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=========
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MemorySSA
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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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``MemorySSA`` is an analysis that allows us to cheaply reason about the
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interactions between various memory operations. Its goal is to replace
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``MemoryDependenceAnalysis`` for most (if not all) use-cases. This is because,
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unless you're very careful, use of ``MemoryDependenceAnalysis`` can easily
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result in quadratic-time algorithms in LLVM. Additionally, ``MemorySSA`` doesn't
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have as many arbitrary limits as ``MemoryDependenceAnalysis``, so you should get
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better results, too. One common use of ``MemorySSA`` is to quickly find out
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that something definitely cannot happen (for example, reason that a hoist
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out of a loop can't happen).
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At a high level, one of the goals of ``MemorySSA`` is to provide an SSA based
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form for memory, complete with def-use and use-def chains, which
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enables users to quickly find may-def and may-uses of memory operations.
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It can also be thought of as a way to cheaply give versions to the complete
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state of memory, and associate memory operations with those versions.
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This document goes over how ``MemorySSA`` is structured, and some basic
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intuition on how ``MemorySSA`` works.
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A paper on MemorySSA (with notes about how it's implemented in GCC) `can be
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found here <http://www.airs.com/dnovillo/Papers/mem-ssa.pdf>`_. Though, it's
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relatively out-of-date; the paper references multiple memory partitions, but GCC
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eventually swapped to just using one, like we now have in LLVM. Like
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GCC's, LLVM's MemorySSA is intraprocedural.
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MemorySSA Structure
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===================
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MemorySSA is a virtual IR. After it's built, ``MemorySSA`` will contain a
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structure that maps ``Instruction``\ s to ``MemoryAccess``\ es, which are
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``MemorySSA``'s parallel to LLVM ``Instruction``\ s.
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Each ``MemoryAccess`` can be one of three types:
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- ``MemoryDef``
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- ``MemoryPhi``
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- ``MemoryUse``
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``MemoryDef``\ s are operations which may either modify memory, or which
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introduce some kind of ordering constraints. Examples of ``MemoryDef``\ s
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include ``store``\ s, function calls, ``load``\ s with ``acquire`` (or higher)
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ordering, volatile operations, memory fences, etc. A ``MemoryDef``
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always introduces a new version of the entire memory and is linked with a single
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``MemoryDef/MemoryPhi`` which is the version of memory that the new
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version is based on. This implies that there is a *single*
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``Def`` chain that connects all the ``Def``\ s, either directly
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or indirectly. For example in:
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.. code-block:: llvm
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b = MemoryDef(a)
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c = MemoryDef(b)
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d = MemoryDef(c)
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``d`` is connected directly with ``c`` and indirectly with ``b``.
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This means that ``d`` potentially clobbers (see below) ``c`` *or*
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``b`` *or* both. This in turn implies that without the use of `The walker`_,
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initially every ``MemoryDef`` clobbers every other ``MemoryDef``.
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``MemoryPhi``\ s are ``PhiNode``\ s, but for memory operations. If at any
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point we have two (or more) ``MemoryDef``\ s that could flow into a
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``BasicBlock``, the block's top ``MemoryAccess`` will be a
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``MemoryPhi``. As in LLVM IR, ``MemoryPhi``\ s don't correspond to any
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concrete operation. As such, ``BasicBlock``\ s are mapped to ``MemoryPhi``\ s
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inside ``MemorySSA``, whereas ``Instruction``\ s are mapped to ``MemoryUse``\ s
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and ``MemoryDef``\ s.
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Note also that in SSA, Phi nodes merge must-reach definitions (that is,
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definitions that *must* be new versions of variables). In MemorySSA, PHI nodes
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merge may-reach definitions (that is, until disambiguated, the versions that
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reach a phi node may or may not clobber a given variable).
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``MemoryUse``\ s are operations which use but don't modify memory. An example of
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a ``MemoryUse`` is a ``load``, or a ``readonly`` function call.
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Every function that exists has a special ``MemoryDef`` called ``liveOnEntry``.
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It dominates every ``MemoryAccess`` in the function that ``MemorySSA`` is being
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run on, and implies that we've hit the top of the function. It's the only
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``MemoryDef`` that maps to no ``Instruction`` in LLVM IR. Use of
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``liveOnEntry`` implies that the memory being used is either undefined or
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defined before the function begins.
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An example of all of this overlaid on LLVM IR (obtained by running ``opt
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-passes='print<memoryssa>' -disable-output`` on an ``.ll`` file) is below. When
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viewing this example, it may be helpful to view it in terms of clobbers.
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The operands of a given ``MemoryAccess`` are all (potential) clobbers of said
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``MemoryAccess``, and the value produced by a ``MemoryAccess`` can act as a clobber
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for other ``MemoryAccess``\ es.
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If a ``MemoryAccess`` is a *clobber* of another, it means that these two
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``MemoryAccess``\ es may access the same memory. For example, ``x = MemoryDef(y)``
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means that ``x`` potentially modifies memory that ``y`` modifies/constrains
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(or has modified / constrained).
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In the same manner, ``a = MemoryPhi({BB1,b},{BB2,c})`` means that
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anyone that uses ``a`` is accessing memory potentially modified / constrained
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by either ``b`` or ``c`` (or both). And finally, ``MemoryUse(x)`` means
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that this use accesses memory that ``x`` has modified / constrained
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(as an example, think that if ``x = MemoryDef(...)``
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and ``MemoryUse(x)`` are in the same loop, the use can't
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be hoisted outside alone).
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Another useful way of looking at it is in terms of memory versions.
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In that view, operands of a given ``MemoryAccess`` are the version
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of the entire memory before the operation, and if the access produces
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a value (i.e. ``MemoryDef/MemoryPhi``),
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the value is the new version of the memory after the operation.
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.. code-block:: llvm
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define void @foo() {
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entry:
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%p1 = alloca i8
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%p2 = alloca i8
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%p3 = alloca i8
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; 1 = MemoryDef(liveOnEntry)
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store i8 0, i8* %p3
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br label %while.cond
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while.cond:
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; 6 = MemoryPhi({entry,1},{if.end,4})
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br i1 undef, label %if.then, label %if.else
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if.then:
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; 2 = MemoryDef(6)
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store i8 0, i8* %p1
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br label %if.end
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if.else:
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; 3 = MemoryDef(6)
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store i8 1, i8* %p2
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br label %if.end
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if.end:
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; 5 = MemoryPhi({if.then,2},{if.else,3})
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; MemoryUse(5)
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%1 = load i8, i8* %p1
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; 4 = MemoryDef(5)
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store i8 2, i8* %p2
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; MemoryUse(1)
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%2 = load i8, i8* %p3
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br label %while.cond
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}
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The ``MemorySSA`` IR is shown in comments that precede the instructions they map
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to (if such an instruction exists). For example, ``1 = MemoryDef(liveOnEntry)``
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is a ``MemoryAccess`` (specifically, a ``MemoryDef``), and it describes the LLVM
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instruction ``store i8 0, i8* %p3``. Other places in ``MemorySSA`` refer to this
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particular ``MemoryDef`` as ``1`` (much like how one can refer to ``load i8, i8*
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%p1`` in LLVM with ``%1``). Again, ``MemoryPhi``\ s don't correspond to any LLVM
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Instruction, so the line directly below a ``MemoryPhi`` isn't special.
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Going from the top down:
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- ``6 = MemoryPhi({entry,1},{if.end,4})`` notes that, when entering
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``while.cond``, the reaching definition for it is either ``1`` or ``4``. This
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``MemoryPhi`` is referred to in the textual IR by the number ``6``.
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- ``2 = MemoryDef(6)`` notes that ``store i8 0, i8* %p1`` is a definition,
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and its reaching definition before it is ``6``, or the ``MemoryPhi`` after
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``while.cond``. (See the `Build-time use optimization`_ and `Precision`_
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sections below for why this ``MemoryDef`` isn't linked to a separate,
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disambiguated ``MemoryPhi``.)
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- ``3 = MemoryDef(6)`` notes that ``store i8 0, i8* %p2`` is a definition; its
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reaching definition is also ``6``.
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- ``5 = MemoryPhi({if.then,2},{if.else,3})`` notes that the clobber before
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this block could either be ``2`` or ``3``.
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- ``MemoryUse(5)`` notes that ``load i8, i8* %p1`` is a use of memory, and that
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it's clobbered by ``5``.
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- ``4 = MemoryDef(5)`` notes that ``store i8 2, i8* %p2`` is a definition; its
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reaching definition is ``5``.
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- ``MemoryUse(1)`` notes that ``load i8, i8* %p3`` is just a user of memory,
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and the last thing that could clobber this use is above ``while.cond`` (e.g.
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the store to ``%p3``). In memory versioning parlance, it really only depends on
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the memory version 1, and is unaffected by the new memory versions generated since
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then.
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As an aside, ``MemoryAccess`` is a ``Value`` mostly for convenience; it's not
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meant to interact with LLVM IR.
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Design of MemorySSA
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===================
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``MemorySSA`` is an analysis that can be built for any arbitrary function. When
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it's built, it does a pass over the function's IR in order to build up its
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mapping of ``MemoryAccess``\ es. You can then query ``MemorySSA`` for things
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like the dominance relation between ``MemoryAccess``\ es, and get the
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``MemoryAccess`` for any given ``Instruction`` .
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When ``MemorySSA`` is done building, it also hands you a ``MemorySSAWalker``
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that you can use (see below).
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The walker
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----------
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A structure that helps ``MemorySSA`` do its job is the ``MemorySSAWalker``, or
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the walker, for short. The goal of the walker is to provide answers to clobber
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queries beyond what's represented directly by ``MemoryAccess``\ es. For example,
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given:
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.. code-block:: llvm
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define void @foo() {
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%a = alloca i8
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%b = alloca i8
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; 1 = MemoryDef(liveOnEntry)
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store i8 0, i8* %a
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; 2 = MemoryDef(1)
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store i8 0, i8* %b
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}
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The store to ``%a`` is clearly not a clobber for the store to ``%b``. It would
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be the walker's goal to figure this out, and return ``liveOnEntry`` when queried
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for the clobber of ``MemoryAccess`` ``2``.
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By default, ``MemorySSA`` provides a walker that can optimize ``MemoryDef``\ s
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and ``MemoryUse``\ s by consulting whatever alias analysis stack you happen to
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be using. Walkers were built to be flexible, though, so it's entirely reasonable
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(and expected) to create more specialized walkers (e.g. one that specifically
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queries ``GlobalsAA``, one that always stops at ``MemoryPhi`` nodes, etc).
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Default walker APIs
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^^^^^^^^^^^^^^^^^^^
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There are two main APIs used to retrieve the clobbering access using the walker:
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- ``MemoryAccess *getClobberingMemoryAccess(MemoryAccess *MA);`` return the
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clobbering memory access for ``MA``, caching all intermediate results
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computed along the way as part of each access queried.
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- ``MemoryAccess *getClobberingMemoryAccess(MemoryAccess *MA, const MemoryLocation &Loc);``
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returns the access clobbering memory location ``Loc``, starting at ``MA``.
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Because this API does not request the clobbering access of a specific memory
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access, there are no results that can be cached.
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Locating clobbers yourself
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^^^^^^^^^^^^^^^^^^^^^^^^^^
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If you choose to make your own walker, you can find the clobber for a
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``MemoryAccess`` by walking every ``MemoryDef`` that dominates said
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``MemoryAccess``. The structure of ``MemoryDef``\ s makes this relatively simple;
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they ultimately form a linked list of every clobber that dominates the
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``MemoryAccess`` that you're trying to optimize. In other words, the
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``definingAccess`` of a ``MemoryDef`` is always the nearest dominating
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``MemoryDef`` or ``MemoryPhi`` of said ``MemoryDef``.
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Build-time use optimization
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---------------------------
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``MemorySSA`` will optimize some ``MemoryAccess``\ es at build-time.
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Specifically, we optimize the operand of every ``MemoryUse`` to point to the
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actual clobber of said ``MemoryUse``. This can be seen in the above example; the
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second ``MemoryUse`` in ``if.end`` has an operand of ``1``, which is a
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``MemoryDef`` from the entry block. This is done to make walking,
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value numbering, etc, faster and easier.
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It is not possible to optimize ``MemoryDef`` in the same way, as we
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restrict ``MemorySSA`` to one memory variable and, thus, one Phi node
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per block.
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Invalidation and updating
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-------------------------
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Because ``MemorySSA`` keeps track of LLVM IR, it needs to be updated whenever
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the IR is updated. "Update", in this case, includes the addition, deletion, and
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motion of ``Instructions``. The update API is being made on an as-needed basis.
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If you'd like examples, ``GVNHoist`` is a user of ``MemorySSA``\ s update API.
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Phi placement
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^^^^^^^^^^^^^
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``MemorySSA`` only places ``MemoryPhi``\ s where they're actually
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needed. That is, it is a pruned SSA form, like LLVM's SSA form. For
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example, consider:
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.. code-block:: llvm
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define void @foo() {
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entry:
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%p1 = alloca i8
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%p2 = alloca i8
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%p3 = alloca i8
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; 1 = MemoryDef(liveOnEntry)
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store i8 0, i8* %p3
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br label %while.cond
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while.cond:
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; 3 = MemoryPhi({%0,1},{if.end,2})
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br i1 undef, label %if.then, label %if.else
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if.then:
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br label %if.end
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if.else:
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br label %if.end
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if.end:
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; MemoryUse(1)
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%1 = load i8, i8* %p1
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; 2 = MemoryDef(3)
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store i8 2, i8* %p2
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; MemoryUse(1)
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%2 = load i8, i8* %p3
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br label %while.cond
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}
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Because we removed the stores from ``if.then`` and ``if.else``, a ``MemoryPhi``
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for ``if.end`` would be pointless, so we don't place one. So, if you need to
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place a ``MemoryDef`` in ``if.then`` or ``if.else``, you'll need to also create
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a ``MemoryPhi`` for ``if.end``.
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If it turns out that this is a large burden, we can just place ``MemoryPhi``\ s
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everywhere. Because we have Walkers that are capable of optimizing above said
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phis, doing so shouldn't prohibit optimizations.
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Non-Goals
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---------
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``MemorySSA`` is meant to reason about the relation between memory
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operations, and enable quicker querying.
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It isn't meant to be the single source of truth for all potential memory-related
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optimizations. Specifically, care must be taken when trying to use ``MemorySSA``
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to reason about atomic or volatile operations, as in:
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.. code-block:: llvm
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define i8 @foo(i8* %a) {
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entry:
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br i1 undef, label %if.then, label %if.end
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if.then:
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; 1 = MemoryDef(liveOnEntry)
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%0 = load volatile i8, i8* %a
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br label %if.end
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if.end:
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%av = phi i8 [0, %entry], [%0, %if.then]
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ret i8 %av
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}
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Going solely by ``MemorySSA``'s analysis, hoisting the ``load`` to ``entry`` may
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seem legal. Because it's a volatile load, though, it's not.
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Design tradeoffs
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----------------
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Precision
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^^^^^^^^^
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``MemorySSA`` in LLVM deliberately trades off precision for speed.
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Let us think about memory variables as if they were disjoint partitions of the
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memory (that is, if you have one variable, as above, it represents the entire
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memory, and if you have multiple variables, each one represents some
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disjoint portion of the memory)
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First, because alias analysis results conflict with each other, and
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each result may be what an analysis wants (IE
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TBAA may say no-alias, and something else may say must-alias), it is
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not possible to partition the memory the way every optimization wants.
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Second, some alias analysis results are not transitive (IE A noalias B,
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and B noalias C, does not mean A noalias C), so it is not possible to
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come up with a precise partitioning in all cases without variables to
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represent every pair of possible aliases. Thus, partitioning
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precisely may require introducing at least N^2 new virtual variables,
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phi nodes, etc.
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Each of these variables may be clobbered at multiple def sites.
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To give an example, if you were to split up struct fields into
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individual variables, all aliasing operations that may-def multiple struct
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fields, will may-def more than one of them. This is pretty common (calls,
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copies, field stores, etc).
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Experience with SSA forms for memory in other compilers has shown that
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it is simply not possible to do this precisely, and in fact, doing it
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precisely is not worth it, because now all the optimizations have to
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walk tons and tons of virtual variables and phi nodes.
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So we partition. At the point at which you partition, again,
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experience has shown us there is no point in partitioning to more than
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one variable. It simply generates more IR, and optimizations still
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have to query something to disambiguate further anyway.
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As a result, LLVM partitions to one variable.
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Use Optimization
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^^^^^^^^^^^^^^^^
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Unlike other partitioned forms, LLVM's ``MemorySSA`` does make one
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useful guarantee - all loads are optimized to point at the thing that
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actually clobbers them. This gives some nice properties. For example,
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for a given store, you can find all loads actually clobbered by that
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store by walking the immediate uses of the store.
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LLVM Developers Meeting presentations
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-------------------------------------
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- `2016 LLVM Developers' Meeting: G. Burgess - MemorySSA in Five Minutes <https://www.youtube.com/watch?v=bdxWmryoHak>`_.
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- `2020 LLVM Developers' Meeting: S. Baziotis & S. Moll - Finding Your Way Around the LLVM Dependence Analysis Zoo <https://www.youtube.com/watch?v=1e5y6WDbXCQ>`_
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