Add no sync_core() test to ooo two writes model

[urcu.git] / formal-model / ooomem-double-update-minimal / mem.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. */

/*
 * Produced process data flow. Updated after each instruction to show which
 * variables are ready. Assigned using SSA (static single assignment) (defuse
 * analysis must be done on the program to map "real" variables to single define
 * followed by use). Using one-hot bit encoding per variable to save state
 * space.  Used as triggers to execute the instructions having those variables
 * as input.
 */

#define PRODUCE_TOKENS(state, bits)	\
	state = (state) | (bits)

/* All bits must be active to consume. All notbits must be inactive. */
/* Consuming a token does not clear it, it just waits for it. */
#define CONSUME_TOKENS(state, bits, notbits)				\
	((!((state) & (notbits))) && ((state) & (bits)) == (bits))

#define CLEAR_TOKENS(state, bits)	\
	state = (state) & ~(bits)

/*
 * Bit encoding, proc_one_produced :
 */

#define P1_PROD_NONE	(1 << 0)

#define P1_READ_ONE	(1 << 1)
#define P1_RMB		(1 << 2)
#define P1_READ_TWO	(1 << 3)

int proc_one_produced;

#define P2_PROD_NONE	(1 << 0)

#define P2_WRITE_ONE	(1 << 1)
#define P2_WMB		(1 << 2)
#define P2_WRITE_TWO	(1 << 3)

int proc_two_produced;

#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;

inline ooo_mem()
{
	atomic {
		RANDOM_CACHE_WRITE_TO_MEM(alpha, get_pid());
		RANDOM_CACHE_WRITE_TO_MEM(beta, get_pid());
		RANDOM_CACHE_READ_FROM_MEM(alpha, get_pid());
		RANDOM_CACHE_READ_FROM_MEM(beta, get_pid());
	}
}

/* must consume all prior read tokens */
inline smp_rmb()
{
	atomic {
		/* todo : consume all read tokens .. ? */
		CACHE_READ_FROM_MEM(alpha, get_pid());
		CACHE_READ_FROM_MEM(beta, get_pid());
	}
}

/* must consume all prior write tokens */
inline smp_wmb()
{
	atomic {
		CACHE_WRITE_TO_MEM(alpha, get_pid());
		CACHE_WRITE_TO_MEM(beta, get_pid());
	}
}

/* sync_core() must consume all prior read and write tokens, including rmb/wmb
 * tokens */

/* must consume all prior read and write tokens */
inline smp_mb()
{
	atomic {
		smp_wmb();
		/* sync_core() */
		smp_rmb();
	}
}

/* Keep in sync manually with smp_rmb, wmp_wmb and ooo_mem */
DECLARE_CACHED_VAR(byte, alpha, 0);
DECLARE_CACHED_VAR(byte, beta, 0);

/* value 2 is uninitialized */
byte read_one = 2;
byte read_two = 2;

active proctype test_proc_one()
{
	assert(get_pid() < NR_PROCS);

	PRODUCE_TOKENS(proc_one_produced, P1_PROD_NONE);
#ifdef NO_RMB
	PRODUCE_TOKENS(proc_one_produced, P1_RMB);
#endif

	do
	:: CONSUME_TOKENS(proc_one_produced, P1_PROD_NONE, P1_READ_ONE) ->
		ooo_mem();
		read_one = READ_CACHED_VAR(beta);
		ooo_mem();
		PRODUCE_TOKENS(proc_one_produced, P1_READ_ONE);
	:: CONSUME_TOKENS(proc_one_produced, P1_READ_ONE, P1_RMB) ->
		smp_rmb();
		PRODUCE_TOKENS(proc_one_produced, P1_RMB);
	:: CONSUME_TOKENS(proc_one_produced, P1_RMB, P1_READ_TWO) ->
		ooo_mem();
		read_two = READ_CACHED_VAR(alpha);
		ooo_mem();
		PRODUCE_TOKENS(proc_one_produced, P1_READ_TWO);
	:: CONSUME_TOKENS(proc_one_produced, P1_PROD_NONE | P1_READ_ONE
		| P1_RMB | P1_READ_TWO, 0) ->
		break;
	od;

	//CLEAR_TOKENS(proc_one_produced,
	//	P1_PROD_NONE | P1_READ_ONE | P1_RMB | P2_READ_TWO);

	// test : [] (read_one == 1 -> read_two == 1)
	assert(read_one != 1 || read_two == 1);
}

active proctype test_proc_two()
{
	assert(get_pid() < NR_PROCS);

	PRODUCE_TOKENS(proc_two_produced, P2_PROD_NONE);
#ifdef NO_WMB
	PRODUCE_TOKENS(proc_two_produced, P2_WMB);
#endif

	do
	:: CONSUME_TOKENS(proc_two_produced, P2_PROD_NONE, P2_WRITE_ONE) ->
		ooo_mem();
		WRITE_CACHED_VAR(alpha, 1);
		ooo_mem();
		PRODUCE_TOKENS(proc_two_produced, P2_WRITE_ONE);
	:: CONSUME_TOKENS(proc_two_produced, P2_WRITE_ONE, P2_WMB) ->
		smp_wmb();
		PRODUCE_TOKENS(proc_two_produced, P2_WMB);
	:: CONSUME_TOKENS(proc_two_produced, P2_WMB, P2_WRITE_TWO) ->
		ooo_mem();
		WRITE_CACHED_VAR(beta, 1);
		ooo_mem();
		PRODUCE_TOKENS(proc_two_produced, P2_WRITE_TWO);
	:: CONSUME_TOKENS(proc_two_produced, P2_PROD_NONE | P2_WRITE_ONE
		| P2_WMB | P2_WRITE_TWO, 0) ->
		break;
	od;

	//CLEAR_TOKENS(proc_two_produced,
	//	P2_PROD_NONE | P2_WRITE_ONE | P2_WMB | P2_WRITE_TWO);
}