This patch implements vector-predicated intrinsics on IR level for fadd,
fsub, fmul, fdiv and frem. There operate in the default floating-point
environment. We will use constrained fp operand bundles for constrained
vector-predicated fp math (D93455).
Reviewed By: craig.topper
Differential Revision: https://reviews.llvm.org/D93470
`VPIntrinsic::getDeclarationForParams` creates a vp intrinsic
declaration for parameters you want to call it with. This is in
preparation of a new builder class that makes emitting vp intrinsic code
nearly as convenient as using a plain ir builder (aka `VectorBuilder`,
to be used by D99750).
Reviewed By: frasercrmck, craig.topper, vkmr
Differential Revision: https://reviews.llvm.org/D102686
Some existing places use getPointerElementType() to create a copy of a
pointer type with some new address space.
Reviewed By: dblaikie
Differential Revision: https://reviews.llvm.org/D103429
Parameter positions seem like they should be unsigned.
While there, make function names lowercase per coding standards.
Reviewed By: frasercrmck
Differential Revision: https://reviews.llvm.org/D103224
The operation of some VP intrinsics do/will not map to regular
instruction opcodes. Returning 'None' seems more intuitive here than
'Instruction::Call'.
Reviewed By: frasercrmck
Differential Revision: https://reviews.llvm.org/D102778
This was reverted to mitigate mitigate miscompiles caused by
the logical and/or to bitwise and/or fold. Reapply it now that
the underlying issue has been fixed by D101191.
-----
This patch folds more operations to poison.
Alive2 proof: https://alive2.llvm.org/ce/z/mxcb9G (it does not contain tests about div/rem because they fold to poison when raising UB)
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D92270
Test that all VP intrinsics are tested.
Test intrinsic id -> opcode -> intrinsic id round tripping.
Test property scopes in the include/llvm/IR/VPIntrinsics.def file.
Reviewed By: frasercrmck
Differential Revision: https://reviews.llvm.org/D93534
Printing pass manager invocations is fairly verbose and not super
useful.
This allows us to remove DebugLogging from pass managers and PassBuilder
since all logging (aside from analysis managers) goes through
instrumentation now.
This has the downside of never being able to print the top level pass
manager via instrumentation, but that seems like a minor downside.
Reviewed By: ychen
Differential Revision: https://reviews.llvm.org/D101797
We're trying to move DebugLogging into instrumentation, rather than
being part of PassManagers/AnalysisManagers.
Reviewed By: ychen
Differential Revision: https://reviews.llvm.org/D102093
verifyFunctionAttrs has a comment that the value V is printed in error messages. The recently added errors for attributes didn't print V. Make them print V.
Change the stringification of AttributeList. Firstly they started with 'PAL[' which stood for ParamAttrsList. Change that to 'AttributeList[' matching its current name AttributeList. Print out semantic meaning of the index instead of the raw index value (i.e. 'return', 'function' or 'arg(n)').
Differential revision: https://reviews.llvm.org/D101484
In quite a few cases in LoopVectorize.cpp we call createStepForVF
with a step value of 0, which leads to unnecessary generation of
llvm.vscale intrinsic calls. I've optimised IRBuilder::CreateVScale
and createStepForVF to return 0 when attempting to multiply
vscale by 0.
Differential Revision: https://reviews.llvm.org/D100763
Value::replaceUsesOutsideBlock doesn't replace debug uses which leads to an
unnecessary reduction in variable location coverage. Fix this, add a unittest for
it, and add a regression test demonstrating the change through instcombine's
replacedSelectWithOperand.
Reviewed By: djtodoro
Differential Revision: https://reviews.llvm.org/D99169
This fixes https://reviews.llvm.org/D93990#2666922
by teaching `m_Undef` to match vectors/aggrs with poison elements.
As suggested, fixes in InstCombine files to use the `m_Undef` matcher instead
of `isa<UndefValue>` will be followed.
Reviewed By: lebedev.ri
Differential Revision: https://reviews.llvm.org/D100122
Attributes don't know their parent Context, adding this would make Attribute larger. Instead, we add hasParentContext that answers whether this Attribute belongs to a particular LLVMContext by checking for itself inside the context's FoldingSet. Same with AttributeSet and AttributeList. The Verifier checks them with the Module context.
Differential Revision: https://reviews.llvm.org/D99362
Value::replaceUsesOutsideBlock doesn't replace debug uses which leads to an
unnecessary reduction in variable location coverage. Fix this, add a unittest for
it, and add a regression test demonstrating the change through instcombine's
replacedSelectWithOperand.
Reviewed By: djtodoro
Differential Revision: https://reviews.llvm.org/D99169
"Does the predicate hold between two ranges?"
Not very surprisingly, some places were already doing this check,
without explicitly naming the algorithm, cleanup them all.
"Does the predicate hold between two ranges?"
Not very surprisingly, some places were already doing this check,
without explicitly naming the algorithm, cleanup them all.
This is a (late) follow-up patch of 8871a4b4ca and
c95f39891a to make ConstantStruct::get/ConstantArray::getImpl
correctly return PoisonValue if all elements are poison.
This was found while discussing about the elements of a vector-typed UndefValue (D99853)
The reason for the NewPM redesign is described in the commit
cba3e783389a: [NewPM] Disable PreservedCFGChecker ...
The checker introduces an internal custom CFG analysis that tracks
current up-to date CFG snapshot. The analysis is invalidated along
any other CFG related analysis (the key is CFGAnalyses). If the CFG
analysis is not invalidated at a functional pass exit then the checker
asserts that the CFG snapshot taken from this analysis is equals to
a snapshot of the current CFG.
Along the way:
- the function CFG::printDiff() is simplified by removing function
name calculation. The name is printed by the caller;
- fixed CFG invalidated condition (see CFG::invalidate());
- StandardInstrumentations::registerCallbacks() gets additional
optional parameter of type FunctionAnalysisManager*, which is
needed by the checker to get the custom CFG analysis;
- several PM related tests updated to explicitly set
-verify-cfg-preserved=1 as they need.
This patch is safe to land as the CFGChecker is left switched off
(the options -verify-cfg-preserved is false by default). It will be
switched on by a separate patch to minimize possible reverts.
Reviewed By: skatkov, kuhar
Differential Revision: https://reviews.llvm.org/D91327
This commit adds debugging support for set types defined in languages
such as Pascal and Modula-2.
Patch by Peter McKinna!
Differential Revision: https://reviews.llvm.org/D76115
I think byval/sret and the others are close to being able to rip out
the code to support the missing type case. A lot of this code is
shared with inalloca, so catch this up to the others so that can
happen.
This patch adds a new llvm.experimental.stepvector intrinsic,
which takes no arguments and returns a linear integer sequence of
values of the form <0, 1, ...>. It is primarily intended for
scalable vectors, although it will work for fixed width vectors
too. It is intended that later patches will make use of this
new intrinsic when vectorising induction variables, currently only
supported for fixed width. I've added a new CreateStepVector
method to the IRBuilder, which will generate a call to this
intrinsic for scalable vectors and fall back on creating a
ConstantVector for fixed width.
For scalable vectors this intrinsic is lowered to a new ISD node
called STEP_VECTOR, which takes a single constant integer argument
as the step. During lowering this argument is set to a value of 1.
The reason for this additional argument at the codegen level is
because in future patches we will introduce various generic DAG
combines such as
mul step_vector(1), 2 -> step_vector(2)
add step_vector(1), step_vector(1) -> step_vector(2)
shl step_vector(1), 1 -> step_vector(2)
etc.
that encourage a canonical format for all targets. This hopefully
means all other targets supporting scalable vectors can benefit
from this too.
I've added cost model tests for both fixed width and scalable
vectors:
llvm/test/Analysis/CostModel/AArch64/neon-stepvector.ll
llvm/test/Analysis/CostModel/AArch64/sve-stepvector.ll
as well as codegen lowering tests for fixed width and scalable
vectors:
llvm/test/CodeGen/AArch64/neon-stepvector.ll
llvm/test/CodeGen/AArch64/sve-stepvector.ll
See this thread for discussion of the intrinsic:
https://lists.llvm.org/pipermail/llvm-dev/2021-January/147943.html
Count iterations of zero-trip loops and assert the count is zero,
rather than asserting inside the loop.
Unreachable functions should use llvm_unreachable.
Remove tautological 'if' statements, even when they're following a
pattern of checks.
Found by the Rotten Green Tests project.
Fixed section of code that iterated through a SmallDenseMap and added
instructions in each iteration, causing non-deterministic code; replaced
SmallDenseMap with MapVector to prevent non-determinism.
This reverts commit 01ac6d1587.
This caused non-deterministic compiler output; see comment on the
code review.
> This patch updates the various IR passes to correctly handle dbg.values with a
> DIArgList location. This patch does not actually allow DIArgLists to be produced
> by salvageDebugInfo, and it does not affect any pass after codegen-prepare.
> Other than that, it should cover every IR pass.
>
> Most of the changes simply extend code that operated on a single debug value to
> operate on the list of debug values in the style of any_of, all_of, for_each,
> etc. Instances of setOperand(0, ...) have been replaced with with
> replaceVariableLocationOp, which takes the value that is being replaced as an
> additional argument. In places where this value isn't readily available, we have
> to track the old value through to the point where it gets replaced.
>
> Differential Revision: https://reviews.llvm.org/D88232
This reverts commit df69c69427.
This parallels ConstantDataArray::getRaw() and can be used with ConstantDataSequential::getRawDataValues() in the base class for both types.
Update BuildConstantData{Array,Vector} tests to test the getRaw API. Also removes its unused Module.
In passing, update some comments to include the support for half and bfloat. Update tests to include testing for bfloat.
Differential Revision: https://reviews.llvm.org/D98302
The LiveDebugValues and LiveDebugVariables implementations for handling
DBG_VALUE_LIST instructions can be simplified significantly if they do not have
to deal with any duplicated operands, such as a DBG_VALUE_LIST that uses the
same register multiple times in its expression. This patch adds a function,
replaceArg, that can be used to simplify a DIExpression in the case of
duplicated operands.
Differential Revision: https://reviews.llvm.org/D83896
This patch updates the various IR passes to correctly handle dbg.values with a
DIArgList location. This patch does not actually allow DIArgLists to be produced
by salvageDebugInfo, and it does not affect any pass after codegen-prepare.
Other than that, it should cover every IR pass.
Most of the changes simply extend code that operated on a single debug value to
operate on the list of debug values in the style of any_of, all_of, for_each,
etc. Instances of setOperand(0, ...) have been replaced with with
replaceVariableLocationOp, which takes the value that is being replaced as an
additional argument. In places where this value isn't readily available, we have
to track the old value through to the point where it gets replaced.
Differential Revision: https://reviews.llvm.org/D88232
This patch adds a new metadata node, DIArgList, which contains a list of SSA
values. This node is in many ways similar in function to the existing
ValueAsMetadata node, with the difference being that it tracks a list instead of
a single value. Internally, it uses ValueAsMetadata to track the individual
values, but there is also a reasonable amount of DIArgList-specific
value-tracking logic on top of that. Similar to ValueAsMetadata, it is a special
case in parsing and printing due to the fact that it requires a function state
(as it may reference function-local values).
This patch should not result in any immediate functional change; it allows for
DIArgLists to be parsed and printed, but debug variable intrinsics do not yet
recognize them as a valid argument (outside of parsing).
Differential Revision: https://reviews.llvm.org/D88175
When one of the inputs is a wrapping range, intersect with the
union of the two inputs. The union of the two inputs corresponds
to the result we would get if we treated the min/max as a simple
select.
This fixes PR48643.
We don't need any special handling for wrapping ranges (or empty
ranges for that matter). The sub() call will already compute a
correct and precise range.
We only need to adjust the test expectation: We're now computing
an optimal result, rather than an unsigned envelope.
When the optimality check fails, print the inputs, the computed
range and the better range that was found. This makes it much
simpler to identify the cause of the failure.
Make sure that full ranges (which, unlikely all the other cases,
have multiple ways to construct them that all result in the same
range) only print one message by handling them separately.
The current infrastructure for exhaustive ConstantRange testing is
somewhat confusing in what exactly it tests and currently cannot even
be used for operations that produce smallest-size results, rather than
signed/unsigned envelopes.
This patch makes the testing more principled by collecting the exact
set of results of an operation into a bit set and then comparing it
against the range approximation by:
* Checking conservative correctness: All elements in the set must be
in the range.
* Checking optimality under a given preference function: None of the
(slack-free) ranges that can be constructed from the set are
preferred over the computed range.
Implemented preference functions are:
* PreferSmallest: Smallest range regardless of signed/unsigned wrapping
behavior. Probably what we would call "optimal" without further
qualification.
* PreferSmallestUnsigned/Signed: Smallest range that has no
unsigned/signed wrapping. We use this if our calculation is precise
only up to signed/unsigned envelope.
* PreferSmallestNonFullUnsigned/Signed: Smallest range that has no
unsigned/signed wrapping -- but preferring a smaller wrapping range
over a (non-wrapping) full range. We use this if we have a fully
precise calculation but apply a sign preference to the result
(union/intersection). Even with a sign preference, returning a
wrapping range is still "strictly better" than returning a full one.
This also addresses PR49273 by replacing the fragile manual range
construction logic in testBinarySetOperationExhaustive() with generic
code that isn't specialized to the particular form of ranges that set
operations can produces.
Differential Revision: https://reviews.llvm.org/D88356
To set non-default rounding mode user usually calls function 'fesetround'
from standard C library. This way has some disadvantages.
* It creates unnecessary dependency on libc. On the other hand, setting
rounding mode requires few instructions and could be made by compiler.
Sometimes standard C library even is not available, like in the case of
GPU or AI cores that execute small kernels.
* Compiler could generate more effective code if it knows that a particular
call just sets rounding mode.
This change introduces new IR intrinsic, namely 'llvm.set.rounding', which
sets current rounding mode, similar to 'fesetround'. It however differs
from the latter, because it is a lower level facility:
* 'llvm.set.rounding' does not return any value, whereas 'fesetround'
returns non-zero value in the case of failure. In glibc 'fesetround'
reports failure if its argument is invalid or unsupported or if floating
point operations are unavailable on the hardware. Compiler usually knows
what core it generates code for and it can validate arguments in many
cases.
* Rounding mode is specified in 'fesetround' using constants like
'FE_TONEAREST', which are target dependent. It is inconvenient to work
with such constants at IR level.
C standard provides a target-independent way to specify rounding mode, it
is used in FLT_ROUNDS, however it does not define standard way to set
rounding mode using this encoding.
This change implements only IR intrinsic. Lowering it to machine code is
target-specific and will be implemented latter. Mapping of 'fesetround'
to 'llvm.set.rounding' is also not implemented here.
Differential Revision: https://reviews.llvm.org/D74729