This is an implementation of P1061 Structure Bindings Introduce a Pack
without the ability to use packs outside of templates. There is a couple
of ways the AST could have been sliced so let me know what you think.
The only part of this change that I am unsure of is the
serialization/deserialization stuff. I followed the implementation of
other Exprs, but I do not really know how it is tested. Thank you for
your time considering this.
---------
Co-authored-by: Yanzuo Liu <zwuis@outlook.com>
This fixes instantiation of definition for friend function templates,
when the declaration found and the one containing the definition have
different template contexts.
In these cases, the the function declaration corresponding to the
definition is not available; it may not even be instantiated at all.
So this patch adds a bit which tracks which function template
declaration was instantiated from the member template. It's used to find
which primary template serves as a context for the purpose of
obtainining the template arguments needed to instantiate the definition.
Fixes#55509
Relanding patch, with no changes, after it was reverted due to revert of
commit this patch depended on.
Currently, these generate incorrect code, as streaming/SME attributes
are not propagated to the outlined function. As we've yet to work on
mixing OpenMP and streaming functions (and determine how they should
interact with OpenMP's runtime), we think it is best to disallow this
for now.
Note that PointerUnion::dyn_cast has been soft deprecated in
PointerUnion.h:
// FIXME: Replace the uses of is(), get() and dyn_cast() with
// isa<T>, cast<T> and the llvm::dyn_cast<T>
Literal migration would result in dyn_cast_if_present (see the
definition of PointerUnion::dyn_cast), but this patch uses dyn_cast
because we expect TemplateOrSpecialization to be nonnull.
We record whether an expression is immediate escalating in the
FunctionScope.
However, that only happen when parsing or transforming an expression.
This might not happen when transforming a non dependent expression.
This patch fixes that by considering a function immediate when
instantiated from an immediate function.
Fixes#123405
Note that PointerUnion::dyn_cast has been soft deprecated in
PointerUnion.h:
// FIXME: Replace the uses of is(), get() and dyn_cast() with
// isa<T>, cast<T> and the llvm::dyn_cast<T>
This patch migrates uses of PointerUnion::dyn_cast to
dyn_cast_if_present (see the definition of PointerUnion::dyn_cast).
Note that we cannot use dyn_cast in any of the migrations in this
patch; placing
assert(!X.isNull());
just before any of dyn_cast_if_present in this patch triggers some
failure in check-clang.
A SYCL kernel entry point function is a non-member function or a static
member function declared with the `sycl_kernel_entry_point` attribute.
Such functions define a pattern for an offload kernel entry point
function to be generated to enable execution of a SYCL kernel on a
device. A SYCL library implementation orchestrates the invocation of
these functions with corresponding SYCL kernel arguments in response to
calls to SYCL kernel invocation functions specified by the SYCL 2020
specification.
The offload kernel entry point function (sometimes referred to as the
SYCL kernel caller function) is generated from the SYCL kernel entry
point function by a transformation of the function parameters followed
by a transformation of the function body to replace references to the
original parameters with references to the transformed ones. Exactly how
parameters are transformed will be explained in a future change that
implements non-trivial transformations. For now, it suffices to state
that a given parameter of the SYCL kernel entry point function may be
transformed to multiple parameters of the offload kernel entry point as
needed to satisfy offload kernel argument passing requirements.
Parameters that are decomposed in this way are reconstituted as local
variables in the body of the generated offload kernel entry point
function.
For example, given the following SYCL kernel entry point function
definition:
```
template<typename KernelNameType, typename KernelType>
[[clang::sycl_kernel_entry_point(KernelNameType)]]
void sycl_kernel_entry_point(KernelType kernel) {
kernel();
}
```
and the following call:
```
struct Kernel {
int dm1;
int dm2;
void operator()() const;
};
Kernel k;
sycl_kernel_entry_point<class kernel_name>(k);
```
the corresponding offload kernel entry point function that is generated
might look as follows (assuming `Kernel` is a type that requires
decomposition):
```
void offload_kernel_entry_point_for_kernel_name(int dm1, int dm2) {
Kernel kernel{dm1, dm2};
kernel();
}
```
Other details of the generated offload kernel entry point function, such
as its name and calling convention, are implementation details that need
not be reflected in the AST and may differ across target devices. For
that reason, only the transformation described above is represented in
the AST; other details will be filled in during code generation.
These transformations are represented using new AST nodes introduced
with this change. `OutlinedFunctionDecl` holds a sequence of
`ImplicitParamDecl` nodes and a sequence of statement nodes that
correspond to the transformed parameters and function body.
`SYCLKernelCallStmt` wraps the original function body and associates it
with an `OutlinedFunctionDecl` instance. For the example above, the AST
generated for the `sycl_kernel_entry_point<kernel_name>` specialization
would look as follows:
```
FunctionDecl 'sycl_kernel_entry_point<kernel_name>(Kernel)'
TemplateArgument type 'kernel_name'
TemplateArgument type 'Kernel'
ParmVarDecl kernel 'Kernel'
SYCLKernelCallStmt
CompoundStmt
<original statements>
OutlinedFunctionDecl
ImplicitParamDecl 'dm1' 'int'
ImplicitParamDecl 'dm2' 'int'
CompoundStmt
VarDecl 'kernel' 'Kernel'
<initialization of 'kernel' with 'dm1' and 'dm2'>
<transformed statements with redirected references of 'kernel'>
```
Any ODR-use of the SYCL kernel entry point function will (with future
changes) suffice for the offload kernel entry point to be emitted. An
actual call to the SYCL kernel entry point function will result in a
call to the function. However, evaluation of a `SYCLKernelCallStmt`
statement is a no-op, so such calls will have no effect other than to
trigger emission of the offload kernel entry point.
Additionally, as a related change inspired by code review feedback,
these changes disallow use of the `sycl_kernel_entry_point` attribute
with functions defined with a _function-try-block_. The SYCL 2020
specification prohibits the use of C++ exceptions in device functions.
Even if exceptions were not prohibited, it is unclear what the semantics
would be for an exception that escapes the SYCL kernel entry point
function; the boundary between host and device code could be an implicit
noexcept boundary that results in program termination if violated, or
the exception could perhaps be propagated to host code via the SYCL
library. Pending support for C++ exceptions in device code and clear
semantics for handling them at the host-device boundary, this change
makes use of the `sycl_kernel_entry_point` attribute with a function
defined with a _function-try-block_ an error.
Note that PointerUnion::dyn_cast has been soft deprecated in
PointerUnion.h:
// FIXME: Replace the uses of is(), get() and dyn_cast() with
// isa<T>, cast<T> and the llvm::dyn_cast<T>
Literal migration would result in dyn_cast_if_present (see the
definition of PointerUnion::dyn_cast), but this patch uses dyn_cast
because we expect TemplateOrSpecialization to be nonnull.
Note that PointerUnion::dyn_cast has been soft deprecated in
PointerUnion.h:
// FIXME: Replace the uses of is(), get() and dyn_cast() with
// isa<T>, cast<T> and the llvm::dyn_cast<T>
Literal migration would result in dyn_cast_if_present (see the
definition of PointerUnion::dyn_cast), but this patch uses dyn_cast
because we expect Init to be nonnull. Note that hasInit returns true
only if Init is nonnull among other conditions.
This is a new Clang-specific attribute to ensure that field
initializations are performed explicitly.
For example, if we have
```
struct B {
[[clang::explicit]] int f1;
};
```
then the diagnostic would trigger if we do `B b{};`:
```
field 'f1' is left uninitialized, but was marked as requiring initialization
```
This prevents callers from accidentally forgetting to initialize fields,
particularly when new fields are added to the class.
Move the common case of FieldDecl::getFieldIndex() inline to mitigate
the cost of removing the extra `FieldNo` induction variable.
Also rename isNoUniqueAddress parameter to isNonVirtualBaseType, which
appears to be more accurate. I think the current name is just a
consequence of autocomplete gone wrong.
This reverts commit 81fc3add1e627c23b7270fe2739cdacc09063e54.
This breaks some LLDB tests, e.g.
SymbolFile/DWARF/x86/no_unique_address-with-bitfields.cpp:
lldb: ../llvm-project/clang/lib/AST/Decl.cpp:4604: unsigned int clang::FieldDecl::getBitWidthValue() const: Assertion `isa<ConstantExpr>(getBitWidth())' failed.
Save the bitwidth value as a `ConstantExpr` with the value set. Remove
the `ASTContext` parameter from `getBitWidthValue()`, so the latter
simply returns the value from the `ConstantExpr` instead of
constant-evaluating the bitwidth expression every time it is called.
Note that PointerUnion::{is,get} have been soft deprecated in
PointerUnion.h:
// FIXME: Replace the uses of is(), get() and dyn_cast() with
// isa<T>, cast<T> and the llvm::dyn_cast<T>
I'm not touching PointerUnion::dyn_cast for now because it's a bit
complicated; we could blindly migrate it to dyn_cast_if_present, but
we should probably use dyn_cast when the operand is known to be
non-null.
We observed 2X slowdown in lldb's expression evaluation with
https://github.com/llvm/llvm-project/pull/109147 in some cases. It turns
out that calling `isRedundantInlineQualifierFor` is quite expensive.
Using short-circuit evaluation in the if statement to avoid unnecessary
calls to that function.
The __builtin_counted_by_ref builtin is used on a flexible array
pointer and returns a pointer to the "counted_by" attribute's COUNT
argument, which is a field in the same non-anonymous struct as the
flexible array member. This is useful for automatically setting the
count field without needing the programmer's intervention. Otherwise
it's possible to get this anti-pattern:
ptr = alloc(<ty>, ..., COUNT);
ptr->FAM[9] = 42; /* <<< Sanitizer will complain */
ptr->count = COUNT;
To prevent this anti-pattern, the user can create an allocator that
automatically performs the assignment:
#define alloc(TY, FAM, COUNT) ({ \
TY __p = alloc(get_size(TY, COUNT)); \
if (__builtin_counted_by_ref(__p->FAM)) \
*__builtin_counted_by_ref(__p->FAM) = COUNT; \
__p; \
})
The builtin's behavior is heavily dependent upon the "counted_by"
attribute existing. It's main utility is during allocation to avoid
the above anti-pattern. If the flexible array member doesn't have that
attribute, the builtin becomes a no-op. Therefore, if the flexible
array member has a "count" field not referenced by "counted_by", it
must be set explicitly after the allocation as this builtin will
return a "nullptr" and the assignment will most likely be elided.
---------
Co-authored-by: Bill Wendling <isanbard@gmail.com>
Co-authored-by: Aaron Ballman <aaron@aaronballman.com>
This patch reapplies #114258, fixing an infinite recursion bug in
`ASTImporter` that occurs when importing the primary template of a class
template specialization when the latest redeclaration of that template
is a friend declaration in the primary template.
This patch fixes a couple of regressions introduced in #111852.
Consider:
```
template<typename T>
struct A
{
template<bool U>
static constexpr bool f() requires U
{
return true;
}
};
template<>
template<bool U>
constexpr bool A<short>::f() requires U
{
return A<long>::f<U>();
}
template<>
template<bool U>
constexpr bool A<long>::f() requires U
{
return true;
}
static_assert(A<short>::f<true>()); // crash here
```
This crashes because when collecting template arguments from the _first_
declaration of `A<long>::f<true>` for constraint checking, we don't add
the template arguments from the enclosing class template specialization
because there exists another redeclaration that is a member
specialization.
This also fixes the following example, which happens for a similar
reason:
```
// input.cppm
export module input;
export template<int N>
constexpr int f();
template<int N>
struct A {
template<int J>
friend constexpr int f();
};
template struct A<0>;
template<int N>
constexpr int f() {
return N;
}
```
```
// input.cpp
import input;
static_assert(f<1>() == 1); // error: static assertion failed
```
This patch reapplies #111173, fixing a bug when instantiating dependent
expressions that name a member template that is later explicitly
specialized for a class specialization that is implicitly instantiated.
The bug is addressed by adding the `hasMemberSpecialization` function,
which return `true` if _any_ redeclaration is a member specialization.
This is then used when determining the instantiation pattern for a
specialization of a template, and when collecting template arguments for
a specialization of a template.
Add a new enumeration `SuppressInlineNamespaceMode` to `PrintingPolicy` that
is explicit about how to handle inline namespaces. `SuppressInlineNamespace`
uses that enumeration now instead of a Boolean value.
Specializing a template from an inline namespace should be transparent.
For instance
```
namespace foo {
inline namespace v1 {
template<typename A>
void function(A&);
}
}
namespace foo {
template<>
void function<int>(int&);
}
```
`hasName` should match both declarations of `foo::function`.
Makes the behavior of `matchesNodeFullSlow` and `matchesNodeFullFast`
consistent, fixing an assert inside `HasNameMatcher::matchesNode`.
This fixes instantiation of definition for friend function templates,
when the declaration found and the one containing the definition
have different template contexts.
In these cases, the the function declaration corresponding to the
definition is not available; it may not even be instantiated at all.
So this patch adds a bit which tracks which function template
declaration was instantiated from the member template.
It's used to find which primary template serves as a context
for the purpose of obtaining the template arguments needed
to instantiate the definition.
Fixes#55509
Reapplies #106585, fixing an issue where non-dependent names of member
templates appearing prior to that member template being explicitly
specialized for an implicitly instantiated class template specialization
would incorrectly use the definition of the explicitly specialized
member template.
HLSL doesn't distinguish `main` from any other function. It does treat
entry points special, but they're not required to be called `main` so we
have a different attribute annotation to mark them.
At the moment this change really just changes the mangling of functions
named `main` in the Itanium mangling.
Fixes#110517
---------
Co-authored-by: Farzon Lotfi <1802579+farzonl@users.noreply.github.com>
This extends default argument deduction to cover class templates as
well, applying only to partial ordering, adding to the provisional
wording introduced in https://github.com/llvm/llvm-project/pull/89807.
This solves some ambuguity introduced in P0522 regarding how template
template parameters are partially ordered, and should reduce the
negative impact of enabling `-frelaxed-template-template-args` by
default.
Given the following example:
```C++
template <class T1, class T2 = float> struct A;
template <class T3> struct B;
template <template <class T4> class TT1, class T5> struct B<TT1<T5>>; // #1
template <class T6, class T7> struct B<A<T6, T7>>; // #2
template struct B<A<int>>;
```
Prior to P0522, `#2` was picked. Afterwards, this became ambiguous. This
patch restores the pre-P0522 behavior, `#2` is picked again.
For mobile applications, it's common for global destructors to never be
called (because the applications have their own lifecycle independent of
the standard C runtime), but threads are created and destroyed as normal
and so thread-local destructors are still called. -fno-static-c++-destructors
omits unnecessary global destructors, which is useful for code size, but
it also omits thread-local destructors, which is unsuitable. Add a
ternary `-fc++-static-destructors={all,none,thread-local}` option
instead to allow omitting only global destructors.
Close https://github.com/llvm/llvm-project/issues/99825
The root cause of the issue is that I didn't realize the things in
implicit global module (the language linkage in module interfaces)
should be considered in module purview.
This reverts commit 18f3bcbb13ca83d33223b00761d8cddf463e9ffb, 15bb02650e26875c48889053d6a9697444583721 and
99873b35da7ecb905143c8a6b8deca4d4416f1a9.
See the post commit message in
https://github.com/llvm/llvm-project/pull/75912 to see the reasons.
module
Possibly fix https://github.com/llvm/llvm-project/issues/96693
The direct reason is that we are calculating the linkage for the
declaration too early so that the linkage got calculated incorrectly.
And after I look into the problem, I found it is completely not
necessary to calculate the linkage there. It is for ModulesTS. So I
simply removes that legacy experimental code and fix the issue.
VarDecl::isNull() doesn't tell whether the VarDecl has an initializer as
methods like ensureEvaluatedStmt can create an EvaluatedStmt even when
there isn't an initializer.
Revert e1c3e16d24b5cc097ff08e9283f53319acd3f245 as the change isn't
needed anymore with this change.
See the discussion in https://github.com/llvm/llvm-project/pull/93749.
`Eval->Value.get` returns a null pointer when the variable doesn't have
an initializer. Use `cast_if_present` instead of `cast`.
This fixes https://github.com/llvm/llvm-project/issues/93625.
rdar://128482541
