[urcu.git] / urcu.c

/*
 * urcu.c
 *
 * Userspace RCU library
 *
 * Copyright February 2009 - Mathieu Desnoyers <mathieu.desnoyers@polymtl.ca>
 *
 * Distributed under GPLv2
 */

#include <stdio.h>
#include <pthread.h>
#include <signal.h>
#include <assert.h>
#include <stdlib.h>
#include <string.h>

#include "urcu.h"

pthread_mutex_t urcu_mutex = PTHREAD_MUTEX_INITIALIZER;

/* Global quiescent period parity */
int urcu_qparity;

int __thread urcu_active_readers[2];

/* Thread IDs of registered readers */
#define INIT_NUM_THREADS 4

struct reader_data {
	pthread_t tid;
	int *urcu_active_readers;
};

#ifdef DEBUG_YIELD
unsigned int yield_active;
unsigned int __thread rand_yield;
#endif

static struct reader_data *reader_data;
static int num_readers, alloc_readers;
static int sig_done;

void internal_urcu_lock(void)
{
	int ret;
	ret = pthread_mutex_lock(&urcu_mutex);
	if (ret) {
		perror("Error in pthread mutex lock");
		exit(-1);
	}
}

void internal_urcu_unlock(void)
{
	int ret;

	ret = pthread_mutex_unlock(&urcu_mutex);
	if (ret) {
		perror("Error in pthread mutex unlock");
		exit(-1);
	}
}

/*
 * called with urcu_mutex held.
 */
static int switch_next_urcu_qparity(void)
{
	int old_parity = urcu_qparity;
	urcu_qparity = 1 - old_parity;
	return old_parity;
}

static void force_mb_all_threads(void)
{
	struct reader_data *index;
	/*
	 * Ask for each threads to execute a mb() so we can consider the
	 * compiler barriers around rcu read lock as real memory barriers.
	 */
	if (!reader_data)
		return;
	debug_yield_write();
	sig_done = 0;
	debug_yield_write();
	mb();	/* write sig_done before sending the signals */
	debug_yield_write();
	for (index = reader_data; index < reader_data + num_readers; index++) {
		pthread_kill(index->tid, SIGURCU);
		debug_yield_write();
	}
	/*
	 * Wait for sighandler (and thus mb()) to execute on every thread.
	 * BUSY-LOOP.
	 */
	while (sig_done < num_readers)
		barrier();
	debug_yield_write();
	mb();	/* read sig_done before ending the barrier */
	debug_yield_write();
}

void wait_for_quiescent_state(int parity)
{
	struct reader_data *index;

	if (!reader_data)
		return;
	/* Wait for each thread urcu_active_readers count to become 0.
	 */
	for (index = reader_data; index < reader_data + num_readers; index++) {
		/*
		 * BUSY-LOOP.
		 */
		while (index->urcu_active_readers[parity] != 0)
			barrier();
	}
	/*
	 * Locally : read *index->urcu_active_readers before freeing old
	 * pointer.
	 * Remote (reader threads) : Order urcu_qparity update and other
	 * thread's quiescent state counter read.
	 */
	force_mb_all_threads();
}

static void switch_qparity(void)
{
	int prev_parity;

	/* All threads should read qparity before accessing data structure. */
	/* Write ptr before changing the qparity */
	force_mb_all_threads();
	debug_yield_write();
	prev_parity = switch_next_urcu_qparity();
	debug_yield_write();

	/*
	 * Wait for previous parity to be empty of readers.
	 */
	wait_for_quiescent_state(prev_parity);
}

void synchronize_rcu(void)
{
	debug_yield_write();
	internal_urcu_lock();
	debug_yield_write();
	switch_qparity();
	debug_yield_write();
	switch_qparity();
	debug_yield_write();
	internal_urcu_lock();
	debug_yield_write();
}

/*
 * Return old pointer, OK to free, no more reference exist.
 * Called under rcu_write_lock.
 */
void *urcu_publish_content(void **ptr, void *new)
{
	void *oldptr;

	debug_yield_write();
	internal_urcu_lock();
	debug_yield_write();
	/*
	 * We can publish the new pointer before we change the current qparity.
	 * Readers seeing the new pointer while being in the previous qparity
	 * window will make us wait until the end of the quiescent state before
	 * we release the unrelated memory area. However, given we hold the
	 * urcu_mutex, we are making sure that no further garbage collection can
	 * occur until we release the mutex, therefore we guarantee that this
	 * given reader will have completed its execution using the new pointer
	 * when the next quiescent state window will be over.
	 */
	oldptr = *ptr;
	debug_yield_write();
	*ptr = new;

	debug_yield_write();
	switch_qparity();
	debug_yield_write();
	switch_qparity();
	debug_yield_write();
	internal_urcu_unlock();
	debug_yield_write();

	return oldptr;
}

void urcu_add_reader(pthread_t id)
{
	struct reader_data *oldarray;

	if (!reader_data) {
		alloc_readers = INIT_NUM_THREADS;
		num_readers = 0;
		reader_data =
			malloc(sizeof(struct reader_data) * alloc_readers);
	}
	if (alloc_readers < num_readers + 1) {
		oldarray = reader_data;
		reader_data = malloc(sizeof(struct reader_data)
				* (alloc_readers << 1));
		memcpy(reader_data, oldarray,
			sizeof(struct reader_data) * alloc_readers);
		alloc_readers <<= 1;
		free(oldarray);
	}
	reader_data[num_readers].tid = id;
	/* reference to the TLS of _this_ reader thread. */
	reader_data[num_readers].urcu_active_readers = urcu_active_readers;
	num_readers++;
}

/*
 * Never shrink (implementation limitation).
 * This is O(nb threads). Eventually use a hash table.
 */
void urcu_remove_reader(pthread_t id)
{
	struct reader_data *index;

	assert(reader_data != NULL);
	for (index = reader_data; index < reader_data + num_readers; index++) {
		if (pthread_equal(index->tid, id)) {
			memcpy(index, &reader_data[num_readers - 1],
				sizeof(struct reader_data));
			reader_data[num_readers - 1].tid = 0;
			reader_data[num_readers - 1].urcu_active_readers = NULL;
			num_readers--;
			return;
		}
	}
	/* Hrm not found, forgot to register ? */
	assert(0);
}

void urcu_register_thread(void)
{
	internal_urcu_lock();
	urcu_add_reader(pthread_self());
	internal_urcu_unlock();
}

void urcu_unregister_thread(void)
{
	internal_urcu_lock();
	urcu_remove_reader(pthread_self());
	internal_urcu_unlock();
}

void sigurcu_handler(int signo, siginfo_t *siginfo, void *context)
{
	mb();
	atomic_inc(&sig_done);
}

void __attribute__((constructor)) urcu_init(void)
{
	struct sigaction act;
	int ret;

	act.sa_sigaction = sigurcu_handler;
	ret = sigaction(SIGURCU, &act, NULL);
	if (ret) {
		perror("Error in sigaction");
		exit(-1);
	}
}

void __attribute__((destructor)) urcu_exit(void)
{
	struct sigaction act;
	int ret;

	ret = sigaction(SIGURCU, NULL, &act);
	if (ret) {
		perror("Error in sigaction");
		exit(-1);
	}
	assert(act.sa_sigaction == sigurcu_handler);
	free(reader_data);
}
Commit	Line	Data
	1	/*
	2	* urcu.c
	3	*
	4	* Userspace RCU library
	5	*
	6	* Copyright February 2009 - Mathieu Desnoyers <mathieu.desnoyers@polymtl.ca>
	7	*
	8	* Distributed under GPLv2
	9	*/
	10
	11	#include <stdio.h>
	12	#include <pthread.h>
	13	#include <signal.h>
	14	#include <assert.h>
	15	#include <stdlib.h>
	16	#include <string.h>
	17
	18	#include "urcu.h"
	19
	20	pthread_mutex_t urcu_mutex = PTHREAD_MUTEX_INITIALIZER;
	21
	22	/* Global quiescent period parity */
	23	int urcu_qparity;
	24
	25	int __thread urcu_active_readers[2];
	26
	27	/* Thread IDs of registered readers */
	28	#define INIT_NUM_THREADS 4
	29
	30	struct reader_data {
	31	pthread_t tid;
	32	int *urcu_active_readers;
	33	};
	34
	35	#ifdef DEBUG_YIELD
	36	unsigned int yield_active;
	37	unsigned int __thread rand_yield;
	38	#endif
	39
	40	static struct reader_data *reader_data;
	41	static int num_readers, alloc_readers;
	42	static int sig_done;
	43
	44	void internal_urcu_lock(void)
	45	{
	46	int ret;
	47	ret = pthread_mutex_lock(&urcu_mutex);
	48	if (ret) {
	49	perror("Error in pthread mutex lock");
	50	exit(-1);
	51	}
	52	}
	53
	54	void internal_urcu_unlock(void)
	55	{
	56	int ret;
	57
	58	ret = pthread_mutex_unlock(&urcu_mutex);
	59	if (ret) {
	60	perror("Error in pthread mutex unlock");
	61	exit(-1);
	62	}
	63	}
	64
	65	/*
	66	* called with urcu_mutex held.
	67	*/
	68	static int switch_next_urcu_qparity(void)
	69	{
	70	int old_parity = urcu_qparity;
	71	urcu_qparity = 1 - old_parity;
	72	return old_parity;
	73	}
	74
	75	static void force_mb_all_threads(void)
	76	{
	77	struct reader_data *index;
	78	/*
	79	* Ask for each threads to execute a mb() so we can consider the
	80	* compiler barriers around rcu read lock as real memory barriers.
	81	*/
	82	if (!reader_data)
	83	return;
	84	debug_yield_write();
	85	sig_done = 0;
	86	debug_yield_write();
	87	mb(); /* write sig_done before sending the signals */
	88	debug_yield_write();
	89	for (index = reader_data; index < reader_data + num_readers; index++) {
	90	pthread_kill(index->tid, SIGURCU);
	91	debug_yield_write();
	92	}
	93	/*
	94	* Wait for sighandler (and thus mb()) to execute on every thread.
	95	* BUSY-LOOP.
	96	*/
	97	while (sig_done < num_readers)
	98	barrier();
	99	debug_yield_write();
	100	mb(); /* read sig_done before ending the barrier */
	101	debug_yield_write();
	102	}
	103
	104	void wait_for_quiescent_state(int parity)
	105	{
	106	struct reader_data *index;
	107
	108	if (!reader_data)
	109	return;
	110	/* Wait for each thread urcu_active_readers count to become 0.
	111	*/
	112	for (index = reader_data; index < reader_data + num_readers; index++) {
	113	/*
	114	* BUSY-LOOP.
	115	*/
	116	while (index->urcu_active_readers[parity] != 0)
	117	barrier();
	118	}
	119	/*
	120	* Locally : read *index->urcu_active_readers before freeing old
	121	* pointer.
	122	* Remote (reader threads) : Order urcu_qparity update and other
	123	* thread's quiescent state counter read.
	124	*/
	125	force_mb_all_threads();
	126	}
	127
	128	static void switch_qparity(void)
	129	{
	130	int prev_parity;
	131
	132	/* All threads should read qparity before accessing data structure. */
	133	/* Write ptr before changing the qparity */
	134	force_mb_all_threads();
	135	debug_yield_write();
	136	prev_parity = switch_next_urcu_qparity();
	137	debug_yield_write();
	138
	139	/*
	140	* Wait for previous parity to be empty of readers.
	141	*/
	142	wait_for_quiescent_state(prev_parity);
	143	}
	144
	145	void synchronize_rcu(void)
	146	{
	147	debug_yield_write();
	148	internal_urcu_lock();
	149	debug_yield_write();
	150	switch_qparity();
	151	debug_yield_write();
	152	switch_qparity();
	153	debug_yield_write();
	154	internal_urcu_lock();
	155	debug_yield_write();
	156	}
	157
	158	/*
	159	* Return old pointer, OK to free, no more reference exist.
	160	* Called under rcu_write_lock.
	161	*/
	162	void urcu_publish_content(void ptr, void new)
	163	{
	164	void *oldptr;
	165
	166	debug_yield_write();
	167	internal_urcu_lock();
	168	debug_yield_write();
	169	/*
	170	* We can publish the new pointer before we change the current qparity.
	171	* Readers seeing the new pointer while being in the previous qparity
	172	* window will make us wait until the end of the quiescent state before
	173	* we release the unrelated memory area. However, given we hold the
	174	* urcu_mutex, we are making sure that no further garbage collection can
	175	* occur until we release the mutex, therefore we guarantee that this
	176	* given reader will have completed its execution using the new pointer
	177	* when the next quiescent state window will be over.
	178	*/
	179	oldptr = *ptr;
	180	debug_yield_write();
	181	*ptr = new;
	182
	183	debug_yield_write();
	184	switch_qparity();
	185	debug_yield_write();
	186	switch_qparity();
	187	debug_yield_write();
	188	internal_urcu_unlock();
	189	debug_yield_write();
	190
	191	return oldptr;
	192	}
	193
	194	void urcu_add_reader(pthread_t id)
	195	{
	196	struct reader_data *oldarray;
	197
	198	if (!reader_data) {
	199	alloc_readers = INIT_NUM_THREADS;
	200	num_readers = 0;
	201	reader_data =
	202	malloc(sizeof(struct reader_data) * alloc_readers);
	203	}
	204	if (alloc_readers < num_readers + 1) {
	205	oldarray = reader_data;
	206	reader_data = malloc(sizeof(struct reader_data)
	207	* (alloc_readers << 1));
	208	memcpy(reader_data, oldarray,
	209	sizeof(struct reader_data) * alloc_readers);
	210	alloc_readers <<= 1;
	211	free(oldarray);
	212	}
	213	reader_data[num_readers].tid = id;
	214	/* reference to the TLS of _this_ reader thread. */
	215	reader_data[num_readers].urcu_active_readers = urcu_active_readers;
	216	num_readers++;
	217	}
	218
	219	/*
	220	* Never shrink (implementation limitation).
	221	* This is O(nb threads). Eventually use a hash table.
	222	*/
	223	void urcu_remove_reader(pthread_t id)
	224	{
	225	struct reader_data *index;
	226
	227	assert(reader_data != NULL);
	228	for (index = reader_data; index < reader_data + num_readers; index++) {
	229	if (pthread_equal(index->tid, id)) {
	230	memcpy(index, &reader_data[num_readers - 1],
	231	sizeof(struct reader_data));
	232	reader_data[num_readers - 1].tid = 0;
	233	reader_data[num_readers - 1].urcu_active_readers = NULL;
	234	num_readers--;
	235	return;
	236	}
	237	}
	238	/* Hrm not found, forgot to register ? */
	239	assert(0);
	240	}
	241
	242	void urcu_register_thread(void)
	243	{
	244	internal_urcu_lock();
	245	urcu_add_reader(pthread_self());
	246	internal_urcu_unlock();
	247	}
	248
	249	void urcu_unregister_thread(void)
	250	{
	251	internal_urcu_lock();
	252	urcu_remove_reader(pthread_self());
	253	internal_urcu_unlock();
	254	}
	255
	256	void sigurcu_handler(int signo, siginfo_t siginfo, void context)
	257	{
	258	mb();
	259	atomic_inc(&sig_done);
	260	}
	261
	262	void __attribute__((constructor)) urcu_init(void)
	263	{
	264	struct sigaction act;
	265	int ret;
	266
	267	act.sa_sigaction = sigurcu_handler;
	268	ret = sigaction(SIGURCU, &act, NULL);
	269	if (ret) {
	270	perror("Error in sigaction");
	271	exit(-1);
	272	}
	273	}
	274
	275	void __attribute__((destructor)) urcu_exit(void)
	276	{
	277	struct sigaction act;
	278	int ret;
	279
	280	ret = sigaction(SIGURCU, NULL, &act);
	281	if (ret) {
	282	perror("Error in sigaction");
	283	exit(-1);
	284	}
	285	assert(act.sa_sigaction == sigurcu_handler);
	286	free(reader_data);
	287	}