PR47805: Use a single object for a function parameter in the caller and
callee in constant evaluation.

We previously made a deep copy of function parameters of class type when
passing them, resultin

PR47805: Use a single object for a function parameter in the caller and
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.

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Revert "PR47805: Use a single object for a function parameter in the caller and"

Breaks a clangd unit test.

This reverts commit 8f8b9f2cca0b73314342c721186ae9c860ca273c.

PR47805: Use a single object for a function parameter in the caller and
callee in constant evaluation.

We previously made a deep copy of function parameters of class type when
passing them, resultin

PR47805: Use a single object for a function parameter in the caller and
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.

show more ...

Revert "PR47805: Use a single object for a function parameter in the caller and"

The buildbots are displeased.

This reverts commit 8d03a972ce8e92815ffe3d5d86aa027605ed92e2.

PR47805: Use a single object for a function parameter in the caller and
callee in constant evaluation.

We previously made a deep copy of function parameters of class type when
passing them, resultin

PR47805: Use a single object for a function parameter in the caller and
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.

show more ...

[c++20] P1064R0: Allow virtual function calls in constant expression
evaluation.

This reinstates r360559, reverted in r360580, with a fix to avoid
crashing if evaluation-for-overflow mode encounters

[c++20] P1064R0: Allow virtual function calls in constant expression
evaluation.

This reinstates r360559, reverted in r360580, with a fix to avoid
crashing if evaluation-for-overflow mode encounters a virtual call on an
object of a class with a virtual base class, and to generally not try to
resolve virtual function calls to objects whose (notional) vptrs are not
readable. (The standard rules are unclear here, but this seems like a
reasonable approach.)

llvm-svn: 360635

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[Sema] Emit -Winteger-overflow for arguments in function calls, ObjC messages.

rdar://problem/35539384

Reviewers: ahatanak, nicholas, rsmith, jkorous-apple

Reviewed By: jkorous-apple

Subscribers:

[Sema] Emit -Winteger-overflow for arguments in function calls, ObjC messages.

rdar://problem/35539384

Reviewers: ahatanak, nicholas, rsmith, jkorous-apple

Reviewed By: jkorous-apple

Subscribers: cfe-commits, jkorous-apple

Differential Revision: https://reviews.llvm.org/D42938

llvm-svn: 328671

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Sema: disable implicit conversion from _Complex to real types in C++.

Converting a _Complex type to a real one simply discards the imaginary part.
This can easily lead to loss of information so for

Sema: disable implicit conversion from _Complex to real types in C++.

Converting a _Complex type to a real one simply discards the imaginary part.
This can easily lead to loss of information so for safety (and GCC
compatibility) this patch disallows that when the conversion would be implicit.

The one exception is bool, which actually compares both real and imaginary
parts and so is safe.

llvm-svn: 310427

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Adjust tests to have consistent integer sizes.

Add a triple to the run lines so that integers will the same sizes across runs.
Also add a compile time check to ensure the assumptions about sizes are

Adjust tests to have consistent integer sizes.

Add a triple to the run lines so that integers will the same sizes across runs.
Also add a compile time check to ensure the assumptions about sizes are met.

llvm-svn: 265991

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Catch more cases when diagnosing integer-constant-expression overflows.

When visiting AssignmentOps, keep evaluating after a failure (when possible) in
order to identify overflow in subexpressions.

Catch more cases when diagnosing integer-constant-expression overflows.

When visiting AssignmentOps, keep evaluating after a failure (when possible) in
order to identify overflow in subexpressions.

Differential Revision: http://reviews.llvm.org/D1238

llvm-svn: 228202

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