368 lines
9.9 KiB
Plaintext
368 lines
9.9 KiB
Plaintext
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On atomic types (atomic_t atomic64_t and atomic_long_t).
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The atomic type provides an interface to the architecture's means of atomic
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RMW operations between CPUs (atomic operations on MMIO are not supported and
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can lead to fatal traps on some platforms).
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API
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---
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The 'full' API consists of (atomic64_ and atomic_long_ prefixes omitted for
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brevity):
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Non-RMW ops:
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atomic_read(), atomic_set()
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atomic_read_acquire(), atomic_set_release()
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RMW atomic operations:
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Arithmetic:
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atomic_{add,sub,inc,dec}()
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atomic_{add,sub,inc,dec}_return{,_relaxed,_acquire,_release}()
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atomic_fetch_{add,sub,inc,dec}{,_relaxed,_acquire,_release}()
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Bitwise:
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atomic_{and,or,xor,andnot}()
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atomic_fetch_{and,or,xor,andnot}{,_relaxed,_acquire,_release}()
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Swap:
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atomic_xchg{,_relaxed,_acquire,_release}()
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atomic_cmpxchg{,_relaxed,_acquire,_release}()
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atomic_try_cmpxchg{,_relaxed,_acquire,_release}()
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Reference count (but please see refcount_t):
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atomic_add_unless(), atomic_inc_not_zero()
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atomic_sub_and_test(), atomic_dec_and_test()
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Misc:
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atomic_inc_and_test(), atomic_add_negative()
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atomic_dec_unless_positive(), atomic_inc_unless_negative()
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Barriers:
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smp_mb__{before,after}_atomic()
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TYPES (signed vs unsigned)
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-----
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While atomic_t, atomic_long_t and atomic64_t use int, long and s64
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respectively (for hysterical raisins), the kernel uses -fno-strict-overflow
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(which implies -fwrapv) and defines signed overflow to behave like
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2s-complement.
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Therefore, an explicitly unsigned variant of the atomic ops is strictly
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unnecessary and we can simply cast, there is no UB.
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There was a bug in UBSAN prior to GCC-8 that would generate UB warnings for
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signed types.
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With this we also conform to the C/C++ _Atomic behaviour and things like
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P1236R1.
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SEMANTICS
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---------
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Non-RMW ops:
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The non-RMW ops are (typically) regular LOADs and STOREs and are canonically
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implemented using READ_ONCE(), WRITE_ONCE(), smp_load_acquire() and
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smp_store_release() respectively. Therefore, if you find yourself only using
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the Non-RMW operations of atomic_t, you do not in fact need atomic_t at all
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and are doing it wrong.
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A note for the implementation of atomic_set{}() is that it must not break the
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atomicity of the RMW ops. That is:
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C Atomic-RMW-ops-are-atomic-WRT-atomic_set
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{
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atomic_t v = ATOMIC_INIT(1);
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}
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P0(atomic_t *v)
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{
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(void)atomic_add_unless(v, 1, 0);
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}
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P1(atomic_t *v)
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{
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atomic_set(v, 0);
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}
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exists
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(v=2)
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In this case we would expect the atomic_set() from CPU1 to either happen
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before the atomic_add_unless(), in which case that latter one would no-op, or
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_after_ in which case we'd overwrite its result. In no case is "2" a valid
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outcome.
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This is typically true on 'normal' platforms, where a regular competing STORE
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will invalidate a LL/SC or fail a CMPXCHG.
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The obvious case where this is not so is when we need to implement atomic ops
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with a lock:
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CPU0 CPU1
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atomic_add_unless(v, 1, 0);
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lock();
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ret = READ_ONCE(v->counter); // == 1
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atomic_set(v, 0);
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if (ret != u) WRITE_ONCE(v->counter, 0);
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WRITE_ONCE(v->counter, ret + 1);
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unlock();
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the typical solution is to then implement atomic_set{}() with atomic_xchg().
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RMW ops:
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These come in various forms:
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- plain operations without return value: atomic_{}()
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- operations which return the modified value: atomic_{}_return()
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these are limited to the arithmetic operations because those are
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reversible. Bitops are irreversible and therefore the modified value
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is of dubious utility.
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- operations which return the original value: atomic_fetch_{}()
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- swap operations: xchg(), cmpxchg() and try_cmpxchg()
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- misc; the special purpose operations that are commonly used and would,
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given the interface, normally be implemented using (try_)cmpxchg loops but
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are time critical and can, (typically) on LL/SC architectures, be more
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efficiently implemented.
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All these operations are SMP atomic; that is, the operations (for a single
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atomic variable) can be fully ordered and no intermediate state is lost or
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visible.
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ORDERING (go read memory-barriers.txt first)
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--------
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The rule of thumb:
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- non-RMW operations are unordered;
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- RMW operations that have no return value are unordered;
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- RMW operations that have a return value are fully ordered;
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- RMW operations that are conditional are unordered on FAILURE,
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otherwise the above rules apply.
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Except of course when an operation has an explicit ordering like:
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{}_relaxed: unordered
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{}_acquire: the R of the RMW (or atomic_read) is an ACQUIRE
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{}_release: the W of the RMW (or atomic_set) is a RELEASE
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Where 'unordered' is against other memory locations. Address dependencies are
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not defeated.
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Fully ordered primitives are ordered against everything prior and everything
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subsequent. Therefore a fully ordered primitive is like having an smp_mb()
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before and an smp_mb() after the primitive.
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The barriers:
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smp_mb__{before,after}_atomic()
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only apply to the RMW atomic ops and can be used to augment/upgrade the
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ordering inherent to the op. These barriers act almost like a full smp_mb():
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smp_mb__before_atomic() orders all earlier accesses against the RMW op
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itself and all accesses following it, and smp_mb__after_atomic() orders all
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later accesses against the RMW op and all accesses preceding it. However,
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accesses between the smp_mb__{before,after}_atomic() and the RMW op are not
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ordered, so it is advisable to place the barrier right next to the RMW atomic
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op whenever possible.
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These helper barriers exist because architectures have varying implicit
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ordering on their SMP atomic primitives. For example our TSO architectures
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provide full ordered atomics and these barriers are no-ops.
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NOTE: when the atomic RmW ops are fully ordered, they should also imply a
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compiler barrier.
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Thus:
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atomic_fetch_add();
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is equivalent to:
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smp_mb__before_atomic();
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atomic_fetch_add_relaxed();
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smp_mb__after_atomic();
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However the atomic_fetch_add() might be implemented more efficiently.
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Further, while something like:
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smp_mb__before_atomic();
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atomic_dec(&X);
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is a 'typical' RELEASE pattern, the barrier is strictly stronger than
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a RELEASE because it orders preceding instructions against both the read
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and write parts of the atomic_dec(), and against all following instructions
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as well. Similarly, something like:
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atomic_inc(&X);
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smp_mb__after_atomic();
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is an ACQUIRE pattern (though very much not typical), but again the barrier is
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strictly stronger than ACQUIRE. As illustrated:
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C Atomic-RMW+mb__after_atomic-is-stronger-than-acquire
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{
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}
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P0(int *x, atomic_t *y)
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{
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r0 = READ_ONCE(*x);
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smp_rmb();
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r1 = atomic_read(y);
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}
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P1(int *x, atomic_t *y)
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{
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atomic_inc(y);
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smp_mb__after_atomic();
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WRITE_ONCE(*x, 1);
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}
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exists
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(0:r0=1 /\ 0:r1=0)
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This should not happen; but a hypothetical atomic_inc_acquire() --
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(void)atomic_fetch_inc_acquire() for instance -- would allow the outcome,
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because it would not order the W part of the RMW against the following
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WRITE_ONCE. Thus:
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P0 P1
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t = LL.acq *y (0)
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t++;
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*x = 1;
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r0 = *x (1)
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RMB
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r1 = *y (0)
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SC *y, t;
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is allowed.
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CMPXCHG vs TRY_CMPXCHG
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----------------------
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int atomic_cmpxchg(atomic_t *ptr, int old, int new);
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bool atomic_try_cmpxchg(atomic_t *ptr, int *oldp, int new);
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Both provide the same functionality, but try_cmpxchg() can lead to more
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compact code. The functions relate like:
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bool atomic_try_cmpxchg(atomic_t *ptr, int *oldp, int new)
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{
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int ret, old = *oldp;
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ret = atomic_cmpxchg(ptr, old, new);
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if (ret != old)
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*oldp = ret;
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return ret == old;
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}
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and:
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int atomic_cmpxchg(atomic_t *ptr, int old, int new)
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{
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(void)atomic_try_cmpxchg(ptr, &old, new);
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return old;
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}
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Usage:
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old = atomic_read(&v); old = atomic_read(&v);
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for (;;) { do {
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new = func(old); new = func(old);
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tmp = atomic_cmpxchg(&v, old, new); } while (!atomic_try_cmpxchg(&v, &old, new));
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if (tmp == old)
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break;
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old = tmp;
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}
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NB. try_cmpxchg() also generates better code on some platforms (notably x86)
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where the function more closely matches the hardware instruction.
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FORWARD PROGRESS
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----------------
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In general strong forward progress is expected of all unconditional atomic
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operations -- those in the Arithmetic and Bitwise classes and xchg(). However
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a fair amount of code also requires forward progress from the conditional
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atomic operations.
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Specifically 'simple' cmpxchg() loops are expected to not starve one another
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indefinitely. However, this is not evident on LL/SC architectures, because
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while an LL/SC architecure 'can/should/must' provide forward progress
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guarantees between competing LL/SC sections, such a guarantee does not
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transfer to cmpxchg() implemented using LL/SC. Consider:
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old = atomic_read(&v);
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do {
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new = func(old);
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} while (!atomic_try_cmpxchg(&v, &old, new));
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which on LL/SC becomes something like:
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old = atomic_read(&v);
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do {
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new = func(old);
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} while (!({
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volatile asm ("1: LL %[oldval], %[v]\n"
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" CMP %[oldval], %[old]\n"
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" BNE 2f\n"
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" SC %[new], %[v]\n"
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" BNE 1b\n"
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"2:\n"
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: [oldval] "=&r" (oldval), [v] "m" (v)
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: [old] "r" (old), [new] "r" (new)
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: "memory");
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success = (oldval == old);
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if (!success)
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old = oldval;
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success; }));
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However, even the forward branch from the failed compare can cause the LL/SC
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to fail on some architectures, let alone whatever the compiler makes of the C
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loop body. As a result there is no guarantee what so ever the cacheline
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containing @v will stay on the local CPU and progress is made.
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Even native CAS architectures can fail to provide forward progress for their
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primitive (See Sparc64 for an example).
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Such implementations are strongly encouraged to add exponential backoff loops
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to a failed CAS in order to ensure some progress. Affected architectures are
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also strongly encouraged to inspect/audit the atomic fallbacks, refcount_t and
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their locking primitives.
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