Follow-up for 4ece50737d5385fb80cfa23f5297d1111f8eed39 (D142027).
Assignment Tracking Analysis now always runs and is skipped internally if
assignment tracking is disabled. Update these tests to expect to see the
pass run.
Buildbot failure: https://lab.llvm.org/buildbot/#/builders/57/builds/24094
Issue #58168 describes the difficulty diagnosing stack size issues
identified by -Wframe-larger-than. For simple code, its easy to
understand the stack layout and where space is being allocated, but in
more complex programs, where code may be heavily inlined, unrolled, and
have duplicated code paths, it is no longer easy to manually inspect the
source program and understand where stack space can be attributed.
This patch implements a machine function pass that emits remarks with a
textual representation of stack slots, and also outputs any available
debug information to map source variables to those slots.
The new behavior can be used by adding `-Rpass-analysis=stack-frame-layout`
to the compiler invocation. Like other remarks the diagnostic
information can be saved to a file in a machine readable format by
adding -fsave-optimzation-record.
Fixes: #58168
Reviewed By: nickdesaulniers, thegameg
Differential Revision: https://reviews.llvm.org/D135488
Issue #58168 describes the difficulty diagnosing stack size issues
identified by -Wframe-larger-than. For simple code, its easy to
understand the stack layout and where space is being allocated, but in
more complex programs, where code may be heavily inlined, unrolled, and
have duplicated code paths, it is no longer easy to manually inspect the
source program and understand where stack space can be attributed.
This patch implements a machine function pass that emits remarks with a
textual representation of stack slots, and also outputs any available
debug information to map source variables to those slots.
The new behavior can be used by adding `-Rpass-analysis=stack-frame-layout`
to the compiler invocation. Like other remarks the diagnostic
information can be saved to a file in a machine readable format by
adding -fsave-optimzation-record.
Fixes: #58168
Reviewed By: nickdesaulniers, thegameg
Differential Revision: https://reviews.llvm.org/D135488
This reverts commit 122efef8ee9be57055d204d52c38700fe933c033.
- Patch fixed to not reuse definitions from predecessors in EH landing pads.
- Late review suggestions (by MaskRay) have been addressed.
- M68k/pipeline.ll test updated.
- Init captures added in processBlock() to avoid capturing structured bindings.
- RISCV has this disabled for now.
Original commit message:
A new pass MachineLateInstrsCleanup is added to be run after PEI.
This is a simple pass that removes redundant and identical instructions
whenever found by scanning the MF once while keeping track of register
definitions in a map. These instructions are typically immediate loads
resulting from rematerialization, and address loads emitted by target in
eliminateFrameInde().
This is enabled by default, but a target could easily disable it by means of
'disablePass(&MachineLateInstrsCleanupID);'.
This late cleanup is naturally not "optimal" in removing instructions as it
is done by looking at phys-regs, but still quite effective. It would be
desirable to improve other parts of CodeGen and avoid these redundant
instructions in the first place, but there are no ideas for this yet.
Differential Revision: https://reviews.llvm.org/D123394
Reviewed By: RKSimon, foad, craig.topper, arsenm, asb
Currently per-function metadata consists of:
(start-pc, size, features)
This adds a new UAR feature and if it's set an additional element:
(start-pc, size, features, stack-args-size)
Reviewed By: melver
Differential Revision: https://reviews.llvm.org/D136078
Init captures added in processBlock() to avoid capturing structured bindings,
which caused the build problems (with clang).
RISCV has this disabled for now until problems relating to post RA pseudo
expansions are resolved.
A new pass MachineLateInstrsCleanup is added to be run after PEI.
This is a simple pass that removes redundant and identical instructions
whenever found by scanning the MF once while keeping track of register
definitions in a map. These instructions are typically immediate loads
resulting from rematerialization, and address loads emitted by target in
eliminateFrameInde().
This is enabled by default, but a target could easily disable it by means of
'disablePass(&MachineLateInstrsCleanupID);'.
This late cleanup is naturally not "optimal" in removing instructions as it
is done by looking at phys-regs, but still quite effective. It would be
desirable to improve other parts of CodeGen and avoid these redundant
instructions in the first place, but there are no ideas for this yet.
Differential Revision: https://reviews.llvm.org/D123394
Reviewed By: RKSimon, foad, craig.topper, arsenm, asb
As stated in
https://discourse.llvm.org/t/rfc-llc-add-expandlargeintfpconvert-pass-for-fp-int-conversion-of-large-bitint/65528,
this implementation is very similar to ExpandLargeDivRem, which expands
‘fptoui .. to’, ‘fptosi .. to’, ‘uitofp .. to’, ‘sitofp .. to’ instructions
with a bitwidth above a threshold into auto-generated functions. This is
useful for targets like x86_64 that cannot lower fp convertions with more
than 128 bits. The expanded nodes are referring from the IR generated by
`compiler-rt/lib/builtins/floattidf.c`, `compiler-rt/lib/builtins/fixdfti.c`,
and etc.
Corner cases:
1. For fp16: as there is no related builtins added in compliler-rt. So I
mainly utilized the fp32 <-> fp16 lib calls to implement.
2. For fp80: as this pass is soft fp emulation and no fp80 instructions can
help in this problem. I recommend users to deprecate this usage. For now, the
implementation uses fp128 as the temporary conversion type and inserts
fptrunc/ext at top/end of the function.
3. For bf16: as clang FE currently doesn't support bf16 algorithm operations
(convert to int, float, +, -, *, ...), this patch doesn't consider bf16 for
now.
4. For unsigned FPToI: since both default hardware behaviors and libgcc are
ignoring "returns 0 for negative input" spec. This pass follows this old way
to ignore unsigned FPToI. See this example:
https://gcc.godbolt.org/z/bnv3jqW1M
The end-to-end tests are uploaded at https://reviews.llvm.org/D138261
Reviewed By: LuoYuanke, mgehre-amd
Differential Revision: https://reviews.llvm.org/D137241
Currently per-function metadata consists of:
(start-pc, size, features)
This adds a new UAR feature and if it's set an additional element:
(start-pc, size, features, stack-args-size)
Reviewed By: melver
Differential Revision: https://reviews.llvm.org/D136078
Adds the Complex Deinterleaving Pass implementing support for complex numbers in a target-independent manner, deferring to the TargetLowering for the given target to create a target-specific intrinsic.
Differential Revision: https://reviews.llvm.org/D114174
This adds the ExpandLargeDivRem to the default pass pipeline.
The limit at which it expands div/rem instructions is configured
via a new TargetTransformInfo hook (default: no expansion)
X86, Arm and AArch64 backends implement this hook to expand div/rem
instructions with more than 128 bits.
Differential Revision: https://reviews.llvm.org/D130076
reapply 62a9b36fcf728b104ea87e6eb84c0be69b779df7 and fix module build
failue:
1: remove MachineCycleInfoWrapperPass in MachinePassRegistry.def
MachineCycleInfoWrapperPass is a anylysis pass, should not be there.
2: move the definition for MachineCycleInfoPrinterPass to cpp file.
Otherwise, there are module conflicit for MachineCycleInfoWrapperPass
in MachinePassRegistry.def and MachineCycleAnalysis.h after
62a9b36fcf728b104ea87e6eb84c0be69b779df7.
MachineCycle can handle irreducible loop. Natural loop
analysis (MachineLoop) can not return correct loop depth if
the loop is irreducible loop. And MachineSink is sensitive
to the loop depth, see MachineSinking::isProfitableToSinkTo().
This patch tries to use MachineCycle so that we can handle
irreducible loop better.
Reviewed By: sameerds, MatzeB
Differential Revision: https://reviews.llvm.org/D123995
MachineCycle can handle irreducible loop. Natural loop
analysis (MachineLoop) can not return correct loop depth if
the loop is irreducible loop. And MachineSink is sensitive
to the loop depth, see MachineSinking::isProfitableToSinkTo().
This patch tries to use MachineCycle so that we can handle
irreducible loop better.
Reviewed By: sameerds, MatzeB
Differential Revision: https://reviews.llvm.org/D123995
This adds a late Machine Pass to work around a Cortex CPU Erratum
affecting Cortex-A57 and Cortex-A72:
- Cortex-A57 Erratum 1742098
- Cortex-A72 Erratum 1655431
The pass inserts instructions to make the inputs to the fused AES
instruction pairs no longer trigger the erratum. Here the pass errs on
the side of caution, inserting the instructions wherever we cannot prove
that the inputs came from a safe instruction.
The pass is used:
- for Cortex-A57 and Cortex-A72,
- for "generic" cores (which are used when using `-march=`),
- when the user specifies `-mfix-cortex-a57-aes-1742098` or
`mfix-cortex-a72-aes-1655431` in the command-line arguments to clang.
Reviewed By: dmgreen, simon_tatham
Differential Revision: https://reviews.llvm.org/D119720
Fixed "private field is not used" warning when compiled
with clang.
original commit: 28d09bbbc3d09c912b54a4d5edb32cab7de32a6f
reverted in: fa49021c68ef7a7adcdf7b8a44b9006506523191
------
This patch permits Swing Modulo Scheduling for ARM targets
turns it on by default for the Cortex-M7. The t2Bcc
instruction is recognized as a loop-ending branch.
MachinePipeliner is extended by adding support for
"unpipelineable" instructions. These instructions are
those which contribute to the loop exit test; in the SMS
papers they are removed before creating the dependence graph
and then inserted into the final schedule of the kernel and
prologues. Support for these instructions was not previously
necessary because current targets supporting SMS have only
supported it for hardware loop branches, which have no
loop-exit-contributing instructions in the loop body.
The current structure of the MachinePipeliner makes it difficult
to remove/exclude these instructions from the dependence graph.
Therefore, this patch leaves them in the graph, but adds a
"normalization" method which moves them in the schedule to
stage 0, which causes them to appear properly in kernel and
prologues.
It was also necessary to be more careful about boundary nodes
when iterating across successors in the dependence graph because
the loop exit branch is now a non-artificial successor to
instructions in the graph. In additional, schedules with physical
use/def pairs in the same cycle should be treated as creating an
invalid schedule because the scheduling logic doesn't respect
physical register dependence once scheduled to the same cycle.
Reviewed By: dmgreen
Differential Revision: https://reviews.llvm.org/D122672
This patch permits Swing Modulo Scheduling for ARM targets
turns it on by default for the Cortex-M7. The t2Bcc
instruction is recognized as a loop-ending branch.
MachinePipeliner is extended by adding support for
"unpipelineable" instructions. These instructions are
those which contribute to the loop exit test; in the SMS
papers they are removed before creating the dependence graph
and then inserted into the final schedule of the kernel and
prologues. Support for these instructions was not previously
necessary because current targets supporting SMS have only
supported it for hardware loop branches, which have no
loop-exit-contributing instructions in the loop body.
The current structure of the MachinePipeliner makes it difficult
to remove/exclude these instructions from the dependence graph.
Therefore, this patch leaves them in the graph, but adds a
"normalization" method which moves them in the schedule to
stage 0, which causes them to appear properly in kernel and
prologues.
It was also necessary to be more careful about boundary nodes
when iterating across successors in the dependence graph because
the loop exit branch is now a non-artificial successor to
instructions in the graph. In additional, schedules with physical
use/def pairs in the same cycle should be treated as creating an
invalid schedule because the scheduling logic doesn't respect
physical register dependence once scheduled to the same cycle.
Reviewed By: dmgreen
Differential Revision: https://reviews.llvm.org/D122672
The bulk of the implementation is common between 'release' mode (==AOT-ed
model) and 'development' mode (for training), the main difference is
that in development mode, we may also log features (for training logs),
inject scoring information (currently after the Virtual Register
Rewriter) and then produce the log file.
This patch also introduces the score injection pass, 'Register
Allocation Pass Scoring', which is trivially just logging the score in
development mode.
Differential Revision: https://reviews.llvm.org/D117147
This patch implements a new MachineFunction in the ARM backend for
placing BTI instructions. It is similar to the existing AArch64
aarch64-branch-targets pass.
BTI instructions are inserted into basic blocks that:
- Have their address taken
- Are the entry block of a function, if the function has external
linkage or has its address taken
- Are mentioned in jump tables
- Are exception/cleanup landing pads
Each BTI instructions is placed in the beginning of a BB after the
so-called meta instructions (e.g. exception handler labels).
Each outlining candidate and the outlined function need to be in agreement about
whether BTI placement is enabled or not. If branch target enforcement is
disabled for a function, the outliner should not covertly enable it by emitting
a call to an outlined function, which begins with BTI.
The cost mode of the outliner is adjusted to account for the extra BTI
instructions in the outlined function.
The ARM Constant Islands pass will maintain the count of the jump tables, which
reference a block. A `BTI` instruction is removed from a block only if the
reference count reaches zero.
PAC instructions in entry blocks are replaced with PACBTI instructions (tests
for this case will be added in a later patch because the compiler currently does
not generate PAC instructions).
The ARM Constant Island pass is adjusted to handle BTI
instructions correctly.
Functions with static linkage that don't have their address taken can
still be called indirectly by linker-generated veneers and thus their
entry points need be marked with BTI or PACBTI.
The changes are tested using "LLVM IR -> assembly" tests, jump tables
also have a MIR test. Unfortunately it is not possible add MIR tests
for exception handling and computed gotos because of MIR parser
limitations.
This patch is part of a series that adds support for the PACBTI-M extension of
the Armv8.1-M architecture, as detailed here:
https://community.arm.com/arm-community-blogs/b/architectures-and-processors-blog/posts/armv8-1-m-pointer-authentication-and-branch-target-identification-extension
The PACBTI-M specification can be found in the Armv8-M Architecture Reference
Manual:
https://developer.arm.com/documentation/ddi0553/latest
The following people contributed to this patch:
- Mikhail Maltsev
- Momchil Velikov
- Ties Stuij
Reviewed By: ostannard
Differential Revision: https://reviews.llvm.org/D112426
Currently when tail predicating loops, vpt blocks need to be created
with the vctp predicate in case we need to revert to non-tail predicated
form. This has the unfortunate side effect of severely hampering post-ra
scheduling at times as the instructions are already stuck in vpt blocks,
not allowed to be independently ordered.
This patch addresses that by just moving the creation of VPT blocks
later in the pipeline, after post-ra scheduling has been performed. This
allows more optimal scheduling post-ra before the vpt blocks are
created, leading to more optimal tail predicated loops.
Differential Revision: https://reviews.llvm.org/D113094
Neither of these passes modify the CFG, allowing us to preserve DomTree
and LoopInfo across them by using setPreservesCFG.
Differential Revision: https://reviews.llvm.org/D110161
This new MIR pass removes redundant DBG_VALUEs.
After the register allocator is done, more precisely, after
the Virtual Register Rewriter, we end up having duplicated
DBG_VALUEs, since some virtual registers are being rewritten
into the same physical register as some of existing DBG_VALUEs.
Each DBG_VALUE should indicate (at least before the LiveDebugValues)
variables assignment, but it is being clobbered for function
parameters during the SelectionDAG since it generates new DBG_VALUEs
after COPY instructions, even though the parameter has no assignment.
For example, if we had a DBG_VALUE $regX as an entry debug value
representing the parameter, and a COPY and after the COPY,
DBG_VALUE $virt_reg, and after the virtregrewrite the $virt_reg gets
rewritten into $regX, we'd end up having redundant DBG_VALUE.
This breaks the definition of the DBG_VALUE since some analysis passes
might be built on top of that premise..., and this patch tries to fix
the MIR with the respect to that.
This first patch performs bacward scan, by trying to detect a sequence of
consecutive DBG_VALUEs, and to remove all DBG_VALUEs describing one
variable but the last one:
For example:
(1) DBG_VALUE $edi, !"var1", ...
(2) DBG_VALUE $esi, !"var2", ...
(3) DBG_VALUE $edi, !"var1", ...
...
in this case, we can remove (1).
By combining the forward scan that will be introduced in the next patch
(from this stack), by inspecting the statistics, the RemoveRedundantDebugValues
removes 15032 instructions by using gdb-7.11 as a testbed.
Differential Revision: https://reviews.llvm.org/D105279
It breaks up the function pass manager in the codegen pipeline.
With empty parameters, it looks at the -mllvm flag -rewrite-map-file.
This is likely not in use.
Add a check that we only have one function pass manager in the codegen
pipeline.
Some tests relied on the fact that we had a module pass somewhere in the
codegen pipeline.
addr-label.ll crashes on ARM due to this change. This is because a
ARMConstantPoolConstant containing a BasicBlock to represent a
blockaddress may hold an invalid pointer to a BasicBlock if the
blockaddress is invalidated by its BasicBlock getting removed. In that
case all referencing blockaddresses are RAUW a constant int. Making
ARMConstantPoolConstant::CVal a WeakVH fixes the crash, but I'm not sure
that's the right fix. As a workaround, create a barrier right before
ISel so that IR optimizations can't happen while a
ARMConstantPoolConstant has been created.
Reviewed By: rnk, MaskRay, compnerd
Differential Revision: https://reviews.llvm.org/D99707
This reverts the revert 02c5ba8679873e878ae7a76fb26808a47940275b
Fix:
Pass was registered as DUMMY_FUNCTION_PASS causing the newpm-pass
functions to be doubly defined. Triggered in -DLLVM_ENABLE_MODULE=1
builds.
Original commit:
This patch implements expansion of llvm.vp.* intrinsics
(https://llvm.org/docs/LangRef.html#vector-predication-intrinsics).
VP expansion is required for targets that do not implement VP code
generation. Since expansion is controllable with TTI, targets can switch
on the VP intrinsics they do support in their backend offering a smooth
transition strategy for VP code generation (VE, RISC-V V, ARM SVE,
AVX512, ..).
Reviewed By: rogfer01
Differential Revision: https://reviews.llvm.org/D78203
This patch implements expansion of llvm.vp.* intrinsics
(https://llvm.org/docs/LangRef.html#vector-predication-intrinsics).
VP expansion is required for targets that do not implement VP code
generation. Since expansion is controllable with TTI, targets can switch
on the VP intrinsics they do support in their backend offering a smooth
transition strategy for VP code generation (VE, RISC-V V, ARM SVE,
AVX512, ..).
Reviewed By: rogfer01
Differential Revision: https://reviews.llvm.org/D78203
It breaks up the function pass manager in the codegen pipeline.
With empty parameters, it looks at the -mllvm flag -rewrite-map-file.
This is likely not in use.
Add a check that we only have one function pass manager in the codegen
pipeline.
This required reverting commit 9583a3f2625818b78c0cf6d473cdedb9f23ad82c:
"[AsmPrinter] Delete dead takeDeletedSymbsForFunction()".
This was not NFC as initially thought. By coalescing two function
psas managers, this exposed the reverted code as necessary.
addr-label.ll was crashing due to an emitted blockaddress's block being
removed but the label not emitted.
Some tests relied on the fact that we had a module pass somewhere in the
codegen pipeline.
Reviewed By: rnk
Differential Revision: https://reviews.llvm.org/D99707
MVE does not have a single sext/zext or trunc instruction that takes the
bottom half of a vector and extends to a full width, like NEON has with
MOVL. Instead it is expected that this happens through top/bottom
instructions. So the MVE equivalent VMOVLT/B instructions take either
the even or odd elements of the input and extend them to the larger
type, producing a vector with half the number of elements each of double
the bitwidth. As there is no simple instruction for a normal extend, we
often have to expand sext/zext/trunc into a series of lane moves (or
stack loads/stores, which we do not do yet).
This pass takes vector code that starts at truncs, looks for
interconnected blobs of operations that end with sext/zext and
transforms them by adding shuffles so that the lanes are interleaved and
the MVE VMOVL/VMOVN instructions can be used. This is done pre-ISel so
that it can work across basic blocks.
This initial version of the pass just handles a limited set of
instructions, not handling constants or splats or FP, which can all come
as extensions to this base.
Differential Revision: https://reviews.llvm.org/D95804
This seems to be more of a Clang thing rather than a generic LLVM thing,
so this moves it out of LLVM pipelines and as Clang extension hooks into
LLVM pipelines.
Move the post-inline EEInstrumentation out of the backend pipeline and
into a late pass, similar to other sanitizer passes. It doesn't fit
into the codegen pipeline.
Also fix up EntryExitInstrumentation not running at -O0 under the new
PM. PR49143
Reviewed By: hans
Differential Revision: https://reviews.llvm.org/D97608
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.
This is a re-try of the original commit 2303e93e66 that was reverted
due to pass manager problems. Other minor changes have also been made.
Differential Revision: https://reviews.llvm.org/D95373
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
This de-pessimizes the arguably more usual case of no masked mem intrinsics,
and gets rid of one more Dominator Tree recalculation.
As per llvm/test/CodeGen/X86/opt-pipeline.ll,
there's one more Dominator Tree recalculation left, we could get rid of.
While this is mostly NFC right now, because only ARM happens
to run this pass with DomTree available before it,
and required after it, more backends will be affected once
the SimplifyCFG's switch for domtree preservation is flipped,
and DwarfEHPrepare also preserves the domtree.
Blocks can be laid out such that a t2WhileLoopStart branches backwards. This is forbidden by the architecture and so it fails to be converted into a low-overhead loop. This new pass checks for these cases and moves the target block, fixing any fall-through that would then be broken.
Differential Revision: https://reviews.llvm.org/D92385
