First step done in this commit is to get flush out enough of the
SymbolizerGetOpInfo() routine to symbolic an X86_64 hello world .o and
its loading of the literal string and call to printf. Also the code to
symbolicate the X86_64_RELOC_SUBTRACTOR relocation and a test is also
added to show a slightly more complicated case.
Next will be to flush out enough of SymbolizerSymbolLookUp() to get the
literal string “Hello world” printed as a comment on the instruction that load
the pointer to it.
llvm-svn: 217893
MSVC 2012 cannot infer any move special members, but it will call them
if available. MSVC 2013 cannot infer move assignment. Therefore,
explicitly implement the special members for the ExecutionContext class
and its contained types.
llvm-svn: 217887
By class-instance values I mean 'Class<Arg>' in 'Class<Arg>.Field' or in
'Other<Class<Arg>>' (syntactically s SimpleValue). This is to differentiate
from unnamed/anonymous record definitions (syntactically an ObjectBody) which
are not affected by this change.
Consider the testcase:
class Struct<int i> {
int I = !shl(i, 1);
int J = !shl(I, 1);
}
class Class<Struct s> {
int Class_J = s.J;
}
multiclass MultiClass<int i> {
def Def : Class<Struct<i>>;
}
defm Defm : MultiClass<2>;
Before this fix, DefmDef.Class_J yields !shl(I, 1) instead of 8.
This is the sequence of events. We start with this:
multiclass MultiClass<int i> {
def Def : Class<Struct<i>>;
}
During ParseDef the anonymous object for the class-instance value is created:
multiclass Multiclass<int i> {
def anonymous_0 : Struct<i>;
def Def : Class<NAME#anonymous_0>;
}
Then class Struct<i> is added to anonymous_0. Also Class<NAME#anonymous_0> is
added to Def:
multiclass Multiclass<int i> {
def anonymous_0 {
int I = !shl(i, 1);
int J = !shl(I, 1);
}
def Def {
int Class_J = NAME#anonymous_0.J;
}
}
So far so good but then we move on to instantiating this in the defm
by substituting the template arg 'i'.
This is how the anonymous prototype looks after fully instantiating.
defm Defm = {
def Defmanonymous_0 {
int I = 4;
int J = !shl(I, 1);
}
Note that we only resolved the reference to the template arg. The
non-template-arg reference in 'J' has not been resolved yet.
Then we go on to instantiating the Def prototype:
def DefmDef {
int Class_J = NAME#anonymous_0.J;
}
Which is resolved to Defmanonymous_0.J and then to !shl(I, 1).
When we fully resolve each record in a defm, Defmanonymous_0.J does get set
to 8 but that's too late for its use.
The patch adds a new attribute to the Record class that indicates that this
def is actually a class-instance value that may be *used* by other defs in a
multiclass. (This is unlike regular defs which don't reference each other and
thus can be resolved indepedently.) They are then fully resolved before the
other defs while the multiclass is instantiated.
I added vg_leak to the new test. I am not sure if this is necessary but I
don't think I have a way to test it. I can also check in without the XFAIL
and let the bots test this part.
Also tested that X86.td.expanded and AAarch64.td.expanded were unchange before
and after this change. (This issue triggering this problem is a WIP patch.)
Part of <rdar://problem/17688758>
llvm-svn: 217886
ADDS/SUBS unless it's safe to clobber the condition flags.
If the merged instructions are in a range where the CPSR is live,
e.g. between a CMP -> Bcc, we can't safely materialize a new base
register.
This problem is quite rare, I couldn't come up with a test case and I've
never actually seen this happen in the tests I'm running - there is a
potential trigger for this in LNT/oggenc (spills being inserted between
a CMP/Bcc), but at the moment this isn't being merged. I'll try to
reduce that into a small test case once I've committed my upcoming patch
to make merging less conservative.
llvm-svn: 217881
Summary: Changed error messages to be more informative and to resemble other clang/llvm error messages (first letter is lower case, no ending punctuation) and updated corresponding tests.
Reviewers: dsanders
Reviewed By: dsanders
Differential Revision: http://reviews.llvm.org/D5065
llvm-svn: 217873
objects. There were a few FIXMEs in ARMAsmBackend.cpp suggesting the class
definitions should be in a separate file. Starting with ARMAsmBackend, the
class definition has been put in a header file, and #includes reduced. Each
sub-type of ARMAsmBackend is now in its own header file.
Derived types have been painted with a different color of bike-shed:
s/DarwinARMAsmBackend/ARMAsmBackendDarwin/g
s/ARMWinCOFFAsmBackend/ARMAsmBackendWinCOFF/g
s/ELFARMAsmBackend/ARMAsmBackendELF/g
Finally, clang-format has been run across ARMAsmBackend.cpp
llvm-svn: 217866
The default implementation of getCmpSelInstrCost, which provides the cost of
icmp/fcmp/select instructions, did not deal sensibly with illegal vector types
that were scalarized. We'd ask for the legalization cost of the vector type,
which would return something like (4, f64) given an input of <4 x double>, and
we'd then check the TLI status of the ISD opcode on that scalar type. This would
result in querying (ISD::VSELECT, f64), for example. Amusingly enough,
ISD::VSELECT on scalar types is marked as Legal by default (as with most other
operations), and most backends never change this because VSELECT is never
generated on scalars. However, seeing the resulting operation as Legal, we'd
neglect to add the scalarization cost before returning. The result is that we'd
grossly under-estimate the cost of cmps/selects on illegal vector types.
Now, if type legalization clearly results in scalarization, we skip the early
return and add the scalarization cost.
llvm-svn: 217859
Teach yaml2obj how to make a bigobj COFF file. Like the rest of LLVM,
we automatically decide whether or not to use regular COFF or bigobj
COFF on the fly depending on how many sections the resulting object
would have.
This ends the task of adding bigobj support to LLVM.
N.B. This was tested by forcing yaml2obj to be used in bigobj mode
regardless of the number of sections. While a dedicated test was
written, the smallest I could make it was 36 MB (!) of yaml and it still
took a significant amount of time to execute on a powerful machine.
llvm-svn: 217858
the blend that is matched by this are "used" in any sense, and so any
build_vector or other nodes feeding these will already drop other lanes.
llvm-svn: 217855
This finishes the ability of llvm-objdump to print out all information from
the LC_DYLD_INFO load command.
The -bind option prints out symbolic references that dyld must resolve
immediately.
The -lazy-bind option prints out symbolc reference that are lazily resolved on
first use.
The -weak-bind option prints out information about symbols which dyld must
try to coalesce across images.
llvm-svn: 217853
matching. This design just fundamentally didn't work because ADDSUB is
available prior to any legal lowerings of BLENDI nodes. Instead, we have
a dedicated ADDSUB synthetic ISD node which is pattern matched trivially
into the instructions. These nodes are then recognized by both the
existing and a trivial new lowering combine in the backend. Removing
these patterns required adding 2 missing shuffle masks to the DAG
combine, without which tests would have failed. Added the masks and
a helpful assert as well to catch if anything ever goes wrong here.
llvm-svn: 217851
that we don't use VSELECT and directly emit an addsub synthetic node.
Also remove a stale comment referencing VSELECT.
The test case is updated to use 'core2' which only has SSE3, not SSE4.1,
and it still passes. Previously it would not because we lacked
sufficient blend support to legalize the VSELECT.
llvm-svn: 217849
ADDSUBPD nodes out of blends of adds and subs.
This allows us to actually form these instructions with SSE3 rather than
only forming them when we had both SSE3 for the ADDSUB instructions and
SSE4.1 for the blend instructions. ;] Kind-of important.
I've adjusted the CPU requirements on one of the tests to demonstrate
this kicking in nicely for an SSE3 cpu configuration.
llvm-svn: 217848
This adds the missing test case for the previous commit:
Allow handling of vectors during return lowering for little endian machines.
Sorry for the noise.
llvm-svn: 217847
Allow handling of vectors during return lowering at least for little endian machines.
This was restricted in r208200 to fix it for big endian machines (according to
the comment), but it also disabled it for little endian too.
llvm-svn: 217846
This changes the debug output of the llvm-cov tool to consistently
write to stderr, and moves the highlighting output closer to where
it's relevant.
llvm-svn: 217838
In r217746, though it was supposed to be NFC, I broke llvm-cov's
handling of showing regions without showing counts. This should've
shown up in the existing tests, except they were checking debug output
that was displayed regardless of what was actually output. I've moved
the relevant debug output to a more appropriate place so that the
tests catch this kind of thing.
llvm-svn: 217835
This lowers frem to a runtime libcall inside fast-isel.
The test case also checks the CallLoweringInfo bug that was exposed by this
change.
This fixes rdar://problem/18342783.
llvm-svn: 217833
This fixes a bug in FastISel::CallLoweringInfo, where the number of
arguments was obtained from the argument vector before it had been
initialized.
Test case follows in another commit.
llvm-svn: 217832
We already have routines to encode SLEB128 as well as encode/decode ULEB128.
This last function fills out the matrix. I'll need this for some llvm-objdump
work I am doing.
llvm-svn: 217830
Summary: UsedByBranch is always true according to how BonusInst is defined.
Test Plan:
Passes check-all, and also verified
if (BonusInst && !UsedByBranch) {
...
}
is never entered during check-all.
Reviewers: resistor, nadav, jingyue
Reviewed By: jingyue
Subscribers: llvm-commits, eliben, meheff
Differential Revision: http://reviews.llvm.org/D5324
llvm-svn: 217824
Summary:
Expand list of supported targets for Mips to include mips32 r1.
Previously it only include r2. More patches are coming where there is
a difference but in the current patches as pushed upstream, r1 and r2
are equivalent.
Test Plan:
simplestorefp1.ll
add new build bots at mips to test this flavor at both -O0 and -O2
Reviewers: dsanders
Reviewed By: dsanders
Differential Revision: http://reviews.llvm.org/D5306
llvm-svn: 217821
introducing a synthetic X86 ISD node representing this generic
operation.
The relevant patterns for mapping these nodes into the concrete
instructions are also added, and a gnarly bit of C++ code in the
target-specific DAG combiner is replaced with simple code emitting this
primitive.
The next step is to generically combine blends of adds and subs into
this node so that we can drop the reliance on an SSE4.1 ISD node
(BLENDI) when matching an SSE3 feature (ADDSUB).
llvm-svn: 217819