[babeltrace.git] / tests / lib / test_ctf_ir_ref.c

/*
 * test_ctf_ir_ref.c
 *
 * CTF IR Reference Count test
 *
 * Copyright 2016 - Jérémie Galarneau <jeremie.galarneau@efficios.com>
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; under version 2 of the License.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License along
 * with this program; if not, write to the Free Software Foundation, Inc.,
 * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 */

#include "tap/tap.h"
#include <babeltrace/ctf-writer/writer.h>
#include <babeltrace/ctf-writer/stream.h>
#include <babeltrace/ctf-writer/clock.h>
#include <babeltrace/ctf-ir/trace.h>
#include <babeltrace/ctf-writer/stream-class.h>
#include <babeltrace/ctf-ir/stream.h>
#include <babeltrace/ctf-ir/fields.h>
#include <babeltrace/ctf-ir/event.h>
#include <babeltrace/ctf-ir/event-class.h>
#include <babeltrace/object-internal.h>
#include <babeltrace/compat/stdlib-internal.h>
#include <assert.h>
#include "common.h"

#define NR_TESTS 41

struct user {
	struct bt_ctf_writer *writer;
	struct bt_ctf_trace *tc;
	struct bt_ctf_stream_class *sc;
	struct bt_ctf_event_class *ec;
	struct bt_ctf_stream *stream;
	struct bt_ctf_event *event;
};

const char *user_names[] = {
	"writer",
	"trace",
	"stream class",
	"event class",
	"stream",
	"event",
};

static const size_t USER_NR_ELEMENTS = sizeof(struct user) / sizeof(void *);

/**
 * Returns a structure containing the following fields:
 *     - uint8_t payload_8;
 *     - uint16_t payload_16;
 *     - uint32_t payload_32;
 */
static struct bt_ctf_field_type *create_integer_struct(void)
{
	int ret;
	struct bt_ctf_field_type *structure = NULL;
	struct bt_ctf_field_type *ui8 = NULL, *ui16 = NULL, *ui32 = NULL;

	structure = bt_ctf_field_type_structure_create();
	if (!structure) {
		goto error;
	}

	ui8 = bt_ctf_field_type_integer_create(8);
	if (!ui8) {
		diag("Failed to create uint8_t type");
		goto error;
	}
	ret = bt_ctf_field_type_structure_add_field(structure, ui8,
		        "payload_8");
	if (ret) {
		diag("Failed to add uint8_t to structure");
		goto error;
	}
	ui16 = bt_ctf_field_type_integer_create(16);
	if (!ui16) {
		diag("Failed to create uint16_t type");
		goto error;
	}
	ret = bt_ctf_field_type_structure_add_field(structure, ui16,
		        "payload_16");
	if (ret) {
		diag("Failed to add uint16_t to structure");
		goto error;
	}
	ui32 = bt_ctf_field_type_integer_create(32);
	if (!ui32) {
		diag("Failed to create uint32_t type");
		goto error;
	}
	ret = bt_ctf_field_type_structure_add_field(structure, ui32,
		        "payload_32");
	if (ret) {
		diag("Failed to add uint32_t to structure");
		goto error;
	}
end:
	BT_PUT(ui8);
	BT_PUT(ui16);
	BT_PUT(ui32);
	return structure;
error:
	BT_PUT(structure);
	goto end;
}

/**
 * A simple event has the following payload:
 *     - uint8_t payload_8;
 *     - uint16_t payload_16;
 *     - uint32_t payload_32;
 */
static struct bt_ctf_event_class *create_simple_event(const char *name)
{
	int ret;
	struct bt_ctf_event_class *event = NULL;
	struct bt_ctf_field_type *payload = NULL;

	assert(name);
	event = bt_ctf_event_class_create(name);
	if (!event) {
		diag("Failed to create simple event");
		goto error;
	}

	payload = create_integer_struct();
	if (!payload) {
		diag("Failed to initialize integer structure");
		goto error;
	}

	ret = bt_ctf_event_class_set_payload_type(event, payload);
	if (ret) {
		diag("Failed to set simple event payload");
		goto error;
	}
end:
	BT_PUT(payload);
	return event;
error:
	BT_PUT(event);
	goto end;;
}

/**
 * A complex event has the following payload:
 *     - uint8_t payload_8;
 *     - uint16_t payload_16;
 *     - uint32_t payload_32;
 *     - struct payload_struct:
 *           - uint8_t payload_8;
 *           - uint16_t payload_16;
 *           - uint32_t payload_32;
 */
static struct bt_ctf_event_class *create_complex_event(const char *name)
{
	int ret;
	struct bt_ctf_event_class *event = NULL;
	struct bt_ctf_field_type *inner = NULL, *outer = NULL;

	assert(name);
	event = bt_ctf_event_class_create(name);
	if (!event) {
		diag("Failed to create complex event");
		goto error;
	}

	outer = create_integer_struct();
	if (!outer) {
		diag("Failed to initialize integer structure");
		goto error;
	}

	inner = create_integer_struct();
	if (!inner) {
		diag("Failed to initialize integer structure");
		goto error;
	}

	ret = bt_ctf_field_type_structure_add_field(outer, inner,
			"payload_struct");
	if (ret) {
		diag("Failed to add inner structure to outer structure");
		goto error;
	}

	ret = bt_ctf_event_class_set_payload_type(event, outer);
	if (ret) {
		diag("Failed to set complex event payload");
		goto error;
	}
end:
	BT_PUT(inner);
	BT_PUT(outer);
	return event;
error:
	BT_PUT(event);
	goto end;;
}

static struct bt_ctf_stream_class *create_sc1(void)
{
	int ret;
	struct bt_ctf_event_class *ec1 = NULL, *ec2 = NULL;
	struct bt_ctf_stream_class *sc1 = NULL, *ret_stream = NULL;

	sc1 = bt_ctf_stream_class_create("sc1");
	if (!sc1) {
		diag("Failed to create Stream Class");
		goto error;
	}

	ec1 = create_complex_event("ec1");
	if (!ec1) {
		diag("Failed to create complex event EC1");
		goto error;
	}
	ret = bt_ctf_stream_class_add_event_class(sc1, ec1);
	if (ret) {
		diag("Failed to add EC1 to SC1");
		goto error;
	}

	ec2 = create_simple_event("ec2");
	if (!ec2) {
		diag("Failed to create simple event EC2");
		goto error;
	}
	ret = bt_ctf_stream_class_add_event_class(sc1, ec2);
	if (ret) {
		diag("Failed to add EC1 to SC1");
		goto error;
	}

	ret_stream = bt_ctf_event_class_get_stream_class(ec1);
	ok(ret_stream == sc1, "Get parent stream SC1 from EC1");
	BT_PUT(ret_stream);

	ret_stream = bt_ctf_event_class_get_stream_class(ec2);
	ok(ret_stream == sc1, "Get parent stream SC1 from EC2");
end:
	BT_PUT(ret_stream);
	BT_PUT(ec1);
	BT_PUT(ec2);
	return sc1;
error:
	BT_PUT(sc1);
	goto end;
}

static struct bt_ctf_stream_class *create_sc2(void)
{
	int ret;
	struct bt_ctf_event_class *ec3 = NULL;
	struct bt_ctf_stream_class *sc2 = NULL, *ret_stream = NULL;

	sc2 = bt_ctf_stream_class_create("sc2");
	if (!sc2) {
		diag("Failed to create Stream Class");
		goto error;
	}

	ec3 = create_simple_event("ec3");
	if (!ec3) {
		diag("Failed to create simple event EC3");
		goto error;
	}
	ret = bt_ctf_stream_class_add_event_class(sc2, ec3);
	if (ret) {
		diag("Failed to add EC3 to SC2");
		goto error;
	}

	ret_stream = bt_ctf_event_class_get_stream_class(ec3);
	ok(ret_stream == sc2, "Get parent stream SC2 from EC3");
end:
	BT_PUT(ret_stream);
	BT_PUT(ec3);
	return sc2;
error:
	BT_PUT(sc2);
	goto end;
}

static struct bt_ctf_trace *create_tc1(void)
{
	int ret;
	struct bt_ctf_trace *tc1 = NULL;
	struct bt_ctf_stream_class *sc1 = NULL, *sc2 = NULL;

	tc1 = bt_ctf_trace_create();
	if (!tc1) {
		diag("bt_ctf_trace_create returned NULL");
		goto error;
	}

	ret = bt_ctf_trace_set_native_byte_order(tc1,
		BT_CTF_BYTE_ORDER_LITTLE_ENDIAN);
	assert(ret == 0);
	sc1 = create_sc1();
	ok(sc1, "Create SC1");
	if (!sc1) {
		goto error;
	}
	ret = bt_ctf_trace_add_stream_class(tc1, sc1);
	ok(!ret, "Add SC1 to TC1");
	if (ret) {
		goto error;
	}

	sc2 = create_sc2();
	ok(sc2, "Create SC2");
	if (!sc2) {
		goto error;
	}
	ret = bt_ctf_trace_add_stream_class(tc1, sc2);
	ok(!ret, "Add SC2 to TC1");
	if (ret) {
		goto error;
	}
end:
	BT_PUT(sc1);
	BT_PUT(sc2);
	return tc1;
error:
	BT_PUT(tc1);
	goto end;
}

static void init_weak_refs(struct bt_ctf_trace *tc,
		struct bt_ctf_trace **tc1,
		struct bt_ctf_stream_class **sc1,
		struct bt_ctf_stream_class **sc2,
		struct bt_ctf_event_class **ec1,
		struct bt_ctf_event_class **ec2,
		struct bt_ctf_event_class **ec3)
{
	*tc1 = tc;
	*sc1 = bt_ctf_trace_get_stream_class_by_index(tc, 0);
	*sc2 = bt_ctf_trace_get_stream_class_by_index(tc, 1);
	*ec1 = bt_ctf_stream_class_get_event_class_by_index(*sc1, 0);
	*ec2 = bt_ctf_stream_class_get_event_class_by_index(*sc1, 1);
	*ec3 = bt_ctf_stream_class_get_event_class_by_index(*sc2, 0);
	bt_put(*sc1);
	bt_put(*sc2);
	bt_put(*ec1);
	bt_put(*ec2);
	bt_put(*ec3);
}

static void test_example_scenario(void)
{
	/**
	 * Weak pointers to CTF-IR objects are to be used very carefully.
	 * This is NOT a good practice and is strongly discouraged; this
	 * is only done to facilitate the validation of expected reference
	 * counts without affecting them by taking "real" references to the
	 * objects.
	 */
	struct bt_ctf_trace *tc1 = NULL, *weak_tc1 = NULL;
	struct bt_ctf_stream_class *weak_sc1 = NULL, *weak_sc2 = NULL;
	struct bt_ctf_event_class *weak_ec1 = NULL, *weak_ec2 = NULL,
			*weak_ec3 = NULL;
	struct user user_a = { 0 }, user_b = { 0 }, user_c = { 0 };

	/* The only reference which exists at this point is on TC1. */
	tc1 = create_tc1();
	ok(tc1, "Initialize trace");
	if (!tc1) {
		return;
	}

	init_weak_refs(tc1, &weak_tc1, &weak_sc1, &weak_sc2, &weak_ec1,
			&weak_ec2, &weak_ec3);

	ok(bt_object_get_ref_count(weak_sc1) == 0,
			"Initial SC1 reference count is 0");
	ok(bt_object_get_ref_count(weak_sc2) == 0,
			"Initial SC2 reference count is 0");
	ok(bt_object_get_ref_count(weak_ec1) == 0,
			"Initial EC1 reference count is 0");
	ok(bt_object_get_ref_count(weak_ec2) == 0,
			"Initial EC2 reference count is 0");
	ok(bt_object_get_ref_count(weak_ec3) == 0,
			"Initial EC3 reference count is 0");

	/* User A has ownership of the trace. */
	BT_MOVE(user_a.tc, tc1);
	ok(bt_object_get_ref_count(user_a.tc) == 1,
			"TC1 reference count is 1");

	/* User A acquires a reference to SC2 from TC1. */
	user_a.sc = bt_ctf_trace_get_stream_class_by_index(user_a.tc, 1);
	ok(user_a.sc, "User A acquires SC2 from TC1");
	ok(bt_object_get_ref_count(weak_tc1) == 2,
			"TC1 reference count is 2");
	ok(bt_object_get_ref_count(weak_sc2) == 1,
			"SC2 reference count is 1");

	/* User A acquires a reference to EC3 from SC2. */
	user_a.ec = bt_ctf_stream_class_get_event_class_by_index(user_a.sc, 0);
	ok(user_a.ec, "User A acquires EC3 from SC2");
	ok(bt_object_get_ref_count(weak_tc1) == 2,
			"TC1 reference count is 2");
	ok(bt_object_get_ref_count(weak_sc2) == 2,
			"SC2 reference count is 2");
	ok(bt_object_get_ref_count(weak_ec3) == 1,
			"EC3 reference count is 1");

	/* User A releases its reference to SC2. */
	diag("User A releases SC2");
	BT_PUT(user_a.sc);
	/*
	 * We keep the pointer to SC2 around to validate its reference
	 * count.
	 */
	ok(bt_object_get_ref_count(weak_tc1) == 2,
			"TC1 reference count is 2");
	ok(bt_object_get_ref_count(weak_sc2) == 1,
			"SC2 reference count is 1");
	ok(bt_object_get_ref_count(weak_ec3) == 1,
			"EC3 reference count is 1");

	/* User A releases its reference to TC1. */
	diag("User A releases TC1");
	BT_PUT(user_a.tc);
	/*
	 * We keep the pointer to TC1 around to validate its reference
	 * count.
	 */
	ok(bt_object_get_ref_count(weak_tc1) == 1,
			"TC1 reference count is 1");
	ok(bt_object_get_ref_count(weak_sc2) == 1,
			"SC2 reference count is 1");
	ok(bt_object_get_ref_count(weak_ec3) == 1,
			"EC3 reference count is 1");

	/* User B acquires a reference to SC1. */
	diag("User B acquires a reference to SC1");
	user_b.sc = bt_get(weak_sc1);
	ok(bt_object_get_ref_count(weak_tc1) == 2,
			"TC1 reference count is 2");
	ok(bt_object_get_ref_count(weak_sc1) == 1,
			"SC1 reference count is 1");

	/* User C acquires a reference to EC1. */
	diag("User C acquires a reference to EC1");
	user_c.ec = bt_ctf_stream_class_get_event_class_by_index(user_b.sc, 0);
	ok(bt_object_get_ref_count(weak_ec1) == 1,
			"EC1 reference count is 1");
	ok(bt_object_get_ref_count(weak_sc1) == 2,
			"SC1 reference count is 2");

	/* User A releases its reference on EC3. */
	diag("User A releases its reference on EC3");
	BT_PUT(user_a.ec);
	ok(bt_object_get_ref_count(weak_ec3) == 0,
			"EC3 reference count is 1");
	ok(bt_object_get_ref_count(weak_sc2) == 0,
			"SC2 reference count is 0");
	ok(bt_object_get_ref_count(weak_tc1) == 1,
			"TC1 reference count is 1");

	/* User B releases its reference on SC1. */
	diag("User B releases its reference on SC1");
	BT_PUT(user_b.sc);
	ok(bt_object_get_ref_count(weak_sc1) == 1,
			"SC1 reference count is 1");

	/*
	 * User C is the sole owner of an object and is keeping the whole
	 * trace hierarchy "alive" by holding a reference to EC1.
	 */
	ok(bt_object_get_ref_count(weak_tc1) == 1,
			"TC1 reference count is 1");
	ok(bt_object_get_ref_count(weak_sc1) == 1,
			"SC1 reference count is 1");
	ok(bt_object_get_ref_count(weak_sc2) == 0,
			"SC2 reference count is 0");
	ok(bt_object_get_ref_count(weak_ec1) == 1,
			"EC1 reference count is 1");
	ok(bt_object_get_ref_count(weak_ec2) == 0,
			"EC2 reference count is 0");
	ok(bt_object_get_ref_count(weak_ec3) == 0,
			"EC3 reference count is 0");

	/* Reclaim last reference held by User C. */
	BT_PUT(user_c.ec);
}

static void create_user_full(struct user *user)
{
	char trace_path[] = "/tmp/ctfwriter_XXXXXX";
	struct bt_ctf_field_type *ft;
	struct bt_ctf_field *field;
	struct bt_ctf_clock *clock;
	int ret;

	if (!bt_mkdtemp(trace_path)) {
		perror("# perror");
	}

	user->writer = bt_ctf_writer_create(trace_path);
	assert(user->writer);
	ret = bt_ctf_writer_set_byte_order(user->writer,
		BT_CTF_BYTE_ORDER_LITTLE_ENDIAN);
	assert(ret == 0);
	user->tc = bt_ctf_writer_get_trace(user->writer);
	assert(user->tc);
	user->sc = bt_ctf_stream_class_create("sc");
	assert(user->sc);
	clock = bt_ctf_clock_create("the_clock");
	assert(clock);
	ret = bt_ctf_writer_add_clock(user->writer, clock);
	assert(!ret);
	ret = bt_ctf_stream_class_set_clock(user->sc, clock);
	assert(!ret);
	BT_PUT(clock);
	user->stream = bt_ctf_writer_create_stream(user->writer, user->sc);
	assert(user->stream);
	user->ec = bt_ctf_event_class_create("ec");
	assert(user->ec);
	ft = create_integer_struct();
	assert(ft);
	ret = bt_ctf_event_class_set_payload_type(user->ec, ft);
	BT_PUT(ft);
	assert(!ret);
	ret = bt_ctf_stream_class_add_event_class(user->sc, user->ec);
	assert(!ret);
	user->event = bt_ctf_event_create(user->ec);
	assert(user->event);
	field = bt_ctf_event_get_payload(user->event, "payload_8");
	assert(field);
	ret = bt_ctf_field_unsigned_integer_set_value(field, 10);
	assert(!ret);
	BT_PUT(field);
	field = bt_ctf_event_get_payload(user->event, "payload_16");
	assert(field);
	ret = bt_ctf_field_unsigned_integer_set_value(field, 20);
	assert(!ret);
	BT_PUT(field);
	field = bt_ctf_event_get_payload(user->event, "payload_32");
	assert(field);
	ret = bt_ctf_field_unsigned_integer_set_value(field, 30);
	assert(!ret);
	BT_PUT(field);
	ret = bt_ctf_stream_append_event(user->stream, user->event);
	assert(!ret);
	recursive_rmdir(trace_path);
}

static void test_put_order_swap(size_t *array, size_t a, size_t b)
{
	size_t temp = array[a];

	array[a] = array[b];
	array[b] = temp;
}

static void test_put_order_put_objects(size_t *array, size_t size)
{
	size_t i;
	struct user user = { 0 };
	void **objects = (void *) &user;

	create_user_full(&user);
	printf("# ");

	for (i = 0; i < size; ++i) {
		void *obj = objects[array[i]];

		printf("%s", user_names[array[i]]);
		BT_PUT(obj);

		if (i < size - 1) {
			printf(" -> ");
		}
	}

	puts("");
}

static void test_put_order_permute(size_t *array, int k, size_t size)
{
	if (k == 0) {
		test_put_order_put_objects(array, size);
	} else {
		int i;

		for (i = k - 1; i >= 0; i--) {
			size_t next_k = k - 1;

			test_put_order_swap(array, i, next_k);
			test_put_order_permute(array, next_k, size);
			test_put_order_swap(array, i, next_k);
		}
	}
}

static void test_put_order(void)
{
	size_t i;
	size_t array[USER_NR_ELEMENTS];

	/* Initialize array of indexes */
	for (i = 0; i < USER_NR_ELEMENTS; ++i) {
		array[i] = i;
	}

	test_put_order_permute(array, USER_NR_ELEMENTS, USER_NR_ELEMENTS);
}

/**
 * The objective of this test is to implement and expand upon the scenario
 * described in the reference counting documentation and ensure that any node of
 * the Trace, Stream Class, Event Class, Stream and Event hiearchy keeps all
 * other "alive" and reachable.
 *
 * External tools (e.g. valgrind) should be used to confirm that this
 * known-good test does not leak memory.
 */
int main(int argc, char **argv)
{
	/* Initialize tap harness before any tests */
	plan_tests(NR_TESTS);

	test_example_scenario();
	test_put_order();

	return exit_status();
}
Commit	Line	Data
c9b3f44b JG	1	/*
	2	* test_ctf_ir_ref.c
	3	*
	4	* CTF IR Reference Count test
	5	*
	6	* Copyright 2016 - Jérémie Galarneau <jeremie.galarneau@efficios.com>
	7	*
	8	* This program is free software; you can redistribute it and/or modify
	9	* it under the terms of the GNU General Public License as published by
	10	* the Free Software Foundation; under version 2 of the License.
	11	*
	12	* This program is distributed in the hope that it will be useful,
	13	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	14	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	15	* GNU General Public License for more details.
	16	*
	17	* You should have received a copy of the GNU General Public License along
	18	* with this program; if not, write to the Free Software Foundation, Inc.,
	19	* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
	20	*/
	21
	22	#include "tap/tap.h"
6271743c PP	23	#include <babeltrace/ctf-writer/writer.h>
	24	#include <babeltrace/ctf-writer/stream.h>
	25	#include <babeltrace/ctf-writer/clock.h>
c9b3f44b	26	#include <babeltrace/ctf-ir/trace.h>
6271743c	27	#include <babeltrace/ctf-writer/stream-class.h>
c9b3f44b	28	#include <babeltrace/ctf-ir/stream.h>
6271743c	29	#include <babeltrace/ctf-ir/fields.h>
c9b3f44b	30	#include <babeltrace/ctf-ir/event.h>
272df73e	31	#include <babeltrace/ctf-ir/event-class.h>
c9b3f44b	32	#include <babeltrace/object-internal.h>
3d9990ac	33	#include <babeltrace/compat/stdlib-internal.h>
c9b3f44b	34	#include <assert.h>
851299b9	35	#include "common.h"
c9b3f44b	36
8bbe269d MJ	37	#define NR_TESTS 41
8bbe269d MJ	38
c9b3f44b	39	struct user {
6271743c	40	struct bt_ctf_writer *writer;
c9b3f44b JG	41	struct bt_ctf_trace *tc;
	42	struct bt_ctf_stream_class *sc;
	43	struct bt_ctf_event_class *ec;
6271743c PP	44	struct bt_ctf_stream *stream;
6271743c PP	45	struct bt_ctf_event *event;
c9b3f44b JG	46	};
c9b3f44b JG	47
6271743c PP	48	const char *user_names[] = {
	49	"writer",
	50	"trace",
	51	"stream class",
	52	"event class",
	53	"stream",
	54	"event",
	55	};
	56
	57	static const size_t USER_NR_ELEMENTS = sizeof(struct user) / sizeof(void *);
	58
c9b3f44b JG	59	/**
	60	* Returns a structure containing the following fields:
	61	* - uint8_t payload_8;
	62	* - uint16_t payload_16;
	63	* - uint32_t payload_32;
	64	*/
	65	static struct bt_ctf_field_type *create_integer_struct(void)
	66	{
	67	int ret;
	68	struct bt_ctf_field_type *structure = NULL;
	69	struct bt_ctf_field_type ui8 = NULL, ui16 = NULL, *ui32 = NULL;
	70
	71	structure = bt_ctf_field_type_structure_create();
	72	if (!structure) {
	73	goto error;
	74	}
	75
	76	ui8 = bt_ctf_field_type_integer_create(8);
	77	if (!ui8) {
	78	diag("Failed to create uint8_t type");
	79	goto error;
	80	}
	81	ret = bt_ctf_field_type_structure_add_field(structure, ui8,
	82	"payload_8");
	83	if (ret) {
	84	diag("Failed to add uint8_t to structure");
	85	goto error;
	86	}
	87	ui16 = bt_ctf_field_type_integer_create(16);
	88	if (!ui16) {
	89	diag("Failed to create uint16_t type");
	90	goto error;
	91	}
	92	ret = bt_ctf_field_type_structure_add_field(structure, ui16,
	93	"payload_16");
	94	if (ret) {
	95	diag("Failed to add uint16_t to structure");
	96	goto error;
	97	}
	98	ui32 = bt_ctf_field_type_integer_create(32);
	99	if (!ui32) {
	100	diag("Failed to create uint32_t type");
	101	goto error;
	102	}
	103	ret = bt_ctf_field_type_structure_add_field(structure, ui32,
	104	"payload_32");
	105	if (ret) {
	106	diag("Failed to add uint32_t to structure");
	107	goto error;
	108	}
	109	end:
	110	BT_PUT(ui8);
	111	BT_PUT(ui16);
	112	BT_PUT(ui32);
	113	return structure;
	114	error:
	115	BT_PUT(structure);
	116	goto end;
	117	}
	118
	119	/**
	120	* A simple event has the following payload:
	121	* - uint8_t payload_8;
	122	* - uint16_t payload_16;
123	* - uint32_t payload_32;
124	*/
125	static struct bt_ctf_event_class create_simple_event(const char name)
126	{
127	int ret;
128	struct bt_ctf_event_class *event = NULL;
129	struct bt_ctf_field_type *payload = NULL;
130
27f4d205	131	assert(name);
c9b3f44b JG	132	event = bt_ctf_event_class_create(name);
	133	if (!event) {
	134	diag("Failed to create simple event");
	135	goto error;
	136	}
	137
	138	payload = create_integer_struct();
	139	if (!payload) {
	140	diag("Failed to initialize integer structure");
	141	goto error;
	142	}
	143
	144	ret = bt_ctf_event_class_set_payload_type(event, payload);
	145	if (ret) {
	146	diag("Failed to set simple event payload");
	147	goto error;
	148	}
	149	end:
	150	BT_PUT(payload);
	151	return event;
	152	error:
	153	BT_PUT(event);
	154	goto end;;
	155	}
	156
	157	/**
	158	* A complex event has the following payload:
	159	* - uint8_t payload_8;
	160	* - uint16_t payload_16;
	161	* - uint32_t payload_32;
	162	* - struct payload_struct:
	163	* - uint8_t payload_8;
	164	* - uint16_t payload_16;
	165	* - uint32_t payload_32;
	166	*/
	167	static struct bt_ctf_event_class create_complex_event(const char name)
	168	{
	169	int ret;
	170	struct bt_ctf_event_class *event = NULL;
	171	struct bt_ctf_field_type inner = NULL, outer = NULL;
	172
27f4d205	173	assert(name);
c9b3f44b JG	174	event = bt_ctf_event_class_create(name);
	175	if (!event) {
	176	diag("Failed to create complex event");
	177	goto error;
	178	}
	179
27f4d205	180	outer = create_integer_struct();
c9b3f44b JG	181	if (!outer) {
	182	diag("Failed to initialize integer structure");
	183	goto error;
	184	}
	185
27f4d205	186	inner = create_integer_struct();
c9b3f44b JG	187	if (!inner) {
	188	diag("Failed to initialize integer structure");
	189	goto error;
	190	}
	191
	192	ret = bt_ctf_field_type_structure_add_field(outer, inner,
27f4d205	193	"payload_struct");
c9b3f44b JG	194	if (ret) {
	195	diag("Failed to add inner structure to outer structure");
	196	goto error;
	197	}
	198
	199	ret = bt_ctf_event_class_set_payload_type(event, outer);
	200	if (ret) {
	201	diag("Failed to set complex event payload");
	202	goto error;
	203	}
	204	end:
	205	BT_PUT(inner);
	206	BT_PUT(outer);
	207	return event;
	208	error:
	209	BT_PUT(event);
	210	goto end;;
	211	}
	212
	213	static struct bt_ctf_stream_class *create_sc1(void)
	214	{
	215	int ret;
	216	struct bt_ctf_event_class ec1 = NULL, ec2 = NULL;
	217	struct bt_ctf_stream_class sc1 = NULL, ret_stream = NULL;
	218
	219	sc1 = bt_ctf_stream_class_create("sc1");
	220	if (!sc1) {
	221	diag("Failed to create Stream Class");
	222	goto error;
	223	}
	224
	225	ec1 = create_complex_event("ec1");
	226	if (!ec1) {
	227	diag("Failed to create complex event EC1");
	228	goto error;
	229	}
	230	ret = bt_ctf_stream_class_add_event_class(sc1, ec1);
	231	if (ret) {
	232	diag("Failed to add EC1 to SC1");
	233	goto error;
	234	}
	235
	236	ec2 = create_simple_event("ec2");
	237	if (!ec2) {
	238	diag("Failed to create simple event EC2");
	239	goto error;
	240	}
	241	ret = bt_ctf_stream_class_add_event_class(sc1, ec2);
	242	if (ret) {
	243	diag("Failed to add EC1 to SC1");
	244	goto error;
	245	}
	246
	247	ret_stream = bt_ctf_event_class_get_stream_class(ec1);
	248	ok(ret_stream == sc1, "Get parent stream SC1 from EC1");
	249	BT_PUT(ret_stream);
	250
	251	ret_stream = bt_ctf_event_class_get_stream_class(ec2);
	252	ok(ret_stream == sc1, "Get parent stream SC1 from EC2");
	253	end:
	254	BT_PUT(ret_stream);
	255	BT_PUT(ec1);
	256	BT_PUT(ec2);
	257	return sc1;
258	error:
259	BT_PUT(sc1);
27f4d205	260	goto end;
c9b3f44b JG	261	}
	262
	263	static struct bt_ctf_stream_class *create_sc2(void)
	264	{
	265	int ret;
	266	struct bt_ctf_event_class *ec3 = NULL;
	267	struct bt_ctf_stream_class sc2 = NULL, ret_stream = NULL;
	268
	269	sc2 = bt_ctf_stream_class_create("sc2");
	270	if (!sc2) {
	271	diag("Failed to create Stream Class");
	272	goto error;
	273	}
	274
	275	ec3 = create_simple_event("ec3");
	276	if (!ec3) {
	277	diag("Failed to create simple event EC3");
	278	goto error;
	279	}
	280	ret = bt_ctf_stream_class_add_event_class(sc2, ec3);
	281	if (ret) {
	282	diag("Failed to add EC3 to SC2");
	283	goto error;
	284	}
	285
	286	ret_stream = bt_ctf_event_class_get_stream_class(ec3);
	287	ok(ret_stream == sc2, "Get parent stream SC2 from EC3");
	288	end:
	289	BT_PUT(ret_stream);
	290	BT_PUT(ec3);
	291	return sc2;
	292	error:
	293	BT_PUT(sc2);
27f4d205	294	goto end;
c9b3f44b JG	295	}
	296
	297	static struct bt_ctf_trace *create_tc1(void)
	298	{
	299	int ret;
	300	struct bt_ctf_trace *tc1 = NULL;
	301	struct bt_ctf_stream_class sc1 = NULL, sc2 = NULL;
	302
27f4d205	303	tc1 = bt_ctf_trace_create();
c9b3f44b JG	304	if (!tc1) {
	305	diag("bt_ctf_trace_create returned NULL");
	306	goto error;
	307	}
	308
d490fcbe PP	309	ret = bt_ctf_trace_set_native_byte_order(tc1,
	310	BT_CTF_BYTE_ORDER_LITTLE_ENDIAN);
	311	assert(ret == 0);
c9b3f44b JG	312	sc1 = create_sc1();
	313	ok(sc1, "Create SC1");
	314	if (!sc1) {
	315	goto error;
	316	}
	317	ret = bt_ctf_trace_add_stream_class(tc1, sc1);
	318	ok(!ret, "Add SC1 to TC1");
	319	if (ret) {
	320	goto error;
	321	}
	322
	323	sc2 = create_sc2();
	324	ok(sc2, "Create SC2");
	325	if (!sc2) {
	326	goto error;
	327	}
	328	ret = bt_ctf_trace_add_stream_class(tc1, sc2);
	329	ok(!ret, "Add SC2 to TC1");
	330	if (ret) {
	331	goto error;
	332	}
	333	end:
	334	BT_PUT(sc1);
	335	BT_PUT(sc2);
	336	return tc1;
	337	error:
	338	BT_PUT(tc1);
27f4d205	339	goto end;
c9b3f44b JG	340	}
	341
	342	static void init_weak_refs(struct bt_ctf_trace *tc,
	343	struct bt_ctf_trace **tc1,
	344	struct bt_ctf_stream_class **sc1,
	345	struct bt_ctf_stream_class **sc2,
	346	struct bt_ctf_event_class **ec1,
	347	struct bt_ctf_event_class **ec2,
	348	struct bt_ctf_event_class **ec3)
	349	{
	350	*tc1 = tc;
9ac68eb1 PP	351	*sc1 = bt_ctf_trace_get_stream_class_by_index(tc, 0);
	352	*sc2 = bt_ctf_trace_get_stream_class_by_index(tc, 1);
	353	ec1 = bt_ctf_stream_class_get_event_class_by_index(sc1, 0);
	354	ec2 = bt_ctf_stream_class_get_event_class_by_index(sc1, 1);
	355	ec3 = bt_ctf_stream_class_get_event_class_by_index(sc2, 0);
c9b3f44b JG	356	bt_put(*sc1);
	357	bt_put(*sc2);
	358	bt_put(*ec1);
	359	bt_put(*ec2);
	360	bt_put(*ec3);
	361	}
	362
6271743c	363	static void test_example_scenario(void)
c9b3f44b JG	364	{
	365	/**
	366	* Weak pointers to CTF-IR objects are to be used very carefully.
	367	* This is NOT a good practice and is strongly discouraged; this
	368	* is only done to facilitate the validation of expected reference
	369	* counts without affecting them by taking "real" references to the
	370	* objects.
	371	*/
	372	struct bt_ctf_trace tc1 = NULL, weak_tc1 = NULL;
	373	struct bt_ctf_stream_class weak_sc1 = NULL, weak_sc2 = NULL;
	374	struct bt_ctf_event_class weak_ec1 = NULL, weak_ec2 = NULL,
	375	*weak_ec3 = NULL;
	376	struct user user_a = { 0 }, user_b = { 0 }, user_c = { 0 };
	377
	378	/* The only reference which exists at this point is on TC1. */
	379	tc1 = create_tc1();
27f4d205	380	ok(tc1, "Initialize trace");
c9b3f44b	381	if (!tc1) {
6271743c	382	return;
c9b3f44b JG	383	}
	384
	385	init_weak_refs(tc1, &weak_tc1, &weak_sc1, &weak_sc2, &weak_ec1,
	386	&weak_ec2, &weak_ec3);
c9b3f44b JG	387
	388	ok(bt_object_get_ref_count(weak_sc1) == 0,
	389	"Initial SC1 reference count is 0");
	390	ok(bt_object_get_ref_count(weak_sc2) == 0,
	391	"Initial SC2 reference count is 0");
	392	ok(bt_object_get_ref_count(weak_ec1) == 0,
	393	"Initial EC1 reference count is 0");
	394	ok(bt_object_get_ref_count(weak_ec2) == 0,
	395	"Initial EC2 reference count is 0");
	396	ok(bt_object_get_ref_count(weak_ec3) == 0,
	397	"Initial EC3 reference count is 0");
	398
	399	/* User A has ownership of the trace. */
	400	BT_MOVE(user_a.tc, tc1);
	401	ok(bt_object_get_ref_count(user_a.tc) == 1,
	402	"TC1 reference count is 1");
	403
	404	/* User A acquires a reference to SC2 from TC1. */
9ac68eb1	405	user_a.sc = bt_ctf_trace_get_stream_class_by_index(user_a.tc, 1);
c9b3f44b JG	406	ok(user_a.sc, "User A acquires SC2 from TC1");
	407	ok(bt_object_get_ref_count(weak_tc1) == 2,
	408	"TC1 reference count is 2");
	409	ok(bt_object_get_ref_count(weak_sc2) == 1,
	410	"SC2 reference count is 1");
	411
	412	/* User A acquires a reference to EC3 from SC2. */
9ac68eb1	413	user_a.ec = bt_ctf_stream_class_get_event_class_by_index(user_a.sc, 0);
c9b3f44b JG	414	ok(user_a.ec, "User A acquires EC3 from SC2");
	415	ok(bt_object_get_ref_count(weak_tc1) == 2,
	416	"TC1 reference count is 2");
	417	ok(bt_object_get_ref_count(weak_sc2) == 2,
	418	"SC2 reference count is 2");
	419	ok(bt_object_get_ref_count(weak_ec3) == 1,
	420	"EC3 reference count is 1");
	421
	422	/* User A releases its reference to SC2. */
	423	diag("User A releases SC2");
	424	BT_PUT(user_a.sc);
	425	/*
	426	* We keep the pointer to SC2 around to validate its reference
	427	* count.
	428	*/
	429	ok(bt_object_get_ref_count(weak_tc1) == 2,
	430	"TC1 reference count is 2");
	431	ok(bt_object_get_ref_count(weak_sc2) == 1,
	432	"SC2 reference count is 1");
	433	ok(bt_object_get_ref_count(weak_ec3) == 1,
	434	"EC3 reference count is 1");
	435
	436	/* User A releases its reference to TC1. */
	437	diag("User A releases TC1");
27f4d205	438	BT_PUT(user_a.tc);
c9b3f44b JG	439	/*
	440	* We keep the pointer to TC1 around to validate its reference
	441	* count.
	442	*/
	443	ok(bt_object_get_ref_count(weak_tc1) == 1,
	444	"TC1 reference count is 1");
	445	ok(bt_object_get_ref_count(weak_sc2) == 1,
	446	"SC2 reference count is 1");
	447	ok(bt_object_get_ref_count(weak_ec3) == 1,
	448	"EC3 reference count is 1");
	449
	450	/* User B acquires a reference to SC1. */
	451	diag("User B acquires a reference to SC1");
	452	user_b.sc = bt_get(weak_sc1);
	453	ok(bt_object_get_ref_count(weak_tc1) == 2,
	454	"TC1 reference count is 2");
	455	ok(bt_object_get_ref_count(weak_sc1) == 1,
	456	"SC1 reference count is 1");
	457
	458	/* User C acquires a reference to EC1. */
	459	diag("User C acquires a reference to EC1");
9ac68eb1	460	user_c.ec = bt_ctf_stream_class_get_event_class_by_index(user_b.sc, 0);
c9b3f44b JG	461	ok(bt_object_get_ref_count(weak_ec1) == 1,
	462	"EC1 reference count is 1");
	463	ok(bt_object_get_ref_count(weak_sc1) == 2,
	464	"SC1 reference count is 2");
	465
	466	/* User A releases its reference on EC3. */
	467	diag("User A releases its reference on EC3");
	468	BT_PUT(user_a.ec);
	469	ok(bt_object_get_ref_count(weak_ec3) == 0,
	470	"EC3 reference count is 1");
	471	ok(bt_object_get_ref_count(weak_sc2) == 0,
	472	"SC2 reference count is 0");
	473	ok(bt_object_get_ref_count(weak_tc1) == 1,
	474	"TC1 reference count is 1");
	475
	476	/* User B releases its reference on SC1. */
	477	diag("User B releases its reference on SC1");
	478	BT_PUT(user_b.sc);
	479	ok(bt_object_get_ref_count(weak_sc1) == 1,
	480	"SC1 reference count is 1");
	481
	482	/*
	483	* User C is the sole owner of an object and is keeping the whole
	484	* trace hierarchy "alive" by holding a reference to EC1.
	485	*/
	486	ok(bt_object_get_ref_count(weak_tc1) == 1,
	487	"TC1 reference count is 1");
	488	ok(bt_object_get_ref_count(weak_sc1) == 1,
	489	"SC1 reference count is 1");
	490	ok(bt_object_get_ref_count(weak_sc2) == 0,
	491	"SC2 reference count is 0");
	492	ok(bt_object_get_ref_count(weak_ec1) == 1,
	493	"EC1 reference count is 1");
	494	ok(bt_object_get_ref_count(weak_ec2) == 0,
	495	"EC2 reference count is 0");
	496	ok(bt_object_get_ref_count(weak_ec3) == 0,
	497	"EC3 reference count is 0");
	498
	499	/* Reclaim last reference held by User C. */
	500	BT_PUT(user_c.ec);
6271743c PP	501	}
	502
	503	static void create_user_full(struct user *user)
	504	{
	505	char trace_path[] = "/tmp/ctfwriter_XXXXXX";
	506	struct bt_ctf_field_type *ft;
	507	struct bt_ctf_field *field;
	508	struct bt_ctf_clock *clock;
	509	int ret;
	510
	511	if (!bt_mkdtemp(trace_path)) {
	512	perror("# perror");
	513	}
	514
	515	user->writer = bt_ctf_writer_create(trace_path);
	516	assert(user->writer);
dc3fffef PP	517	ret = bt_ctf_writer_set_byte_order(user->writer,
	518	BT_CTF_BYTE_ORDER_LITTLE_ENDIAN);
	519	assert(ret == 0);
6271743c PP	520	user->tc = bt_ctf_writer_get_trace(user->writer);
	521	assert(user->tc);
	522	user->sc = bt_ctf_stream_class_create("sc");
	523	assert(user->sc);
	524	clock = bt_ctf_clock_create("the_clock");
	525	assert(clock);
81582b6b JG	526	ret = bt_ctf_writer_add_clock(user->writer, clock);
81582b6b JG	527	assert(!ret);
6271743c PP	528	ret = bt_ctf_stream_class_set_clock(user->sc, clock);
6271743c PP	529	assert(!ret);
dc3fffef	530	BT_PUT(clock);
6271743c PP	531	user->stream = bt_ctf_writer_create_stream(user->writer, user->sc);
	532	assert(user->stream);
	533	user->ec = bt_ctf_event_class_create("ec");
	534	assert(user->ec);
	535	ft = create_integer_struct();
	536	assert(ft);
	537	ret = bt_ctf_event_class_set_payload_type(user->ec, ft);
	538	BT_PUT(ft);
	539	assert(!ret);
	540	ret = bt_ctf_stream_class_add_event_class(user->sc, user->ec);
	541	assert(!ret);
	542	user->event = bt_ctf_event_create(user->ec);
	543	assert(user->event);
	544	field = bt_ctf_event_get_payload(user->event, "payload_8");
	545	assert(field);
	546	ret = bt_ctf_field_unsigned_integer_set_value(field, 10);
	547	assert(!ret);
	548	BT_PUT(field);
	549	field = bt_ctf_event_get_payload(user->event, "payload_16");
	550	assert(field);
	551	ret = bt_ctf_field_unsigned_integer_set_value(field, 20);
	552	assert(!ret);
	553	BT_PUT(field);
	554	field = bt_ctf_event_get_payload(user->event, "payload_32");
	555	assert(field);
	556	ret = bt_ctf_field_unsigned_integer_set_value(field, 30);
	557	assert(!ret);
	558	BT_PUT(field);
	559	ret = bt_ctf_stream_append_event(user->stream, user->event);
	560	assert(!ret);
851299b9	561	recursive_rmdir(trace_path);
6271743c PP	562	}
	563
	564	static void test_put_order_swap(size_t *array, size_t a, size_t b)
	565	{
	566	size_t temp = array[a];
	567
	568	array[a] = array[b];
	569	array[b] = temp;
	570	}
	571
	572	static void test_put_order_put_objects(size_t *array, size_t size)
	573	{
	574	size_t i;
	575	struct user user = { 0 };
6f2097e2	576	void *objects = (void ) &user;
6271743c PP	577
	578	create_user_full(&user);
	579	printf("# ");
	580
	581	for (i = 0; i < size; ++i) {
6f2097e2	582	void *obj = objects[array[i]];
6271743c PP	583
	584	printf("%s", user_names[array[i]]);
	585	BT_PUT(obj);
	586
	587	if (i < size - 1) {
	588	printf(" -> ");
	589	}
	590	}
	591
	592	puts("");
	593	}
	594
	595	static void test_put_order_permute(size_t *array, int k, size_t size)
	596	{
	597	if (k == 0) {
	598	test_put_order_put_objects(array, size);
	599	} else {
	600	int i;
	601
	602	for (i = k - 1; i >= 0; i--) {
	603	size_t next_k = k - 1;
	604
	605	test_put_order_swap(array, i, next_k);
	606	test_put_order_permute(array, next_k, size);
	607	test_put_order_swap(array, i, next_k);
	608	}
	609	}
	610	}
	611
	612	static void test_put_order(void)
	613	{
	614	size_t i;
	615	size_t array[USER_NR_ELEMENTS];
	616
	617	/* Initialize array of indexes */
	618	for (i = 0; i < USER_NR_ELEMENTS; ++i) {
	619	array[i] = i;
	620	}
	621
	622	test_put_order_permute(array, USER_NR_ELEMENTS, USER_NR_ELEMENTS);
	623	}
	624
	625	/**
	626	* The objective of this test is to implement and expand upon the scenario
	627	* described in the reference counting documentation and ensure that any node of
	628	* the Trace, Stream Class, Event Class, Stream and Event hiearchy keeps all
	629	* other "alive" and reachable.
	630	*
	631	* External tools (e.g. valgrind) should be used to confirm that this
	632	* known-good test does not leak memory.
	633	*/
	634	int main(int argc, char **argv)
	635	{
27f4d205	636	/* Initialize tap harness before any tests */
6271743c PP	637	plan_tests(NR_TESTS);
	638
	639	test_example_scenario();
	640	test_put_order();
	641
c9b3f44b JG	642	return exit_status();
c9b3f44b JG	643	}