Don't allow vectors to split into GPRs for 'r' and other scalar
constraints. Prevents assertion in getCopyToPartsVector.
Makes PR50907 give a better error instead of crashing.
This is a mechanical change. This actually also renames the
similarly named methods in the SmallString class, however these
methods don't seem to be used outside of the llvm subproject, so
this doesn't break building of the rest of the monorepo.
It looks like the fold introduced in 63f3383ece can cause crashes
if the type of the bitcasted value is not a valid vector element type,
like x86_mmx.
To resolve the crash, reject invalid vector element types. The way it is
done in the patch is a bit clunky. Perhaps there's a better way to
check?
Reviewed By: RKSimon
Differential Revision: https://reviews.llvm.org/D104792
select (cmpeq Cond0, Cond1), LHS, (select (cmpugt Cond0, Cond1), LHS, Y) --> (select (cmpuge Cond0, Cond1), LHS, Y)
etc,
We already perform this fold in DAGCombiner for MVT::i1 comparison results, but these can still appear after legalization (in x86 case with MVT::i8 results), where we need to be more careful about generating new comparison codes.
Pulled out of D101074 to help address the remaining regressions.
Differential Revision: https://reviews.llvm.org/D104707
Since this method can apply to cmpxchg operations, make sure it's clear
what value we're actually retrieving. This will help ensure we don't
accidentally ignore the failure ordering of cmpxchg in the future.
We could potentially introduce a getOrdering() method on AtomicSDNode
that asserts the operation isn't cmpxchg, but not sure that's
worthwhile.
Differential Revision: https://reviews.llvm.org/D103338
As per the discussion in D103818, so far, this does not appear to be worthwhile.
Reviewed By: RKSimon
Differential Revision: https://reviews.llvm.org/D103818
Fixes:
- PR36507 Floating point varargs are not handled correctly with
-mno-implicit-float
- PR48528 __builtin_va_start assumes it can pass SSE registers
when using -Xclang -msoft-float -Xclang -no-implicit-float
On x86_64, floating-point parameters are normally passed in XMM
registers. For va_start, we spill those to memory so va_arg can
find them. There is an interaction here with -msoft-float and
-no-implicit-float:
When -msoft-float is in effect, instead of passing floating-point
parameters in XMM registers, they are passed in general-purpose
registers.
When -no-implicit-float is in effect, it "disables implicit
floating-point instructions" (per the LangRef). The intended
effect is to not have the compiler generate floating-point code
unless explicit floating-point operations are present in the
source code, but what exactly counts as an explicit floating-point
operation is not specified. The existing behavior of LLVM here has
led to some surprises and PRs.
This change modifies the behavior as follows:
| soft | no-implicit | old behavior | new behavior |
| no | no | spill XMM regs | spill XMM regs |
| yes | no | don't spill XMM | don't spill XMM |
| no | yes | don't spill XMM | spill XMM regs |
| yes | yes | assert | don't spill XMM |
In particular, this avoids the assert that happens when
-msoft-float and -no-implicit-float are both in effect. This
seems like a perfectly reasonable combination: If we don't want
to rely on hardware floating-point support, we want to both
avoid using float registers to pass parameters and avoid having
the compiler generate floating-point code that wasn't in the
original program. Instead of crashing the compiler, the new
behavior is to not synthesize floating-point code in this
case. This fixes PR48528.
The other interesting case is when -no-implicit-float is in
effect, but -msoft-float is not. In that case, any floating-point
parameters that are present will be in XMM registers, and so we
have to spill them to correctly handle those. This fixes
PR36507. The spill is conditional on %al indicating that
parameters are present in XMM registers, so no floating-point
code will be executed unless the function is called with
floating-point parameters.
Reviewed By: rnk
Differential Revision: https://reviews.llvm.org/D104001
Changing vector element type doesn't work for v6i32->v6i16 now
that v6i32 is an MVT and v6i16 is not.
I would like to fix this in changeVectorElementType, but you
need a LLVMContext to call getVectorVT which we can't get from
an MVT.
Fixes PR50709.
Fixes crash reported here https://reviews.llvm.org/D73607
Using a store to keep the trunc intact. Returning v16i24 would
cause the trunc to be optimized away in SelectionDAGBuilder.
Reviewed By: RKSimon
Differential Revision: https://reviews.llvm.org/D103940
Don't require a specific kind of IRBuilder for TargetLowering hooks.
This allows us to drop the IRBuilder.h include from TargetLowering.h.
Differential Revision: https://reviews.llvm.org/D103759
We were hitting an issue when the scalar_to_vector source was being implicitly truncated (in this case to i8 to vXi1) but we were also using the i8 source in a broadcast to a vXi8 value.
Fixes PR50374
Currently, X86 backend only has a global one-size-fits-all `FeatureFastVariableShuffle` feature,
which controls profitability of both the cross-lane and per-lane variable shuffles.
I guess, this has been fine so far.
But at least on AMD Zen 3, while per-line variable shuffles (e.g. `VPSHUFB`)
are as fast as as shuffles with fixed/immediate mask,
while lane-crossing shuffles, e.g. `VPERMPS` is performing worse.
So to get the benefits of variable-mask shuffles, but not the drawbacks of lane-crossing shuffles,
as suggested by @RKSimon, split the feature flag into two.
Differential Revision: https://reviews.llvm.org/D103274
SwiftTailCC has a different set of requirements than the C calling convention
for a tail call. The exact argument sequence doesn't have to match, but fewer
ABI-affecting attributes are allowed.
Also make sure the musttail diagnostic triggers if a musttail call isn't
actually a tail call.
We could previously do this by accident through the later
call to getTargetConstantBitsFromNode I think, but that only worked
if N0 had a single use. This patch makes it explicit for undef and
doesn't have a use count check.
I think this is needed to move the (shl X, 1)->(add X, X)
fold to isel for PR50468. We need to be sure X won't be IMPLICIT_DEF
which might prevent the same vreg from being used for both operands.
Differential Revision: https://reviews.llvm.org/D103192
D88631 added initial support for:
- -mstack-protector-guard=
- -mstack-protector-guard-reg=
- -mstack-protector-guard-offset=
flags, and D100919 extended these to AArch64. Unfortunately, these flags
aren't retained for LTO. Make them module attributes rather than
TargetOptions.
Link: https://github.com/ClangBuiltLinux/linux/issues/1378
Reviewed By: tejohnson
Differential Revision: https://reviews.llvm.org/D102742
This patch adds support for lowering function calls with the
`clang.arc.attachedcall` bundle. The goal is to expand such calls to the
following sequence of instructions:
callq @fn
movq %rax, %rdi
callq _objc_retainAutoreleasedReturnValue / _objc_unsafeClaimAutoreleasedReturnValue
This sequence of instructions triggers Objective-C runtime optimizations,
hence we want to ensure no instructions get moved in between them.
This patch achieves that by adding a new CALL_RVMARKER ISD node,
which gets turned into the CALL64_RVMARKER pseudo, which eventually gets
expanded into the sequence mentioned above.
The ObjC runtime function to call is determined by the
argument in the bundle, which is passed through as a
target constant to the pseudo.
@ahatanak is working on using this attribute in the front- & middle-end.
Together with the front- & middle-end changes, this should address
PR31925 for X86.
This is the X86 version of 46bc40e502,
which added similar support for AArch64.
Reviewed By: ab
Differential Revision: https://reviews.llvm.org/D94597
This is another FMF gap exposed by D90901, but I don't see a way
to show the difference in a regression test as with:
f66ba4c6025663
We will see an asm difference if we add a test as part of D90901.
Generalize the fix from rGd0902a8665b1 by ensuring we widen/narrow the indices subvector first and then perform the ZERO_EXTEND_VECTOR_INREG (if necessary), which should allow us to perform the variable permutes with source/destination/indices vectors of any widths.
D101838 incorrectly handled indices vectors of the same size but with higher element counts to just bitcast to the target indices type instead of performing a ZERO_EXTEND_VECTOR_INREG
This adds support to the X86 backend for the newly committed swiftasync
function parameter. If such a (pointer) parameter is present it gets stored
into an augmented frame record (populated in IR, but generally containing
enhanced backtrace for coroutines using lots of tail calls back and forth).
The context frame is identical to AArch64 (primarily so that unwinders etc
don't get extra complexity). Specfically, the new frame record is [AsyncCtx,
%rbp, ReturnAddr], and its presence is signalled by bit 60 of the stored %rbp
being set to 1. %rbp still points to the frame pointer in memory for backwards
compatibility (only partial on x86, but OTOH the weird AsyncCtx before the rest
of the record is because of x86).
Recommited with a fix for unwind info when i386 pc-rel thunks are
adjacent to a prologue.
This adds support to the X86 backend for the newly committed swiftasync
function parameter. If such a (pointer) parameter is present it gets stored
into an augmented frame record (populated in IR, but generally containing
enhanced backtrace for coroutines using lots of tail calls back and forth).
The context frame is identical to AArch64 (primarily so that unwinders etc
don't get extra complexity). Specfically, the new frame record is [AsyncCtx,
%rbp, ReturnAddr], and its presence is signalled by bit 60 of the stored %rbp
being set to 1. %rbp still points to the frame pointer in memory for backwards
compatibility (only partial on x86, but OTOH the weird AsyncCtx before the rest
of the record is because of x86).
Swift's new concurrency features are going to require guaranteed tail calls so
that they don't consume excessive amounts of stack space. This would normally
mean "tailcc", but there are also Swift-specific ABI desires that don't
naturally go along with "tailcc" so this adds another calling convention that's
the combination of "swiftcc" and "tailcc".
Support is added for AArch64 and X86 for now.
The intention is to be able to run this from additional locations (such as shuffle combining) in the future.
Reapplies rGb95a103808ac (after reversion at rGc012a388a15b), with SSE3/SSSE3 typo fix, test added at rG0afb10de1449.
On AVX1 targets we can handle v4i64 logical shifts by 32 bits as a pair of v8f32 shuffles with zero.
I was hoping to put this in LowerScalarImmediateShift, but performing that early causes regressions where other instructions were respliting the subvectors.
getVectorNumElements() returns a value for scalable vectors
without any warning so it is effectively getVectorMinNumElements().
By renaming it and making getVectorNumElements() forward to
it, we can insert a check for scalable vectors into getVectorNumElements()
similar to EVT. I didn't do that in this patch because there are still more
fixes needed, but I was able to temporarily do it and passed the RISCV
lit tests with these changes.
The changes to isPow2VectorType and getPow2VectorType are copied from EVT.
The change to TypeInfer::EnforceSameNumElts reduces the size of AArch64's isel table.
We're now considering SameNumElts to require the scalable property to match which
removes some unneeded type checks.
This was motivated by the bug I fixed yesterday in 80b9510806
Reviewed By: frasercrmck, sdesmalen
Differential Revision: https://reviews.llvm.org/D102262
Extend the HOP(HOP(X,Y),HOP(Z,W)) and SHUFFLE(HOP(X,Y),HOP(Z,W)) folds to handle repeating 256/512-bit vector cases.
This allows us to drop the UNPACK(HOP(),HOP()) custom fold in combineTargetShuffle.
This required isRepeatedTargetShuffleMask to be tweaked to support target shuffle masks taking more than 2 inputs.
foldShuffleOfHorizOp only handled basic shufps(hop(x,y),hop(z,w)) folds - by moving this to canonicalizeShuffleMaskWithHorizOp we can work with more general/combined v4x32 shuffles masks, float/integer domains and support shuffle-of-packs as well.
The next step will be to support 256/512-bit vector cases.
Ensure we don't try to fold when one might be an opaque constant - the constant fold will fail and then the reverse fold will happen in DAGCombine.....
Based off a discussion on D89281 - where the AARCH64 implementations were being replaced to use funnel shifts.
Any target that has efficient funnel shift lowering can handle the shift parts expansion using the same expansion, avoiding a lot of duplication.
I've generalized the X86 implementation and moved it to TargetLowering - so far I've found that AARCH64 and AMDGPU benefit, but many other targets (ARM, PowerPC + RISCV in particular) could easily use this with a few minor improvements to their funnel shift lowering (or the folding of their target ops that funnel shifts lower to).
NOTE: I'm trying to avoid adding full SHIFT_PARTS legalizer handling as I think it might actually be possible to remove these opcodes in the medium-term and use funnel shift / libcall expansion directly.
Differential Revision: https://reviews.llvm.org/D101987
Need to perfortm a bitcast on IndicesVec rather than subvector extract
if the original size of the IndicesVec is the same as the size of the
destination type.
Differential Revision: https://reviews.llvm.org/D101838
Related to PR50172.
Protects us against regressions after we will start doing cttz(zext(x)) -> zext(cttz(x)) transformation in the middle-end.
Reviewed By: craig.topper
Differential Revision: https://reviews.llvm.org/D101662
Previously we used an i32 constant to store the saturation width, but i32 isn't
legal on RISCV64. This wasn't a big deal to fix, but it is extra work for the
type legalizer.
This patch uses a VTSDNode to store the type similar to SEXT_INREG. This makes
it opaque to the type legalizer.
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D101262
GCC supports negative values for -mstack-protector-guard-offset=, this
should be a signed value. Pre-req to D100919.
Reviewed By: MaskRay
Differential Revision: https://reviews.llvm.org/D101325
PR50049 demonstrated an infinite loop between OR(SHUFFLE,SHUFFLE) <-> BLEND(SHUFFLE,SHUFFLE) patterns.
The UNDEF elements were allowing a combined shuffle mask to be widened which lost the undef element, resulting us needing to use the BLEND pattern (as the undef element would need to be zero for the OR pattern). But then bitcast folds would re-expose the undef element allowing us to use OR again.....
If we are truncating from a i32 source before comparing the result against zero, then see if we can directly compare the source value against zero.
If the upper (truncated) bits are known to be zero then we can compare against that, hopefully increasing the chances of us folding the compare into a EFLAG result of the source's operation.
Fixes PR49028.
Differential Revision: https://reviews.llvm.org/D100491
In the fold SHUFFLE(BINOP(X,Y),BINOP(Z,W)) -> BINOP(SHUFFLE(X,Z),SHUFFLE(Y,W)), check if both X/Z AND Y/W have at least one merge-able shuffle in which case the total number of shuffle should still fall.
Helps with instruction count regressions we saw while fixing PR48823
Extension to rG74f98391a7a4, we can also include any of the upper (known zero) bits in the comparison in the shuffle removal fold, just as long as we demand all the elements of the movmsk source vector.
We already allow the comparison of the upper bits of 'IsAllOf' (allbits) patterns, but we can safely compare the known zero bits for 'IsAnyOf' (zerobits) patterns as well.
This fixes an issues where we are comparing a type wide than the number of vector elements, which avoids a regression mentioned in rGbaadbe04bf75.
Fixes the issues noted in PR48768, where the and/or/xor instruction had been promoted to avoid i8/i16 partial-dependencies, but the test against zero had not.
We can almost certainly relax this fold to work for any truncation, although it breaks a number of existing folds (notable movmsk folds which tend to rely on the truncate to determine the demanded bits/elts in the source vector).
There is a reverse combine in TargetLowering.SimplifySetCC so we must wait until after legalization before attempting this.
Improve AVX512 mask inversion, rG38c799bce801 exposed some missing opportunities to move scalar not() back onto the boolvector types for folding with setcc etc.
Followup to D100177, handle an similar (demorgan inverse style) case from PR47797 as well
The AVX512 test cases could be further improved if we folded not(iX bitcast(vXi1)) -> (iX bitcast(not(vXi1)))
Alive2: https://alive2.llvm.org/ce/z/AnA_-W
I've initially just enabled this for BMI which has the ANDN instruction for i32/i64 - the i16/i8 cases give an idea of what'd we get when we enable it in all cases (I'll do this as a later commit).
Additionally, the i16/i8 cases could be freely promoted to i32 (as the args are already zeroext) and we could then make use of ANDN + the free cmp0 there as well - this has come up in PR48768 and PR49028 so I'm going to look at this soon.
https://alive2.llvm.org/ce/z/QVWHP_https://alive2.llvm.org/ce/z/pLngT-
Vector cases do not appear to benefit from this as we end up with having to generate the zero vector as well - this is one of the reasons I didn't try to tie this into hasAndNot/hasAndNotCompare.
Differential Revision: https://reviews.llvm.org/D100177
Fixes PR47603
This should probably be transferable to DAGCombine - the main limitation with the existing trunc(logicop) DAG fold is we don't know if legalization has tried to promote truncated logicops already. We might be able to peek through extensions as well.
Use the getTargetShuffleInputs helper for all shuffle decoding
Reapplied (after reversion in rGfa0aff6d6960) with fix+test for subvector splitting - we weren't accounting for peeking through bitcasts changing the vector element count of the shuffle sources.
The default expansion creates a MUL and either a MULHS/MULHU. Each
of those separately expand to sequences that use one or more
PMULLW instructions as well as additional instructions to
extend the types to vXi16. The MULHS/MULHU expansion computes the
whole 16-bit product, but only keeps the high part.
We can improve the lowering of SMULO/UMULO for some cases by using the MULHS/MULHU
expansion, but keep both the high and low parts. And we can use
those parts to calculate the overflow.
For AVX512 we might have vXi1 overflow outputs. We can improve those by using
vpcmpeqw to produce a k register if AVX512BW is enabled. This is a little better
than truncating the high result to use vpcmpeqb. If we don't have avx512bw we
can extend up to v16i32 to use vpcmpeqd to produce a k register.
Reviewed By: RKSimon
Differential Revision: https://reviews.llvm.org/D97624
Currently needsStackRealignment returns false if canRealignStack returns false.
This means that the behavior of needsStackRealignment does not correspond to
it's name and description; a function might need stack realignment, but if it
is not possible then this function returns false. Furthermore,
needsStackRealignment is not virtual and therefore some backends have made use
of canRealignStack to indicate whether a function needs stack realignment.
This patch attempts to clarify the situation by separating them and introducing
new names:
- shouldRealignStack - true if there is any reason the stack should be
realigned
- canRealignStack - true if we are still able to realign the stack (e.g. we
can still reserve/have reserved a frame pointer)
- hasStackRealignment = shouldRealignStack && canRealignStack (not target
customisable)
Targets can now override shouldRealignStack to indicate that stack realignment
is required.
This change will make it easier in a future change to handle the case where we
need to realign the stack but can't do so (for example when the register
allocator creates an aligned spill after the frame pointer has been
eliminated).
Differential Revision: https://reviews.llvm.org/D98716
Change-Id: Ib9a4d21728bf9d08a545b4365418d3ffe1af4d87
This was crashing with the example from:
https://llvm.org/PR49716
...and that was avoided with a283d72583 ,
but as we can see from the SSE vs. AVX test code diff,
we can try harder to match the pattern.
This matcher code was adapted from another pmadd pattern
match in D49636, but it needs different ops to deal with
size mismatches.
Differential Revision: https://reviews.llvm.org/D99531
For these cases we need to extract the upper or lower elements,
multiply them using 16-bit multiplies and repack them.
Previously we used punpcklbw/punpckhbw+psraw or pmovsxbw+pshudfd to
extract and sign extend so we could use pmullw to compute the 16-bit
product and then shift down the high bits.
We can avoid the need to sign extend if we unpack the bytes into
the high byte of each word and fill the lower byte with 0 using
pxor. This puts the sign bit of each byte into the sign bit of
each word. Since the LHS and RHS have 8 trailing zeros, the full
32-bit product of those 16-bit values will have 16 trailing zeros.
This means the 16-bit product of the original bytes is in the upper
16 bits which we can calculate using pmulhw.
Reviewed By: RKSimon
Differential Revision: https://reviews.llvm.org/D98587
Remove VBROADCAST/MOVDDUP/splat-shuffle handling from foldShuffleOfHorizOp
This can all be handled by canonicalizeShuffleMaskWithHorizOp along as we check that the HADD/SUB are only used once (to prevent infinite loops on slow-horizop targets which will try to reuse the nodes again followed by a post-hop shuffle).
See if the combined shuffle mask is equivalent to an identity shuffle, typically this is due to repeated LHS/RHS ops in horiz-ops, but isTargetShuffleEquivalent might see other patterns as well.
This is another small step towards getting rid of foldShuffleOfHorizOp and relying on canonicalizeShuffleMaskWithHorizOp and generic shuffle combining.
Until AVX512 we don't have any vector truncation instructions, and always lower using shuffles instead.
combineVectorTruncation performs this earlier than lowering as it makes it easier to use any sign/zero-extended bits in the truncated bits with PACKSS/PACKUS to perform the shuffle.
We currently don't attempt to use combineVectorTruncation on AVX2 targets as in the past 256-bit PACKSS/PACKUS tended to cause 128-bit lane shuffle regressions - but these should now be all resolved with combineHorizOpWithShuffle and in all cases we now reduce the amount of cross-lane shuffling and variable shuffle mask usage.
Differential Revision: https://reviews.llvm.org/D96609
LowerVSETCC calls splitIntVSETCC after canonicalizing certain patterns, in particular (X & CPow2 != 0) -> (X & CPow2 == CPow2).
Unfortunately if we're splitting for AVX1/non-AVX512BW cases, we lose these canonicalizations as we call the split with the original SetCC node, and when the split nodes are later lowered in LowerVSETCC the patterns are lost behind extract_subvector etc. But if we pass the canonicalized operands for splitting we retain the optimizations.
Differential Revision: https://reviews.llvm.org/D99256
If we're truncating to vXi1 from a wider type, then prefer the original wider vector as is simplifies folding the separate truncations + extensions.
AVX1 this is only worth it for v8i1 cases, not v4i1 where we're always better off truncating down to v4i32 for movmsk.
Helps with some regressions encountered in D96609
Prefer broadcast from scalar on AVX targets as this makes it easier for later folds to strip away bitcasts etc.
This helps a lot with the AVX1 poor codegen from PR49658.
There's a trivial regression in bitcast-int-to-vector-bool-*ext.ll tests due to SimplifyDemandedBits not being able to see a multi-use case, but there's bigger existing codegen issues to be addressed first in those tests (unnecessary NOTs).
Helps fix cases where we've splatted smaller types to a wider vector element type without needing the upper bits.
Avoid this on AVX512 targets as that can affect broadcast folding.
The target shuffle code handles vector sources, but X86ISD::VBROADCAST can also accept a scalar source for splatting.
Suggested by @craig.topper on PR49658
For slow-hop targets, see if any single-op hops are duplicating work already done on another (dual-op) hop, which can sometimes occur as isHorizontalBinOp tries to find potential duplicates (but can't merge them itself). If so, reuse the other hop and shuffle the result.
That review is extracted from D69372.
It fixes https://bugs.llvm.org/show_bug.cgi?id=42219 bug.
For the noimplicitfloat mode, the compiler mustn't generate
floating-point code if it was not asked directly to do so.
This rule does not work with variable function arguments currently.
Though compiler correctly guards block of code, which copies xmm vararg
parameters with a check for %al, it does not protect spills for xmm registers.
Thus, such spills are generated in non-protected areas and could break code,
which does not expect floating-point data. The problem happens in -O0
optimization mode. With this optimization level there is used
FastRegisterAllocator, which spills virtual registers at basic block boundaries.
Register Allocator does not protect spills with additional control-flow modifications.
Thus to resolve that problem, it is suggested to not copy incoming physical
registers into virtual registers. Instead, store incoming physical xmm registers
into the memory from scratch.
Differential Revision: https://reviews.llvm.org/D80163
Generalize the shuffle(not(x)) -> not(shuffle(x)) fold to handle any binop with 0/-1.
Hopefully we can further generalize to help push target unary/binary shuffles through binops similar to what we do in DAGCombiner::visitVECTOR_SHUFFLE
As discussed on D97478. The removal of the custom tag causes some changes in the add/sub-overflow expansion as it no longer expands to sat-arith codegen.
We should be able to extend this "canonicalizeShuffleWithBinOps" to handle more generic binop cases where either/both operands can be cheaply shuffled.
In conjunction with the 'vperm2x128(bitcast(x),bitcast(y),c) -> bitcast(vperm2x128(x,y,c))' fold in combineTargetShuffle, this should remove any unnecessary bitcasts around vperm2x128 lane shuffles.
Extend the existing combine that handles bitcasting for fp-logic ops to also help remove logic ops across bitcasts to/from the same integer types.
This helps improve AVX512 predicate handling for D/Q logic ops and also allows DAGCombine's scalarizeExtractedBinop to remove some annoying gpr->simd->gpr transfers.
The concat_vectors regression in pr40891.ll will be addressed in a followup commit on this patch.
Differential Revision: https://reviews.llvm.org/D96206
This patch fixes some crashes coming from
X86ISelLowering::getSetCCResultType, which would occasionally return
an EVT constructed from an invalid MVT, which has a null Type pointer.
This patch refers to D95434.
Differential Revision: https://reviews.llvm.org/D97036
Fold shuffle(bop(shuffle(x,y),shuffle(z,w)),bop(shuffle(a,b),shuffle(c,d))) -> bop(shuffle(x,y),shuffle(z,w)),bop(shuffle(a,b),shuffle(c,d))
Attempt to fold from a shuffle of a pair of binops to a binop of shuffles, as long as one/both of the binop sources are also shuffles that can be merged with the outer shuffle. This should guarantee that we remove one binop without introducing any additional shuffles.
Technically there's potential for a merged shuffle's lowering to be poorer than the original shuffle, but it could also be better, and I'm not seeing any regressions as long as we keep the 'don't merge splats' rule already present in MergeInnerShuffle.
This expands and generalizes an existing X86 combine and attempts to merge either of each binop's sources (with an on-the-fly commutation of the shuffle mask) - we couldn't do that in the x86 version as it had to stay in a form that DAGCombine's MergeInnerShuffle would still recognise.
Fixes issue raised by @saugustine in rG5aa8f4c0843a where we were failing to replace null shuffle operands from MergeInnerShuffle to UNDEFs.
Differential Revision: https://reviews.llvm.org/D96345
This reverts commit 5dfba562dd.
That commit causes an assertion failure with the following repro:
typedef long b __attribute__((__vector_size__(16)));
b *d;
b e;
b __attribute__((__always_inline__)) c(b h, b i) {
return (__attribute__((__vector_size__(8 * sizeof(short)))) short)h + i;
}
j() {
b k, l, m, n, o[6], p, q;
m = d[5];
b r = m;
b s = f(r, 8);
q = s;
l = d[1];
p = l;
t(q);
n = c(m, l);
o[1] = c(s, f(p, 8));
k = __builtin_shufflevector(n, o[1], 0, 2);
e = __builtin_ia32_psrlwi128(k, j);
}
./bin/clang -cc1 -triple x86_64-grtev4-linux-gnu -emit-obj -O1 -std=c99 test.c
Fold shuffle(bop(shuffle(x,y),shuffle(z,w)),bop(shuffle(a,b),shuffle(c,d))) -> bop(shuffle(x,y),shuffle(z,w)),bop(shuffle(a,b),shuffle(c,d))
Attempt to fold from a shuffle of a pair of binops to a binop of shuffles, as long as one/both of the binop sources are also shuffles that can be merged with the outer shuffle. This should guarantee that we remove one binop without introducing any additional shuffles.
Technically there's potential for a merged shuffle's lowering to be poorer than the original shuffle, but it could also be better, and I'm not seeing any regressions as long as we keep the 'don't merge splats' rule already present in MergeInnerShuffle.
This expands and generalizes an existing X86 combine and attempts to merge either of each binop's sources (with an on-the-fly commutation of the shuffle mask) - we couldn't do that in the x86 version as it had to stay in a form that DAGCombine's MergeInnerShuffle would still recognise.
Differential Revision: https://reviews.llvm.org/D96345
Begin transitioning the X86 vector code to recognise sub(umax(a,b) ,b) or sub(a,umin(a,b)) USUBSAT patterns to make it more generic and available to all targets.
This initial patch just moves the basic umin/umax patterns to DAG, removing some vector-only checks on the way - these are some of the patterns that the legalizer will try to expand back to so we can be reasonably relaxed about matching these pre-legalization.
We can handle the trunc(sub(..))) variants as well, which helps with patterns where we were promoting to a wider type to detect overflow/saturation.
The remaining x86 code requires some cleanup first - some of it isn't actually tested etc. I also need to resurrect D25987.
Differential Revision: https://reviews.llvm.org/D96413
Fold shufps(hop(x,y),hop(z,w)) -> permute(hop(x,z)) - this is very similar to the equivalent unpack fold.
I did start trying to convert foldShuffleOfHorizOp to handle generic shuffle masks but we're relying on a lot of special cases at the moment.
I don't think we have any reason to believe the FP_ROUND here doesn't change the value.
Found while trying to see if we still need the fp128 block in CanCombineFCOPYSIGN_EXTEND_ROUND.
Removing that check caused this FP_ROUND to fire for fp128 which introduced a libcall expansion that asserted for this being a 1.
Reviewed By: RKSimon, pengfei
Differential Revision: https://reviews.llvm.org/D96098
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.
Extends D95779 to permit insertion into float/doubles vectors while avoiding a lot of aliased memory traffic.
The scalar value is already on the simd unit, so we only need to transfer and splat the index value, then perform the select.
SSE4 codegen is a little bulky due to the tied register requirements of (non-VEX) BLENDPS/PD but the extra moves are cheap so shouldn't be an actual problem.
Differential Revision: https://reviews.llvm.org/D95866
Craig Topper