This tries to add some costs for the shuffle in a ST3/ST4 instruction,
which are represented in LLVM IR as store(interleaving shuffle). In
order to detect the store, it needs to add a CxtI context instruction to
check the users of the shuffle. LD3 and LD4 are added, LD2 should be a
zip1 shuffle, which will be added in another patch.
It should help fix some of the regressions from #87510.
extract subvector.
Many targets do not have cost for extractsubvector shuffle kind, but
have the costs for single source permute. If there are no costs
estimation for extractsubvector, better to switchto single source
permute for better cost estimation.
Reviewers: RKSimon, davemgreen, arsenm
Reviewed By: RKSimon
Pull Request: https://github.com/llvm/llvm-project/pull/79837
This patch replaces uses of StringRef::{starts,ends}with with
StringRef::{starts,ends}_with for consistency with
std::{string,string_view}::{starts,ends}_with in C++20.
I'm planning to deprecate and eventually remove
StringRef::{starts,ends}with.
I think this is right, that the undef bits should be the undef bits from
the passthrough (operand 0), with the top/bottom lanes cleared, as they
come from the second arg (operand 1). We don't yet attempt to look for
undef elements in the second operand, but this should fix the bug with
all elements being marked as undef and the instruction being optimized
away.
For MVE tail predicated loops, better code can be generated by keeping
the loop whole than to unroll to an upper bound, which requires the
expansion of active lane masks that can be difficult to generate good
code for. This patch disables UpperBound unrolling when we find a
active_lane_mask in the loop.
This adds some basic and/or/xor reduction costs for NEON/MVE, handling them
like other reductions where vector operations are used to reduce to legal
sizes, followed by an optional VREV+VAND/VORR/VEOR step and scalarization from
there.
This adds some basic smin/smax/umin/umax reduction costs for MVE/NEON, similar
to the existing Add reduction costs. They follow the same style as Add
reductions, but include a higher cost as the costs tend to be dependant on the
element size for vminv/vmaxv. These costs may not be precise, but will be more
inline than the default that extracts each element.
Similar to the other reductions, this changes the cost of fmin/fmax reductions
under MVE/NEON to perform vector operations until the types need to be
scalarized. The fp16 vectors can perform a VREV+FMIN/FMAX to skip a step of the
reduction, and otherwise need lanewise extract fro the top lanes.
This adds some basic fadd/fmul reduction costs for MVE/NEON. It reduces by
halving the vector size until it it gets scalarized, with some additional costs
for fp16 which may require extracting the top lanes.
Differential Revision: https://reviews.llvm.org/D159367
D141386 changed the semantics of !range metadata to return poison
on violation. If !range is combined with !noundef, violation is
immediate UB instead, matching the old semantics.
In theory, these IR semantics should also carry over into SDAG.
In practice, DAGCombine has at least one key transform that is
invalid in the presence of poison, namely the conversion of logical
and/or to bitwise and/or (c7b537bf09/llvm/lib/CodeGen/SelectionDAG/DAGCombiner.cpp (L11252)).
Ideally, we would fix this transform, but this will require
substantial work to avoid codegen regressions.
In the meantime, avoid transferring !range metadata without
!noundef, effectively restoring the old !range metadata semantics
on the SDAG layer.
Fixes https://github.com/llvm/llvm-project/issues/64589.
Differential Revision: https://reviews.llvm.org/D157685
SubtargetFeature.h is currently part of MC while it doesn't depend on
anything in MC. Since some LLVM components might have the need to work
with target features without necessarily needing MC, it might be
worthwhile to move SubtargetFeature.h to a different location. This will
reduce the dependencies of said components.
Note that I choose TargetParser as the destination because that's where
Triple lives and SubtargetFeatures feels related to that.
This issues came up during a JITLink review (D149522). JITLink would
like to avoid a dependency on MC while still needing to store target
features.
Reviewed By: MaskRay, arsenm
Differential Revision: https://reviews.llvm.org/D150549
This is rework of;
- rG13e77db2df94 (r328395; MVT)
Since `LowLevelType.h` has been restored to `CodeGen`, `MachinveValueType.h`
can be restored as well.
Depends on D148767
Differential Revision: https://reviews.llvm.org/D149024
If a gather/scatter is masked and will need to be scalarized then the cost
should be higher than we currently produce. An additional cost for scalarizing
the mask, extracting i1s and branching on the result needs to be added, which
this patch gives a cost of 5.
Differential Revision: https://reviews.llvm.org/D147331
Given just how many arguments we pass to
preferPredicateOverEpilogue and considering this list may
grow over time I've decided to pass in a pointer to a new
TailFoldingInfo structure instead, similar to what we do
with IntrinsicCostAttributes, etc. In addition, many of the
arguments we pass in are actually available in the
LoopVectorizationLegality class so I've managed to
reduce the set of pointers that we need to pass in the
TailFoldingInfo struct.
Differential Revision: https://reviews.llvm.org/D146127
This work follows on from D142109 and addresses a possible regression
when we know the loop iteration counter cannot overflow.
When we know the overflow-check always evaluates to false, it's better to
use the other style of tail folding where it assumes a runtime check was
added, because that avoids having to calculate a modified trip-count.
Reviewed By: paulwalker-arm
Differential Revision: https://reviews.llvm.org/D142894
[Originally committed as f6ddf7781471b71243fa3c3ae7c93073f95c7dff;
reverted in bbef38352fbade9e014ec97d5991da5dee306da7 due to test
breakage; now relanded with the Arm tests conditioned on
`arm-registered-target`]
The LowerTypeTests pass emits a jump table in the form of an
`inlineasm` IR node containing a string representation of some
assembly. It tests the target triple to see what architecture it
should be generating assembly for. But that's not good enough for
`Triple::thumb`, because the 32-bit PC-relative `b.w` branch
instruction isn't available in all supported architecture versions. In
particular, Armv6-M doesn't support that instruction (although the
similar Armv8-M Baseline does).
Most of this patch is concerned with working out whether the
compilation target is Armv6-M or not, which I'm doing by going through
all the functions in the module, retrieving a TargetTransformInfo for
each one, and querying it via a new method I've added to check its
SubtargetInfo. If any function's TTI indicates that it's targeting an
architecture supporting B.W, then we assume we're also allowed to use
B.W in the jump table.
The Armv6-M compatible jump table format requires a temporary
register, and therefore also has to use the stack in order to restore
that register.
Another consequence of this change is that jump tables on Arm/Thumb
are no longer always the same size. In particular, on an architecture
that supports Arm and Thumb-1 but not Thumb-2, the Arm and Thumb
tables are different sizes from //each other//. As a consequence,
``getJumpTableEntrySize`` can no longer base its answer on the target
triple's architecture: it has to take into account the decision that
``selectJumpTableArmEncoding`` made, which meant I had to move that
function to an earlier point in the code and store its answer in the
``LowerTypeTestsModule`` class.
Reviewed By: lenary
Differential Revision: https://reviews.llvm.org/D143576
This reverts commit f6ddf7781471b71243fa3c3ae7c93073f95c7dff.
Eight buildbots reported that the two test files changed by that
commit had started failing. The buildbots in question all had in
common that they build with a very restricted `LLVM_TARGETS_TO_BUILD`,
such as only X86 or AArch64 or Hexagon. I didn't notice this before
commit because my own build has the full default set of targets, and
in that circumstance, the tests pass.
I assume the problem has something to do with the attempt to query
TargetTransformInfo: if you can't make a valid TTI for the target
triple then you can't ask it what kind of inline assembler you should
be emitting, and so `opt` without the Arm backend can't get the Arm
cases of these tests right.
I don't have time to fix this until next week, so I'll revert the
change for now to keep the buildbots happy.
The LowerTypeTests pass emits a jump table in the form of an
`inlineasm` IR node containing a string representation of some
assembly. It tests the target triple to see what architecture it
should be generating assembly for. But that's not good enough for
`Triple::thumb`, because the 32-bit PC-relative `b.w` branch
instruction isn't available in all supported architecture versions. In
particular, Armv6-M doesn't support that instruction (although the
similar Armv8-M Baseline does).
Most of this patch is concerned with working out whether the
compilation target is Armv6-M or not, which I'm doing by going through
all the functions in the module, retrieving a TargetTransformInfo for
each one, and querying it via a new method I've added to check its
SubtargetInfo. If any function's TTI indicates that it's targeting an
architecture supporting B.W, then we assume we're also allowed to use
B.W in the jump table.
The Armv6-M compatible jump table format requires a temporary
register, and therefore also has to use the stack in order to restore
that register.
Another consequence of this change is that jump tables on Arm/Thumb
are no longer always the same size. In particular, on an architecture
that supports Arm and Thumb-1 but not Thumb-2, the Arm and Thumb
tables are different sizes from //each other//. As a consequence,
``getJumpTableEntrySize`` can no longer base its answer on the target
triple's architecture: it has to take into account the decision that
``selectJumpTableArmEncoding`` made, which meant I had to move that
function to an earlier point in the code and store its answer in the
``LowerTypeTestsModule`` class.
Reviewed By: lenary
Differential Revision: https://reviews.llvm.org/D143576
This NFC (intended) patch has several small changes:
* It renames PredicationStyle to TailFoldingStyle.
* It renames TTI.emitActiveLaneMask() to TTI.getPreferredTailFoldingStyle()
* Simplifies some of its uses in the LoopVectorizer
Rationale: To my surprise PredicationStyle::None did not mean 'no
predication', but rather 'no active lane mask intrinsic', such that the
predicate is created using a splat + compare with stepvector. The enum is
also highly specific to tail folding, so it seems better to name this
around that feature, i.e. 'tail folding style'.
This also makes it more amenable to extend it to other tail folding styles,
such as the one added in D142109.
Reviewed By: david-arm
Differential Revision: https://reviews.llvm.org/D142887
LoopUnroll estimates the loop size via getInstructionCost(),
but getInstructionCost() cannot pass CostKind to getVectorInstrCost().
And so does getShuffleCost() to getBroadcastShuffleOverhead(),
getPermuteShuffleOverhead(), getExtractSubvectorOverhead(),
and getInsertSubvectorOverhead().
To address this, this patch adds an argument CostKind to these
functions.
Reviewed By: RKSimon
Differential Revision: https://reviews.llvm.org/D142116
Need to include the cost of the initial insertelement to the cost of the
broadcasts. Also, need to adjust the cost of the gather/buildvector if
the element is inserted into poison/undef vector.
Differential Revision: https://reviews.llvm.org/D140498
This is purely NFC restructure in advance of a change which actually exposes zero strides. This is mostly because I find this interface confusing each time I look at it.
This has the effect of exposing the power-of-two property for use in memory op costing, but no target actually uses it yet. The main point of this change is simple consistency with the recently changes getArithmeticInstrCost, and to remove the last (interface) use of OperandValueKind.
This change completes the process of replacing OperandValueKind and OperandValueProperties which were previously passed independently in this API with a single container class which contains both.
This is the change which motivated the whole sequence which preceeded it. In an original spike version of this change, I'd noticed a nasty bug: I'd changed the signature without changing names, and as result, we silently passed additional information through a callsite which previously dropped the power-of-two fact. This might be harmless in most cases, but at least a couple clearly dependend for correctness on not passing that property through.
I did my best to split off prior changes which reduced the scope of this one, and which made it possible to use compiler assistance. For instance, every parameter which changes type in this change also changes name. This was intentional to make sure that every call site possible effected must show up in the diff. This let me audit each one closely.
Defaults to TCK_RecipThroughput - as most explicit calls were assuming TCK_RecipThroughput (vectorizers) or was just doing a before-vs-after comparison (vectorcombiner). Calls via getInstructionCost were just dropping the CostKind, so again there should be no change at this time (as getShuffleCost and its expansions don't use CostKind yet) - but it will make it easier for us to better account for size/latency shuffle costs in inline/unroll passes in the future.
Differential Revision: https://reviews.llvm.org/D132287
* Replace getUserCost with getInstructionCost, covering all cost kinds.
* Remove getInstructionLatency, it's not implemented by any backends, and we should fold the functionality into getUserCost (now getInstructionCost) to make it easier for targets to handle the cost kinds with their existing cost callbacks.
Original Patch by @samparker (Sam Parker)
Differential Revision: https://reviews.llvm.org/D79483
TragetLowering had two last InstructionCost related `getTypeLegalizationCost()`
and `getScalingFactorCost()` members, but all other costs are processed in TTI.
E.g. it is not comfortable to use other TTI members in these two functions
overrided in a target.
Minor refactoring: `getTypeLegalizationCost()` now doesn't need DataLayout
parameter - it was always passed from TTI.
Reviewed By: RKSimon
Differential Revision: https://reviews.llvm.org/D117723
If we have interleave groups in the loop we want to vectorise then
we should fall back on normal vectorisation with a scalar epilogue. In
such cases when tail-folding is enabled we'll almost certainly go on to
create vplans with very high costs for all vector VFs and fall back on
VF=1 anyway. This is likely to be worse than if we'd just used an
unpredicated vector loop in the first place.
Once the vectoriser has proper support for analysing all the costs
for each combination of VF and vectorisation style, then we should
be able to remove this.
Added an extra test here:
Transforms/LoopVectorize/AArch64/sve-tail-folding-option.ll
Differential Revision: https://reviews.llvm.org/D128342
Now the API getExtendedAddReductionCost is used to determine the cost of extended Add reduction with optional Mul. For Arm, it could cover the cases. But for other target, for example: RISCV, they support other kinds of extended recution, such as FAdd.
This patch does the following changes:
1, Split getExtendedAddReductionCost into 2 new API: getExtendedReductionCost which handles the extended reduction with addtional input of Opcode; getMulAccReductionCost which handle the MLA cases the getExtendedAddReductionCost.
2, Refactor getReductionPatternCost, add some contraint condition to make sure the getMulAccReductionCost should only handle the reuction of Add + Mul.
Differential Revision: https://reviews.llvm.org/D130868
This patch adds the AArch64 hook for preferPredicateOverEpilogue,
which currently returns true if SVE is enabled and one of the
following conditions (non-exhaustive) is met:
1. The "sve-tail-folding" option is set to "all", or
2. The "sve-tail-folding" option is set to "all+noreductions"
and the loop does not contain reductions,
3. The "sve-tail-folding" option is set to "all+norecurrences"
and the loop has no first-order recurrences.
Currently the default option is "disabled", but this will be
changed in a later patch.
I've added new tests to show the options behave as expected here:
Transforms/LoopVectorize/AArch64/sve-tail-folding-option.ll
Differential Revision: https://reviews.llvm.org/D129560
Currently, for vectorised loops that use the get.active.lane.mask
intrinsic we only use the mask for predicated vector operations,
such as masked loads and stores, etc. The loop itself is still
controlled by comparing the canonical induction variable with the
trip count. However, for some targets this is inefficient when it's
cheap to use the mask itself to control the loop.
This patch adds support for using the active lane mask for control
flow by:
1. Generating the active lane mask for the next iteration of the
vector loop, rather than the current one. If there are still any
remaining iterations then at least the first bit of the mask will
be set.
2. Extract the first bit of this mask and use this bit for the
conditional branch.
I did this by creating a new VPActiveLaneMaskPHIRecipe that sets
up the initial PHI values in the vector loop pre-header. I've also
made use of the new BranchOnCond VPInstruction for the final
instruction in the loop region.
Differential Revision: https://reviews.llvm.org/D125301
The MVE shuffle costing for VREV instructions was making incorrect
assumptions as to legalized vector types remaining as vectors. Add a
quick check to ensure they are indeed vectors before attempting to get
the number of elements.
Building on top of D125665, this adds MVE costs for fptosi.sat and
fptoui.sat, providing MVE is available and the types are legal.
Differential Revision: https://reviews.llvm.org/D125666
Similar to D124357, this adds some cost modelling for fptoi_sat for Arm
targets. Where VFP2 is available (and FP64/FP16 for the relevant types),
the operations are legal as the Arm instructions naturally saturate.
Otherwise they will need an extra smin/smax clamp, similar to AArch64.
Differential Revision: https://reviews.llvm.org/D125665
Before this patch `Args` was used to pass a broadcat's arguments by SLP.
This patch changes this. `Args` is now used for passing the operands of
the shuffle.
Differential Revision: https://reviews.llvm.org/D124202
I assume we meant to return the result of the call to
BaseT::isLoweredToCall(F).
This might not be a functional change in practice because it would
still hit the default case in the switch and call
BaseT::isLoweredToCall(F) at the end.
Reviewed By: efriedma
Differential Revision: https://reviews.llvm.org/D123333
