This adds another tablegen fold that converts an i16 odd-lane-insert of
an even-lane-extract into a VINS. We extract the existing f32 value from
the destination register and VINS the new value into it. The rest of the
backend then is able to optimize the INSERT_SUBREG / COPY_TO_REGCLASS /
EXTRACT_SUBREG.
Differential Revision: https://reviews.llvm.org/D95456
Terminate pads, cleanup pads with `__clang_call_terminate` call, have
`catch` instruction in them because `__clang_call_terminate` takes an
exception pointer. But these terminate pads should be reached also in
case of foreign exception. So this pass attaches an additional
`catch_all` BB after every terminate pad BB, with a call to
`std::terminate`.
Reviewed By: tlively
Differential Revision: https://reviews.llvm.org/D94050
Now that PR48908 has been dealt with, we can handle v4f64 permute cases by extracting the low/high lane VPERMILPD masks and creating a new mask based on which lanes are referenced by the VPERM2F128 mask.
This fixes unwind destination mismatches caused by 'catch'es, which
occur when a foreign exception is not caught by the nearest `catch` and
the next outer `catch` is not the catch it should unwind to, or the next
unwind destination should be the caller instead. This kind of mismatches
didn't exist in the previous version of the spec, because in the
previous spec `catch` was effectively `catch_all`, catching all
exceptions.
Reviewed By: tlively
Differential Revision: https://reviews.llvm.org/D94049
This adds `delegate` instruction and use it to fix unwind destination
mismatches created by marker placement in CFGStackify.
There are two kinds of unwind destination mismatches:
- Mismatches caused by throwing instructions (here we call it "call
unwind mismatches", even though `throw` and `rethrow` can also cause
mismatches)
- Mismatches caused by `catch`es, in case a foreign exception is not
caught by the nearest `catch` and the next outer `catch` is not the
catch it should unwind to. This kind of mismatches didn't exist in the
previous version of the spec, because in the previous spec `catch` was
effectively `catch_all`, catching all exceptions.
This implements routines to fix the first kind of unwind mismatches,
which we call "call unwind mismatches". The second mismatch (catch
unwind mismatches) will be fixed in a later CL.
This also reenables all previously disabled tests in cfg-stackify-eh.ll
and updates FileCheck lines to match the new spec. Two tests were
deleted because they specifically tested the way we fixed unwind
mismatches before using `exnref`s and branches, which we don't do
anymore.
Reviewed By: tlively
Differential Revision: https://reviews.llvm.org/D94048
GNU ld>=2.36 supports mixed SHF_LINK_ORDER and non-SHF_LINK_ORDER sections in an
output section, so we can set SHF_LINK_ORDER if -fbinutils-version=2.36 or above.
If -fno-function-sections or older binutils, drop unique ID for -fno-unique-section-names.
The users can just specify -fbinutils-version=2.36 or above to allow GC with both GNU ld and LLD.
(LLD does not support garbage collection of non-group non-SHF_LINK_ORDER .gcc_except_table sections.)
This matches GCC behavior when the configure-time binutils is new. GNU ld<2.36
did not support mixed SHF_LINK_ORDER and non-SHF_LINK_ORDER sections in an
output section, so we conservatively disable SHF_LINK_ORDER for <2.36.
These passes are causing numerical discrepancies after being added to
the pipeline. Disable while investigating.
Reviewed By: rupprecht
Differential Revision: https://reviews.llvm.org/D96166
This patch adds a pass to replace calls to vector intrinsics
(i.e., LLVM intrinsics operating on vector operands) with
calls to a vector library.
Currently, calls to LLVM intrinsics are only replaced with
calls to vector libraries when scalar calls to intrinsics are
vectorized by the Loop- or SLP-Vectorizer.
With this pass, it is now possible to replace calls to LLVM
intrinsics already operating on vector operands, e.g., if
such code was generated by MLIR. For the replacement,
information from the TargetLibraryInfo, e.g., as specified
via -vector-library is used.
Differential Revision: https://reviews.llvm.org/D95373
Make sure scalable property is preserved by using getVectorElementCount().
Reviewed By: paulwalker-arm
Differential Revision: https://reviews.llvm.org/D95967
emitting retainRV or claimRV calls in the IR
This reapplies 3fe3946d9a958b7af6130241996d9cfcecf559d4 without the
changes made to lib/IR/AutoUpgrade.cpp, which was violating layering.
Original commit message:
Background:
This patch makes changes to the front-end and middle-end that are
needed to fix a longstanding problem where llvm breaks ARC's autorelease
optimization (see the link below) by separating calls from the marker
instructions or retainRV/claimRV calls. The backend changes are in
https://reviews.llvm.org/D92569.
https://clang.llvm.org/docs/AutomaticReferenceCounting.html#arc-runtime-objc-autoreleasereturnvalue
What this patch does to fix the problem:
- The front-end adds operand bundle "clang.arc.rv" to calls, which
indicates the call is implicitly followed by a marker instruction and
an implicit retainRV/claimRV call that consumes the call result. In
addition, it emits a call to @llvm.objc.clang.arc.noop.use, which
consumes the call result, to prevent the middle-end passes from changing
the return type of the called function. This is currently done only when
the target is arm64 and the optimization level is higher than -O0.
- ARC optimizer temporarily emits retainRV/claimRV calls after the calls
with the operand bundle in the IR and removes the inserted calls after
processing the function.
- ARC contract pass emits retainRV/claimRV calls after the call with the
operand bundle. It doesn't remove the operand bundle on the call since
the backend needs it to emit the marker instruction. The retainRV and
claimRV calls are emitted late in the pipeline to prevent optimization
passes from transforming the IR in a way that makes it harder for the
ARC middle-end passes to figure out the def-use relationship between
the call and the retainRV/claimRV calls (which is the cause of
PR31925).
- The function inliner removes an autoreleaseRV call in the callee if
nothing in the callee prevents it from being paired up with the
retainRV/claimRV call in the caller. It then inserts a release call if
the call is annotated with claimRV since autoreleaseRV+claimRV is
equivalent to a release. If it cannot find an autoreleaseRV call, it
tries to transfer the operand bundle to a function call in the callee.
This is important since ARC optimizer can remove the autoreleaseRV
returning the callee result, which makes it impossible to pair it up
with the retainRV/claimRV call in the caller. If that fails, it simply
emits a retain call in the IR if the implicit call is a call to
retainRV and does nothing if it's a call to claimRV.
Future work:
- Use the operand bundle on x86-64.
- Fix the auto upgrader to convert call+retainRV/claimRV pairs into
calls annotated with the operand bundles.
rdar://71443534
Differential Revision: https://reviews.llvm.org/D92808
This reverts commit 3fe3946d9a958b7af6130241996d9cfcecf559d4.
The commit violates layering by including a header from Analysis in
lib/IR/AutoUpgrade.cpp.
emitting retainRV or claimRV calls in the IR
Background:
This patch makes changes to the front-end and middle-end that are
needed to fix a longstanding problem where llvm breaks ARC's autorelease
optimization (see the link below) by separating calls from the marker
instructions or retainRV/claimRV calls. The backend changes are in
https://reviews.llvm.org/D92569.
https://clang.llvm.org/docs/AutomaticReferenceCounting.html#arc-runtime-objc-autoreleasereturnvalue
What this patch does to fix the problem:
- The front-end adds operand bundle "clang.arc.rv" to calls, which
indicates the call is implicitly followed by a marker instruction and
an implicit retainRV/claimRV call that consumes the call result. In
addition, it emits a call to @llvm.objc.clang.arc.noop.use, which
consumes the call result, to prevent the middle-end passes from changing
the return type of the called function. This is currently done only when
the target is arm64 and the optimization level is higher than -O0.
- ARC optimizer temporarily emits retainRV/claimRV calls after the calls
with the operand bundle in the IR and removes the inserted calls after
processing the function.
- ARC contract pass emits retainRV/claimRV calls after the call with the
operand bundle. It doesn't remove the operand bundle on the call since
the backend needs it to emit the marker instruction. The retainRV and
claimRV calls are emitted late in the pipeline to prevent optimization
passes from transforming the IR in a way that makes it harder for the
ARC middle-end passes to figure out the def-use relationship between
the call and the retainRV/claimRV calls (which is the cause of
PR31925).
- The function inliner removes an autoreleaseRV call in the callee if
nothing in the callee prevents it from being paired up with the
retainRV/claimRV call in the caller. It then inserts a release call if
the call is annotated with claimRV since autoreleaseRV+claimRV is
equivalent to a release. If it cannot find an autoreleaseRV call, it
tries to transfer the operand bundle to a function call in the callee.
This is important since ARC optimizer can remove the autoreleaseRV
returning the callee result, which makes it impossible to pair it up
with the retainRV/claimRV call in the caller. If that fails, it simply
emits a retain call in the IR if the implicit call is a call to
retainRV and does nothing if it's a call to claimRV.
Future work:
- Use the operand bundle on x86-64.
- Fix the auto upgrader to convert call+retainRV/claimRV pairs into
calls annotated with the operand bundles.
rdar://71443534
Differential Revision: https://reviews.llvm.org/D92808
The test shows how "usub with overflow" opt gets or does not get applied
to increment of IV depending on its code placement, while two cases are
semantically equivalent.
It is possible to eliminate redundant calls to the SVE ptrue intrinsic.
For example: suppose that we have two SVE ptrue intrinsic calls P1 and
P2. If P1 is at least as wide as P2, then P2 can be written as a
reinterpret P1 using the SVE reinterpret intrinsics.
Coalescing ptrue intrinsics can result in fewer ptrue instructions in
the codegen, and is conducive to better analysis further down the line.
This commit extends the aarch64-sve-intrinsic-opts pass to support
coalescing ptrue intrisic calls.
Reviewed By: david-arm
Differential Revision: https://reviews.llvm.org/D94230
This patch adds support for the integer reduction intrinsics supported
by RVV. This excludes "mul" which has no corresponding instruction.
The reduction instructions in RVV have slightly complicated type
constraints given they always produce a single "M1" vector register.
They are lowered to custom nodes including the second "scalar" reduction
operand to simplify the patterns and in the hope that they can be useful
for future DAG combines.
Reviewed By: craig.topper
Differential Revision: https://reviews.llvm.org/D95620
This patch custom-legalizes all integer EXTRACT_VECTOR_ELT nodes where
SEW < XLEN to VMV_S_X nodes to help the compiler infer sign bits from
the result. This allows us to eliminate redundant sign extensions.
For parity, all integer EXTRACT_VECTOR_ELT nodes are legalized this way
so that we don't need TableGen patterns for some and not others.
Reviewed By: craig.topper
Differential Revision: https://reviews.llvm.org/D95741
This patch adds support for lowering the sqrt intrinsic to the RVV
vfsqrt instruction.
Reviewed By: craig.topper
Differential Revision: https://reviews.llvm.org/D96012
These tests demonstrate that LSR does not insert IV increment
into the latch block (as it supposes to) when it can use an
existing Phi as IV rather than creating a new LSR IV.
The vrgather.vv instruction uses a vector of indices with the same
SEW as operand 0. The vrgather.vx instructions use a scalar index
operand of XLen bits.
By splitting this into 2 intrinsics we are able to use LLVMatchType
in the definition to avoid specifying the type for the index operand
when creating the IR for the intrinsic. For .vv it will match the
operand 0 type. And for .vx it will match the type of the vl operand
we already needed to specify a type for.
I'm considering splitting more intrinsics. This was a somewhat
odd one because the .vx doesn't use the element type, it always
use XLen.
Reviewed By: HsiangKai
Differential Revision: https://reviews.llvm.org/D95979
loadRegFromStackSlot()/storeRegToStackSlot() can generate aligned access
instructions for stack slots even if the stack is unaligned, based on the
assumption that the stack can be realigned.
However, this doesn't work for fixed slots, which are e.g. used for
spilling XMM registers in a non-leaf function with
`__attribute__((preserve_all))`.
When compiling such code with `-mstack-alignment=8`, this causes general
protection faults.
Fix it by only considering stack realignment for non-fixed slots.
Note that this changes the output of three existing tests which spill AVX
registers, since AVX requires higher alignment than the ABI provides on
stack frame entry.
Reviewed By: rnk, jyknight
Differential Revision: https://reviews.llvm.org/D73126
As mentioned in TODO comment, casting double to float causes NaNs to change bits.
To avoid the change, this patch adds support for single-floating-point immediate value on MachineCode.
Patch by Yuta Saito.
Differential Revision: https://reviews.llvm.org/D77384
This improves our coverage of these operations and shows that we
use really large constants for division by constant on i8/i16
especially on RV64. The issue is that BuildSDIV/BuildUDIV are
limited to legal types so we have to promote to i64 before it
kicks in. At that point we've lost the range information for the
original type.
The upstream callers (the vectorizers) were fixed with:
bbed5f2f8a04 ( D95690 )
77adbe6a8c71
We should remove this pass entirely now that reduction
legalization/lowering is expected to work just as well,
but we need to confirm that the shuffle ops do not
regress (for x86 in particular).
This should be the last step needed to close:
https://llvm.org/PR23116
When widening, each half of the v2s16 operands needs to be sign extended
for G_ASHR or zero extended for G_LSHR.
Differential Revision: https://reviews.llvm.org/D96048
SALU min/max s32 instructions exist so use them. This means that
regbankselect can handle min/max much like add/sub/mul/shifts.
Differential Revision: https://reviews.llvm.org/D96047
In 85e8e6246e0fcc62ba727e8fb5990f1a632125d0, these tests were modified
to work with AVR, but the regex matchers were finicky and required a
fix forward patch, being this.
This patch adds 'XFAIL: avr' to 2 Generic CodeGen tests, bringing the
Generic CodeGen tests for AVR to a pass, with only two XFAILures.
After this patch, the Generic CodeGen tests pass on AVR.
If amdgpu-unsafe-fp-atomics is specified, allow {flat|global}_atomic_add_f32 even if atomic modes don't match.
Differential Revision: https://reviews.llvm.org/D95391
It was discussed a few years ago and agreed that it makes sense to
remove this assertion as other targets do not perform similar register
size checking in inline assembly constraint logic, so the check just
adds a needless barrier on AVR.
This patch removes the assertion and removes 'XFAIL' from two Generic
CodeGen tests for AVR as a result.
This new f16 shuffle under Neon would hit an assert in
GeneratePerfectShuffle as it would try to treat a f16 vector as an i8.
Add f16 handling, treating them like an i16.
Differential Revision: https://reviews.llvm.org/D95446
When SGPRs are spilled to VGPRs, they can overwrite any lane. We need
to preserve the value of inactive lanes in function calls, so we save
the register even if it is marked as caller saved.
Also, teach buildPrologSpill to work when no registers are free like in
CodeGen/AMDGPU/pei-scavenge-vgpr-spill.mir and update the comment on
findScratchNonCalleeSaveRegister as it is not used anymore to realign
the stack pointer since D95865.
Differential Revision: https://reviews.llvm.org/D95946
Similar to the G_PTR_ADD + G_LOAD twiddling we do in `preISelLower`.
The imported patterns expect scalars only, so they can't handle things like
```
G_STORE %ptr1, %ptr2
```
To get around this, use s64 instead.
(This probably makes a good portion of the manual selection code for G_STORE
dead.)
This is a 0.2% geomean code size improvement on CTMark at -Os.
(Best is consumer-typeset @ -0.7%)
Differential Revision: https://reviews.llvm.org/D95908
When we have a zeroext parameter coming in on the stack, build
```
%x = G_LOAD ...
%x_assert_zext = G_ASSERT_ZEXT %x, narrow_size
%trunc = G_TRUNC %x_assert_zext
```
Rather than just loading into the truncated type.
This allows us to optimize cases like this: https://godbolt.org/z/vfjhW8
Differential Revision: https://reviews.llvm.org/D95805
This was only adding undef to the use if the copy itself had a
subregister index. It did not consider the subrange liveness if the
use had a subreg index to begin with.
If we had a pair of copies inside a loop which introduced new liveness
to a subregister which was undef before the loop, we would have a
dummy phi-only segment remaining across the loop body. Later, this
false segment would confuse RenameIndependentSubregs causing it to
introduce IMPLICIT_DEFs with broken value numbering.
It seems always adding the lanes to ShrinkMask is OK, so any
conditions should be purely a compile time filter.
If sext_inreg is supported, we will turn this into sext_inreg. That
will then remove it if there are enough sign bits. But if sext_inreg
isn't supported, we can still remove the shift pair based on sign
bits.
Split from D95890.