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.
The reduction clause has some minor restrictions on the variable
references that are implementable, so this implements those. Others
require reachability analysis, so this patch documents that we're not
going to do that in the CFE(or at least save it for the MLIR passes).
Until now, these have been hardcoded as a downstream patches in lld. Add
them to the driver so that the private patches can be removed.
PS5 only. On PS4, the equivalent hardcoded configuration will remain in
the proprietary linker.
SIE tracker: TOOLCHAIN-16704
This patch extends the filtering heuristic to apply for the
Lifetimebound code path.
This will suppress a common false positive:
```
namespace std {
template<typename T>
struct unique_ptr {
T &operator*();
T *get() const [[clang::lifetimebound]];
};
} // namespace std
struct X {
X(std::unique_ptr<int> up) :
pointer(up.get()), owner(std::move(up)) {}
int *pointer;
std::unique_ptr<int> owner;
};
```
See #114201.
This PR introduces alpha.webkit.UncheckedLocalVarsChecker which detects
a raw reference or a raw pointer local, static, or global variable to a
CheckedPtr capable object without a guardian variable in an outer scope.
This PR resolves a crash triggered by a forward reference to an enum
type in a function parameter list. The fix includes setting `Invalid`
when `TagUseKind` is `Declaration` to ensure correct error handling.
Fixes#112208
In https://github.com/llvm/llvm-project/pull/109837, it sets a global
variable(`PGOInstrumentColdFunctionOnly`) in PassBuilderPipelines.cpp
which introduced a data race detected by TSan. To fix this, I decouple
the flag setting, the flags are now set
separately(`instrument-cold-function-only-path` is required to be used
with `--pgo-instrument-cold-function-only`).
This PR removes the `HeaderFileInfo::Framework` member and reduces the
size of this data type from 32B to 16B. This should improve Clang's
memory usage in situations where it keeps track of lots of header files.
NFCI. Depends on #114459.
This PR removes the `-index-header-map` functionality from Clang. AFAIK
this was only used internally at Apple and is now dead code. The main
motivation behind this change is to enable the removal of
`HeaderFileInfo::Framework` member and reducing the size of that data
structure.
rdar://84036149
We want to support CFI instrumentation for the bitcode section, without
miscompiling the object code portion of a FatLTO object. We can reuse
the existing mechanisms in the LowerTypeTestsPass to do that, by just
adding the pass to the FatLTO pipeline after the EmbedBitcodePass with
the correct options set.
Fixes#112053
The nested switch exists to share setting IntrinsicsTypes to {ResultType}.
clz/ctz return before we reach that so they can just be in the top
level switch.
When reading a path from a bitstream blob, `ASTReader` performs up to
three allocations:
1. Conversion of the `StringRef` blob into `std::string` to conform to
the `ResolveImportedPath()` API that takes `std::string &`.
2. Concatenation of the module file prefix directory and the relative
path into a fresh `SmallString<128>` buffer in `ResolveImportedPath()`.
3. Propagating the result out of `ResolveImportedPath()` by calling
`std::string::assign()` on the out-parameter.
This patch makes is so that we avoid allocations altogether (amortized)
by:
1. Avoiding conversion of the `StringRef` blob into `std::string` and
changing the `ResolveImportedPath()` API.
2. Using one "global" buffer to hold the concatenation.
3. Returning `StringRef` that points into the buffer and ensuring the
contents are not overwritten while it lives.
Note that in some places of the bitstream we don't store paths as blobs,
but rather as records that get VBR-encoded. This makes the allocation in
(1) unavoidable. I plan to fix this in a follow-up PR by changing the
PCM format.
Moreover, there are some data structures (e.g.
`serialization::InputFileInfo`) that store deserialized and resolved
paths as `std::string`. If we don't access them frequently, it would be
more efficient to store just the unresolved `StringRef` and resolve them
on demand (within some kind of shared buffer to prevent allocations).
This PR alone improves `clang-scan-deps` performance on my workload by
3.6%.
This is a subset of #68288, with hopefully narrower scope. It does not
support bitcasting to non-integral types yet.
Bitfields are supported, but only if they result in a full byte-sized
final buffer. It does not support casting from null-pointers yet or
casting from indeterminate bits.
The tests are from #68288 and partially from #74775.
The `BitcastBuffer` struct is currently always working in single bits,
but I plan to (try to) optimize this for the common full-byte case.
The test `clang/test/CodeGen/2004-02-20-Builtins.c` will erroneously
fail if "builtin" is in the path to your source tree.
This change adds a `CHECK-LABEL !llvm.ident` after the `CHECK-NOT` to
avoid searching into the metadata containing the path.
Fixes#62985Fixes#58820
When 3rd-party header files are included as system headers, their
overloaded `new` and `delete` operators are also considered as the std
ones. However, those overloaded operator functions will also be inlined.
This makes the same
symbolic memory marked as released twice: during `checkPreCall` of the
overloaded `delete` operator and when calling `::operator delete` after
inlining the overloaded operator function (if it has).
This patch attempts to fix this bug by adjusting the strategy of
verifying whether the callee is a standard `new` or `delete` operator in
the `isStandardNewDelete` function.
Until now, this has been hardcoded as a downstream patch in lld. Add it
to the driver so that the private patch can be removed.
PS5 only. On PS4, the equivalent hardcoded configuration will remain in
the proprietary linker.
SIE tracker: TOOLCHAIN-16704
This PR is one of the many PRs in the SYCL upstreaming effort focusing
on device code linking during the SYCL offload compilation process. RFC:
https://discourse.llvm.org/t/rfc-offloading-design-for-sycl-offload-kind-and-spir-targets/74088
In this PR, we introduce a new tool that will be used to perform device
code linking for SYCL offload kind. It accepts SYCL device objects in
LLVM IR bitcode format and will generate a fully linked device object
that can then be wrapped and linked into the host object.
A primary use case for this tool is to perform device code linking for
objects with SYCL offload kind inside the clang-linker-wrapper. It can
also be invoked via clang driver as follows:
`clang --target=spirv64 --sycl-link input.bc`
Device code linking for SYCL offloading kind has a number of known
quirks that makes it difficult to use in a unified offloading setting.
Two of the primary issues are:
1. Several finalization steps are required to be run on the fully-linked
LLVM IR bitcode to gaurantee conformance to SYCL standards. This step is
unique to SYCL offloading compilation flow.
2. SPIR-V LLVM Translator tool is an extenal tool and hence SPIR-V IR
code generation cannot be done as part of LTO. This limitation will be
lifted once SPIR-V backend is available as a viable LLVM backend.
Hence, we introduce this new tool to provide a clean wrapper to perform
SYCL device linking.
Co-Author: Michael Toguchi
Thanks
---------
Signed-off-by: Arvind Sudarsanam <arvind.sudarsanam@intel.com>
Swift ClangImporter now supports concurrency annotations on imported
declarations and their parameters/results, to make it possible to use
imported APIs in Swift safely there has to be a way to annotate
individual parameters and result types with relevant attributes that
indicate that e.g. a block is called on a particular actor or it accepts
a `Sendable` parameter.
To faciliate that `SwiftAttr` is switched from `InheritableAttr` which
is a declaration attribute to `DeclOrTypeAttr`. To support this
attribute in type context we need access to its "Attribute" argument
which requires `AttributedType` to be extended to include `Attr *` when
available instead of just `attr::Kind` otherwise it won't be possible to
determine what attribute should be imported.
SValBuilder::getKnownValue, getMinValue, getMaxValue use
SValBuilder::simplifySVal.
simplifySVal does repeated simplification until a fixed-point is
reached. A single step is done by SimpleSValBuilder::simplifySValOnce,
using a Simplifier visitor. That will basically decompose SymSymExprs,
and apply constant folding using the constraints we have in the State.
Once it decomposes a SymSymExpr, it simplifies both sides and then uses
the SValBuilder::evalBinOp to reconstruct the same - but now simpler -
SymSymExpr, while applying some caching to remain performant.
This decomposition, and then the subsequent re-composition poses new
challenges to the SValBuilder::evalBinOp, which is built to handle
expressions coming from real C/C++ code, thus applying some implicit
assumptions.
One previous assumption was that nobody would form an expression like
"((int*)0) - q" (where q is an int pointer), because it doesn't really
makes sense to write code like that.
However, during simplification, we may end up with a call to evalBinOp
similar to this.
To me, simplifying a SymbolRef should never result in Unknown or Undef,
unless it was Unknown or Undef initially or, during simplification we
realized that it's a division by zero once we did the constant folding,
etc.
In the following case the simplified SVal should not become UnknownVal:
```c++
void top(char *p, char *q) {
int diff = p - q; // diff: reg<p> - reg<q>
if (!p) // p: NULL
simplify(diff); // diff after simplification should be: 0(loc) - reg<q>
}
```
Returning Unknown from the simplifySVal can weaken analysis precision in
other places too, such as in SValBuilder::getKnownValue, getMinValue, or
getMaxValue because we call simplifySVal before doing anything else.
For nonloc::SymbolVals, this loss of precision is critical, because for
those the SymbolRef carries an accurate type of the encoded computation,
thus we should at least have a conservative upper or lower bound that we
could return from getMinValue or getMaxValue - yet we would just return
nullptr.
```c++
const llvm::APSInt *SimpleSValBuilder::getKnownValue(ProgramStateRef state,
SVal V) {
return getConstValue(state, simplifySVal(state, V));
}
const llvm::APSInt *SimpleSValBuilder::getMinValue(ProgramStateRef state,
SVal V) {
V = simplifySVal(state, V);
if (const llvm::APSInt *Res = getConcreteValue(V))
return Res;
if (SymbolRef Sym = V.getAsSymbol())
return state->getConstraintManager().getSymMinVal(state, Sym);
return nullptr;
}
```
For now, I don't plan to make the simplification bullet-proof, I'm just
explaining why I made this change and what you need to look out for in
the future if you see a similar issue.
CPP-5750
This PR makes webkit.UncountedLambdaCapturesChecker ignore trivial
functions as well as the one being passed to an argument with
[[clang::noescape]] attribute. This dramatically reduces the false
positive rate for this checker.
To do this, this PR replaces VisitLambdaExpr in favor of checking
lambdas via VisitDeclRefExpr and VisitCallExpr. The idea is that if a
lambda is defined but never called or stored somewhere, then capturing
whatever variable in such a lambda is harmless.
VisitCallExpr explicitly looks for direct invocation of lambdas and
registers its DeclRefExpr to be ignored in VisitDeclRefExpr. If a lambda
is being passed to a function, it checks whether its argument is
annotated with [[clang::noescape]]. If it's not annotated such, it
checks captures for their safety.
Because WTF::switchOn could not be annotated with [[clang::noescape]] as
function type parameters are variadic template function so we hard-code
this function into the checker.
Finally, this PR also converts the accompanying test to use -verify and
adds a bunch of tests.