At the moment, the emergency spill slot is a fixed object for entry
functions and chain functions, and a regular stack object otherwise.
This patch adopts the latter behaviour for entry/chain functions too. It
seems this was always the intention [1] and it will also save us a bit
of stack space in cases where the first stack object has a large
alignment.
[1]
34c8b835b1
Similar to 806761a7629df268c8aed49657aeccffa6bca449.
For IR files without a target triple, -mtriple= specifies the full
target triple while -march= merely sets the architecture part of the
default target triple, leaving a target triple which may not make sense,
e.g. amdgpu-apple-darwin.
Therefore, -march= is error-prone and not recommended for tests without
a target triple. The issue has been benign as we recognize
$unknown-apple-darwin as ELF instead of rejecting it outrightly.
This patch changes AMDGPU tests to not rely on the default
OS/environment components. Tests that need fixes are not changed:
```
LLVM :: CodeGen/AMDGPU/fabs.f64.ll
LLVM :: CodeGen/AMDGPU/fabs.ll
LLVM :: CodeGen/AMDGPU/floor.ll
LLVM :: CodeGen/AMDGPU/fneg-fabs.f64.ll
LLVM :: CodeGen/AMDGPU/fneg-fabs.ll
LLVM :: CodeGen/AMDGPU/r600-infinite-loop-bug-while-reorganizing-vector.ll
LLVM :: CodeGen/AMDGPU/schedule-if-2.ll
```
PR #66334 tried to renumber slot indexes before register allocation, but
the numbering was still affected by list entries for instructions which
had been erased. Fix this to make the register allocator's live range
length heuristics even less dependent on the history of how instructions
have been added to and removed from SlotIndexes's maps.
SIInsertWaitcnts inserts waitcnt instructions to resolve data
dependencies. The GFX10+ vscnt (VMEM store count) counter is never used
in this way. It is only used to resolve memory dependencies, and that is
handled by SIMemoryLegalizer. Hence there is no need to conservatively
wait for vscnt to be 0 on function entry and before returns.
Differential Revision: https://reviews.llvm.org/D153537
1. Remove the existing code that would encode the constant offsets (if
there were any) on buffer intrinsic operations onto their
`MachineMemOperand`s. As far as I can tell, this use of `offset` has
no substantial impact on the generated code, especially since the same
reasoning is performed by areMemAccessesTriviallyDisjoint().
2. When a buffer resource intrinsic takes a pointer argument as the
base resource/descriptor, place that memory argument in the value
field of the MachineMemOperand attached to that intrinsic.
This is more conservative than what would be produced by more typical
LLVM code using GEP, as the Value (for alias analysis purposes)
corresponding to accessing buffer[0] and buffer[1] is the same.
However, the target-specific analysis of disjoint offsets covers a lot
of the simple usecases.
Despite this limitation, the new buffer intrinsics, combined with
LLVM's existing pointer annotations, allow for non-trivial
optimizations, as seen in the new tests, where marking two buffer
descriptors "noalias" allows merging together loads and stores in a
"load from A, modify loaded value, store to B" sequence, which would
not be possible previously.
Depends on D147547
Reviewed By: arsenm
Differential Revision: https://reviews.llvm.org/D148184
In order to enable the LLVM frontend to better analyze buffer
operations (and to potentially enable more precise analyses on the
backend), define versions of the raw and structured buffer intrinsics
that use `ptr addrspace(8)` instead of `<4 x i32>` to represent their
rsrc arguments.
The new intrinsics are named by replacing `buffer.` with `buffer.ptr`.
One advantage to these intrinsic definitions is that, instead of
specifying that a buffer load/store will read/write some memory, we
can indicate that the memory read or written will be based on the
pointer argument. This means that, for example, a read from a
`noalias` buffer can be pulled out of a loop that is modifying a
distinct buffer.
In the future, we will define custom PseudoSourceValues that will
allow us to package up the (buffer, index, offset) triples that buffer
intrinsics contain and allow for more precise backend analysis.
This work also enables creating address space 7, which represents
manipulation of raw buffers using native LLVM load and store
instructions.
Where tests simply used a buffer intrinsic while testing some other
code path (such as the tests for VGPR spills), they have been updated
to use the new intrinsic form. Tests that are "about" buffer
intrinsics (for instance, those that ensure that they codegen as
expected) have been duplicated, either within existing files or into
new ones.
Depends on D145441
Reviewed By: arsenm, #amdgpu
Differential Revision: https://reviews.llvm.org/D147547
In some cases, breaking large PHIs can very negatively affect
performance (3x more instructions observed in a particular test case).
This patch adds some basic profitability heuristics to help with some of these issues without affecting the "good" cases.
e.g. avoid breaking PHIs if it causes back-and-forth between vector/scalar form for no good reason.
Fixes SWDEV-392803
Fixes SWDEV-393781
Fixes SWDEV-394228
Reviewed By: arsenm
Differential Revision: https://reviews.llvm.org/D147786
DAGISel uses CopyToReg/CopyFromReg to lower PHI nodes. With large PHIs, this can result in poor codegen.
This is because it introduces a need to have a build_vector before copying the PHI value, and that build_vector may have many undef elements. This can cause very high register pressure and abnormal stack usage in some cases.
This scalarization/phi "break-up" can be easily tuned/disabled through CL options in case it's not beneficial for some users.
It's also only enabled for DAGIsel and GlobalISel handles PHIs much better (as it works on the whole function).
This can both scalarize (break a vector into its elements) and simplify (break a vector into smaller, more manageable subvectors) PHIs.
Fixes SWDEV-321581
Reviewed By: kzhuravl
Differential Revision: https://reviews.llvm.org/D143731
Create new VALU instructions in moveToVALU instead of mutating the
existing SALU instruction. This makes it easier to add extra operands so
we can convert to the VOP3 form of VALU instructions.
NFCI but it does have the minor side effect of removing duplicate
implicit operands that were present on the original SALU if they are
default implicit operands for the VALU.
Differential Revision: https://reviews.llvm.org/D137324
Strict WQM does not require a WQM transistion if it occurs within
an existing WQM section.
This occurs heavily in GFX11 pixel shaders with LDS_PARAM_LOAD.
Which leads to unnecessary EXEC mask manipulation.
To avoid these transitions, detect WQM -> Strict WQM -> WQM
and substitute new ENTER_PSEUDO_WM/EXIT_PSEUDO_WM markers instead.
These are treat similarly by WWM register pre-allocation pass,
but do not manipulate EXEC or use registers to save EXEC state.
Reviewed By: piotr
Differential Revision: https://reviews.llvm.org/D136813
Surprisingly these were getting legalized to something
zero initialized.
This fixes an infinite loop when combining some vector types.
Also fixes zero initializing some undef values.
SimplifyDemandedVectorElts / SimplifyDemandedBits are not checking
for the legality of the output undefs they are replacing unused
operations with. This resulted in turning vectors into undefs
that were later re-legalized back into zero vectors.
Edit the IR input for some codegen tests to simulate what the IR code
sinking pass would do to it. This makes the tests immune to the presence
or absence of the code sinking pass in the codegen pass pipeline, which
does not belong there.
Differential Revision: https://reviews.llvm.org/D130169
This patch merges a consecutive sequence of
s_or_saveexec s_o, s_i
s_xor exec, exec, s_o
into a single
s_andn2_saveexec s_o, s_i instruction.
This patch also cleans up the SIOptimizeExecMasking pass a bit.
Reviewed By: nhaehnle
Differential Revision: https://reviews.llvm.org/D129073
On GFX10.3 targets, the following instruction sequence
v_cmp_* SGPR, ...
s_and_saveexec ..., SGPR
leads to a fairly long stall caused by a VALU write to a SGPR and having the
following SALU wait for the SGPR.
An equivalent sequence is to save the exec mask manually instead of letting
s_and_saveexec do the work and use a v_cmpx instruction instead to do the
comparison.
This patch modifies the SIOptimizeExecMasking pass as this is the last position
where s_and_saveexec instructions are inserted. It does the transformation by
trying to find the pattern, extracting the operands and generating the new
instruction sequence.
It also changes some existing lit tests and introduces a few new tests to show
the changed behavior on GFX10.3 targets.
Same as D119696 including a buildbot and MIR test fix.
Reviewed By: critson
Differential Revision: https://reviews.llvm.org/D122332
This reverts commit 011c64191ef9ccc6538d52f4b57f98f37d4ea36e and
e725e2afe02e18398525652c9bceda1eb055ea64.
Differential Revision: https://reviews.llvm.org/D122117
On GFX10.3 targets, the following instruction sequence
v_cmp_* SGPR, ...
s_and_saveexec ..., SGPR
leads to a fairly long stall caused by a VALU write to a SGPR and having the
following SALU wait for the SGPR.
An equivalent sequence is to save the exec mask manually instead of letting
s_and_saveexec do the work and use a v_cmpx instruction instead to do the
comparison.
This patch modifies the SIOptimizeExecMasking pass as this is the last position
where s_and_saveexec instructions are inserted. It does the transformation by
trying to find the pattern, extracting the operands and generating the new
instruction sequence.
It also changes some existing lit tests and introduces a few new tests to show
the changed behavior on GFX10.3 targets.
Reviewed By: sebastian-ne, critson
Differential Revision: https://reviews.llvm.org/D119696
Extend pre-emit peephole for S_CBRANCH_VCC[N]Z to eliminate
redundant S_AND operations against EXEC for V_CMP results in VCC.
These occur after after register allocation when VCC has been
selected as the comparison destination.
Reviewed By: rampitec
Differential Revision: https://reviews.llvm.org/D120202
The WWM register has unmodeled register liveness, For v_set_inactive_*,
clobberring source register is dangerous because it will overwrite the
inactive lanes. When the source vgpr is dead at v_set_inactive_lane,
the inactive lanes may be not really dead. This may make common
optimizations doing wrong.
For example in a simple if-then cfg in Machine IR:
bb.if:
%src =
bb.then:
%src1 = COPY %src
%dst = V_SET_INACTIVE %src1(tied-def 0), %inactive
bb.end
... = PHI [0, %bb.then] [%src, %bb.if]
The register coalescer will think it is safe to optimize "%src1 = COPY %src"
in bb.then. And at the same time, there is no interference for the PHI in
bb.end. The source and destination values of the PHI will be assigned
the same register. The single PHI register will be overwritten by the
v_set_inactive, then we would get wrong value in bb.end.
With this change, we will copy the content of the source register before
setting inactive lanes after register allocation. Yes, this will sacrifice
the WWM code generation a little, but I don't have any better idea to do things
correctly.
Differential Revision: https://reviews.llvm.org/D117482
Switch wqm.ll to be autogenerated.
Replace gfx6 and gfx8 targets with gfx9 (wave64) and gfx10 (wave32).
Reviewed By: kmitropoulou
Differential Revision: https://reviews.llvm.org/D117455
The compiler was generating symbols in the final code object for local
branch target labels. This bloats the code object, slows down the loader,
and is only used to simplify disassembly.
Use '--symbolize-operands' with llvm-objdump to improve readability of the
branch target operands in disassembly.
Fixes: SWDEV-312223
Reviewed By: scott.linder
Differential Revision: https://reviews.llvm.org/D114273
When tracking defined lanes through phi nodes in the live range
graph each branch of the phi must be handled independently.
Also rewrite the marking algorithm to reduce unnecessary
operations.
Previously a shared set of defined lanes was used which caused
marking to stop prematurely. This was observable in existing lit
tests, but test patterns did not cover this detail.
Reviewed By: piotr
Differential Revision: https://reviews.llvm.org/D98614
* Add amdgcn_strict_wqm intrinsic.
* Add a corresponding STRICT_WQM machine instruction.
* The semantic is similar to amdgcn_strict_wwm with a notable difference that not all threads will be forcibly enabled during the computations of the intrinsic's argument, but only all threads in quads that have at least one thread active.
* The difference between amdgc_wqm and amdgcn_strict_wqm, is that in the strict mode an inactive lane will always be enabled irrespective of control flow decisions.
Reviewed By: critson
Differential Revision: https://reviews.llvm.org/D96258
* Introduce the new intrinsic amdgcn_strict_wwm
* Deprecate the old intrinsic amdgcn_wwm
The change is done for consistency as the "strict"
prefix will become an important, distinguishing factor
between amdgcn_wqm and amdgcn_strictwqm in the future.
The "strict" prefix indicates that inactive lanes do not
take part in control flow, specifically an inactive lane
enabled by a strict mode will always be enabled irrespective
of control flow decisions.
The amdgcn_wwm will be removed, but doing so in two steps
gives users time to switch to the new name at their own pace.
Reviewed By: critson
Differential Revision: https://reviews.llvm.org/D96257
Move implementation of kill intrinsics to WQM pass. Add live lane
tracking by updating a stored exec mask when lanes are killed.
Use live lane tracking to enable early termination of shader
at any point in control flow.
Reviewed By: piotr
Differential Revision: https://reviews.llvm.org/D94746
Exec mask manipulation inserted by SIWholeQuadMode barriers to
instruction scheduling. Move the entire pass after the machine
instruction scheduler and make changes so pass is correct for
non-SSA operation. These changes should leave the pass still
usable pre-scheduler, although tests have be updated to reflect
post-scheduler results.
Reviewed By: nhaehnle
Differential Revision: https://reviews.llvm.org/D88081
This reverts commit c3492a1aa1b98c8d81b0969d52cea7681f0624c2.
I think this is the wrong strategy and wrong place to do this
transform anyway. Also reverts follow up commit
7d593d0d6905b55ca1124fca5e4d1ebb17203138.
- Need to lower COPY from SGPR to VGPR to a real instruction as the
standard COPY is used where the source and destination are from the
same register bank so that we potentially coalesc them together and
save one COPY. Considering that, backend optimizations, such as CSE,
won't handle them. However, the copy from SGPR to VGPR always needs
materializing to a native instruction, it should be lowered into a
real one before other backend optimizations.
Differential Revision: https://reviews.llvm.org/D87556
Add handling of s_andn2 and mask of 0.
This eliminates redundant instructions from uniform control flow.
Reviewed By: rampitec
Differential Revision: https://reviews.llvm.org/D83641
Add the scratch wave offset to the scratch buffer descriptor (SRSrc) in
the entry function prologue. This allows us to removes the scratch wave
offset register from the calling convention ABI.
As part of this change, allow the use of an inline constant zero for the
SOffset of MUBUF instructions accessing the stack in entry functions
when a frame pointer is not requested/required. Entry functions with
calls still need to set up the calling convention ABI stack pointer
register, and reference it in order to address arguments of called
functions. The ABI stack pointer register remains unswizzled, but is now
wave-relative instead of queue-relative.
Non-entry functions also use an inline constant zero SOffset for
wave-relative scratch access, but continue to use the stack and frame
pointers as before. When the stack or frame pointer is converted to a
swizzled offset it is now scaled directly, as the scratch wave offset no
longer needs to be subtracted first.
Update llvm/docs/AMDGPUUsage.rst to reflect these changes to the calling
convention.
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D75138
The current implementation of skip insertion (SIInsertSkip) makes it a
mandatory pass required for correctness. Initially, the idea was to
have an optional pass. This patch inserts the s_cbranch_execz upfront
during SILowerControlFlow to skip over the sections of code when no
lanes are active. Later, SIRemoveShortExecBranches removes the skips
for short branches, unless there is a sideeffect and the skip branch is
really necessary.
This new pass will replace the handling of skip insertion in the
existing SIInsertSkip Pass.
Differential revision: https://reviews.llvm.org/D68092
The current implementation of skip insertion (SIInsertSkip) makes it a
mandatory pass required for correctness. Initially, the idea was to
have an optional pass. This patch inserts the s_cbranch_execz upfront
during SILowerControlFlow to skip over the sections of code when no
lanes are active. Later, SIRemoveShortExecBranches removes the skips
for short branches, unless there is a sideeffect and the skip branch is
really necessary.
This new pass will replace the handling of skip insertion in the
existing SIInsertSkip Pass.
Differential revision: https://reviews.llvm.org/D68092
Summary:
- SI Whole Quad Mode phase is replacing WQM pseudo instructions with v_mov instructions.
While this is necessary for the special handling of moving results out of WWM live ranges,
it is not necessary for WQM live ranges. The result is a v_mov from a register to itself after every
WQM operation. This change uses a COPY psuedo in these cases, which allows the register
allocator to coalesce the moves away.
Reviewers: tpr, dstuttard, foad, nhaehnle
Reviewed By: nhaehnle
Subscribers: arsenm, kzhuravl, jvesely, wdng, nhaehnle, yaxunl, dstuttard, tpr, t-tye, hiraditya, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D71386
This reverts r369664 (git commit 51f48295cbe8fa3a44db263b528dd9f7bae7bf9a)
It causes many benchmark regressions, internally and in llvm's benchmark suite.
llvm-svn: 370398
Patch https://reviews.llvm.org/D43256 introduced more aggressive loop layout optimization which depends on profile information. If profile information is not available, the statically estimated profile information(generated by BranchProbabilityInfo.cpp) is used. If user program doesn't behave as BranchProbabilityInfo.cpp expected, the layout may be worse.
To be conservative this patch restores the original layout algorithm in plain mode. But user can still try the aggressive layout optimization with -force-precise-rotation-cost=true.
Differential Revision: https://reviews.llvm.org/D65673
llvm-svn: 369664
It caused assertions to fire when building Chromium:
lib/CodeGen/LiveDebugValues.cpp:331: bool
{anonymous}::LiveDebugValues::OpenRangesSet::empty() const: Assertion
`Vars.empty() == VarLocs.empty() && "open ranges are inconsistent"' failed.
See https://crbug.com/992871#c3 for how to reproduce.
> Patch https://reviews.llvm.org/D43256 introduced more aggressive loop layout optimization which depends on profile information. If profile information is not available, the statically estimated profile information(generated by BranchProbabilityInfo.cpp) is used. If user program doesn't behave as BranchProbabilityInfo.cpp expected, the layout may be worse.
>
> To be conservative this patch restores the original layout algorithm in plain mode. But user can still try the aggressive layout optimization with -force-precise-rotation-cost=true.
>
> Differential Revision: https://reviews.llvm.org/D65673
llvm-svn: 368579
Patch https://reviews.llvm.org/D43256 introduced more aggressive loop layout optimization which depends on profile information. If profile information is not available, the statically estimated profile information(generated by BranchProbabilityInfo.cpp) is used. If user program doesn't behave as BranchProbabilityInfo.cpp expected, the layout may be worse.
To be conservative this patch restores the original layout algorithm in plain mode. But user can still try the aggressive layout optimization with -force-precise-rotation-cost=true.
Differential Revision: https://reviews.llvm.org/D65673
llvm-svn: 368339
Current findBestLoopTop can find and move one kind of block to top, a latch block has one successor. Another common case is:
* a latch block
* it has two successors, one is loop header, another is exit
* it has more than one predecessors
If it is below one of its predecessors P, only P can fall through to it, all other predecessors need a jump to it, and another conditional jump to loop header. If it is moved before loop header, all its predecessors jump to it, then fall through to loop header. So all its predecessors except P can reduce one taken branch.
Differential Revision: https://reviews.llvm.org/D43256
llvm-svn: 363471
