This caused severe compile-time regressions, see PR43455.
> Modern processors predict the targets of an indirect branch regardless of
> the size of any jump table used to glean its target address. Moreover,
> branch predictors typically use resources limited by the number of actual
> targets that occur at run time.
>
> This patch changes the semantics of the option `-max-jump-table-size` to limit
> the number of different targets instead of the number of entries in a jump
> table. Thus, it is now renamed to `-max-jump-table-targets`.
>
> Before, when `-max-jump-table-size` was specified, it could happen that
> cluster jump tables could have targets used repeatedly, but each one was
> counted and typically resulted in tables with the same number of entries.
> With this patch, when specifying `-max-jump-table-targets`, tables may have
> different lengths, since the number of unique targets is counted towards the
> limit, but the number of unique targets in tables is the same, but for the
> last one containing the balance of targets.
>
> Differential revision: https://reviews.llvm.org/D60295
llvm-svn: 373060
We can't use short granules with stack instrumentation when targeting older
API levels because the rest of the system won't understand the short granule
tags stored in shadow memory.
Moreover, we need to be able to let old binaries (which won't understand
short granule tags) run on a new system that supports short granule
tags. Such binaries will call the __hwasan_tag_mismatch function when their
outlined checks fail. We can compensate for the binary's lack of support
for short granules by implementing the short granule part of the check in
the __hwasan_tag_mismatch function. Unfortunately we can't do anything about
inline checks, but I don't believe that we can generate these by default on
aarch64, nor did we do so when the ABI was fixed.
A new function, __hwasan_tag_mismatch_v2, is introduced that lets code
targeting the new runtime avoid redoing the short granule check. Because tag
mismatches are rare this isn't important from a performance perspective; the
main benefit is that it introduces a symbol dependency that prevents binaries
targeting the new runtime from running on older (i.e. incompatible) runtimes.
Differential Revision: https://reviews.llvm.org/D68059
llvm-svn: 373035
When checking for tail call eligibility, we should use the correct CCAssignFn
for each argument, rather than just checking if the caller/callee is varargs or
not.
This is important for tail call lowering with varargs. If we don't check it,
then basically any varargs callee with parameters cannot be tail called on
Darwin, for one thing. If the parameters are all guaranteed to be in registers,
this should be entirely safe.
On top of that, not checking for this could potentially make it so that we have
the wrong stack offsets when checking for tail call eligibility.
Also refactor some of the stuff for CCAssignFnForCall and pull it out into a
helper function.
Update call-translator-tail-call.ll to show that we can now correctly tail call
on Darwin. Also add two extra tail call checks. The first verifies that we still
respect the caller's stack size, and the second verifies that we still don't
tail call when a varargs function has a memory argument.
Differential Revision: https://reviews.llvm.org/D67939
llvm-svn: 372897
Modern processors predict the targets of an indirect branch regardless of
the size of any jump table used to glean its target address. Moreover,
branch predictors typically use resources limited by the number of actual
targets that occur at run time.
This patch changes the semantics of the option `-max-jump-table-size` to limit
the number of different targets instead of the number of entries in a jump
table. Thus, it is now renamed to `-max-jump-table-targets`.
Before, when `-max-jump-table-size` was specified, it could happen that
cluster jump tables could have targets used repeatedly, but each one was
counted and typically resulted in tables with the same number of entries.
With this patch, when specifying `-max-jump-table-targets`, tables may have
different lengths, since the number of unique targets is counted towards the
limit, but the number of unique targets in tables is the same, but for the
last one containing the balance of targets.
Differential revision: https://reviews.llvm.org/D60295
llvm-svn: 372893
I think we should be able to use shl instead of sshl and ushl for
positive constant shift values, unless I am missing something.
We already have the machinery in place to ensure we only replace
nodes, if the shift value is positive and <= the element width.
This is a generalization of an earlier patch rL372565.
Reviewers: t.p.northover, samparker, dmgreen, anemet
Reviewed By: anemet
Differential Revision: https://reviews.llvm.org/D67955
llvm-svn: 372824
Summary:
The Regex "match" and "sub" member functions were previously not "const"
because they wrote to the "error" member variable. This commit removes
those assignments, and instead assumes that the validity of the regex
is already known after the initial compilation of the regular
expression. As a result, these member functions were possible to make
"const". This makes it easier to do things like pre-compile Regexes
up-front, and makes "match" and "sub" thread-safe. The error status is
now returned as an optional output, which also makes the API of "match"
and "sub" more consistent with each other.
Also, some uses of Regex that could be refactored to be const were made const.
Patch by Nicolas Guillemot
Reviewers: jankratochvil, thopre
Subscribers: llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D67241
llvm-svn: 372764
Summary:
The functions different in two ways:
- getLLVMRegNum could return both "eh" and "other" dwarf register
numbers, while getLLVMRegNumFromEH only returned the "eh" number.
- getLLVMRegNum asserted if the register was not found, while the second
function returned -1.
The second distinction was pretty important, but it was very hard to
infer that from the function name. Aditionally, for the use case of
dumping dwarf expressions, we needed a function which can work with both
kinds of number, but does not assert.
This patch solves both of these issues by merging the two functions into
one, returning an Optional<unsigned> value. While the same thing could
be achieved by adding an "IsEH" argument to the (renamed)
getLLVMRegNumFromEH function, it seemed better to avoid the confusion of
two functions and put the choice of asserting into the hands of the
caller -- if he checks the Optional value, he can safely process
"untrusted" input, and if he blindly dereferences the Optional, he gets
the assertion.
I've updated all call sites to the new API, choosing between the two
options according to the function they were calling originally, except
that I've updated the usage in DWARFExpression.cpp to use the "safe"
method instead, and added a test case which would have previously
triggered an assertion failure when processing (incorrect?) dwarf
expressions.
Reviewers: dsanders, arsenm, JDevlieghere
Subscribers: wdng, aprantl, javed.absar, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D67154
llvm-svn: 372710
Try to generate ushll/sshll for aarch64_neon_ushl/aarch64_neon_sshl,
if their first operand is extended and the second operand is a constant
Also adds a few tests marked with FIXME, where we can further increase
codegen.
Reviewers: t.p.northover, samparker, dmgreen, anemet
Reviewed By: anemet
Differential Revision: https://reviews.llvm.org/D62308
llvm-svn: 372565
The static analyzer is warning about potential null dereferences, but we should be able to use cast<> directly and if not assert will fire for us.
llvm-svn: 372507
This patch adds the patterns to select the dot product instructions.
Tested on aarch64-linux with make check-all.
Differential Revision: https://reviews.llvm.org/D67645
llvm-svn: 372408
This reverts r372314, reapplying r372285 and the commits which depend
on it (r372286-r372293, and r372296-r372297)
This was missing one switch to getTargetConstant in an untested case.
llvm-svn: 372338
As commented on D67557 we have a lot of uses of depth checks all using magic numbers.
This patch adds the SelectionDAG::MaxRecursionDepth constant and moves over some general cases to use this explicitly.
Differential Revision: https://reviews.llvm.org/D67711
llvm-svn: 372315
This broke the Chromium build, causing it to fail with e.g.
fatal error: error in backend: Cannot select: t362: v4i32 = X86ISD::VSHLI t392, Constant:i8<15>
See llvm-commits thread of r372285 for details.
This also reverts r372286, r372287, r372288, r372289, r372290, r372291,
r372292, r372293, r372296, and r372297, which seemed to depend on the
main commit.
> Encode them directly as an imm argument to G_INTRINSIC*.
>
> Since now intrinsics can now define what parameters are required to be
> immediates, avoid using registers for them. Intrinsics could
> potentially want a constant that isn't a legal register type. Also,
> since G_CONSTANT is subject to CSE and legalization, transforms could
> potentially obscure the value (and create extra work for the
> selector). The register bank of a G_CONSTANT is also meaningful, so
> this could throw off future folding and legalization logic for AMDGPU.
>
> This will be much more convenient to work with than needing to call
> getConstantVRegVal and checking if it may have failed for every
> constant intrinsic parameter. AMDGPU has quite a lot of intrinsics wth
> immarg operands, many of which need inspection during lowering. Having
> to find the value in a register is going to add a lot of boilerplate
> and waste compile time.
>
> SelectionDAG has always provided TargetConstant for constants which
> should not be legalized or materialized in a register. The distinction
> between Constant and TargetConstant was somewhat fuzzy, and there was
> no automatic way to force usage of TargetConstant for certain
> intrinsic parameters. They were both ultimately ConstantSDNode, and it
> was inconsistently used. It was quite easy to mis-select an
> instruction requiring an immediate. For SelectionDAG, start emitting
> TargetConstant for these arguments, and using timm to match them.
>
> Most of the work here is to cleanup target handling of constants. Some
> targets process intrinsics through intermediate custom nodes, which
> need to preserve TargetConstant usage to match the intrinsic
> expectation. Pattern inputs now need to distinguish whether a constant
> is merely compatible with an operand or whether it is mandatory.
>
> The GlobalISelEmitter needs to treat timm as a special case of a leaf
> node, simlar to MachineBasicBlock operands. This should also enable
> handling of patterns for some G_* instructions with immediates, like
> G_FENCE or G_EXTRACT.
>
> This does include a workaround for a crash in GlobalISelEmitter when
> ARM tries to uses "imm" in an output with a "timm" pattern source.
llvm-svn: 372314
Encode them directly as an imm argument to G_INTRINSIC*.
Since now intrinsics can now define what parameters are required to be
immediates, avoid using registers for them. Intrinsics could
potentially want a constant that isn't a legal register type. Also,
since G_CONSTANT is subject to CSE and legalization, transforms could
potentially obscure the value (and create extra work for the
selector). The register bank of a G_CONSTANT is also meaningful, so
this could throw off future folding and legalization logic for AMDGPU.
This will be much more convenient to work with than needing to call
getConstantVRegVal and checking if it may have failed for every
constant intrinsic parameter. AMDGPU has quite a lot of intrinsics wth
immarg operands, many of which need inspection during lowering. Having
to find the value in a register is going to add a lot of boilerplate
and waste compile time.
SelectionDAG has always provided TargetConstant for constants which
should not be legalized or materialized in a register. The distinction
between Constant and TargetConstant was somewhat fuzzy, and there was
no automatic way to force usage of TargetConstant for certain
intrinsic parameters. They were both ultimately ConstantSDNode, and it
was inconsistently used. It was quite easy to mis-select an
instruction requiring an immediate. For SelectionDAG, start emitting
TargetConstant for these arguments, and using timm to match them.
Most of the work here is to cleanup target handling of constants. Some
targets process intrinsics through intermediate custom nodes, which
need to preserve TargetConstant usage to match the intrinsic
expectation. Pattern inputs now need to distinguish whether a constant
is merely compatible with an operand or whether it is mandatory.
The GlobalISelEmitter needs to treat timm as a special case of a leaf
node, simlar to MachineBasicBlock operands. This should also enable
handling of patterns for some G_* instructions with immediates, like
G_FENCE or G_EXTRACT.
This does include a workaround for a crash in GlobalISelEmitter when
ARM tries to uses "imm" in an output with a "timm" pattern source.
llvm-svn: 372285
Since we now lower most tail calls, it makes sense to support musttail.
Instead of always falling back to SelectionDAG, only fall back when a musttail
call was not able to be emitted as a tail call. Once we can handle most
incoming and outgoing arguments, we can change this to a `report_fatal_error`
like in ISelLowering.
Remove the assert that we don't have varargs and a musttail, and replace it
with a return false. Implementing this requires that we implement
`saveVarArgRegisters` from AArch64ISelLowering, which is an entirely different
patch.
Add GlobalISel lines to vararg-tallcall.ll to make sure that we produce correct
code. Right now we only fall back, but eventually this will be relevant.
Differential Revision: https://reviews.llvm.org/D67681
llvm-svn: 372273
Summary:
AArch64 GlobalISel doesn't support MachO's large code model, so this patch
adds a check for that combination before implicitly enabling it.
Reviewers: paquette
Subscribers: kristof.beyls, ributzka, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D67724
llvm-svn: 372256
This patch fixes a bug exposed by D65653 where a subsequent invocation
of `determineCalleeSaves` ends up with a different size for the callee
save area, leading to different frame-offsets in debug information.
In the invocation by PEI, `determineCalleeSaves` tries to determine
whether it needs to spill an extra callee-saved register to get an
emergency spill slot. To do this, it calls 'estimateStackSize' and
manually adds the size of the callee-saves to this. PEI then allocates
the spill objects for the callee saves and the remaining frame layout
is calculated accordingly.
A second invocation in LiveDebugValues causes estimateStackSize to return
the size of the stack frame including the callee-saves. Given that the
size of the callee-saves is added to this, these callee-saves are counted
twice, which leads `determineCalleeSaves` to believe the stack has
become big enough to require spilling an extra callee-save as emergency
spillslot. It then updates CalleeSavedStackSize with a larger value.
Since CalleeSavedStackSize is used in the calculation of the frame
offset in getFrameIndexReference, this leads to incorrect offsets for
variables/locals when this information is recalculated after PEI.
Reviewers: omjavaid, eli.friedman, thegameg, efriedma
Reviewed By: efriedma
Differential Revision: https://reviews.llvm.org/D66935
llvm-svn: 372204
This adds support for `-tailcallopt` tail calls to CallLowering. This
piggy-backs off the changes from D67577, since doing it without a bit of
refactoring gets extremely ugly.
Support is basically ported from AArch64ISelLowering. The main difference here
is that tail calls in `-tailcallopt` change the ABI, so there's some extra
bookkeeping for the stack.
Show that we are correctly lowering these by updating tail-call.ll.
Also show that we don't do anything strange in general by updating
fastcc-reserved.ll, which passes `-tailcallopt`, but doesn't emit any tail
calls.
Differential Revision: https://reviews.llvm.org/D67580
llvm-svn: 372177
When you begin implementing -tailcallopt, this gets somewhat hairy. Refactor
the call lowering code so that the tail call lowering stuff gets its own
function.
Differential Revision: https://reviews.llvm.org/D67577
llvm-svn: 372164
* Reordered MVT simple types to group scalable vector types
together.
* New range functions in MachineValueType.h to only iterate over
the fixed-length int/fp vector types.
* Stopped backends which don't support scalable vector types from
iterating over scalable types.
Reviewers: sdesmalen, greened
Reviewed By: greened
Differential Revision: https://reviews.llvm.org/D66339
llvm-svn: 372099
Summary:
Adds the following inline asm constraints for SVE:
- Upl: One of the low eight SVE predicate registers, P0 to P7 inclusive
- Upa: SVE predicate register with full range, P0 to P15
Reviewers: t.p.northover, sdesmalen, rovka, momchil.velikov, cameron.mcinally, greened, rengolin
Reviewed By: rovka
Subscribers: javed.absar, tschuett, rkruppe, psnobl, cfe-commits, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D66524
llvm-svn: 371967
After our previous machinecombiner exercises (rL371321, rL371818, rL371833), we
were still missing a few FP16 FMA patterns.
Differential Revision: https://reviews.llvm.org/D67576
llvm-svn: 371960
Because memory intrinsics are handled differently than other calls, we need to
check them for tail call eligiblity in the legalizer. This allows us to still
inline them when it's beneficial to do so, but also tail call when possible.
This adds simple tail calling support for when the intrinsic is followed by a
return.
It ports the attribute checks from `TargetLowering::isInTailCallPosition` into
a similarly-named function in LegalizerHelper.cpp. The target-specific
`isUsedByReturnOnly` hook is not ported here.
Update tailcall-mem-intrinsics.ll to show that GlobalISel can now tail call
memory intrinsics.
Update legalize-memcpy-et-al.mir to have a case where we don't tail call.
Differential Revision: https://reviews.llvm.org/D67566
llvm-svn: 371893
In preparation for def-pat selection of dot product instructions,
this patch moves the custom instruction selection of extract_vector_elt
to the td file. Without this change it is impossible to catch a pattern that
starts with an extract_vector_elt: the custom cpp code is executed first
ahead of the patterns in the td files that are only executed at the end of
the switch statement in SelectCode(Node).
With this patch applied, it becomes possible to select a different pattern
that starts with extract_vector_elt by selecting a higher complexity than
this pattern.
The patch has been tested on aarch64-linux with make check-all.
Differential Revision: https://reviews.llvm.org/D67497
llvm-svn: 371887
This adds support for tail calling callees with varargs, equivalent to how it
is done in AArch64ISelLowering.
This only works for sibling calls, and does not add the necessary support for
musttail with varargs. (See r345641 for equivalent ISelLowering support.) This
should be implemented when we stop falling back on musttail.
Update call-translator-tail-call.ll to show that we can now tail call varargs.
Differential Revision: https://reviews.llvm.org/D67518
llvm-svn: 371868
Follow-up of rL371321 that added some more FP16 FMA patterns, and an attempt to
reduce the copy-pasting and make this more readable.
Differential Revision: https://reviews.llvm.org/D67403
llvm-svn: 371818
Swiftself uses a callee-saved register. We can tail call when the register used
in the caller and callee is the same.
This behaviour is equivalent to that in `TargetLowering::parametersInCSRMatch`.
Update call-translator-tail-call.ll to verify that we can do this. When we
support inline assembly, we can write a check similar to the one in the
general swiftself.ll. For now, we need to verify that we get the correct COPY
instruction after call lowering.
Differential Revision: https://reviews.llvm.org/D67511
llvm-svn: 371788
This adds support for lowering sibling calls with outgoing arguments.
e.g
```
define void @foo(i32 %a)
```
Support is ported from AArch64ISelLowering's `isEligibleForTailCallOptimization`.
The only thing that is missing is a full port of
`TargetLowering::parametersInCSRMatch`. So, if we're using swiftself,
we'll never tail call.
- Rename `analyzeCallResult` to `analyzeArgInfo`, since the function is now used
for both outgoing and incoming arguments
- Teach `OutgoingArgHandler` about tail calls. Tail calls use frame indices for
stack arguments.
- Teach `lowerFormalArguments` to set the bytes in the caller's stack argument
area. This is used later to check if the tail call's parameters will fit on
the caller's stack.
- Add `areCalleeOutgoingArgsTailCallable` to perform the eligibility check on
the callee's outgoing arguments.
For testing:
- Update call-translator-tail-call to verify that we can now tail call with
outgoing arguments, use G_FRAME_INDEX for stack arguments, and respect the
size of the caller's stack
- Remove GISel-specific check lines from speculation-hardening.ll, since GISel
now tail calls like the other selectors
- Add a GISel test line to tailcall-string-rvo.ll since we can tail call in that
test now
- Add a GISel test line to tailcall_misched_graph.ll since we tail call there
now. Add specific check lines for GISel, since the debug output from the
machine-scheduler differs with GlobalISel. The dependency still holds, but
the output comes out in a different order.
Differential Revision: https://reviews.llvm.org/D67471
llvm-svn: 371780
This is the main CodeGen patch to support the arm64_32 watchOS ABI in LLVM.
FastISel is mostly disabled for now since it would generate incorrect code for
ILP32.
llvm-svn: 371722
Before, we only checked the callee for swifterror. However, we should also be
checking the caller to see if it has a swifterror parameter.
Since we don't currently handle outgoing arguments, this didn't show up in the
swifterror.ll testcase.
Also, remove the swifterror checks from call-translator-tail-call.ll, since
they are covered by the existing swifterror testing. Better to have it all in
one place.
Differential Revision: https://reviews.llvm.org/D67465
llvm-svn: 371692
This fixes a crash in tail call translation caused by assume and lifetime_end
intrinsics.
It's possible to have instructions other than a return after a tail call which
will still have `Analysis::isInTailCallPosition` return true. (Namely,
lifetime_end and assume intrinsics.)
If we emit a tail call, we should stop translating instructions in the block.
Otherwise, we can end up emitting an extra return, or dead instructions in
general. This makes the verifier unhappy, and is generally unfortunate for
codegen.
This also removes the code from AArch64CallLowering that checks if we have a
tail call when lowering a return. This is covered by the new code now.
Also update call-translator-tail-call.ll to show that we now properly tail call
in the presence of lifetime_end and assume.
Differential Revision: https://reviews.llvm.org/D67415
llvm-svn: 371572
Add support for sibcalling calls whose calling convention differs from the
caller's.
- Port over `CCState::resultsCombatible` from CallingConvLower.cpp into
CallLowering. This is used to verify that the way the caller and callee CC
handle incoming arguments matches up.
- Add `CallLowering::analyzeCallResult`. This is basically a port of
`CCState::AnalyzeCallResult`, but using `ArgInfo` rather than `ISD::InputArg`.
- Add `AArch64CallLowering::doCallerAndCalleePassArgsTheSameWay`. This checks
that the calling conventions are compatible, and that the caller and callee
preserve the same registers.
For testing:
- Update call-translator-tail-call.ll to show that we can now handle this.
- Add a GISel line to tailcall-ccmismatch.ll to show that we will not tail call
when the regmasks don't line up.
Differential Revision: https://reviews.llvm.org/D67361
llvm-svn: 371570
Just return once you emit the call, which is exactly what SelectionDAG does in
this situation.
Update call-translator-tail-call.ll.
Also update dllimport.ll to show that we tail call here in GISel again. Add
-verify-machineinstrs to the GISel line too, to defend against verifier
failures.
Differential revision: https://reviews.llvm.org/D67282
llvm-svn: 371425
Summary:
This patch implements two arithmetic intrinsics:
* int_aarch64_sve_abs
* int_aarch64_sve_neg
testing the support for scalable vector types in intrinsics added in D65930.
Reviewed By: greened
Differential Revision: https://reviews.llvm.org/D65931
llvm-svn: 371388
Loosely based on DAGCombiner version, but this part is slightly simpler in
GlobalIsel because all address calculation is performed by G_GEP. That makes
the inc/dec distinction moot so there's just pre/post to think about.
No targets can handle it yet so testing is via a special flag that overrides
target hooks.
llvm-svn: 371384
Hans Wennborg