static int ut_200counter(int argc, const char **argv)
	{
	const char *usage_error =
	"expect <v1> [<v2> [...]]";
	int value;
	int k;

	if (argc < 1)
	die("%s", usage_error);

	for (k = 0; k < argc; k++) {
	if (get_i(&value, argv[k]))
	die("invalid value[%s] -- %s",
	argv[k], usage_error);
	trace2_counter_add(TRACE2_COUNTER_ID_TEST1, value);
	}

	return 0;
	}

	/*
	* Multi-threaded counter test. Create seveal threads that each increment
	* the TEST2 global counter. The test script can verify that an individual
	* "th_counter" event is generated with a partial sum for each thread and
	* that a final aggregate "counter" event is generated.
	*/

	struct ut_201_data {
	int v1;
	int v2;
	};

	static void ut_201counter_thread_proc(void _ut_201_data)
	{
	struct ut_201_data *data = _ut_201_data;

	trace2_thread_start("ut_201");

	trace2_counter_add(TRACE2_COUNTER_ID_TEST2, data->v1);
	trace2_counter_add(TRACE2_COUNTER_ID_TEST2, data->v2);

	trace2_thread_exit();
	return NULL;
	}

	static int ut_201counter(int argc, const char **argv)
	{
	const char *usage_error =
	"expect <v1> <v2> <threads>";

	struct ut_201_data data = { 0, 0 };
	int nr_threads = 0;
	int k;
	pthread_t *pids = NULL;

	if (argc != 3)
	die("%s", usage_error);
	if (get_i(&data.v1, argv[0]))
	die("%s", usage_error);
	if (get_i(&data.v2, argv[1]))
	die("%s", usage_error);
	if (get_i(&nr_threads, argv[2]))
	die("%s", usage_error);

	CALLOC_ARRAY(pids, nr_threads);

	for (k = 0; k < nr_threads; k++) {
	if (pthread_create(&pids[k], NULL, ut_201counter_thread_proc, &data))
	die("failed to create thread[%d]", k);
	}

	for (k = 0; k < nr_threads; k++) {
	if (pthread_join(pids[k], NULL))
	die("failed to join thread[%d]", k);
	}

	free(pids);

	return 0;
	}

	static int ut_300redact_start(int argc, const char **argv)
	{
	if (!argc)
	die("expect <argv...>");

	trace2_cmd_start(argv);

	return 0;
	}

	static int ut_301redact_child_start(int argc, const char **argv)
	{
	struct child_process cmd = CHILD_PROCESS_INIT;
	int k;

	if (!argc)
	die("expect <argv...>");

	for (k = 0; argv[k]; k++)
	strvec_push(&cmd.args, argv[k]);

	trace2_child_start(&cmd);

	strvec_clear(&cmd.args);

	return 0;
	}

	static int ut_302redact_exec(int argc, const char **argv)
	{
	if (!argc)
	die("expect <exe> <argv...>");

	trace2_exec(argv[0], &argv[1]);

	return 0;
	}

	static int ut_303redact_def_param(int argc, const char **argv)
	{
	struct key_value_info kvi = KVI_INIT;

	if (argc < 2)
	die("expect <key> <value>");

	trace2_def_param(argv[0], argv[1], &kvi);

	return 0;
	}

	/*
	* Usage:
	* test-tool trace2 <ut_name_1> <ut_usage_1>
	* test-tool trace2 <ut_name_2> <ut_usage_2>
	* ...
	*/
	#define USAGE_PREFIX "test-tool trace2"

	/* clang-format off */
	static struct unit_test ut_table[] = {
	{ ut_001return, "001return", "<exit_code>" },
	{ ut_002exit, "002exit", "<exit_code>" },
	{ ut_003error, "003error", "<error_message>+" },
	{ ut_004child, "004child", "[<child_command_line>]" },
	{ ut_005exec, "005exec", "<git_command_args>" },
	{ ut_006data, "006data", "[<category> <key> <value>]+" },
	{ ut_007BUG, "007bug", "" },
	{ ut_008bug, "008bug", "" },
	{ ut_009bug_BUG, "009bug_BUG","" },
	{ ut_010bug_BUG, "010bug_BUG","" },

	{ ut_100timer, "100timer", "<count> <ms_delay>" },
	{ ut_101timer, "101timer", "<count> <ms_delay> <threads>" },

	{ ut_200counter, "200counter", "<v1> [<v2> [<v3> [...]]]" },
	{ ut_201counter, "201counter", "<v1> <v2> <threads>" },

	{ ut_300redact_start, "300redact_start", "<argv...>" },
	{ ut_301redact_child_start, "301redact_child_start", "<argv...>" },
	{ ut_302redact_exec, "302redact_exec", "<exe> <argv...>" },
	{ ut_303redact_def_param, "303redact_def_param", "<key> <value>" },
	};
	/* clang-format on */

	/* clang-format off */
	#define for_each_ut(k, ut_k) \
	for (k = 0, ut_k = &ut_table[k]; \
	k < ARRAY_SIZE(ut_table); \
	k++, ut_k = &ut_table[k])
	/* clang-format on */

	static int print_usage(void)
	{
	int k;
	struct unit_test *ut_k;

	fprintf(stderr, "usage:\n");
	for_each_ut (k, ut_k)
	fprintf(stderr, "\t%s %s %s\n", USAGE_PREFIX, ut_k->ut_name,
	ut_k->ut_usage);

	return 129;
	}

	/*
	* Issue various trace2 events for testing.
	*
	* We assume that these trace2 routines has already been called:
	* [] trace2_initialize() [common-main.c:main()]
	* [] trace2_cmd_start() [common-main.c:main()]
	* [] trace2_cmd_name() [test-tool.c:cmd_main()]
	* [] tracd2_cmd_list_config() [test-tool.c:cmd_main()]
	* So that:
	* [] the various trace2 streams are open.
	* [] the process SID has been created.
	* [] the "version" event has been generated.
	* [] the "start" event has been generated.
	* [] the "cmd_name" event has been generated.
	* [] this writes various "def_param" events for interesting config values.
	*
	* We return from here and let test-tool.c::cmd_main() pass the exit
	* code to common-main.c::main(), which will use it to call
	* trace2_cmd_exit().
	*/
	int cmd__trace2(int argc, const char **argv)
	{
	int k;
	struct unit_test *ut_k;

	argc--; /* skip over "trace2" arg */
	argv++;

	if (argc)
	for_each_ut (k, ut_k)
	if (!strcmp(argv[0], ut_k->ut_name))
	return ut_k->ut_fn(argc - 1, argv + 1);

	return print_usage();
	}