.. _atomics-ref: ========================= Atomic operations in QEMU ========================= CPUs perform independent memory operations effectively in random order. but this can be a problem for CPU-CPU interaction (including interactions between QEMU and the guest). Multi-threaded programs use various tools to instruct the compiler and the CPU to restrict the order to something that is consistent with the expectations of the programmer. The most basic tool is locking. Mutexes, condition variables and semaphores are used in QEMU, and should be the default approach to synchronization. Anything else is considerably harder, but it's also justified more often than one would like; the most performance-critical parts of QEMU in particular require a very low level approach to concurrency, involving memory barriers and atomic operations. The semantics of concurrent memory accesses are governed by the C11 memory model. QEMU provides a header, ``qemu/atomic.h``, which wraps C11 atomics to provide better portability and a less verbose syntax. ``qemu/atomic.h`` provides macros that fall in three camps: - compiler barriers: ``barrier()``; - weak atomic access and manual memory barriers: ``qatomic_read()``, ``qatomic_set()``, ``smp_rmb()``, ``smp_wmb()``, ``smp_mb()``, ``smp_mb_acquire()``, ``smp_mb_release()``, ``smp_read_barrier_depends()``, ``smp_mb__before_rmw()``, ``smp_mb__after_rmw()``; - sequentially consistent atomic access: everything else. In general, use of ``qemu/atomic.h`` should be wrapped with more easily used data structures (e.g. the lock-free singly-linked list operations ``QSLIST_INSERT_HEAD_ATOMIC`` and ``QSLIST_MOVE_ATOMIC``) or synchronization primitives (such as RCU, ``QemuEvent`` or ``QemuLockCnt``). Bare use of atomic operations and memory barriers should be limited to inter-thread checking of flags and documented thoroughly. Compiler memory barrier ======================= ``barrier()`` prevents the compiler from moving the memory accesses on either side of it to the other side. The compiler barrier has no direct effect on the CPU, which may then reorder things however it wishes. ``barrier()`` is mostly used within ``qemu/atomic.h`` itself. On some architectures, CPU guarantees are strong enough that blocking compiler optimizations already ensures the correct order of execution. In this case, ``qemu/atomic.h`` will reduce stronger memory barriers to simple compiler barriers. Still, ``barrier()`` can be useful when writing code that can be interrupted by signal handlers. Sequentially consistent atomic access ===================================== Most of the operations in the ``qemu/atomic.h`` header ensure *sequential consistency*, where "the result of any execution is the same as if the operations of all the processors were executed in some sequential order, and the operations of each individual processor appear in this sequence in the order specified by its program". ``qemu/atomic.h`` provides the following set of atomic read-modify-write operations:: void qatomic_inc(ptr) void qatomic_dec(ptr) void qatomic_add(ptr, val) void qatomic_sub(ptr, val) void qatomic_and(ptr, val) void qatomic_or(ptr, val) typeof(*ptr) qatomic_fetch_inc(ptr) typeof(*ptr) qatomic_fetch_dec(ptr) typeof(*ptr) qatomic_fetch_add(ptr, val) typeof(*ptr) qatomic_fetch_sub(ptr, val) typeof(*ptr) qatomic_fetch_and(ptr, val) typeof(*ptr) qatomic_fetch_or(ptr, val) typeof(*ptr) qatomic_fetch_xor(ptr, val) typeof(*ptr) qatomic_fetch_inc_nonzero(ptr) typeof(*ptr) qatomic_xchg(ptr, val) typeof(*ptr) qatomic_cmpxchg(ptr, old, new) all of which return the old value of ``*ptr``. These operations are polymorphic; they operate on any type that is as wide as a pointer or smaller. Similar operations return the new value of ``*ptr``:: typeof(*ptr) qatomic_inc_fetch(ptr) typeof(*ptr) qatomic_dec_fetch(ptr) typeof(*ptr) qatomic_add_fetch(ptr, val) typeof(*ptr) qatomic_sub_fetch(ptr, val) typeof(*ptr) qatomic_and_fetch(ptr, val) typeof(*ptr) qatomic_or_fetch(ptr, val) typeof(*ptr) qatomic_xor_fetch(ptr, val) ``qemu/atomic.h`` also provides an optimized shortcut for ``qatomic_set`` followed by ``smp_mb``:: void qatomic_set_mb(ptr, val) Weak atomic access and manual memory barriers ============================================= Compared to sequentially consistent atomic access, programming with weaker consistency models can be considerably more complicated. The only guarantees that you can rely upon in this case are: - atomic accesses will not cause data races (and hence undefined behavior); ordinary accesses instead cause data races if they are concurrent with other accesses of which at least one is a write. In order to ensure this, the compiler will not optimize accesses out of existence, create unsolicited accesses, or perform other similar optimizations. - acquire operations will appear to happen, with respect to the other components of the system, before all the LOAD or STORE operations specified afterwards. - release operations will appear to happen, with respect to the other components of the system, after all the LOAD or STORE operations specified before. - release operations will *synchronize with* acquire operations; see :ref:`acqrel` for a detailed explanation. When using this model, variables are accessed with: - ``qatomic_read()`` and ``qatomic_set()``; these prevent the compiler from optimizing accesses out of existence and creating unsolicited accesses, but do not otherwise impose any ordering on loads and stores: both the compiler and the processor are free to reorder them. - ``qatomic_load_acquire()``, which guarantees the LOAD to appear to happen, with respect to the other components of the system, before all the LOAD or STORE operations specified afterwards. Operations coming before ``qatomic_load_acquire()`` can still be reordered after it. - ``qatomic_store_release()``, which guarantees the STORE to appear to happen, with respect to the other components of the system, after all the LOAD or STORE operations specified before. Operations coming after ``qatomic_store_release()`` can still be reordered before it. Restrictions to the ordering of accesses can also be specified using the memory barrier macros: ``smp_rmb()``, ``smp_wmb()``, ``smp_mb()``, ``smp_mb_acquire()``, ``smp_mb_release()``, ``smp_read_barrier_depends()``. Memory barriers control the order of references to shared memory. They come in six kinds: - ``smp_rmb()`` guarantees that all the LOAD operations specified before the barrier will appear to happen before all the LOAD operations specified after the barrier with respect to the other components of the system. In other words, ``smp_rmb()`` puts a partial ordering on loads, but is not required to have any effect on stores. - ``smp_wmb()`` guarantees that all the STORE operations specified before the barrier will appear to happen before all the STORE operations specified after the barrier with respect to the other components of the system. In other words, ``smp_wmb()`` puts a partial ordering on stores, but is not required to have any effect on loads. - ``smp_mb_acquire()`` guarantees that all the LOAD operations specified before the barrier will appear to happen before all the LOAD or STORE operations specified after the barrier with respect to the other components of the system. - ``smp_mb_release()`` guarantees that all the STORE operations specified *after* the barrier will appear to happen after all the LOAD or STORE operations specified *before* the barrier with respect to the other components of the system. - ``smp_mb()`` guarantees that all the LOAD and STORE operations specified before the barrier will appear to happen before all the LOAD and STORE operations specified after the barrier with respect to the other components of the system. ``smp_mb()`` puts a partial ordering on both loads and stores. It is stronger than both a read and a write memory barrier; it implies both ``smp_mb_acquire()`` and ``smp_mb_release()``, but it also prevents STOREs coming before the barrier from overtaking LOADs coming after the barrier and vice versa. - ``smp_read_barrier_depends()`` is a weaker kind of read barrier. On most processors, whenever two loads are performed such that the second depends on the result of the first (e.g., the first load retrieves the address to which the second load will be directed), the processor will guarantee that the first LOAD will appear to happen before the second with respect to the other components of the system. Therefore, unlike ``smp_rmb()`` or ``qatomic_load_acquire()``, ``smp_read_barrier_depends()`` can be just a compiler barrier on weakly-ordered architectures such as Arm or PPC\ [#alpha]_. Note that the first load really has to have a _data_ dependency and not a control dependency. If the address for the second load is dependent on the first load, but the dependency is through a conditional rather than actually loading the address itself, then it's a _control_ dependency and a full read barrier or better is required. .. [#alpha] The DEC Alpha is an exception, because ``smp_read_barrier_depends()`` needs a processor barrier. On strongly-ordered architectures such as x86 or s390, ``smp_rmb()`` and ``qatomic_load_acquire()`` can also be compiler barriers only. Memory barriers and ``qatomic_load_acquire``/``qatomic_store_release`` are mostly used when a data structure has one thread that is always a writer and one thread that is always a reader: +----------------------------------+----------------------------------+ | thread 1 | thread 2 | +==================================+==================================+ | :: | :: | | | | | qatomic_store_release(&a, x); | y = qatomic_load_acquire(&b); | | qatomic_store_release(&b, y); | x = qatomic_load_acquire(&a); | +----------------------------------+----------------------------------+ In this case, correctness is easy to check for using the "pairing" trick that is explained below. Sometimes, a thread is accessing many variables that are otherwise unrelated to each other (for example because, apart from the current thread, exactly one other thread will read or write each of these variables). In this case, it is possible to "hoist" the barriers outside a loop. For example: +------------------------------------------+----------------------------------+ | before | after | +==========================================+==================================+ | :: | :: | | | | | n = 0; | n = 0; | | for (i = 0; i < 10; i++) | for (i = 0; i < 10; i++) | | n += qatomic_load_acquire(&a[i]); | n += qatomic_read(&a[i]); | | | smp_mb_acquire(); | +------------------------------------------+----------------------------------+ | :: | :: | | | | | | smp_mb_release(); | | for (i = 0; i < 10; i++) | for (i = 0; i < 10; i++) | | qatomic_store_release(&a[i], false); | qatomic_set(&a[i], false); | +------------------------------------------+----------------------------------+ Splitting a loop can also be useful to reduce the number of barriers: +------------------------------------------+----------------------------------+ | before | after | +==========================================+==================================+ | :: | :: | | | | | n = 0; | smp_mb_release(); | | for (i = 0; i < 10; i++) { | for (i = 0; i < 10; i++) | | qatomic_store_release(&a[i], false); | qatomic_set(&a[i], false); | | smp_mb(); | smb_mb(); | | n += qatomic_read(&b[i]); | n = 0; | | } | for (i = 0; i < 10; i++) | | | n += qatomic_read(&b[i]); | +------------------------------------------+----------------------------------+ In this case, a ``smp_mb_release()`` is also replaced with a (possibly cheaper, and clearer as well) ``smp_wmb()``: +------------------------------------------+----------------------------------+ | before | after | +==========================================+==================================+ | :: | :: | | | | | | smp_mb_release(); | | for (i = 0; i < 10; i++) { | for (i = 0; i < 10; i++) | | qatomic_store_release(&a[i], false); | qatomic_set(&a[i], false); | | qatomic_store_release(&b[i], false); | smb_wmb(); | | } | for (i = 0; i < 10; i++) | | | qatomic_set(&b[i], false); | +------------------------------------------+----------------------------------+ .. _acqrel: Acquire/release pairing and the *synchronizes-with* relation ------------------------------------------------------------ Atomic operations other than ``qatomic_set()`` and ``qatomic_read()`` have either *acquire* or *release* semantics\ [#rmw]_. This has two effects: .. [#rmw] Read-modify-write operations can have both---acquire applies to the read part, and release to the write. - within a thread, they are ordered either before subsequent operations (for acquire) or after previous operations (for release). - if a release operation in one thread *synchronizes with* an acquire operation in another thread, the ordering constraints propagates from the first to the second thread. That is, everything before the release operation in the first thread is guaranteed to *happen before* everything after the acquire operation in the second thread. The concept of acquire and release semantics is not exclusive to atomic operations; almost all higher-level synchronization primitives also have acquire or release semantics. For example: - ``pthread_mutex_lock`` has acquire semantics, ``pthread_mutex_unlock`` has release semantics and synchronizes with a ``pthread_mutex_lock`` for the same mutex. - ``pthread_cond_signal`` and ``pthread_cond_broadcast`` have release semantics; ``pthread_cond_wait`` has both release semantics (synchronizing with ``pthread_mutex_lock``) and acquire semantics (synchronizing with ``pthread_mutex_unlock`` and signaling of the condition variable). - ``pthread_create`` has release semantics and synchronizes with the start of the new thread; ``pthread_join`` has acquire semantics and synchronizes with the exiting of the thread. - ``qemu_event_set`` has release semantics, ``qemu_event_wait`` has acquire semantics. For example, in the following example there are no atomic accesses, but still thread 2 is relying on the *synchronizes-with* relation between ``pthread_exit`` (release) and ``pthread_join`` (acquire): +----------------------+-------------------------------+ | thread 1 | thread 2 | +======================+===============================+ | :: | :: | | | | | *a = 1; | | | pthread_exit(a); | pthread_join(thread1, &a); | | | x = *a; | +----------------------+-------------------------------+ Synchronization between threads basically descends from this pairing of a release operation and an acquire operation. Therefore, atomic operations other than ``qatomic_set()`` and ``qatomic_read()`` will almost always be paired with another operation of the opposite kind: an acquire operation will pair with a release operation and vice versa. This rule of thumb is extremely useful; in the case of QEMU, however, note that the other operation may actually be in a driver that runs in the guest! ``smp_read_barrier_depends()``, ``smp_rmb()``, ``smp_mb_acquire()``, ``qatomic_load_acquire()`` and ``qatomic_rcu_read()`` all count as acquire operations. ``smp_wmb()``, ``smp_mb_release()``, ``qatomic_store_release()`` and ``qatomic_rcu_set()`` all count as release operations. ``smp_mb()`` counts as both acquire and release, therefore it can pair with any other atomic operation. Here is an example: +----------------------+------------------------------+ | thread 1 | thread 2 | +======================+==============================+ | :: | :: | | | | | qatomic_set(&a, 1);| | | smp_wmb(); | | | qatomic_set(&b, 2);| x = qatomic_read(&b); | | | smp_rmb(); | | | y = qatomic_read(&a); | +----------------------+------------------------------+ Note that a load-store pair only counts if the two operations access the same variable: that is, a store-release on a variable ``x`` *synchronizes with* a load-acquire on a variable ``x``, while a release barrier synchronizes with any acquire operation. The following example shows correct synchronization: +--------------------------------+--------------------------------+ | thread 1 | thread 2 | +================================+================================+ | :: | :: | | | | | qatomic_set(&a, 1); | | | qatomic_store_release(&b, 2);| x = qatomic_load_acquire(&b);| | | y = qatomic_read(&a); | +--------------------------------+--------------------------------+ Acquire and release semantics of higher-level primitives can also be relied upon for the purpose of establishing the *synchronizes with* relation. Note that the "writing" thread is accessing the variables in the opposite order as the "reading" thread. This is expected: stores before a release operation will normally match the loads after the acquire operation, and vice versa. In fact, this happened already in the ``pthread_exit``/``pthread_join`` example above. Finally, this more complex example has more than two accesses and data dependency barriers. It also does not use atomic accesses whenever there cannot be a data race: +----------------------+------------------------------+ | thread 1 | thread 2 | +======================+==============================+ | :: | :: | | | | | b[2] = 1; | | | smp_wmb(); | | | x->i = 2; | | | smp_wmb(); | | | qatomic_set(&a, x);| x = qatomic_read(&a); | | | smp_read_barrier_depends(); | | | y = x->i; | | | smp_read_barrier_depends(); | | | z = b[y]; | +----------------------+------------------------------+ Comparison with Linux kernel primitives ======================================= Here is a list of differences between Linux kernel atomic operations and memory barriers, and the equivalents in QEMU: - atomic operations in Linux are always on a 32-bit int type and use a boxed ``atomic_t`` type; atomic operations in QEMU are polymorphic and use normal C types. - Originally, ``atomic_read`` and ``atomic_set`` in Linux gave no guarantee at all. Linux 4.1 updated them to implement volatile semantics via ``ACCESS_ONCE`` (or the more recent ``READ``/``WRITE_ONCE``). QEMU's ``qatomic_read`` and ``qatomic_set`` implement C11 atomic relaxed semantics if the compiler supports it, and volatile semantics otherwise. Both semantics prevent the compiler from doing certain transformations; the difference is that atomic accesses are guaranteed to be atomic, while volatile accesses aren't. Thus, in the volatile case we just cross our fingers hoping that the compiler will generate atomic accesses, since we assume the variables passed are machine-word sized and properly aligned. No barriers are implied by ``qatomic_read`` and ``qatomic_set`` in either Linux or QEMU. - atomic read-modify-write operations in Linux are of three kinds: ===================== ========================================= ``atomic_OP`` returns void ``atomic_OP_return`` returns new value of the variable ``atomic_fetch_OP`` returns the old value of the variable ``atomic_cmpxchg`` returns the old value of the variable ===================== ========================================= In QEMU, the second kind is named ``atomic_OP_fetch``. - different atomic read-modify-write operations in Linux imply a different set of memory barriers. In QEMU, all of them enforce sequential consistency: there is a single order in which the program sees them happen. - however, according to the C11 memory model that QEMU uses, this order does not propagate to other memory accesses on either side of the read-modify-write operation. As far as those are concerned, the operation consist of just a load-acquire followed by a store-release. Stores that precede the RMW operation, and loads that follow it, can still be reordered and will happen *in the middle* of the read-modify-write operation! Therefore, the following example is correct in Linux but not in QEMU: +----------------------------------+--------------------------------+ | Linux (correct) | QEMU (incorrect) | +==================================+================================+ | :: | :: | | | | | a = atomic_fetch_add(&x, 2); | a = qatomic_fetch_add(&x, 2);| | b = READ_ONCE(&y); | b = qatomic_read(&y); | +----------------------------------+--------------------------------+ because the read of ``y`` can be moved (by either the processor or the compiler) before the write of ``x``. Fixing this requires a full memory barrier between the write of ``x`` and the read of ``y``. QEMU provides ``smp_mb__before_rmw()`` and ``smp_mb__after_rmw()``; they act both as an optimization, avoiding the memory barrier on processors where it is unnecessary, and as a clarification of this corner case of the C11 memory model: +--------------------------------+ | QEMU (correct) | +================================+ | :: | | | | a = qatomic_fetch_add(&x, 2);| | smp_mb__after_rmw(); | | b = qatomic_read(&y); | +--------------------------------+ In the common case where only one thread writes ``x``, it is also possible to write it like this: +--------------------------------+ | QEMU (correct) | +================================+ | :: | | | | a = qatomic_read(&x); | | qatomic_set_mb(&x, a + 2); | | b = qatomic_read(&y); | +--------------------------------+ Sources ======= - ``Documentation/memory-barriers.txt`` from the Linux kernel