Also use the default LLVM target as default for dlltool. This
matches how GNU dlltool behaves; it is compiled with one default
target, which is used if no option is provided.
Extend the anonymous namespace in the implementation file instead
of using static functions.
Based on a patch by Mateusz Mikuła.
The effect of the default LLVM target, if neither the -m option
nor a tool triple prefix is provided, isn't tested, as we can't
make assumptions about what it is set to.
(We could make the default be forced to one of the four supported
architectures if the default triple is another arch, and then just
test that llvm-dlltool without an -m option is able to produce an
import library, without checking the actual architecture though.)
Differential Revision: https://reviews.llvm.org/D104212
The existing tests only test that some options (but not e.g. arm)
are accepted, but it doesn't test their functional effect of
affecting the generated object files.
Differential Revision: https://reviews.llvm.org/D104215
The --coff-exports option to llvm-readobj prints the exported symbols
from a DLL/EXE, it doesn't do anything with regards to an import
library.
Differential Revision: https://reviews.llvm.org/D104214
This is similar to attribute and type interfaces and mostly the same mechanism
(FallbackModel / ExternalModel, ODS generation). There are minor differences in
how the concept-based polymorphism is implemented for operations that are
accounted for by ODS backends, and this essentially adds a test and exposes the
API.
Reviewed By: rriddle
Differential Revision: https://reviews.llvm.org/D104294
With the exception of `frem`, this patch supports the current set of VP
floating-point binary intrinsics by lowering them to to RVV instructions. It
does so by using the existing `RISCVISD *_VL` custom nodes as an intermediate
layer. Both scalable and fixed-length vectors are supported by using this
method.
The `frem` node is unsupported due to a lack of available instructions. For
fixed-length vectors we could scalarize but that option is not (currently)
available for scalable-vector types. The support is intentionally left out so
it equivalent for both vector types.
The matching of vector/scalar forms is currently lacking, as scalable vector
types do not lower to the custom `VFMV_V_F_VL` node. We could either make
floating-point scalable vector splats lower to this node, or support the
matching of multiple kinds of splat via a `ComplexPattern`, much like we do for
integer types.
Reviewed By: rogfer01
Differential Revision: https://reviews.llvm.org/D104237
Template parameters are created in ASTImporter with the translation unit as DeclContext.
The DeclContext is later updated (by the create function of template classes).
ASTImporterLookupTable was not updated after these changes of the DC. The patch
adds update of the DeclContext in ASTImporterLookupTable.
Reviewed By: martong
Differential Revision: https://reviews.llvm.org/D103792
The Interleave Access pass will convert shuffle(binop(load, load)) to
binop(shuffle(load), shuffle(load)), in order to create more
interleaving load patterns (VLD2/3/4) that might have been messed up by
instcombine. As shown in D104247 we were missing copying IR flags to the
new instruction though, which should just be kept the same as the
original instruction.
Differential Revision: https://reviews.llvm.org/D104255
The llvm::demangle is currently used by llvm-objdump and llvm-readobj,
so this effectively adds support for Rust v0 mangling to those
applications.
Reviewed By: dblaikie
Differential Revision: https://reviews.llvm.org/D104340
At the moment, we create insertelement instructions directly after
LastInst when inserting scalar values in a vector in
VPTransformState::get.
This results in invalid IR when LastInst is a phi, followed by another
phi. In that case, the new instructions should be inserted just after
the last PHI node in the block.
At the moment, I don't think the problematic case can be triggered, but
it can happen once predicate regions are merged and multiple
VPredInstPHI recipes are in the same block (D100260).
Reviewed By: Ayal
Differential Revision: https://reviews.llvm.org/D104188
D66572 separated BugReport and BugReporter into basic and path sensitive
versions. As a result, checker silencing, which worked deep in the path
sensitive report generation facilities became specific to it. DeadStoresChecker,
for instance, despite being in the static analyzer, emits non-pathsensitive
reports, and was impossible to silence.
This patch moves the corresponding code before the call to the virtual function
generateDiagnosticForConsumerMap (which is overriden by the specific kinds of
bug reporters). Although we see bug reporting as relatively lightweight compared
to the analysis, this will get rid of several steps we used to throw away.
Quoting from D65379:
At a very high level, this consists of 3 steps:
For all BugReports in the same BugReportEquivClass, collect all their error
nodes in a set. With that set, create a new, trimmed ExplodedGraph whose leafs
are all error nodes.
Until a valid report is found, construct a bug path, which is yet another
ExplodedGraph, that is linear from a given error node to the root of the graph.
Run all visitors on the constructed bug path. If in this process the report got
invalidated, start over from step 2.
Checker silencing used to kick in after all of these. Now it does before any of
them :^)
Differential Revision: https://reviews.llvm.org/D102914
Change-Id: Ice42939304516f2bebd05a1ea19878b89c96a25d
ODS currently emits the interface trait class as a nested class inside the
interface class. As an unintended consequence, the default implementations of
interface methods have implicit access to static fields of the interface class,
e.g. those declared in `extraClassDeclaration`, including private methods (!),
or in the parent class. This may break the use of default implementations for
external models, which are not defined in the interface class, and generally
complexifies the abstraction.
Emit intraface traits outside of the interface class itself to avoid accidental
implicit visibility. Public static fields can still be accessed via explicit
qualification with a class name, e.g., `MyOpInterface::staticMethod()` instead
of `staticMethod`.
Update the documentation to clarify the role of `extraClassDeclaration` in
interfaces.
Reviewed By: rriddle
Differential Revision: https://reviews.llvm.org/D104384
Clang 5 and Clang 6 can no longer parse newer versions of libc++. As we can't
specify the specific libc++ version in the decorator, let's only allow Clang
versions that can parse all currently available libc++ versions.
This can be seen as a follow up to commit 0ee439b705,
that changed the second argument of __powidf2, __powisf2 and
__powitf2 in compiler-rt from si_int to int. That was to align with
how those runtimes are defined in libgcc.
One thing that seem to have been missing in that patch was to make
sure that the rest of LLVM also handle that the argument now depends
on the size of int (not using the si_int machine mode for 32-bit).
When using __builtin_powi for a target with 16-bit int clang crashed.
And when emitting libcalls to those rtlib functions, typically when
lowering @llvm.powi), the backend would always prepare the exponent
argument as an i32 which caused miscompiles when the rtlib was
compiled with 16-bit int.
The solution used here is to use an overloaded type for the second
argument in @llvm.powi. This way clang can use the "correct" type
when lowering __builtin_powi, and then later when emitting the libcall
it is assumed that the type used in @llvm.powi matches the rtlib
function.
One thing that needed some extra attention was that when vectorizing
calls several passes did not support that several arguments could
be overloaded in the intrinsics. This patch allows overload of a
scalar operand by adding hasVectorInstrinsicOverloadedScalarOpd, with
an entry for powi.
Differential Revision: https://reviews.llvm.org/D99439
Ignored diagnostics were only checked after level adjusters and assumed
it would stay the same for the rest. But it can also be modified by
FeatureModules.
Differential Revision: https://reviews.llvm.org/D103387
The dsb after instruction cache invalidation only needs to be executed
if any instruction cache invalidation did happen.
Without this change, if the CTR_EL0.DIC bit indicates that instruction
cache invalidation is not needed, __clear_cache would execute two dsb
instructions in a row; with the second one being unnecessary.
Differential Revision: https://reviews.llvm.org/D104371
Based on dicussion in
[this](https://llvm.discourse.group/t/remove-canonicalizer-for-memref-dim-via-shapedtypeopinterface/3641)
thread the pattern to resolve the `memref.dim` of a value that is a
result of an operation that implements the
`InferShapedTypeOpInterface` is moved to a separate pass instead of
running it as a canonicalization pass. This allows shape resolution to
happen when explicitly required, instead of automatically through a
canonicalization.
Differential Revision: https://reviews.llvm.org/D104321
Many tests fails by D101969 (https://reviews.llvm.org/D101969)
on big-endian machines. This patch changes bit order of
TrailingOperandStorage in big-endian machines. This patch
works on System Z (Triple = "s390x-ibm-linux", CPU = "z14").
Signed-off-by: Haruki Imai <imaihal@jp.ibm.com>
Reviewed By: rriddle
Differential Revision: https://reviews.llvm.org/D104225
When the vscode extension is published, it may be unclear how to contribute improvements to the extension. This revision makes it clear that contributions should follow the traditional LLVM guidelines.
when dealing with -gmodules debug info.
This fixes the bot failures on Darwin.
A recent clang change (presumably https://reviews.llvm.org/D104291)
introduced a bug where .pcm files would identify themselves as
DW_LANG_C_plus_plus, but the .o that references them would identify as
DW_LANG_C_plus_plus_14. While that bug needs to be fixed, too, it
shows that the current strict comparison also isn't meaningful.
rdar://79423225
When a function is called in a specification expression, it must be
sufficiently defined, and cannot be a recursive call (10.1.11(5)).
The best fix for this is to change the contract for the procedure
characterization infrastructure to catch and report such errors,
and to guarantee that it does emit errors on failed characterizations.
Some call sites were adjusted to avoid cascades.
Differential Revision: https://reviews.llvm.org/D104330
Fixes PR50591.
When analyzing classes with members which have user-defined conversion
operators to builtin types, the defaulted comparison analyzer was
picking the member type instead of the type for the builtin operator
which was selected as the best match.
This could either result in wrong comparison category being selected,
or a crash when runtime checks are enabled.
Signed-off-by: Matheus Izvekov <mizvekov@gmail.com>
Reviewed By: rsmith
Differential Revision: https://reviews.llvm.org/D103760
Recently added convertConstantExprsToInstructions() does not handle
a case when a same ConstantExpr used multiple times in the same
instruction. A first use is replaced and the rest of the uses in the
instruction are replaced as well with the replaceUsesOfWith(). Then
function attempts to replace a constant already destroyed.
So far this interface is only used by the AMDGPU BE.
Differential Revision: https://reviews.llvm.org/D104425
This expands NRVO propagation for more cases:
Parse analysis improvement:
* Lambdas and Blocks with dependent return type can have their variables
marked as NRVO Candidates.
Variable instantiation improvements:
* Fixes crash when instantiating NRVO variables in Blocks.
* Functions, Lambdas, and Blocks which have auto return type have their
variables' NRVO status propagated. For Blocks with non-auto return type,
as a limitation, this propagation does not consider the actual return
type.
This also implements exclusion of VarDecls which are references to
dependent types.
Signed-off-by: Matheus Izvekov <mizvekov@gmail.com>
Reviewed By: Quuxplusone
Differential Revision: https://reviews.llvm.org/D99696
This patch changes the (not recommended) static registration API from:
static PassRegistration<MyPass> reg("my-pass", "My Pass Description.");
to:
static PassRegistration<MyPass> reg;
And the explicit registration from:
void registerPass("my-pass", "My Pass Description.",
[] { return createMyPass(); });
To:
void registerPass([] { return createMyPass(); });
It is expected that Pass implementations overrides the getArgument() method
instead. This will ensure that pipeline description can be printed and parsed
back.
Differential Revision: https://reviews.llvm.org/D104421
Recent code for folding MINVAL() didn't allow for architectures
whose C/C++ char type is unsigned, so the value of the maximum
Fortran character was incorrect. This was caught by the
folding20.f90 test. The fix is to avoid numeric_limits<> and
use hard values for max signed integers of various character kinds.
Pushing into llvm-project/main to restore ARM/POWER buildbots.
Currently the value is only used when calling `F->viewCFG()` which is missing out on its potential and usefulness.
So I added the check to the printer passes as well.
Reviewed By: MaskRay
Differential Revision: https://reviews.llvm.org/D102011
Use a "double-double" accumulator, a/k/a Kahan summation,
in the SUM intrinsic in the runtime for real & complex.
This seems to be the best-recommended technique for reducing
error, as opposed to the initial implementation of SUM's
distinct accumulators for positive and negative items.
Differential Revision: https://reviews.llvm.org/D104338
The `MockAllocator` used in `ScudoTSDTest` wasn't allocated
properly aligned, which resulted in the `TSDs` of the shared
registry not being aligned either. This lead to some failures
like: https://reviews.llvm.org/D103119#2822008
This changes how the `MockAllocator` is allocated, same as
Vitaly did in the combined tests, properly aligning it, which
results in the `TSDs` being aligned as well.
Add a `DCHECK` in the shared registry to check that it is.
Differential Revision: https://reviews.llvm.org/D104402
Implement constant folding for the reduction transformational
intrinsic functions MAXVAL and MINVAL.
In anticipation of more folding work to follow, with (I hope)
some common infrastructure, these two have been implemented in a
new header file.
Differential Revision: https://reviews.llvm.org/D104337
The test added in https://reviews.llvm.org/D104305 will only work with
the new driver and should be marked as such.
Sending this without a review as it's fairly straightforward and fixes
test failures for developers that don't want to build the new driver.
When a program attempts to put something like a subprogram
into an array constructor, emit an error rather than crashing.
Differential Revision: https://reviews.llvm.org/D104336
Two-level distributed barrier is a new experimental barrier designed
for Intel hardware that has better performance in some cases than the
default hyper barrier.
This barrier is designed to handle fine granularity parallelism where
barriers are used frequently with little compute and memory access
between barriers. There is no need to use it for codes with few
barriers and large granularity compute, or memory intensive
applications, as little difference will be seen between this barrier
and the default hyper barrier. This barrier is designed to work
optimally with a fixed number of threads, and has a significant setup
time, so should NOT be used in situations where the number of threads
in a team is varied frequently.
The two-level distributed barrier is off by default -- hyper barrier
is used by default. To use this barrier, you must set all barrier
patterns to use this type, because it will not work with other barrier
patterns. Thus, to turn it on, the following settings are required:
KMP_FORKJOIN_BARRIER_PATTERN=dist,dist
KMP_PLAIN_BARRIER_PATTERN=dist,dist
KMP_REDUCTION_BARRIER_PATTERN=dist,dist
Branching factors (set with KMP_FORKJOIN_BARRIER, KMP_PLAIN_BARRIER,
and KMP_REDUCTION_BARRIER) are ignored by the two-level distributed
barrier.
Differential Revision: https://reviews.llvm.org/D103121
Martin Storsjö