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==============================================
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LLVM Atomic Instructions and Concurrency Guide
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==============================================
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.. contents::
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:local:
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Introduction
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============
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LLVM supports instructions which are well-defined in the presence of threads and
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asynchronous signals.
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The atomic instructions are designed specifically to provide readable IR and
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optimized code generation for the following:
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* The C++11 ``<atomic>`` header. (`C++11 draft available here
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<http://www.open-std.org/jtc1/sc22/wg21/>`_.) (`C11 draft available here
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<http://www.open-std.org/jtc1/sc22/wg14/>`_.)
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* Proper semantics for Java-style memory, for both ``volatile`` and regular
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shared variables. (`Java Specification
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<http://docs.oracle.com/javase/specs/jls/se8/html/jls-17.html>`_)
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* gcc-compatible ``__sync_*`` builtins. (`Description
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<https://gcc.gnu.org/onlinedocs/gcc/_005f_005fsync-Builtins.html>`_)
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* Other scenarios with atomic semantics, including ``static`` variables with
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non-trivial constructors in C++.
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Atomic and volatile in the IR are orthogonal; "volatile" is the C/C++ volatile,
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which ensures that every volatile load and store happens and is performed in the
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stated order. A couple examples: if a SequentiallyConsistent store is
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immediately followed by another SequentiallyConsistent store to the same
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address, the first store can be erased. This transformation is not allowed for a
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pair of volatile stores. On the other hand, a non-volatile non-atomic load can
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be moved across a volatile load freely, but not an Acquire load.
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This document is intended to provide a guide to anyone either writing a frontend
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for LLVM or working on optimization passes for LLVM with a guide for how to deal
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with instructions with special semantics in the presence of concurrency. This
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is not intended to be a precise guide to the semantics; the details can get
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extremely complicated and unreadable, and are not usually necessary.
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.. _Optimization outside atomic:
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Optimization outside atomic
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===========================
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The basic ``'load'`` and ``'store'`` allow a variety of optimizations, but can
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lead to undefined results in a concurrent environment; see `NotAtomic`_. This
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section specifically goes into the one optimizer restriction which applies in
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concurrent environments, which gets a bit more of an extended description
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because any optimization dealing with stores needs to be aware of it.
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From the optimizer's point of view, the rule is that if there are not any
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instructions with atomic ordering involved, concurrency does not matter, with
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one exception: if a variable might be visible to another thread or signal
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handler, a store cannot be inserted along a path where it might not execute
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otherwise. Take the following example:
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.. code-block:: c
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/* C code, for readability; run through clang -O2 -S -emit-llvm to get
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equivalent IR */
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int x;
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void f(int* a) {
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for (int i = 0; i < 100; i++) {
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if (a[i])
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x += 1;
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}
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}
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The following is equivalent in non-concurrent situations:
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.. code-block:: c
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int x;
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void f(int* a) {
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int xtemp = x;
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for (int i = 0; i < 100; i++) {
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if (a[i])
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xtemp += 1;
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}
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x = xtemp;
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}
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However, LLVM is not allowed to transform the former to the latter: it could
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indirectly introduce undefined behavior if another thread can access ``x`` at
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the same time. (This example is particularly of interest because before the
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concurrency model was implemented, LLVM would perform this transformation.)
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Note that speculative loads are allowed; a load which is part of a race returns
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``undef``, but does not have undefined behavior.
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Atomic instructions
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===================
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For cases where simple loads and stores are not sufficient, LLVM provides
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various atomic instructions. The exact guarantees provided depend on the
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ordering; see `Atomic orderings`_.
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``load atomic`` and ``store atomic`` provide the same basic functionality as
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non-atomic loads and stores, but provide additional guarantees in situations
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where threads and signals are involved.
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``cmpxchg`` and ``atomicrmw`` are essentially like an atomic load followed by an
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atomic store (where the store is conditional for ``cmpxchg``), but no other
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memory operation can happen on any thread between the load and store.
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A ``fence`` provides Acquire and/or Release ordering which is not part of
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another operation; it is normally used along with Monotonic memory operations.
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A Monotonic load followed by an Acquire fence is roughly equivalent to an
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Acquire load, and a Monotonic store following a Release fence is roughly
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equivalent to a Release store. SequentiallyConsistent fences behave as both
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an Acquire and a Release fence, and offer some additional complicated
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guarantees, see the C++11 standard for details.
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Frontends generating atomic instructions generally need to be aware of the
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target to some degree; atomic instructions are guaranteed to be lock-free, and
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therefore an instruction which is wider than the target natively supports can be
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impossible to generate.
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.. _Atomic orderings:
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Atomic orderings
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================
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In order to achieve a balance between performance and necessary guarantees,
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there are six levels of atomicity. They are listed in order of strength; each
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level includes all the guarantees of the previous level except for
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Acquire/Release. (See also `LangRef Ordering <LangRef.html#ordering>`_.)
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.. _NotAtomic:
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NotAtomic
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---------
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NotAtomic is the obvious, a load or store which is not atomic. (This isn't
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really a level of atomicity, but is listed here for comparison.) This is
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essentially a regular load or store. If there is a race on a given memory
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location, loads from that location return undef.
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Relevant standard
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This is intended to match shared variables in C/C++, and to be used in any
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other context where memory access is necessary, and a race is impossible. (The
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precise definition is in `LangRef Memory Model <LangRef.html#memmodel>`_.)
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Notes for frontends
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The rule is essentially that all memory accessed with basic loads and stores
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by multiple threads should be protected by a lock or other synchronization;
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otherwise, you are likely to run into undefined behavior. If your frontend is
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for a "safe" language like Java, use Unordered to load and store any shared
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variable. Note that NotAtomic volatile loads and stores are not properly
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atomic; do not try to use them as a substitute. (Per the C/C++ standards,
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volatile does provide some limited guarantees around asynchronous signals, but
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atomics are generally a better solution.)
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Notes for optimizers
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Introducing loads to shared variables along a codepath where they would not
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otherwise exist is allowed; introducing stores to shared variables is not. See
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`Optimization outside atomic`_.
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Notes for code generation
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The one interesting restriction here is that it is not allowed to write to
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bytes outside of the bytes relevant to a store. This is mostly relevant to
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unaligned stores: it is not allowed in general to convert an unaligned store
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into two aligned stores of the same width as the unaligned store. Backends are
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also expected to generate an i8 store as an i8 store, and not an instruction
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which writes to surrounding bytes. (If you are writing a backend for an
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architecture which cannot satisfy these restrictions and cares about
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concurrency, please send an email to llvm-dev.)
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Unordered
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---------
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Unordered is the lowest level of atomicity. It essentially guarantees that races
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produce somewhat sane results instead of having undefined behavior. It also
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guarantees the operation to be lock-free, so it does not depend on the data
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being part of a special atomic structure or depend on a separate per-process
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global lock. Note that code generation will fail for unsupported atomic
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operations; if you need such an operation, use explicit locking.
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Relevant standard
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This is intended to match the Java memory model for shared variables.
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Notes for frontends
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This cannot be used for synchronization, but is useful for Java and other
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"safe" languages which need to guarantee that the generated code never
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exhibits undefined behavior. Note that this guarantee is cheap on common
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platforms for loads of a native width, but can be expensive or unavailable for
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wider loads, like a 64-bit store on ARM. (A frontend for Java or other "safe"
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languages would normally split a 64-bit store on ARM into two 32-bit unordered
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stores.)
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Notes for optimizers
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In terms of the optimizer, this prohibits any transformation that transforms a
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single load into multiple loads, transforms a store into multiple stores,
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narrows a store, or stores a value which would not be stored otherwise. Some
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examples of unsafe optimizations are narrowing an assignment into a bitfield,
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rematerializing a load, and turning loads and stores into a memcpy
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call. Reordering unordered operations is safe, though, and optimizers should
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take advantage of that because unordered operations are common in languages
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that need them.
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Notes for code generation
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These operations are required to be atomic in the sense that if you use
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unordered loads and unordered stores, a load cannot see a value which was
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never stored. A normal load or store instruction is usually sufficient, but
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note that an unordered load or store cannot be split into multiple
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instructions (or an instruction which does multiple memory operations, like
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``LDRD`` on ARM without LPAE, or not naturally-aligned ``LDRD`` on LPAE ARM).
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Monotonic
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---------
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Monotonic is the weakest level of atomicity that can be used in synchronization
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primitives, although it does not provide any general synchronization. It
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essentially guarantees that if you take all the operations affecting a specific
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address, a consistent ordering exists.
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Relevant standard
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This corresponds to the C++11/C11 ``memory_order_relaxed``; see those
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standards for the exact definition.
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Notes for frontends
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If you are writing a frontend which uses this directly, use with caution. The
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guarantees in terms of synchronization are very weak, so make sure these are
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only used in a pattern which you know is correct. Generally, these would
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either be used for atomic operations which do not protect other memory (like
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an atomic counter), or along with a ``fence``.
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Notes for optimizers
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In terms of the optimizer, this can be treated as a read+write on the relevant
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memory location (and alias analysis will take advantage of that). In addition,
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it is legal to reorder non-atomic and Unordered loads around Monotonic
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loads. CSE/DSE and a few other optimizations are allowed, but Monotonic
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operations are unlikely to be used in ways which would make those
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optimizations useful.
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Notes for code generation
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Code generation is essentially the same as that for unordered for loads and
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stores. No fences are required. ``cmpxchg`` and ``atomicrmw`` are required
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to appear as a single operation.
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Acquire
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-------
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Acquire provides a barrier of the sort necessary to acquire a lock to access
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other memory with normal loads and stores.
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Relevant standard
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This corresponds to the C++11/C11 ``memory_order_acquire``. It should also be
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used for C++11/C11 ``memory_order_consume``.
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Notes for frontends
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If you are writing a frontend which uses this directly, use with caution.
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Acquire only provides a semantic guarantee when paired with a Release
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operation.
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Notes for optimizers
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Optimizers not aware of atomics can treat this like a nothrow call. It is
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also possible to move stores from before an Acquire load or read-modify-write
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operation to after it, and move non-Acquire loads from before an Acquire
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operation to after it.
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Notes for code generation
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Architectures with weak memory ordering (essentially everything relevant today
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except x86 and SPARC) require some sort of fence to maintain the Acquire
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semantics. The precise fences required varies widely by architecture, but for
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a simple implementation, most architectures provide a barrier which is strong
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enough for everything (``dmb`` on ARM, ``sync`` on PowerPC, etc.). Putting
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such a fence after the equivalent Monotonic operation is sufficient to
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maintain Acquire semantics for a memory operation.
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Release
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-------
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Release is similar to Acquire, but with a barrier of the sort necessary to
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release a lock.
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Relevant standard
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This corresponds to the C++11/C11 ``memory_order_release``.
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Notes for frontends
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If you are writing a frontend which uses this directly, use with caution.
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Release only provides a semantic guarantee when paired with a Acquire
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operation.
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Notes for optimizers
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Optimizers not aware of atomics can treat this like a nothrow call. It is
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also possible to move loads from after a Release store or read-modify-write
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operation to before it, and move non-Release stores from after an Release
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operation to before it.
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Notes for code generation
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See the section on Acquire; a fence before the relevant operation is usually
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sufficient for Release. Note that a store-store fence is not sufficient to
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implement Release semantics; store-store fences are generally not exposed to
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IR because they are extremely difficult to use correctly.
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AcquireRelease
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--------------
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AcquireRelease (``acq_rel`` in IR) provides both an Acquire and a Release
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barrier (for fences and operations which both read and write memory).
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Relevant standard
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This corresponds to the C++11/C11 ``memory_order_acq_rel``.
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Notes for frontends
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If you are writing a frontend which uses this directly, use with caution.
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Acquire only provides a semantic guarantee when paired with a Release
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operation, and vice versa.
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Notes for optimizers
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In general, optimizers should treat this like a nothrow call; the possible
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optimizations are usually not interesting.
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Notes for code generation
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This operation has Acquire and Release semantics; see the sections on Acquire
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and Release.
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SequentiallyConsistent
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----------------------
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SequentiallyConsistent (``seq_cst`` in IR) provides Acquire semantics for loads
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and Release semantics for stores. Additionally, it guarantees that a total
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ordering exists between all SequentiallyConsistent operations.
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Relevant standard
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This corresponds to the C++11/C11 ``memory_order_seq_cst``, Java volatile, and
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the gcc-compatible ``__sync_*`` builtins which do not specify otherwise.
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Notes for frontends
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If a frontend is exposing atomic operations, these are much easier to reason
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about for the programmer than other kinds of operations, and using them is
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generally a practical performance tradeoff.
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Notes for optimizers
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Optimizers not aware of atomics can treat this like a nothrow call. For
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SequentiallyConsistent loads and stores, the same reorderings are allowed as
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for Acquire loads and Release stores, except that SequentiallyConsistent
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operations may not be reordered.
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Notes for code generation
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SequentiallyConsistent loads minimally require the same barriers as Acquire
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operations and SequentiallyConsistent stores require Release
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barriers. Additionally, the code generator must enforce ordering between
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SequentiallyConsistent stores followed by SequentiallyConsistent loads. This
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is usually done by emitting either a full fence before the loads or a full
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fence after the stores; which is preferred varies by architecture.
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Atomics and IR optimization
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===========================
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Predicates for optimizer writers to query:
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* ``isSimple()``: A load or store which is not volatile or atomic. This is
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what, for example, memcpyopt would check for operations it might transform.
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* ``isUnordered()``: A load or store which is not volatile and at most
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Unordered. This would be checked, for example, by LICM before hoisting an
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operation.
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* ``mayReadFromMemory()``/``mayWriteToMemory()``: Existing predicate, but note
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that they return true for any operation which is volatile or at least
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Monotonic.
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* ``isStrongerThan`` / ``isAtLeastOrStrongerThan``: These are predicates on
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orderings. They can be useful for passes that are aware of atomics, for
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example to do DSE across a single atomic access, but not across a
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release-acquire pair (see MemoryDependencyAnalysis for an example of this)
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* Alias analysis: Note that AA will return ModRef for anything Acquire or
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Release, and for the address accessed by any Monotonic operation.
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To support optimizing around atomic operations, make sure you are using the
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right predicates; everything should work if that is done. If your pass should
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optimize some atomic operations (Unordered operations in particular), make sure
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it doesn't replace an atomic load or store with a non-atomic operation.
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Some examples of how optimizations interact with various kinds of atomic
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operations:
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* ``memcpyopt``: An atomic operation cannot be optimized into part of a
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memcpy/memset, including unordered loads/stores. It can pull operations
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across some atomic operations.
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* LICM: Unordered loads/stores can be moved out of a loop. It just treats
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monotonic operations like a read+write to a memory location, and anything
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stricter than that like a nothrow call.
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* DSE: Unordered stores can be DSE'ed like normal stores. Monotonic stores can
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be DSE'ed in some cases, but it's tricky to reason about, and not especially
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important. It is possible in some case for DSE to operate across a stronger
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atomic operation, but it is fairly tricky. DSE delegates this reasoning to
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MemoryDependencyAnalysis (which is also used by other passes like GVN).
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* Folding a load: Any atomic load from a constant global can be constant-folded,
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because it cannot be observed. Similar reasoning allows sroa with
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atomic loads and stores.
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Atomics and Codegen
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===================
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Atomic operations are represented in the SelectionDAG with ``ATOMIC_*`` opcodes.
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On architectures which use barrier instructions for all atomic ordering (like
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ARM), appropriate fences can be emitted by the AtomicExpand Codegen pass if
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``setInsertFencesForAtomic()`` was used.
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The MachineMemOperand for all atomic operations is currently marked as volatile;
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this is not correct in the IR sense of volatile, but CodeGen handles anything
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marked volatile very conservatively. This should get fixed at some point.
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One very important property of the atomic operations is that if your backend
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supports any inline lock-free atomic operations of a given size, you should
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support *ALL* operations of that size in a lock-free manner.
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When the target implements atomic ``cmpxchg`` or LL/SC instructions (as most do)
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this is trivial: all the other operations can be implemented on top of those
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primitives. However, on many older CPUs (e.g. ARMv5, SparcV8, Intel 80386) there
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are atomic load and store instructions, but no ``cmpxchg`` or LL/SC. As it is
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invalid to implement ``atomic load`` using the native instruction, but
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``cmpxchg`` using a library call to a function that uses a mutex, ``atomic
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load`` must *also* expand to a library call on such architectures, so that it
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can remain atomic with regards to a simultaneous ``cmpxchg``, by using the same
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mutex.
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AtomicExpandPass can help with that: it will expand all atomic operations to the
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proper ``__atomic_*`` libcalls for any size above the maximum set by
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``setMaxAtomicSizeInBitsSupported`` (which defaults to 0).
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On x86, all atomic loads generate a ``MOV``. SequentiallyConsistent stores
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generate an ``XCHG``, other stores generate a ``MOV``. SequentiallyConsistent
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fences generate an ``MFENCE``, other fences do not cause any code to be
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generated. ``cmpxchg`` uses the ``LOCK CMPXCHG`` instruction. ``atomicrmw xchg``
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uses ``XCHG``, ``atomicrmw add`` and ``atomicrmw sub`` use ``XADD``, and all
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other ``atomicrmw`` operations generate a loop with ``LOCK CMPXCHG``. Depending
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on the users of the result, some ``atomicrmw`` operations can be translated into
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operations like ``LOCK AND``, but that does not work in general.
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On ARM (before v8), MIPS, and many other RISC architectures, Acquire, Release,
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and SequentiallyConsistent semantics require barrier instructions for every such
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operation. Loads and stores generate normal instructions. ``cmpxchg`` and
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``atomicrmw`` can be represented using a loop with LL/SC-style instructions
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which take some sort of exclusive lock on a cache line (``LDREX`` and ``STREX``
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on ARM, etc.).
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It is often easiest for backends to use AtomicExpandPass to lower some of the
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atomic constructs. Here are some lowerings it can do:
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* cmpxchg -> loop with load-linked/store-conditional
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by overriding ``shouldExpandAtomicCmpXchgInIR()``, ``emitLoadLinked()``,
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``emitStoreConditional()``
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* large loads/stores -> ll-sc/cmpxchg
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by overriding ``shouldExpandAtomicStoreInIR()``/``shouldExpandAtomicLoadInIR()``
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* strong atomic accesses -> monotonic accesses + fences by overriding
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``shouldInsertFencesForAtomic()``, ``emitLeadingFence()``, and
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``emitTrailingFence()``
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* atomic rmw -> loop with cmpxchg or load-linked/store-conditional
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by overriding ``expandAtomicRMWInIR()``
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* expansion to __atomic_* libcalls for unsupported sizes.
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For an example of all of these, look at the ARM backend.
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Libcalls: __atomic_*
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====================
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There are two kinds of atomic library calls that are generated by LLVM. Please
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note that both sets of library functions somewhat confusingly share the names of
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builtin functions defined by clang. Despite this, the library functions are
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not directly related to the builtins: it is *not* the case that ``__atomic_*``
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builtins lower to ``__atomic_*`` library calls and ``__sync_*`` builtins lower
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to ``__sync_*`` library calls.
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The first set of library functions are named ``__atomic_*``. This set has been
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"standardized" by GCC, and is described below. (See also `GCC's documentation
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<https://gcc.gnu.org/wiki/Atomic/GCCMM/LIbrary>`_)
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LLVM's AtomicExpandPass will translate atomic operations on data sizes above
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``MaxAtomicSizeInBitsSupported`` into calls to these functions.
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There are four generic functions, which can be called with data of any size or
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alignment::
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void __atomic_load(size_t size, void *ptr, void *ret, int ordering)
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void __atomic_store(size_t size, void *ptr, void *val, int ordering)
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void __atomic_exchange(size_t size, void *ptr, void *val, void *ret, int ordering)
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bool __atomic_compare_exchange(size_t size, void *ptr, void *expected, void *desired, int success_order, int failure_order)
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There are also size-specialized versions of the above functions, which can only
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be used with *naturally-aligned* pointers of the appropriate size. In the
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signatures below, "N" is one of 1, 2, 4, 8, and 16, and "iN" is the appropriate
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integer type of that size; if no such integer type exists, the specialization
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cannot be used::
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iN __atomic_load_N(iN *ptr, iN val, int ordering)
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void __atomic_store_N(iN *ptr, iN val, int ordering)
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iN __atomic_exchange_N(iN *ptr, iN val, int ordering)
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bool __atomic_compare_exchange_N(iN *ptr, iN *expected, iN desired, int success_order, int failure_order)
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Finally there are some read-modify-write functions, which are only available in
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the size-specific variants (any other sizes use a ``__atomic_compare_exchange``
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loop)::
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iN __atomic_fetch_add_N(iN *ptr, iN val, int ordering)
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iN __atomic_fetch_sub_N(iN *ptr, iN val, int ordering)
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iN __atomic_fetch_and_N(iN *ptr, iN val, int ordering)
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iN __atomic_fetch_or_N(iN *ptr, iN val, int ordering)
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iN __atomic_fetch_xor_N(iN *ptr, iN val, int ordering)
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iN __atomic_fetch_nand_N(iN *ptr, iN val, int ordering)
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This set of library functions have some interesting implementation requirements
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to take note of:
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- They support all sizes and alignments -- including those which cannot be
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implemented natively on any existing hardware. Therefore, they will certainly
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use mutexes in for some sizes/alignments.
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- As a consequence, they cannot be shipped in a statically linked
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compiler-support library, as they have state which must be shared amongst all
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DSOs loaded in the program. They must be provided in a shared library used by
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all objects.
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- The set of atomic sizes supported lock-free must be a superset of the sizes
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any compiler can emit. That is: if a new compiler introduces support for
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inline-lock-free atomics of size N, the ``__atomic_*`` functions must also have a
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lock-free implementation for size N. This is a requirement so that code
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produced by an old compiler (which will have called the ``__atomic_*`` function)
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interoperates with code produced by the new compiler (which will use native
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the atomic instruction).
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Note that it's possible to write an entirely target-independent implementation
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of these library functions by using the compiler atomic builtins themselves to
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implement the operations on naturally-aligned pointers of supported sizes, and a
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generic mutex implementation otherwise.
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Libcalls: __sync_*
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==================
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Some targets or OS/target combinations can support lock-free atomics, but for
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various reasons, it is not practical to emit the instructions inline.
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There's two typical examples of this.
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Some CPUs support multiple instruction sets which can be swiched back and forth
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on function-call boundaries. For example, MIPS supports the MIPS16 ISA, which
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has a smaller instruction encoding than the usual MIPS32 ISA. ARM, similarly,
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has the Thumb ISA. In MIPS16 and earlier versions of Thumb, the atomic
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instructions are not encodable. However, those instructions are available via a
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function call to a function with the longer encoding.
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Additionally, a few OS/target pairs provide kernel-supported lock-free
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atomics. ARM/Linux is an example of this: the kernel `provides
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<https://www.kernel.org/doc/Documentation/arm/kernel_user_helpers.txt>`_ a
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function which on older CPUs contains a "magically-restartable" atomic sequence
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(which looks atomic so long as there's only one CPU), and contains actual atomic
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instructions on newer multicore models. This sort of functionality can typically
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be provided on any architecture, if all CPUs which are missing atomic
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compare-and-swap support are uniprocessor (no SMP). This is almost always the
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case. The only common architecture without that property is SPARC -- SPARCV8 SMP
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systems were common, yet it doesn't support any sort of compare-and-swap
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operation.
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In either of these cases, the Target in LLVM can claim support for atomics of an
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appropriate size, and then implement some subset of the operations via libcalls
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to a ``__sync_*`` function. Such functions *must* not use locks in their
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implementation, because unlike the ``__atomic_*`` routines used by
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AtomicExpandPass, these may be mixed-and-matched with native instructions by the
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target lowering.
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Further, these routines do not need to be shared, as they are stateless. So,
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there is no issue with having multiple copies included in one binary. Thus,
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typically these routines are implemented by the statically-linked compiler
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runtime support library.
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LLVM will emit a call to an appropriate ``__sync_*`` routine if the target
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ISelLowering code has set the corresponding ``ATOMIC_CMPXCHG``, ``ATOMIC_SWAP``,
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or ``ATOMIC_LOAD_*`` operation to "Expand", and if it has opted-into the
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availability of those library functions via a call to ``initSyncLibcalls()``.
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The full set of functions that may be called by LLVM is (for ``N`` being 1, 2,
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4, 8, or 16)::
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iN __sync_val_compare_and_swap_N(iN *ptr, iN expected, iN desired)
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iN __sync_lock_test_and_set_N(iN *ptr, iN val)
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iN __sync_fetch_and_add_N(iN *ptr, iN val)
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iN __sync_fetch_and_sub_N(iN *ptr, iN val)
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iN __sync_fetch_and_and_N(iN *ptr, iN val)
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iN __sync_fetch_and_or_N(iN *ptr, iN val)
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iN __sync_fetch_and_xor_N(iN *ptr, iN val)
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iN __sync_fetch_and_nand_N(iN *ptr, iN val)
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iN __sync_fetch_and_max_N(iN *ptr, iN val)
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iN __sync_fetch_and_umax_N(iN *ptr, iN val)
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iN __sync_fetch_and_min_N(iN *ptr, iN val)
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iN __sync_fetch_and_umin_N(iN *ptr, iN val)
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This list doesn't include any function for atomic load or store; all known
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architectures support atomic loads and stores directly (possibly by emitting a
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fence on either side of a normal load or store.)
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There's also, somewhat separately, the possibility to lower ``ATOMIC_FENCE`` to
|
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``__sync_synchronize()``. This may happen or not happen independent of all the
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above, controlled purely by ``setOperationAction(ISD::ATOMIC_FENCE, ...)``.
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