213 строки
6.7 KiB
ReStructuredText
213 строки
6.7 KiB
ReStructuredText
======================================
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vlocks for Bare-Metal Mutual Exclusion
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======================================
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Voting Locks, or "vlocks" provide a simple low-level mutual exclusion
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mechanism, with reasonable but minimal requirements on the memory
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system.
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These are intended to be used to coordinate critical activity among CPUs
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which are otherwise non-coherent, in situations where the hardware
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provides no other mechanism to support this and ordinary spinlocks
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cannot be used.
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vlocks make use of the atomicity provided by the memory system for
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writes to a single memory location. To arbitrate, every CPU "votes for
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itself", by storing a unique number to a common memory location. The
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final value seen in that memory location when all the votes have been
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cast identifies the winner.
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In order to make sure that the election produces an unambiguous result
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in finite time, a CPU will only enter the election in the first place if
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no winner has been chosen and the election does not appear to have
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started yet.
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Algorithm
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---------
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The easiest way to explain the vlocks algorithm is with some pseudo-code::
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int currently_voting[NR_CPUS] = { 0, };
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int last_vote = -1; /* no votes yet */
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bool vlock_trylock(int this_cpu)
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{
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/* signal our desire to vote */
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currently_voting[this_cpu] = 1;
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if (last_vote != -1) {
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/* someone already volunteered himself */
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currently_voting[this_cpu] = 0;
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return false; /* not ourself */
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}
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/* let's suggest ourself */
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last_vote = this_cpu;
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currently_voting[this_cpu] = 0;
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/* then wait until everyone else is done voting */
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for_each_cpu(i) {
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while (currently_voting[i] != 0)
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/* wait */;
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}
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/* result */
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if (last_vote == this_cpu)
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return true; /* we won */
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return false;
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}
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bool vlock_unlock(void)
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{
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last_vote = -1;
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}
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The currently_voting[] array provides a way for the CPUs to determine
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whether an election is in progress, and plays a role analogous to the
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"entering" array in Lamport's bakery algorithm [1].
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However, once the election has started, the underlying memory system
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atomicity is used to pick the winner. This avoids the need for a static
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priority rule to act as a tie-breaker, or any counters which could
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overflow.
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As long as the last_vote variable is globally visible to all CPUs, it
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will contain only one value that won't change once every CPU has cleared
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its currently_voting flag.
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Features and limitations
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------------------------
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* vlocks are not intended to be fair. In the contended case, it is the
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_last_ CPU which attempts to get the lock which will be most likely
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to win.
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vlocks are therefore best suited to situations where it is necessary
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to pick a unique winner, but it does not matter which CPU actually
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wins.
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* Like other similar mechanisms, vlocks will not scale well to a large
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number of CPUs.
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vlocks can be cascaded in a voting hierarchy to permit better scaling
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if necessary, as in the following hypothetical example for 4096 CPUs::
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/* first level: local election */
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my_town = towns[(this_cpu >> 4) & 0xf];
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I_won = vlock_trylock(my_town, this_cpu & 0xf);
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if (I_won) {
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/* we won the town election, let's go for the state */
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my_state = states[(this_cpu >> 8) & 0xf];
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I_won = vlock_lock(my_state, this_cpu & 0xf));
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if (I_won) {
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/* and so on */
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I_won = vlock_lock(the_whole_country, this_cpu & 0xf];
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if (I_won) {
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/* ... */
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}
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vlock_unlock(the_whole_country);
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}
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vlock_unlock(my_state);
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}
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vlock_unlock(my_town);
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ARM implementation
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------------------
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The current ARM implementation [2] contains some optimisations beyond
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the basic algorithm:
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* By packing the members of the currently_voting array close together,
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we can read the whole array in one transaction (providing the number
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of CPUs potentially contending the lock is small enough). This
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reduces the number of round-trips required to external memory.
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In the ARM implementation, this means that we can use a single load
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and comparison::
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LDR Rt, [Rn]
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CMP Rt, #0
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...in place of code equivalent to::
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LDRB Rt, [Rn]
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CMP Rt, #0
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LDRBEQ Rt, [Rn, #1]
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CMPEQ Rt, #0
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LDRBEQ Rt, [Rn, #2]
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CMPEQ Rt, #0
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LDRBEQ Rt, [Rn, #3]
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CMPEQ Rt, #0
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This cuts down on the fast-path latency, as well as potentially
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reducing bus contention in contended cases.
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The optimisation relies on the fact that the ARM memory system
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guarantees coherency between overlapping memory accesses of
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different sizes, similarly to many other architectures. Note that
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we do not care which element of currently_voting appears in which
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bits of Rt, so there is no need to worry about endianness in this
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optimisation.
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If there are too many CPUs to read the currently_voting array in
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one transaction then multiple transations are still required. The
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implementation uses a simple loop of word-sized loads for this
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case. The number of transactions is still fewer than would be
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required if bytes were loaded individually.
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In principle, we could aggregate further by using LDRD or LDM, but
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to keep the code simple this was not attempted in the initial
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implementation.
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* vlocks are currently only used to coordinate between CPUs which are
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unable to enable their caches yet. This means that the
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implementation removes many of the barriers which would be required
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when executing the algorithm in cached memory.
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packing of the currently_voting array does not work with cached
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memory unless all CPUs contending the lock are cache-coherent, due
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to cache writebacks from one CPU clobbering values written by other
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CPUs. (Though if all the CPUs are cache-coherent, you should be
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probably be using proper spinlocks instead anyway).
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* The "no votes yet" value used for the last_vote variable is 0 (not
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-1 as in the pseudocode). This allows statically-allocated vlocks
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to be implicitly initialised to an unlocked state simply by putting
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them in .bss.
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An offset is added to each CPU's ID for the purpose of setting this
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variable, so that no CPU uses the value 0 for its ID.
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Colophon
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--------
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Originally created and documented by Dave Martin for Linaro Limited, for
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use in ARM-based big.LITTLE platforms, with review and input gratefully
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received from Nicolas Pitre and Achin Gupta. Thanks to Nicolas for
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grabbing most of this text out of the relevant mail thread and writing
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up the pseudocode.
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Copyright (C) 2012-2013 Linaro Limited
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Distributed under the terms of Version 2 of the GNU General Public
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License, as defined in linux/COPYING.
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References
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----------
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[1] Lamport, L. "A New Solution of Dijkstra's Concurrent Programming
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Problem", Communications of the ACM 17, 8 (August 1974), 453-455.
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https://en.wikipedia.org/wiki/Lamport%27s_bakery_algorithm
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[2] linux/arch/arm/common/vlock.S, www.kernel.org.
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