[mirror_ubuntu-artful-kernel.git] / Documentation / arm / vlocks.txt

vlocks for Bare-Metal Mutual Exclusion
======================================

Voting Locks, or "vlocks" provide a simple low-level mutual exclusion
mechanism, with reasonable but minimal requirements on the memory
system.

These are intended to be used to coordinate critical activity among CPUs
which are otherwise non-coherent, in situations where the hardware
provides no other mechanism to support this and ordinary spinlocks
cannot be used.


vlocks make use of the atomicity provided by the memory system for
writes to a single memory location.  To arbitrate, every CPU "votes for
itself", by storing a unique number to a common memory location.  The
final value seen in that memory location when all the votes have been
cast identifies the winner.

In order to make sure that the election produces an unambiguous result
in finite time, a CPU will only enter the election in the first place if
no winner has been chosen and the election does not appear to have
started yet.


Algorithm
---------

The easiest way to explain the vlocks algorithm is with some pseudo-code:


	int currently_voting[NR_CPUS] = { 0, };
	int last_vote = -1; /* no votes yet */

	bool vlock_trylock(int this_cpu)
	{
		/* signal our desire to vote */
		currently_voting[this_cpu] = 1;
		if (last_vote != -1) {
			/* someone already volunteered himself */
			currently_voting[this_cpu] = 0;
			return false; /* not ourself */
		}

		/* let's suggest ourself */
		last_vote = this_cpu;
		currently_voting[this_cpu] = 0;

		/* then wait until everyone else is done voting */
		for_each_cpu(i) {
			while (currently_voting[i] != 0)
				/* wait */;
		}

		/* result */
		if (last_vote == this_cpu)
			return true; /* we won */
		return false;
	}

	bool vlock_unlock(void)
	{
		last_vote = -1;
	}


The currently_voting[] array provides a way for the CPUs to determine
whether an election is in progress, and plays a role analogous to the
"entering" array in Lamport's bakery algorithm [1].

However, once the election has started, the underlying memory system
atomicity is used to pick the winner.  This avoids the need for a static
priority rule to act as a tie-breaker, or any counters which could
overflow.

As long as the last_vote variable is globally visible to all CPUs, it
will contain only one value that won't change once every CPU has cleared
its currently_voting flag.


Features and limitations
------------------------

 * vlocks are not intended to be fair.  In the contended case, it is the
   _last_ CPU which attempts to get the lock which will be most likely
   to win.

   vlocks are therefore best suited to situations where it is necessary
   to pick a unique winner, but it does not matter which CPU actually
   wins.

 * Like other similar mechanisms, vlocks will not scale well to a large
   number of CPUs.

   vlocks can be cascaded in a voting hierarchy to permit better scaling
   if necessary, as in the following hypothetical example for 4096 CPUs:

	/* first level: local election */
	my_town = towns[(this_cpu >> 4) & 0xf];
	I_won = vlock_trylock(my_town, this_cpu & 0xf);
	if (I_won) {
		/* we won the town election, let's go for the state */
		my_state = states[(this_cpu >> 8) & 0xf];
		I_won = vlock_lock(my_state, this_cpu & 0xf));
		if (I_won) {
			/* and so on */
			I_won = vlock_lock(the_whole_country, this_cpu & 0xf];
			if (I_won) {
				/* ... */
			}
			vlock_unlock(the_whole_country);
		}
		vlock_unlock(my_state);
	}
	vlock_unlock(my_town);


ARM implementation
------------------

The current ARM implementation [2] contains some optimisations beyond
the basic algorithm:

 * By packing the members of the currently_voting array close together,
   we can read the whole array in one transaction (providing the number
   of CPUs potentially contending the lock is small enough).  This
   reduces the number of round-trips required to external memory.

   In the ARM implementation, this means that we can use a single load
   and comparison:

	LDR	Rt, [Rn]
	CMP	Rt, #0

   ...in place of code equivalent to:

	LDRB	Rt, [Rn]
	CMP	Rt, #0
	LDRBEQ	Rt, [Rn, #1]
	CMPEQ	Rt, #0
	LDRBEQ	Rt, [Rn, #2]
	CMPEQ	Rt, #0
	LDRBEQ	Rt, [Rn, #3]
	CMPEQ	Rt, #0

   This cuts down on the fast-path latency, as well as potentially
   reducing bus contention in contended cases.

   The optimisation relies on the fact that the ARM memory system
   guarantees coherency between overlapping memory accesses of
   different sizes, similarly to many other architectures.  Note that
   we do not care which element of currently_voting appears in which
   bits of Rt, so there is no need to worry about endianness in this
   optimisation.

   If there are too many CPUs to read the currently_voting array in
   one transaction then multiple transations are still required.  The
   implementation uses a simple loop of word-sized loads for this
   case.  The number of transactions is still fewer than would be
   required if bytes were loaded individually.


   In principle, we could aggregate further by using LDRD or LDM, but
   to keep the code simple this was not attempted in the initial
   implementation.


 * vlocks are currently only used to coordinate between CPUs which are
   unable to enable their caches yet.  This means that the
   implementation removes many of the barriers which would be required
   when executing the algorithm in cached memory.

   packing of the currently_voting array does not work with cached
   memory unless all CPUs contending the lock are cache-coherent, due
   to cache writebacks from one CPU clobbering values written by other
   CPUs.  (Though if all the CPUs are cache-coherent, you should be
   probably be using proper spinlocks instead anyway).


 * The "no votes yet" value used for the last_vote variable is 0 (not
   -1 as in the pseudocode).  This allows statically-allocated vlocks
   to be implicitly initialised to an unlocked state simply by putting
   them in .bss.

   An offset is added to each CPU's ID for the purpose of setting this
   variable, so that no CPU uses the value 0 for its ID.


Colophon
--------

Originally created and documented by Dave Martin for Linaro Limited, for
use in ARM-based big.LITTLE platforms, with review and input gratefully
received from Nicolas Pitre and Achin Gupta.  Thanks to Nicolas for
grabbing most of this text out of the relevant mail thread and writing
up the pseudocode.

Copyright (C) 2012-2013  Linaro Limited
Distributed under the terms of Version 2 of the GNU General Public
License, as defined in linux/COPYING.


References
----------

[1] Lamport, L. "A New Solution of Dijkstra's Concurrent Programming
    Problem", Communications of the ACM 17, 8 (August 1974), 453-455.

    http://en.wikipedia.org/wiki/Lamport%27s_bakery_algorithm

[2] linux/arch/arm/common/vlock.S, www.kernel.org.
Commit	Line	Data
9762f12d DM	1	vlocks for Bare-Metal Mutual Exclusion
	2	======================================
	3
	4	Voting Locks, or "vlocks" provide a simple low-level mutual exclusion
	5	mechanism, with reasonable but minimal requirements on the memory
	6	system.
	7
	8	These are intended to be used to coordinate critical activity among CPUs
	9	which are otherwise non-coherent, in situations where the hardware
	10	provides no other mechanism to support this and ordinary spinlocks
	11	cannot be used.
	12
	13
	14	vlocks make use of the atomicity provided by the memory system for
	15	writes to a single memory location. To arbitrate, every CPU "votes for
	16	itself", by storing a unique number to a common memory location. The
	17	final value seen in that memory location when all the votes have been
	18	cast identifies the winner.
	19
	20	In order to make sure that the election produces an unambiguous result
	21	in finite time, a CPU will only enter the election in the first place if
	22	no winner has been chosen and the election does not appear to have
	23	started yet.
	24
	25
	26	Algorithm
	27	---------
	28
	29	The easiest way to explain the vlocks algorithm is with some pseudo-code:
	30
	31
	32	int currently_voting[NR_CPUS] = { 0, };
	33	int last_vote = -1; /* no votes yet */
	34
	35	bool vlock_trylock(int this_cpu)
	36	{
	37	/* signal our desire to vote */
	38	currently_voting[this_cpu] = 1;
	39	if (last_vote != -1) {
	40	/* someone already volunteered himself */
	41	currently_voting[this_cpu] = 0;
	42	return false; /* not ourself */
	43	}
	44
	45	/* let's suggest ourself */
	46	last_vote = this_cpu;
	47	currently_voting[this_cpu] = 0;
	48
	49	/* then wait until everyone else is done voting */
	50	for_each_cpu(i) {
	51	while (currently_voting[i] != 0)
	52	/* wait */;
	53	}
	54
	55	/* result */
	56	if (last_vote == this_cpu)
	57	return true; /* we won */
	58	return false;
	59	}
	60
	61	bool vlock_unlock(void)
	62	{
	63	last_vote = -1;
	64	}
65
66
67	The currently_voting[] array provides a way for the CPUs to determine
68	whether an election is in progress, and plays a role analogous to the
69	"entering" array in Lamport's bakery algorithm [1].
70
71	However, once the election has started, the underlying memory system
72	atomicity is used to pick the winner. This avoids the need for a static
73	priority rule to act as a tie-breaker, or any counters which could
74	overflow.
75
76	As long as the last_vote variable is globally visible to all CPUs, it
77	will contain only one value that won't change once every CPU has cleared
78	its currently_voting flag.
79
80
81	Features and limitations
82	------------------------
83
84	* vlocks are not intended to be fair. In the contended case, it is the
85	_last_ CPU which attempts to get the lock which will be most likely
86	to win.
87
88	vlocks are therefore best suited to situations where it is necessary
89	to pick a unique winner, but it does not matter which CPU actually
90	wins.
91
92	* Like other similar mechanisms, vlocks will not scale well to a large
93	number of CPUs.
94
95	vlocks can be cascaded in a voting hierarchy to permit better scaling
96	if necessary, as in the following hypothetical example for 4096 CPUs:
97
98	/* first level: local election */
99	my_town = towns[(this_cpu >> 4) & 0xf];
100	I_won = vlock_trylock(my_town, this_cpu & 0xf);
101	if (I_won) {
102	/* we won the town election, let's go for the state */
103	my_state = states[(this_cpu >> 8) & 0xf];
104	I_won = vlock_lock(my_state, this_cpu & 0xf));
105	if (I_won) {
106	/* and so on */
107	I_won = vlock_lock(the_whole_country, this_cpu & 0xf];
108	if (I_won) {
109	/* ... */
110	}
111	vlock_unlock(the_whole_country);
112	}
113	vlock_unlock(my_state);
114	}
115	vlock_unlock(my_town);
116
117
118	ARM implementation
119	------------------
120
121	The current ARM implementation [2] contains some optimisations beyond
122	the basic algorithm:
123
124	* By packing the members of the currently_voting array close together,
125	we can read the whole array in one transaction (providing the number
126	of CPUs potentially contending the lock is small enough). This
127	reduces the number of round-trips required to external memory.
128
129	In the ARM implementation, this means that we can use a single load
130	and comparison:
131
132	LDR Rt, [Rn]
133	CMP Rt, #0
134
135	...in place of code equivalent to:
136
137	LDRB Rt, [Rn]
138	CMP Rt, #0
139	LDRBEQ Rt, [Rn, #1]
140	CMPEQ Rt, #0
141	LDRBEQ Rt, [Rn, #2]
142	CMPEQ Rt, #0
143	LDRBEQ Rt, [Rn, #3]
144	CMPEQ Rt, #0
145
146	This cuts down on the fast-path latency, as well as potentially
147	reducing bus contention in contended cases.
148
149	The optimisation relies on the fact that the ARM memory system
150	guarantees coherency between overlapping memory accesses of
151	different sizes, similarly to many other architectures. Note that
152	we do not care which element of currently_voting appears in which
153	bits of Rt, so there is no need to worry about endianness in this
154	optimisation.
155
156	If there are too many CPUs to read the currently_voting array in
157	one transaction then multiple transations are still required. The
158	implementation uses a simple loop of word-sized loads for this
159	case. The number of transactions is still fewer than would be
160	required if bytes were loaded individually.
161
162
163	In principle, we could aggregate further by using LDRD or LDM, but
164	to keep the code simple this was not attempted in the initial
165	implementation.
166
167
168	* vlocks are currently only used to coordinate between CPUs which are
169	unable to enable their caches yet. This means that the
170	implementation removes many of the barriers which would be required
171	when executing the algorithm in cached memory.
172
173	packing of the currently_voting array does not work with cached
174	memory unless all CPUs contending the lock are cache-coherent, due
175	to cache writebacks from one CPU clobbering values written by other
176	CPUs. (Though if all the CPUs are cache-coherent, you should be
177	probably be using proper spinlocks instead anyway).
178
179
180	* The "no votes yet" value used for the last_vote variable is 0 (not
181	-1 as in the pseudocode). This allows statically-allocated vlocks
182	to be implicitly initialised to an unlocked state simply by putting
183	them in .bss.
184
185	An offset is added to each CPU's ID for the purpose of setting this
186	variable, so that no CPU uses the value 0 for its ID.
187
188
189	Colophon
190	--------
191
192	Originally created and documented by Dave Martin for Linaro Limited, for
193	use in ARM-based big.LITTLE platforms, with review and input gratefully
194	received from Nicolas Pitre and Achin Gupta. Thanks to Nicolas for
195	grabbing most of this text out of the relevant mail thread and writing
196	up the pseudocode.
197
198	Copyright (C) 2012-2013 Linaro Limited
199	Distributed under the terms of Version 2 of the GNU General Public
200	License, as defined in linux/COPYING.
201
202
203	References
204	----------
205
206	[1] Lamport, L. "A New Solution of Dijkstra's Concurrent Programming
207	Problem", Communications of the ACM 17, 8 (August 1974), 453-455.
208
209	http://en.wikipedia.org/wiki/Lamport%27s_bakery_algorithm
210
211	[2] linux/arch/arm/common/vlock.S, www.kernel.org.