This ensures that we format:
void longFunctionName {
} // long comment here
And not:
void longFunctionName {}
// long comment here
As requested in post-commit-review.
llvm-svn: 182024
It turns out that several implementations go through the trouble of
setting up a SourceManager and Lexer and abstracting this into a
function makes usage easier.
Also abstracts SourceManager-independent ranges out of
tooling::Refactoring and provides a convenience function to create them
from line ranges.
llvm-svn: 181997
Clang has an issue between mingw/include/float.h and clang/Headers/float.h with cyclic include_next.
For now, it should work to suppress #include_next in clang/float.h with an explicit target.
(It may work with -U__MINGW32__, though.)
llvm-svn: 181988
a FieldDecl from it, and propagate both into the closure type and the
LambdaExpr.
You can't do much useful with them yet -- you can't use them within the body
of the lambda, because we don't have a representation for "the this of the
lambda, not the this of the enclosing context". We also don't have support or a
representation for a nested capture of an init-capture yet, which was intended
to work despite not being allowed by the current standard wording.
llvm-svn: 181985
In the case of inline functions, we have to special case local types
when they are used as template arguments to make sure the template
instantiations are still uniqued in case the function itself is inlined.
llvm-svn: 181981
The page is generated from a text file listing DR numbers and implementation
status, plus a copy of the cwg_index.html from the WG21 website. Recipe:
$ wget http://www.open-std.org/jtc1/sc22/wg21/docs/cwg_index.html
$ ./make_cxx_dr_status >! cxx_dr_status.html
The intent here is to go through all the DRs, add tests for each one, then mark
them as done once such tests are committed and passing. I've not linked to this
page from anywhere, since it doesn't contain any useful information yet.
llvm-svn: 181967
This reverts commit r181393 (git 3923d6a87fe7b2c91cc4a7dbd90c4ec7e2316bcd).
This seems to be emitting too much extra debug info for two (known)
reasons:
* full class definitions are emitted when only declarations are expected
* unused using declarations still produce DW_TAG_imported_declarations
llvm-svn: 181947
This class is a StmtVisitor that distinguishes between block-level and
non-block-level statements in a CFG. However, it does so using a hard-coded
idea of which statements might be block-level, which probably isn't accurate
anymore. The only implementer of the CFGStmtVisitor hierarchy was the
analyzer's DeadStoresChecker, and the analyzer creates a linearized CFG
anyway (every non-trivial statement is a block-level statement).
This also allows us to remove the block-expr map ("BlkExprMap"), which
mapped statements to positions in the CFG. Apart from having a helper type
that really should have just been Optional<unsigned>, it was only being
used to ask /if/ a particular expression was block-level, for traversal
purposes in CFGStmtVisitor.
llvm-svn: 181945
DefaultBool is basically just "bool with a default constructor", so it
really should implicitly convert to bool. In fact, it should convert to
bool&, so that it could be passed to functions that take bools by reference.
This time, mark the operator bool& as implicit to promise that it's
deliberate.
llvm-svn: 181908
Before:
namespace abc { class SomeClass; }
namespace def { void someFunction() {} }
After:
namespace abc {
class Def;
}
namespace def {
void someFunction() {}
}
Rationale:
a) Having anything other than forward declaration on the same line
as a namespace looks confusing.
b) Formatting namespace-forward-declaration-combinations different
from other stuff is inconsistent.
c) Wasting vertical space close to such forward declarations really
does not affect readability.
llvm-svn: 181887
This commit improves Clang's diagnostics for string initialization.
Where it would previously say:
/tmp/a.c:3:9: error: array initializer must be an initializer list
wchar_t s[] = "Hi";
^
/tmp/a.c:4:6: error: array initializer must be an initializer list or string literal
char t[] = L"Hi";
^
It will now say
/tmp/a.c:3:9: error: initializing wide char array with non-wide string literal
wchar_t s[] = "Hi";
^
/tmp/a.c:4:6: error: initializing char array with wide string literal
char t[] = L"Hi";
^
As a bonus, it also fixes the fact that Clang would previously reject
this valid C11 code:
char16_t s[] = u"hi";
char32_t t[] = U"hi";
because it would only recognize the built-in types for char16_t and
char32_t, which do not exist in C.
llvm-svn: 181880
The function type detection in r181438 and r181764 detected function
types too eagerly. This led to inconsistent formatting of inline
assembly and (together with r181687) to an incorrect formatting of calls
in macros.
Before: #define DEREF_AND_CALL_F(parameter) f (*parameter)
After: #define DEREF_AND_CALL_F(parameter) f(*parameter)
llvm-svn: 181870
The most common (non-buggy) case are where such objects are used as
return expressions in bool-returning functions or as boolean function
arguments. In those cases I've used (& added if necessary) a named
function to provide the equivalent (or sometimes negative, depending on
convenient wording) test.
DiagnosticBuilder kept its implicit conversion operator owing to the
prevalent use of it in return statements.
One bug was found in ExprConstant.cpp involving a comparison of two
PointerUnions (PointerUnion did not previously have an operator==, so
instead both operands were converted to bool & then compared). A test
is included in test/SemaCXX/constant-expression-cxx1y.cpp for the fix
(adding operator== to PointerUnion in LLVM).
llvm-svn: 181869
These intrinsics use the __builtin_shuffle() function to extract the
low and high half, respectively, of a 128-bit NEON vector. Currently,
they're defined to use bitcasts to simplify the emitter, so we get code
like:
uint16x4_t vget_low_u32(uint16x8_t __a) {
return (uint32x2_t) __builtin_shufflevector((int64x2_t) __a,
(int64x2_t) __a,
0);
}
While this works, it results in those bitcasts going all the way through
to the IR, resulting in code like:
%1 = bitcast <8 x i16> %in to <2 x i64>
%2 = shufflevector <2 x i64> %1, <2 x i64> undef, <1 x i32>
%zeroinitializer
%3 = bitcast <1 x i64> %2 to <4 x i16>
We can instead easily perform the operation directly on the input vector
like:
uint16x4_t vget_low_u16(uint16x8_t __a) {
return __builtin_shufflevector(__a, __a, 0, 1, 2, 3);
}
Not only is that much easier to read on its own, it also results in
cleaner IR like:
%1 = shufflevector <8 x i16> %in, <8 x i16> undef,
<4 x i32> <i32 0, i32 1, i32 2, i32 3>
This is both easier to read and easier for the back end to reason
about effectively since the operation is obfuscating the source with
bitcasts.
rdar://13894163
llvm-svn: 181865
David Fang