[urcu.git] / formal-model / urcu / urcu.spin

/*
 * mem.spin: Promela code to validate memory barriers with OOO memory.
 *
 * 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; either version 2 of the License, or
 * (at your option) any later version.
 *
 * 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
 *
 * Copyright (c) 2009 Mathieu Desnoyers
 */

/* Promela validation variables. */

#define NR_READERS 1
#define NR_WRITERS 1

#define NR_PROCS 2

#define get_pid()	(_pid)

/*
 * Each process have its own data in cache. Caches are randomly updated.
 * smp_wmb and smp_rmb forces cache updates (write and read), wmb_mb forces
 * both.
 */

#define DECLARE_CACHED_VAR(type, x, v)	\
	type mem_##x = v;		\
	type cached_##x[NR_PROCS] = v;	\
	bit cache_dirty_##x[NR_PROCS] = 0

#define IS_CACHE_DIRTY(x, id)	(cache_dirty_##x[id])

#define READ_CACHED_VAR(x)	(cached_##x[get_pid()])

#define WRITE_CACHED_VAR(x, v)		\
	atomic {			\
		cached_##x[get_pid()] = v;	\
		cache_dirty_##x[get_pid()] = 1;	\
	}

#define CACHE_WRITE_TO_MEM(x, id)		\
	if					\
	:: IS_CACHE_DIRTY(x, id) ->		\
		mem_##x = cached_##x[id];	\
		cache_dirty_##x[id] = 0;	\
	:: else ->				\
		skip				\
	fi;

#define CACHE_READ_FROM_MEM(x, id)	\
	if				\
	:: !IS_CACHE_DIRTY(x, id) ->	\
		cached_##x[id] = mem_##x;\
	:: else ->			\
		skip			\
	fi;

/*
 * May update other caches if cache is dirty, or not.
 */
#define RANDOM_CACHE_WRITE_TO_MEM(x, id)\
	if				\
	:: 1 -> CACHE_WRITE_TO_MEM(x, id);	\
	:: 1 -> skip			\
	fi;

#define RANDOM_CACHE_READ_FROM_MEM(x, id)\
	if				\
	:: 1 -> CACHE_READ_FROM_MEM(x, id);	\
	:: 1 -> skip			\
	fi;

/*
 * Remote barriers tests the scheme where a signal (or IPI) is sent to all
 * reader threads to promote their compiler barrier to a smp_mb().
 */
#ifdef REMOTE_BARRIERS

inline smp_rmb_pid(i)
{
	atomic {
		CACHE_READ_FROM_MEM(urcu_gp_ctr, i);
		CACHE_READ_FROM_MEM(urcu_active_readers_one, i);
		CACHE_READ_FROM_MEM(generation_ptr, i);
	}
}

inline smp_wmb_pid(i)
{
	atomic {
		CACHE_WRITE_TO_MEM(urcu_gp_ctr, i);
		CACHE_WRITE_TO_MEM(urcu_active_readers_one, i);
		CACHE_WRITE_TO_MEM(generation_ptr, i);
	}
}

inline smp_mb_pid(i)
{
	atomic {
#ifndef NO_WMB
		smp_wmb_pid(i);
#endif
#ifndef NO_RMB
		smp_rmb_pid(i);
#endif
		skip;
	}
}

/*
 * Readers do a simple barrier(), writers are doing a smp_mb() _and_ sending a
 * signal or IPI to have all readers execute a smp_mb.
 * We are not modeling the whole rendez-vous between readers and writers here,
 * we just let the writer update each reader's caches remotely.
 */
inline smp_mb(i)
{
	if
	:: get_pid() >= NR_READERS ->
		smp_mb_pid(get_pid());
		i = 0;
		do
		:: i < NR_READERS ->
			smp_mb_pid(i);
			i++;
		:: i >= NR_READERS -> break
		od;
		smp_mb_pid(get_pid());
	:: else -> skip;
	fi;
}

#else

inline smp_rmb(i)
{
	atomic {
		CACHE_READ_FROM_MEM(urcu_gp_ctr, get_pid());
		CACHE_READ_FROM_MEM(urcu_active_readers_one, get_pid());
		CACHE_READ_FROM_MEM(generation_ptr, get_pid());
	}
}

inline smp_wmb(i)
{
	atomic {
		CACHE_WRITE_TO_MEM(urcu_gp_ctr, get_pid());
		CACHE_WRITE_TO_MEM(urcu_active_readers_one, get_pid());
		CACHE_WRITE_TO_MEM(generation_ptr, get_pid());
	}
}

inline smp_mb(i)
{
	atomic {
#ifndef NO_WMB
		smp_wmb(i);
#endif
#ifndef NO_RMB
		smp_rmb(i);
#endif
		skip;
	}
}

#endif

/* Keep in sync manually with smp_rmb, wmp_wmb and ooo_mem */
DECLARE_CACHED_VAR(byte, urcu_gp_ctr, 1);
/* Note ! currently only one reader */
DECLARE_CACHED_VAR(byte, urcu_active_readers_one, 0);
/* pointer generation */
DECLARE_CACHED_VAR(byte, generation_ptr, 0);

byte last_free_gen = 0;
bit free_done = 0;
byte read_generation = 1;
bit data_access = 0;

bit write_lock = 0;

inline ooo_mem(i)
{
	atomic {
		RANDOM_CACHE_WRITE_TO_MEM(urcu_gp_ctr, get_pid());
		RANDOM_CACHE_WRITE_TO_MEM(urcu_active_readers_one,
						get_pid());
		RANDOM_CACHE_WRITE_TO_MEM(generation_ptr, get_pid());
		RANDOM_CACHE_READ_FROM_MEM(urcu_gp_ctr, get_pid());
		RANDOM_CACHE_READ_FROM_MEM(urcu_active_readers_one,
						get_pid());
		RANDOM_CACHE_READ_FROM_MEM(generation_ptr, get_pid());
	}
}

#define get_readerid()	(get_pid())
#define get_writerid()	(get_readerid() + NR_READERS)

inline wait_for_reader(tmp, id, i)
{
	do
	:: 1 ->
		ooo_mem(i);
		tmp = READ_CACHED_VAR(urcu_active_readers_one);
		if
		:: (tmp & RCU_GP_CTR_NEST_MASK)
			&& ((tmp ^ READ_CACHED_VAR(urcu_gp_ctr))
				& RCU_GP_CTR_BIT) ->
#ifndef GEN_ERROR_WRITER_PROGRESS
			smp_mb(i);
#else
			skip;
#endif
		:: else	->
			break;
		fi;
	od;
}

inline wait_for_quiescent_state(tmp, i, j)
{
	i = 0;
	do
	:: i < NR_READERS ->
		wait_for_reader(tmp, i, j);
		i++
	:: i >= NR_READERS -> break
	od;
}

/* Model the RCU read-side critical section. */

inline urcu_one_read(i, nest_i, tmp, tmp2)
{
	nest_i = 0;
	do
	:: nest_i < READER_NEST_LEVEL ->
		ooo_mem(i);
		tmp = READ_CACHED_VAR(urcu_active_readers_one);
		ooo_mem(i);
		if
		:: (!(tmp & RCU_GP_CTR_NEST_MASK))
			->
			tmp2 = READ_CACHED_VAR(urcu_gp_ctr);
			ooo_mem(i);
			WRITE_CACHED_VAR(urcu_active_readers_one, tmp2);
		:: else	->
			WRITE_CACHED_VAR(urcu_active_readers_one,
					 tmp + 1);
		fi;
		ooo_mem(i);
		smp_mb(i);
		nest_i++;
	:: nest_i >= READER_NEST_LEVEL -> break;
	od;

	ooo_mem(i);
	read_generation = READ_CACHED_VAR(generation_ptr);
	ooo_mem(i);
	data_access = 1;
	ooo_mem(i);
	data_access = 0;

	nest_i = 0;
	do
	:: nest_i < READER_NEST_LEVEL ->
		ooo_mem(i);
		smp_mb(i);
		ooo_mem(i);
		tmp2 = READ_CACHED_VAR(urcu_active_readers_one);
		ooo_mem(i);
		WRITE_CACHED_VAR(urcu_active_readers_one, tmp2 - 1);
		nest_i++;
	:: nest_i >= READER_NEST_LEVEL -> break;
	od;
	ooo_mem(i);
	//smp_mc(i);	/* added */
}

active [NR_READERS] proctype urcu_reader()
{
	byte i, nest_i;
	byte tmp, tmp2;

	assert(get_pid() < NR_PROCS);

end_reader:
	do
	:: 1 ->
		/*
		 * We do not test reader's progress here, because we are mainly
		 * interested in writer's progress. The reader never blocks
		 * anyway. We have to test for reader/writer's progress
		 * separately, otherwise we could think the writer is doing
		 * progress when it's blocked by an always progressing reader.
		 */
#ifdef READER_PROGRESS
progress_reader:
#endif
		urcu_one_read(i, nest_i, tmp, tmp2);
	od;
}

/* Model the RCU update process. */

active [NR_WRITERS] proctype urcu_writer()
{
	byte i, j;
	byte tmp;
	byte old_gen;

	assert(get_pid() < NR_PROCS);

	do
	:: (READ_CACHED_VAR(generation_ptr) < 5) ->
#ifdef WRITER_PROGRESS
progress_writer1:
#endif
		ooo_mem(i);
		atomic {
			old_gen = READ_CACHED_VAR(generation_ptr);
			WRITE_CACHED_VAR(generation_ptr, old_gen + 1);
		}
		ooo_mem(i);

		do
		:: 1 ->
			atomic {
				if
				:: write_lock == 0 ->
					write_lock = 1;
					break;
				:: else ->
					skip;
				fi;
			}
		od;
		smp_mb(i);
		ooo_mem(i);
		tmp = READ_CACHED_VAR(urcu_gp_ctr);
		ooo_mem(i);
		WRITE_CACHED_VAR(urcu_gp_ctr, tmp ^ RCU_GP_CTR_BIT);
		ooo_mem(i);
		//smp_mc(i);
		wait_for_quiescent_state(tmp, i, j);
		//smp_mc(i);
#ifndef SINGLE_FLIP
		ooo_mem(i);
		tmp = READ_CACHED_VAR(urcu_gp_ctr);
		ooo_mem(i);
		WRITE_CACHED_VAR(urcu_gp_ctr, tmp ^ RCU_GP_CTR_BIT);
		//smp_mc(i);
		ooo_mem(i);
		wait_for_quiescent_state(tmp, i, j);
#endif
		ooo_mem(i);
		smp_mb(i);
		ooo_mem(i);
		write_lock = 0;
		/* free-up step, e.g., kfree(). */
		atomic {
			last_free_gen = old_gen;
			free_done = 1;
		}
	:: else -> break;
	od;
	/*
	 * Given the reader loops infinitely, let the writer also busy-loop
	 * with progress here so, with weak fairness, we can test the
	 * writer's progress.
	 */
end_writer:
	do
	:: 1 ->
#ifdef WRITER_PROGRESS
progress_writer2:
#endif
		skip;
	od;
}
Commit	Line	Data
60a1db9d MD	1	/*
	2	* mem.spin: Promela code to validate memory barriers with OOO memory.
	3	*
	4	* This program is free software; you can redistribute it and/or modify
	5	* it under the terms of the GNU General Public License as published by
	6	* the Free Software Foundation; either version 2 of the License, or
	7	* (at your option) any later version.
	8	*
	9	* This program is distributed in the hope that it will be useful,
	10	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	11	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	12	* GNU General Public License for more details.
	13	*
	14	* You should have received a copy of the GNU General Public License
	15	* along with this program; if not, write to the Free Software
	16	* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
	17	*
	18	* Copyright (c) 2009 Mathieu Desnoyers
	19	*/
	20
	21	/* Promela validation variables. */
	22
	23	#define NR_READERS 1
89674313	24	#define NR_WRITERS 1
60a1db9d	25
89674313	26	#define NR_PROCS 2
60a1db9d MD	27
	28	#define get_pid() (_pid)
	29
	30	/*
	31	* Each process have its own data in cache. Caches are randomly updated.
	32	* smp_wmb and smp_rmb forces cache updates (write and read), wmb_mb forces
	33	* both.
	34	*/
	35
	36	#define DECLARE_CACHED_VAR(type, x, v) \
	37	type mem_##x = v; \
	38	type cached_##x[NR_PROCS] = v; \
	39	bit cache_dirty_##x[NR_PROCS] = 0
	40
	41	#define IS_CACHE_DIRTY(x, id) (cache_dirty_##x[id])
	42
	43	#define READ_CACHED_VAR(x) (cached_##x[get_pid()])
	44
	45	#define WRITE_CACHED_VAR(x, v) \
	46	atomic { \
	47	cached_##x[get_pid()] = v; \
	48	cache_dirty_##x[get_pid()] = 1; \
	49	}
	50
	51	#define CACHE_WRITE_TO_MEM(x, id) \
	52	if \
	53	:: IS_CACHE_DIRTY(x, id) -> \
	54	mem_##x = cached_##x[id]; \
	55	cache_dirty_##x[id] = 0; \
	56	:: else -> \
	57	skip \
	58	fi;
	59
	60	#define CACHE_READ_FROM_MEM(x, id) \
	61	if \
	62	:: !IS_CACHE_DIRTY(x, id) -> \
	63	cached_##x[id] = mem_##x;\
	64	:: else -> \
	65	skip \
	66	fi;
	67
	68	/*
	69	* May update other caches if cache is dirty, or not.
	70	*/
	71	#define RANDOM_CACHE_WRITE_TO_MEM(x, id)\
	72	if \
	73	:: 1 -> CACHE_WRITE_TO_MEM(x, id); \
	74	:: 1 -> skip \
	75	fi;
	76
	77	#define RANDOM_CACHE_READ_FROM_MEM(x, id)\
	78	if \
	79	:: 1 -> CACHE_READ_FROM_MEM(x, id); \
	80	:: 1 -> skip \
	81	fi;
	82
cc76fd1d MD	83	/*
	84	* Remote barriers tests the scheme where a signal (or IPI) is sent to all
	85	* reader threads to promote their compiler barrier to a smp_mb().
	86	*/
	87	#ifdef REMOTE_BARRIERS
	88
	89	inline smp_rmb_pid(i)
	90	{
	91	atomic {
	92	CACHE_READ_FROM_MEM(urcu_gp_ctr, i);
	93	CACHE_READ_FROM_MEM(urcu_active_readers_one, i);
	94	CACHE_READ_FROM_MEM(generation_ptr, i);
	95	}
	96	}
	97
	98	inline smp_wmb_pid(i)
	99	{
	100	atomic {
	101	CACHE_WRITE_TO_MEM(urcu_gp_ctr, i);
	102	CACHE_WRITE_TO_MEM(urcu_active_readers_one, i);
	103	CACHE_WRITE_TO_MEM(generation_ptr, i);
	104	}
	105	}
	106
	107	inline smp_mb_pid(i)
	108	{
	109	atomic {
	110	#ifndef NO_WMB
	111	smp_wmb_pid(i);
	112	#endif
	113	#ifndef NO_RMB
	114	smp_rmb_pid(i);
	115	#endif
	116	skip;
	117	}
	118	}
	119
	120	/*
	121	* Readers do a simple barrier(), writers are doing a smp_mb() _and_ sending a
	122	* signal or IPI to have all readers execute a smp_mb.
	123	* We are not modeling the whole rendez-vous between readers and writers here,
	124	* we just let the writer update each reader's caches remotely.
	125	*/
	126	inline smp_mb(i)
	127	{
	128	if
	129	:: get_pid() >= NR_READERS ->
	130	smp_mb_pid(get_pid());
	131	i = 0;
	132	do
	133	:: i < NR_READERS ->
	134	smp_mb_pid(i);
	135	i++;
	136	:: i >= NR_READERS -> break
	137	od;
	138	smp_mb_pid(get_pid());
	139	:: else -> skip;
	140	fi;
	141	}
	142
	143	#else
	144
60a1db9d MD	145	inline smp_rmb(i)
	146	{
	147	atomic {
	148	CACHE_READ_FROM_MEM(urcu_gp_ctr, get_pid());
	149	CACHE_READ_FROM_MEM(urcu_active_readers_one, get_pid());
	150	CACHE_READ_FROM_MEM(generation_ptr, get_pid());
	151	}
	152	}
	153
	154	inline smp_wmb(i)
	155	{
	156	atomic {
	157	CACHE_WRITE_TO_MEM(urcu_gp_ctr, get_pid());
	158	CACHE_WRITE_TO_MEM(urcu_active_readers_one, get_pid());
	159	CACHE_WRITE_TO_MEM(generation_ptr, get_pid());
	160	}
	161	}
	162
	163	inline smp_mb(i)
	164	{
	165	atomic {
	166	#ifndef NO_WMB
	167	smp_wmb(i);
	168	#endif
	169	#ifndef NO_RMB
	170	smp_rmb(i);
	171	#endif
	172	skip;
	173	}
	174	}
	175
cc76fd1d MD	176	#endif
cc76fd1d MD	177
60a1db9d MD	178	/* Keep in sync manually with smp_rmb, wmp_wmb and ooo_mem */
	179	DECLARE_CACHED_VAR(byte, urcu_gp_ctr, 1);
	180	/* Note ! currently only one reader */
	181	DECLARE_CACHED_VAR(byte, urcu_active_readers_one, 0);
	182	/* pointer generation */
	183	DECLARE_CACHED_VAR(byte, generation_ptr, 0);
	184
	185	byte last_free_gen = 0;
	186	bit free_done = 0;
	187	byte read_generation = 1;
	188	bit data_access = 0;
	189
2ba2a48d MD	190	bit write_lock = 0;
2ba2a48d MD	191
60a1db9d MD	192	inline ooo_mem(i)
	193	{
	194	atomic {
	195	RANDOM_CACHE_WRITE_TO_MEM(urcu_gp_ctr, get_pid());
	196	RANDOM_CACHE_WRITE_TO_MEM(urcu_active_readers_one,
	197	get_pid());
	198	RANDOM_CACHE_WRITE_TO_MEM(generation_ptr, get_pid());
	199	RANDOM_CACHE_READ_FROM_MEM(urcu_gp_ctr, get_pid());
	200	RANDOM_CACHE_READ_FROM_MEM(urcu_active_readers_one,
	201	get_pid());
	202	RANDOM_CACHE_READ_FROM_MEM(generation_ptr, get_pid());
	203	}
	204	}
	205
	206	#define get_readerid() (get_pid())
	207	#define get_writerid() (get_readerid() + NR_READERS)
	208
	209	inline wait_for_reader(tmp, id, i)
	210	{
60a1db9d	211	do
89674313 MD	212	:: 1 ->
	213	ooo_mem(i);
	214	tmp = READ_CACHED_VAR(urcu_active_readers_one);
	215	if
	216	:: (tmp & RCU_GP_CTR_NEST_MASK)
	217	&& ((tmp ^ READ_CACHED_VAR(urcu_gp_ctr))
	218	& RCU_GP_CTR_BIT) ->
	219	#ifndef GEN_ERROR_WRITER_PROGRESS
	220	smp_mb(i);
	221	#else
60a1db9d	222	skip;
89674313 MD	223	#endif
89674313 MD	224	:: else ->
60a1db9d	225	break;
89674313	226	fi;
60a1db9d MD	227	od;
	228	}
	229
	230	inline wait_for_quiescent_state(tmp, i, j)
	231	{
	232	i = 0;
	233	do
	234	:: i < NR_READERS ->
	235	wait_for_reader(tmp, i, j);
	236	i++
	237	:: i >= NR_READERS -> break
	238	od;
	239	}
	240
	241	/* Model the RCU read-side critical section. */
	242
6ae334b0	243	inline urcu_one_read(i, nest_i, tmp, tmp2)
	244	{
	245	nest_i = 0;
	246	do
	247	:: nest_i < READER_NEST_LEVEL ->
	248	ooo_mem(i);
	249	tmp = READ_CACHED_VAR(urcu_active_readers_one);
	250	ooo_mem(i);
	251	if
	252	:: (!(tmp & RCU_GP_CTR_NEST_MASK))
	253	->
	254	tmp2 = READ_CACHED_VAR(urcu_gp_ctr);
	255	ooo_mem(i);
	256	WRITE_CACHED_VAR(urcu_active_readers_one, tmp2);
	257	:: else ->
	258	WRITE_CACHED_VAR(urcu_active_readers_one,
	259	tmp + 1);
	260	fi;
	261	ooo_mem(i);
	262	smp_mb(i);
	263	nest_i++;
	264	:: nest_i >= READER_NEST_LEVEL -> break;
	265	od;
	266
	267	ooo_mem(i);
	268	read_generation = READ_CACHED_VAR(generation_ptr);
	269	ooo_mem(i);
	270	data_access = 1;
	271	ooo_mem(i);
	272	data_access = 0;
	273
	274	nest_i = 0;
	275	do
	276	:: nest_i < READER_NEST_LEVEL ->
	277	ooo_mem(i);
	278	smp_mb(i);
	279	ooo_mem(i);
	280	tmp2 = READ_CACHED_VAR(urcu_active_readers_one);
	281	ooo_mem(i);
	282	WRITE_CACHED_VAR(urcu_active_readers_one, tmp2 - 1);
	283	nest_i++;
	284	:: nest_i >= READER_NEST_LEVEL -> break;
	285	od;
	286	ooo_mem(i);
	287	//smp_mc(i); /* added */
	288	}
	289
60a1db9d MD	290	active [NR_READERS] proctype urcu_reader()
60a1db9d MD	291	{
06d6106d	292	byte i, nest_i;
60a1db9d MD	293	byte tmp, tmp2;
	294
	295	assert(get_pid() < NR_PROCS);
	296
89674313 MD	297	end_reader:
	298	do
	299	:: 1 ->
	300	/*
	301	* We do not test reader's progress here, because we are mainly
	302	* interested in writer's progress. The reader never blocks
	303	* anyway. We have to test for reader/writer's progress
	304	* separately, otherwise we could think the writer is doing
	305	* progress when it's blocked by an always progressing reader.
	306	*/
	307	#ifdef READER_PROGRESS
	308	progress_reader:
	309	#endif
6ae334b0	310	urcu_one_read(i, nest_i, tmp, tmp2);
89674313	311	od;
60a1db9d MD	312	}
60a1db9d MD	313
60a1db9d MD	314	/* Model the RCU update process. */
	315
	316	active [NR_WRITERS] proctype urcu_writer()
	317	{
	318	byte i, j;
	319	byte tmp;
	320	byte old_gen;
	321
	322	assert(get_pid() < NR_PROCS);
	323
2ba2a48d	324	do
89674313 MD	325	:: (READ_CACHED_VAR(generation_ptr) < 5) ->
	326	#ifdef WRITER_PROGRESS
	327	progress_writer1:
	328	#endif
	329	ooo_mem(i);
710b09b7	330	atomic {
89674313 MD	331	old_gen = READ_CACHED_VAR(generation_ptr);
89674313 MD	332	WRITE_CACHED_VAR(generation_ptr, old_gen + 1);
710b09b7	333	}
89674313 MD	334	ooo_mem(i);
	335
	336	do
	337	:: 1 ->
	338	atomic {
	339	if
	340	:: write_lock == 0 ->
	341	write_lock = 1;
	342	break;
	343	:: else ->
	344	skip;
	345	fi;
	346	}
	347	od;
	348	smp_mb(i);
	349	ooo_mem(i);
	350	tmp = READ_CACHED_VAR(urcu_gp_ctr);
	351	ooo_mem(i);
	352	WRITE_CACHED_VAR(urcu_gp_ctr, tmp ^ RCU_GP_CTR_BIT);
	353	ooo_mem(i);
	354	//smp_mc(i);
	355	wait_for_quiescent_state(tmp, i, j);
	356	//smp_mc(i);
d4e437ba	357	#ifndef SINGLE_FLIP
89674313 MD	358	ooo_mem(i);
	359	tmp = READ_CACHED_VAR(urcu_gp_ctr);
	360	ooo_mem(i);
	361	WRITE_CACHED_VAR(urcu_gp_ctr, tmp ^ RCU_GP_CTR_BIT);
	362	//smp_mc(i);
	363	ooo_mem(i);
	364	wait_for_quiescent_state(tmp, i, j);
d4e437ba	365	#endif
89674313 MD	366	ooo_mem(i);
	367	smp_mb(i);
	368	ooo_mem(i);
	369	write_lock = 0;
	370	/* free-up step, e.g., kfree(). */
	371	atomic {
	372	last_free_gen = old_gen;
	373	free_done = 1;
	374	}
	375	:: else -> break;
2ba2a48d	376	od;
89674313 MD	377	/*
	378	* Given the reader loops infinitely, let the writer also busy-loop
	379	* with progress here so, with weak fairness, we can test the
	380	* writer's progress.
	381	*/
	382	end_writer:
	383	do
	384	:: 1 ->
	385	#ifdef WRITER_PROGRESS
	386	progress_writer2:
2ba2a48d	387	#endif
89674313 MD	388	skip;
89674313 MD	389	od;
60a1db9d	390	}