Summary:
IgnoreUnlessSpelledInSource mode should ignore these because they are
not written in the source. This matters for example when trying to
replace types or values which are templated. The new test in
TransformerTest.cpp in this commit demonstrates the problem.
In existing matcher code, users can write
`unless(isInTemplateInstantiation())` or `unless(isInstantiated())` (the
user must know which to use). The point of the
TK_IgnoreUnlessSpelledInSource mode is to allow the novice to avoid such
details. This patch changes the IgnoreUnlessSpelledInSource mode to
skip over implicit template instantiations.
This patch does not change the TK_AsIs mode.
Note: An obvious attempt at an alternative implementation would simply
change the shouldVisitTemplateInstantiations() in ASTMatchFinder.cpp to
return something conditional on the operational TraversalKind. That
does not work because shouldVisitTemplateInstantiations() is called
before a possible top-level traverse() matcher changes the operational
TraversalKind.
Reviewers: sammccall, aaron.ballman, gribozavr2, ymandel, klimek
Subscribers: cfe-commits
Tags: #clang
Differential Revision: https://reviews.llvm.org/D80961
The attribute has no effect on a do statement since the path of execution
will always include its substatement.
It adds a diagnostic when the attribute is used on an infinite while loop
since the codegen omits the branch here. Since the likelihood attributes
have no effect on a do statement no diagnostic will be issued for
do [[unlikely]] {...} while(0);
Differential Revision: https://reviews.llvm.org/D89899
friends.
When determining whether a function has a template instantiation
pattern, look for other declarations of that function that were
instantiated from a friend function definition, rather than assuming
that checking for member specialization information on whichever
declaration name lookup found will be sufficient.
This patch adds tests and support for operations on SVE vectors created
by the 'arm_sve_vector_bits' attribute, described by the Arm C Language
Extensions (ACLE, version 00bet6, section 3.7.3.3) for SVE [1].
This covers the following:
* VLSTs support the same forms of element-wise initialization as GNU
vectors.
* VLSTs support the same built-in C and C++ operators as GNU vectors.
* Conditional and binary expressions containing GNU and SVE vectors
(fixed or sizeless) are invalid since the ambiguity around the result
type affects the ABI.
No functional changes were required to support vector initialization and
operators. The functional changes are to address unsupported conditional and
binary expressions.
[1] https://developer.arm.com/documentation/100987/latest
Reviewed By: fpetrogalli
Differential Revision: https://reviews.llvm.org/D88233
As mentioned in the defect, the lambda static invoker does not follow
the calling convention of the lambda itself, which seems wrong. This
patch ensures that the calling convention of operator() is passed onto
the invoker and conversion-operator type.
This is accomplished by extracting the calling-convention determination
code out into a separate function in order to better reflect the 'thiscall'
work, as well as somewhat better support the future implementation of
https://devblogs.microsoft.com/oldnewthing/20150220-00/?p=44623
For any target (basically just win32) that has a different free and
static function calling convention, this generates BOTH alternatives.
This required some work to get the Windows mangler to work correctly for
this, as well as some tie-breaking for the unary operators.
Differential Revision: https://reviews.llvm.org/D89559
Summary:
Skip over elidable nodes, and ensure that intermediate
CXXFunctionalCastExpr nodes are also skipped if they are semantic.
Reviewers: klimek, ymandel
Subscribers: cfe-commits
Tags: #clang
Differential Revision: https://reviews.llvm.org/D82278
Checks to make sure that stdlib's (std::)free is being appropriately
used. Presently checks for the following misuses:
- free(&stack_object)
- free(stack_array)
Differential Revision: https://reviews.llvm.org/D89988
Define the __vector_pair and __vector_quad types that are used to manipulate
the new accumulator registers introduced by MMA on PowerPC. Because these two
types are specific to PowerPC, they are defined in a separate new file so it
will be easier to add other PowerPC specific types if we need to in the future.
Differential Revision: https://reviews.llvm.org/D81508
The local variable CmpResult added in that change shadowed the
type CmpResult, which confused an older gcc. Rename the variable
CmpResult to APFloatCmpResult.
It turns out that `FileInfo` *always* has a ContentCache. Clarify that
in the code:
- Update the private version of `SourceManager::createFileID` to take a
`ContentCache&` instead of `ContentCache*`, and rename it to
`createFileIDImpl` for clarity.
- Change `FileInfo::getContentCache` to return a reference.
Differential Revision: https://reviews.llvm.org/D89554
This requires that we track enough information to determine the original
type of the parameter in a substituted non-type template parameter, to
distinguish the reference-to-class case from the class case.
non-type template parameters.
Create a unique TemplateParamObjectDecl instance for each such value,
representing the globally unique template parameter object to which the
template parameter refers.
No IR generation support yet; that will follow in a separate patch.
Changes:
- initializer expressions of constexpr variable are now wraped in a ConstantExpr. this is mainly used for testing purposes. the old caching system has not yet been removed.
- Add all the missing Serialization and Importing for APValue.
- Improve dumping of APValue when ASTContext isn't available.
- Cleanup leftover from last patch.
- Add Tests for Import and serialization.
Differential Revision: https://reviews.llvm.org/D63640
Permitting non-standards-driven "do the best you can" constant-folding
of array bounds is permitted solely as a GNU compatibility feature. We
should not be doing it in any language mode that is attempting to be
conforming.
From https://reviews.llvm.org/D20090 it appears the intent here was to
permit `__constant int` globals to be used in array bounds, but the
change in that patch only added half of the functionality necessary to
support that in the constant evaluator. This patch adds the other half
of the functionality and turns off constant folding for array bounds in
OpenCL.
I couldn't find any spec justification for accepting the kinds of cases
that D20090 accepts, so a reference to where in the OpenCL specification
this is permitted would be useful.
Note that this change also affects the code generation in one test:
because after 'const int n = 0' we now treat 'n' as a constant
expression with value 0, it's now a null pointer, so '(local int *)n'
forms a null pointer rather than a zero pointer.
Reviewed By: Anastasia
Differential Revision: https://reviews.llvm.org/D89520
This fixes miscomputation of __builtin_constant_evaluated in the
initializer of a variable that's not usable in constant expressions, but
is readable when constant-folding.
If evaluation of a constant initializer fails, we throw away the
evaluated result instead of keeping it as a non-constant-initializer
value for the variable, because it might not be a correct value.
To avoid regressions for initializers that are foldable but not formally
constant initializers, we now try constant-evaluating some globals in
C++ twice: once to check for a constant initializer (in an mode where
is_constannt_evaluated returns true) and again to determine the runtime
value if the initializer is not a constant initializer.
Instead of framing the interface around whether the variable is an ICE
(which is only interesting in C++98), primarily track whether the
initializer is a constant initializer (which is interesting in all C++
language modes).
No functionality change intended.
for which it matters.
This is a step towards separating checking for a constant initializer
(in which std::is_constant_evaluated returns true) and any other
evaluation of a variable initializer (in which it returns false).
PartialDiagnostic misses some functions compared to DiagnosticBuilder.
This patch refactors DiagnosticBuilder and PartialDiagnostic, extracts
the common functionality so that the streaming << operators are
shared.
Differential Revision: https://reviews.llvm.org/D84362
This implements the likelihood attribute for the switch statement. Based on the
discussion in D85091 and D86559 it only handles the attribute when placed on
the case labels or the default labels.
It also marks the likelihood attribute as feature complete. There are more QoI
patches in the pipeline.
Differential Revision: https://reviews.llvm.org/D89210
This addresses a regression where pretty much all C++ compilations using
-frounding-math now fail, due to rounding being performed in constexpr
function definitions in the standard library.
This follows the "manifestly constant evaluated" approach described in
https://reviews.llvm.org/D87528#2270676 -- evaluations that are required
to succeed at compile time are permitted even in regions with dynamic
rounding modes, as are (unfortunately) the evaluation of the
initializers of local variables of const integral types.
Differential Revision: https://reviews.llvm.org/D89360
This reverts commits 683b308c07 and
8487bfd4e9.
We will go for a more restricted approach that does not give freedom to
everyone to change ABIs on whichever platform.
See the discussion on https://reviews.llvm.org/D85802.
Capitalize the profile function of APValue such that it can be used by FoldingSetNodeID
Reviewed By: rsmith
Differential Revision: https://reviews.llvm.org/D88643
callee in constant evaluation.
We previously made a deep copy of function parameters of class type when
passing them, resulting in the destructor for the parameter applying to
the original argument value, ignoring any modifications made in the
function body. This also meant that the 'this' pointer of the function
parameter could be observed changing between the caller and the callee.
This change completely reimplements how we model function parameters
during constant evaluation. We now model them roughly as if they were
variables living in the caller, albeit with an artificially reduced
scope that covers only the duration of the function call, instead of
modeling them as temporaries in the caller that we partially "reparent"
into the callee at the point of the call. This brings some minor
diagnostic improvements, as well as significantly reduced stack usage
during constant evaluation.
Remove `ContentCache::getBuffer`, which always returned a
dereferenceable `MemoryBuffer*` and had a `bool*Invalid` out parameter,
and replace it with:
- `ContentCache::getBufferOrNone`, which returns
`Optional<MemoryBufferRef>`. This is the new API that consumers should
use. Later it could be renamed to `getBuffer`, but intentionally using
a different name to root out any unexpected callers.
- `ContentCache::getBufferPointer`, which returns `MemoryBuffer*` with
"optional" semantics. This is `private` to avoid growing callers and
`SourceManager` has temporarily been made a `friend` to access it.
Later paches will update the transitive callers to not need a raw
pointer, and eventually this will be deleted.
No functionality change intended here.
Differential Revision: https://reviews.llvm.org/D89348
This implements the flag proposed in RFC http://lists.llvm.org/pipermail/cfe-dev/2020-August/066437.html.
The goal is to add a way to override the default target C++ ABI through
a compiler flag. This makes it easier to test and transition between different
C++ ABIs through compile flags rather than build flags.
In this patch:
- Store `-fc++-abi=` in a LangOpt. This isn't stored in a
CodeGenOpt because there are instances outside of codegen where Clang
needs to know what the ABI is (particularly through
ASTContext::createCXXABI), and we should be able to override the
target default if the flag is provided at that point.
- Expose the existing ABIs in TargetCXXABI as values that can be passed
through this flag.
- Create a .def file for these ABIs to make it easier to check flag
values.
- Add an error for diagnosing bad ABI flag values.
Differential Revision: https://reviews.llvm.org/D85802
During the import of attributes we forgot to set the spelling list
index. This caused a segfault when we wanted to traverse the AST
(e.g. by the dump() method).
Differential Revision: https://reviews.llvm.org/D89318
During the import of FormatAttrs we forgot to import the type (e.g
`__scanf__`) of the attribute. This caused a segfault when we wanted to
traverse the AST (e.g. by the dump() method).
Differential Revision: https://reviews.llvm.org/D89319
Instead of collecting all specializations and doing a post-filterin, we
can just get all targeted specializations from getPartialSpecializationsizations.
Differential Revision: https://reviews.llvm.org/D89220
callee in constant evaluation.
We previously made a deep copy of function parameters of class type when
passing them, resulting in the destructor for the parameter applying to
the original argument value, ignoring any modifications made in the
function body. This also meant that the 'this' pointer of the function
parameter could be observed changing between the caller and the callee.
This change completely reimplements how we model function parameters
during constant evaluation. We now model them roughly as if they were
variables living in the caller, albeit with an artificially reduced
scope that covers only the duration of the function call, instead of
modeling them as temporaries in the caller that we partially "reparent"
into the callee at the point of the call. This brings some minor
diagnostic improvements, as well as significantly reduced stack usage
during constant evaluation.
callee in constant evaluation.
We previously made a deep copy of function parameters of class type when
passing them, resulting in the destructor for the parameter applying to
the original argument value, ignoring any modifications made in the
function body. This also meant that the 'this' pointer of the function
parameter could be observed changing between the caller and the callee.
This change completely reimplements how we model function parameters
during constant evaluation. We now model them roughly as if they were
variables living in the caller, albeit with an artificially reduced
scope that covers only the duration of the function call, instead of
modeling them as temporaries in the caller that we partially "reparent"
into the callee at the point of the call. This brings some minor
diagnostic improvements, as well as significantly reduced stack usage
during constant evaluation.
Stephen Kelly