Avoid calling ConstantExpr::get() for associative/commutative
binops, call ConstantFoldBinaryOpOperands() instead. We only
want to perform the reassociation of the constants actually fold.
Replace ConstantExpr:getFAdd etc with call to
ConstantFoldBinaryOpOperands(). I'm using the constant folding API
rather than IRBuilder here to ensure that this does actually
constant fold. These transforms don't use m_ImmConstant(), so this
would not otherwise be guaranteed (and apparently, they can't use
m_ImmConstant because they want to handle scalable vector splats).
There is an opportunity here to further migrate these to the
ConstantFoldFPInstOperands() API, which would respect the denormal
mode. I've held off on doing so here, because some of this code
explicitly checks for denormal results, and I don't want to touch
it in a mostly NFC change.
Since we can't change the destination of indirectbr, so when
encounter indirectbr as PredPredBB terminator, we should pass it.
Differential Revision: https://reviews.llvm.org/D129193
After D129205, we support SplitBlockPredecessors() for predecessors
with callbr terminators. This means that it is now also safe to
invoke critical edge splitting for an edge coming from a callbr
terminator. Remove checks in various passes that were protecting
against that.
Differential Revision: https://reviews.llvm.org/D129256
For the longest time we used `AAValueSimplify` and
`genericValueTraversal` to determine "potential values". This was
problematic for many reasons:
- We recomputed the result a lot as there was no caching for the 9
locations calling `genericValueTraversal`.
- We added the idea of "intra" vs. "inter" procedural simplification
only as an afterthought. `genericValueTraversal` did offer an option
but `AAValueSimplify` did not. Thus, we might end up with "too much"
simplification in certain situations and then gave up on it.
- Because `genericValueTraversal` was not a real `AA` we ended up with
problems like the infinite recursion bug (#54981) as well as code
duplication.
This patch introduces `AAPotentialValues` and replaces the
`AAValueSimplify` uses with it. `genericValueTraversal` is folded into
`AAPotentialValues` as are the instruction simplifications performed in
`AAValueSimplify` before. We further distinguish "intra" and "inter"
procedural simplification now.
`AAValueSimplify` was not deleted as we haven't ported the
re-materialization of instructions yet. There are other differences over
the former handling, e.g., we may not fold trivially foldable
instructions right now, e.g., `add i32 1, 1` is not folded to `i32 2`
but if an operand would be simplified to `i32 1` we would fold it still.
We are also even more aware of function/SCC boundaries in CGSCC passes,
which is good even if some tests look like they regress.
Fixes: https://github.com/llvm/llvm-project/issues/54981
Note: A previous version was flawed and consequently reverted in
6555558a80.
We recently learned to place the alloca during the heap2stack
transformation in the entry block but we did not account for other
concurrent modifications. We need to record our decision rather than
checking (then outdated) passes during the manifest stage. This will
also allow us to use a custom (=optimistic) "loop info" in the future.
This way it can be reused easily in D128387.
Note this changes the IR slightly. Before The steps for calculating and storing the frame record info were:
1. getPC
2. getSP
3. inttoptr
4. or SP, PC
5. store
Now the steps are:
1. getPC
2. getSP
3. or SP, PC
4. inttoptr
5. store
Differential Revision: https://reviews.llvm.org/D129315
Enhance memchr and strchr handling to simplify calls to the functions
used in equality expressions with the first argument to at most two
integer comparisons:
- memchr(A, C, N) == A to N && *A == C for either a dereferenceable
A or a nonzero N,
- strchr(S, C) == S to *S == C for any S and C, and
- strchr(S, '\0') == 0 to true for any S
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D128939
Fix bug exposed by https://reviews.llvm.org/D125990
rewriteLoopExitValues calls InductionDescriptor::isInductionPHI which requires
the PHI node to have an incoming edge from the loop preheader. This adds checks
before calling InductionDescriptor::isInductionPHI to see that the loop has a
preheader. Also did some refactoring.
Differential Revision: https://reviews.llvm.org/D129297
The 'and (sext (ashr X, ShiftC)), C' --> 'lshr (sext X), ShiftC'
transformation would access out of bounds bits in APInt::getLowBitsSet
if the shift count was larger than X's bit width or if it was negative.
Fixes#56424
This patchs adds a new metadata kind `exclude` which implies that the
global variable should be given the necessary flags during code
generation to not be included in the final executable. This is done
using the ``SHF_EXCLUDE`` flag on ELF for example. This should make it
easier to specify this flag on a variable without needing to explicitly
check the section name in the target backend.
Depends on D129053 D129052
Reviewed By: jdoerfert
Differential Revision: https://reviews.llvm.org/D129151
Currently we use the `embedBufferInModule` function to store binary
strings containing device offloading data inside the host object to
create a fatbinary. In the case of LTO, we need to extract this object
from the LLVM-IR. This patch adds a metadata node for the embedded
objects containing the embedded pointers and the sections they were
stored at. This should create a cleaner interface for identifying these
values.
In the future it may be worthwhile to also encode an `ID` in the
metadata corresponding to the object's special section type if relevant.
This would allow us to extract the data from an object file and LLVM-IR
using the same ID.
Reviewed By: jdoerfert
Differential Revision: https://reviews.llvm.org/D129033
Now that removeDeadRecipes can remove most dead recipes across a whole
VPlan, there is no need to first collect some dead instructions.
Instead removeDeadRecipes can simply clean them up.
Depends D127580.
Reviewed By: Ayal
Differential Revision: https://reviews.llvm.org/D128408
SplitBlockPredecessors currently asserts if one of the predecessor
terminators is a callbr. This limitation was originally necessary,
because just like with indirectbr, it was not possible to replace
successors of a callbr. However, this is no longer the case since
D67252. As the requirement nowadays is that callbr must reference
all blockaddrs directly in the call arguments, and these get
automatically updated when setSuccessor() is called, we no longer
need this limitation.
The only thing we need to do here is use replaceSuccessorWith()
instead of replaceUsesOfWith(), because only the former does the
necessary blockaddr updating magic.
I believe there's other similar limitations that can be removed,
e.g. related to critical edge splitting.
Differential Revision: https://reviews.llvm.org/D129205
This can enable additional region merging, while not losing
opportunities as region merging does not produce dead recipes.
Reviewed By: Ayal
Differential Revision: https://reviews.llvm.org/D128831
Previously the scope of debug type of __coro_frame is limited in the
current function. It looked good at the first sight. But it prevent us
to print the type in splitted functions and other functions. Also the
debug type is different for different coroutine functions. So it makes
sense to rename the debug type to make it related to the function name.
After this patch, we could access the coroutine frame type in a function
by `function_name.coro_frame_ty`.
Reviewed By: dblaikie
Differential Revision: https://reviews.llvm.org/D127623
Debugify in OriginalDebugInfo mode, introduced with D82545,
runs only with legacy PassManager.
This patch enables this utility for the NewPM.
Differential Revision: https://reviews.llvm.org/D115351
This patch adds the support for `fmax` and `fmin` operations in `atomicrmw`
instruction. For now (at least in this patch), the instruction will be expanded
to CAS loop. There are already a couple of targets supporting the feature. I'll
create another patch(es) to enable them accordingly.
Reviewed By: arsenm
Differential Revision: https://reviews.llvm.org/D127041
This addresses the assertion failure reported in
https://reviews.llvm.org/D124159#3631240.
I believe that this limitation in SplitBlockPredecessors is not
actually necessary (because unlike with indirectbr, callbr is
restricted in a way that does allow updating successors), but for
now fix the assertion failure the same way we do everywhere else,
by also skipping callbr.
Currently, LLVM doesn't have the correct shadow offset
mapping for the n32 ABI.
This patch introduces the correct shadow offset value
for the n32 ABI - 1ULL << 29.
Differential Revision: https://reviews.llvm.org/D127096
As constant expressions can no longer trap, it only makes sense to
call isSafeToSpeculativelyExecute on Instructions, so limit the
API to accept only them, rather than general Operators or Values.
As integer div/rem constant expressions are no longer supported,
constants can no longer trap and are always safe to speculate.
Remove the Constant::canTrap() method and its usages.
By LangRef, hoisting token-returning instructions obsures the origin
so it should be skipped. Found this issue while investigating a
CoroSplit pass crash.
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D129025
This in an extension to the code added in D123911 which added vector
combine folding of shuffle-select patterns, attempting to reduce the
total amount of shuffling required in patterns like:
%x = shuffle %i1, %i2
%y = shuffle %i1, %i2
%a = binop %x, %y
%b = binop %x, %y
shuffle %a, %b, selectmask
This patch extends the handing of shuffles that are dependent on one
another, which can arise from the SLP vectorizer, as-in:
%x = shuffle %i1, %i2
%y = shuffle %x
The input shuffles can also be emitted, in which case they are treated
like identity shuffles. This patch also attempts to calculate a better
ordering of input shuffles, which can help getting lower cost input
shuffles, pushing complex shuffles further down the tree.
This is a recommit with some additional checks for supported forms and
out-of-bounds mask elements, with some extra tests.
Differential Revision: https://reviews.llvm.org/D128732
This reverts commit 4e545bdb35.
The newly added test is the third infinite combine loop caused by
this change. In this case, it's a combination of the branch to
common dest and jump threading folds that keeps peeling off loop
iterations.
The core problem here is that we ideally would not thread over
loop backedges, both because it is potentially non-profitable
(it may break canonical loop structure) and because it may result
in these kinds of loops. Unfortunately, due to the lack of a
dominator tree in SimplifyCFG, there is no good way to prevent
this. While we have LoopHeaders, this is an optional structure and
we don't do a good job of keeping it up to date. It would be fine
for a profitability check, but is not suitable for a correctness
check.
So for now I'm just giving up here, as I don't see a good way to
robustly prevent infinite combine loops.
Fixes https://github.com/llvm/llvm-project/issues/56203.
This removes creation of udiv/sdiv/urem/srem constant expressions,
in preparation for their removal. I've added a
ConstantExpr::isDesirableBinOp() predicate to determine whether
an expression should be created for a certain operator.
With this patch, div/rem expressions can still be created through
explicit IR/bitcode, forbidding them entirely will be the next step.
Differential Revision: https://reviews.llvm.org/D128820
If there are multiple predecessors that have the same condition
value (and thus same "real destination"), these were previously
handled by copying the threaded block for each predecessor.
Instead, we can reuse one block for all of them. This makes the
behavior of SimplifyCFG's jump threading match that of the
actual JumpThreading pass.
This also avoids the infinite combine loop reported in:
https://reviews.llvm.org/D124159#3624387
In D95959, the improve analysis for "C >> X" broken the fold
((%x & C) == 0) --> %x u< (-C) iff (-C) is power of two.
It simplifies C, but fails to satisfy the fold condition.
This patch try to restore C before the fold.
Reviewed By: spatel
Differential Revision: https://reviews.llvm.org/D128790
For scalable VFs, the minimum assumed vscale needs to be included in the
cost-computation, otherwise a smaller VF may be used for RT check cost
computation than was used for earlier cost computations.
Fixes a RISCV test failing with UBSan due to both scalar and vector
loops having the same cost.
The test diffs are cosmetic -- but improvements -- because we
let instcombine handle replacement. Instead of dropping the
old value name, it propagates to the new instruction.
This fixes an UBSan failure after 644a965c1e. When using
user-provided VFs/ICs (via the force-vector-width /
force-vector-interleave options) the scalar cost is zero, which would
cause divide-by-zero.
When forcing vectorization using the options, the cost of the runtime
checks should not block vectorization.
This patch replaces the tight hard cut-off for the number of runtime
checks with a more accurate cost-driven approach.
The new approach allows vectorization with a larger number of runtime
checks in general, but only executes the vector loop (and runtime checks) if
considered profitable at runtime. Profitable here means that the cost-model
indicates that the runtime check cost + vector loop cost < scalar loop cost.
To do that, LV computes the minimum trip count for which runtime check cost
+ vector-loop-cost < scalar loop cost.
Note that there is still a hard cut-off to avoid excessive compile-time/code-size
increases, but it is much larger than the original limit.
The performance impact on standard test-suites like SPEC2006/SPEC2006/MultiSource
is mostly neutral, but the new approach can give substantial gains in cases where
we failed to vectorize before due to the over-aggressive cut-offs.
On AArch64 with -O3, I didn't observe any regressions outside the noise level (<0.4%)
and there are the following execution time improvements. Both `IRSmk` and `srad` are relatively short running, but the changes are far above the noise level for them on my benchmark system.
```
CFP2006/447.dealII/447.dealII -1.9%
CINT2017rate/525.x264_r/525.x264_r -2.2%
ASC_Sequoia/IRSmk/IRSmk -9.2%
Rodinia/srad/srad -36.1%
```
`size` regressions on AArch64 with -O3 are
```
MultiSource/Applications/hbd/hbd 90256.00 106768.00 18.3%
MultiSourc...ks/ASCI_Purple/SMG2000/smg2000 240676.00 257268.00 6.9%
MultiSourc...enchmarks/mafft/pairlocalalign 472603.00 489131.00 3.5%
External/S...2017rate/525.x264_r/525.x264_r 613831.00 630343.00 2.7%
External/S...NT2006/464.h264ref/464.h264ref 818920.00 835448.00 2.0%
External/S...te/538.imagick_r/538.imagick_r 1994730.00 2027754.00 1.7%
MultiSourc...nchmarks/tramp3d-v4/tramp3d-v4 1236471.00 1253015.00 1.3%
MultiSource/Applications/oggenc/oggenc 2108147.00 2124675.00 0.8%
External/S.../CFP2006/447.dealII/447.dealII 4742999.00 4759559.00 0.3%
External/S...rate/510.parest_r/510.parest_r 14206377.00 14239433.00 0.2%
```
Reviewed By: lebedev.ri, ebrevnov, dmgreen
Differential Revision: https://reviews.llvm.org/D109368
This patch slightly extends the limit on the RecursionMaxDepth inside
the SLP vectorizer. It does it only when it hits a load (or zext/sext of
a load), which allows it to peek through in the places where it will be
the most valuable, without ballooning out the O(..) by any 2^n factors.
Differential Revision: https://reviews.llvm.org/D122148
Use ConstantFoldBinaryOpOperands() instead, to handle the case
where not all binary ops have a constant expression variant.
This is a bit awkward because we only want to pop the element from
Ops once we're sure that it has folded.
This in an extension to the code added in D123911 which added vector
combine folding of shuffle-select patterns, attempting to reduce the
total amount of shuffling required in patterns like:
%x = shuffle %i1, %i2
%y = shuffle %i1, %i2
%a = binop %x, %y
%b = binop %x, %y
shuffle %a, %b, selectmask
This patch extends the handing of shuffles that are dependent on one
another, which can arise from the SLP vectorizer, as-in:
%x = shuffle %i1, %i2
%y = shuffle %x
The input shuffles can also be emitted, in which case they are treated
like identity shuffles. This patch also attempts to calculate a better
ordering of input shuffles, which can help getting lower cost input
shuffles, pushing complex shuffles further down the tree.
Differential Revision: https://reviews.llvm.org/D128732
These conditions are later checked in the HoistTerminator code
path. Checking them here is somewhat confusing, because this code
only checks the first instruction in the block, which is not
necessarily the terminator.
(-(X & 1)) & Y --> (X & 1) == 0 ? 0 : Y
https://alive2.llvm.org/ce/z/rhpH3i
This is noted as a missing IR canonicalization in issue #55618.
We already managed to fix codegen to the expected form.
The moved helpers are only used for codegen. It will allow moving the
remaining ::execute implementations out of LoopVectorize.cpp.
Reviewed By: Ayal
Differential Revision: https://reviews.llvm.org/D128657
If we are certainly not in a loop we can directly emit the heap2stack
allocas in the function entry block. This will help to get rid of them
(SROA) and avoid stacksave/restore intrinsics when the function is
inlined.
This transform is responsible for a long-standing miscompile
as discussed in issue #47012 (was bugzilla #47668).
There was a proposal to correct it in D88432, but that was
abandoned and there hasn't been any recent activity to fix
it AFAICT.
The original patch D45108 started with a constant-shift-only
restriction and only expanded during review, so I don't think
there's much risk of perf regression on the motivating code.
Add an emitter for the memrchr common extension and simplify the strrchr
call handler to use it. This enables transforming calls with the empty
string to the test C ? S : 0.
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D128954
LoopSimplify only requires that the loop predecessor has a single
successor and is safe to hoist into -- it doesn't necessarily have
to be an unconditional BranchInst.
Adjust LoopDeletion to assert conditions closer to what it actually
needs for correctness, namely a single successor and a
side-effect-free terminator (as the terminator is getting dropped).
Fixes https://github.com/llvm/llvm-project/issues/56266.
At the moment, the same VPlan can be used code generation of both the
main vector and epilogue vector loop. This can lead to wrong results, if
the plan is optimized based on the VF of the main vector loop and then
re-used for the epilogue loop.
One example where this is problematic is if the scalar loops need to
execute at least one iteration, e.g. due to interleave groups.
To prevent mis-compiles in the short-term, disable optimizing exit
conditions for VPlans when using epilogue vectorization. The proper fix
is to avoid re-using the same plan for both loops, which will require
support for cloning plans first.
Fixes#56319.
When converting strchr(p, '\0') to p + strlen(p) we know that
strlen() must return an offset that is inbounds of the allocated
object (otherwise it would be UB), so we can use an inbounds GEP.
An equivalent argument can be made for the other cases.
The moved helpers are only used for codegen. It will allow moving the
remaining ::execute implementations out of LoopVectorize.cpp.
Depends on D127966.
Depends on D127965.
Reviewed By: Ayal
Differential Revision: https://reviews.llvm.org/D127968
This is a minor refinement of resolvedUndefsIn(), mostly for clarity.
If the value of an instruction is undef, then that's already a legal
final result -- we can safely rauw such an instruction with undef.
We only need to mark unknown values as overdefined, as that's the
result we get for an instruction that has not been processed because
it has an undef operand.
Differential Revision: https://reviews.llvm.org/D128251
The unidentified objects recognized in `getUnderlyingObjects` may
still alias to the noalias parameter because `getUnderlyingObjects`
may not check deep enough to get the underlying object because of
`MaxLookup`. The real underlying object for the unidentified object
may still be the noalias parameter.
Originally Patched By: tingwang
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D127202
When merging GEP of GEP with constant indices, if the second GEP's offset is not divisible by the first GEP's element size, convert both type to i8* and merge.
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D125934
I looked at canonicalizing in the other direction, but that causes
many potential regressions and infinite loops because we already
(possibly wrongly) canonicalize "trunc X to i1" into an and+icmp.
This has a data layout restriction to avoid creating illegal
mask instructions, but we could remove that if we can show
that the backend can undo this when needed.
The motivating example from issue #56119 is modeled by the
PhaseOrdering test.
Correct a logic bug in the memrchr enhancement added in D123629 that
makes it ineffective in a subset of cases.
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D128856
Migrate all binops to use FoldXYZ rather than CreateXYZ APIs,
which are compatible with InstSimplifyFolder and fallible constant
folding.
Rather than continuing to add one method for every single operator,
add a generic FoldBinOp (plus variants for nowrap, exact and fmf
operators), which we would need anyway for CreateBinaryOp.
This change is not NFC because IRBuilder with InstSimplifyFolder
may perform more folding. However, this patch changes SCEVExpander
to not use the folder in InsertBinOp to minimize practical impact
and keep this change as close to NFC as possible.
This means we no longer need to have the same API between IRBuilder
and IRBuilderFolder.
The constant case is substantially simpler, so implementing it
separately isn't an undue burden.
Nowdays we have a generic constant folding API to load a type from
an offset. It should be able to do anything that VNCoercion can do.
This avoids the weird templating between IRBuilder and ConstantFolder
in one function, which is will stop working as the IRBuilderFolder
moves from CreateXYZ to FoldXYZ APIs.
Unfortunately, this doesn't eliminate this pattern from VNCoercion
entirely yet.
At the moment LoopVersioning is only created for inner-loop
vectorization. This patch moves it to LVP::execute, which means it will
also be added for epilogue vectorization. As a consequence, the proper
noalias metadata is now also added to epilogue vector loops.
LVer will be moved to VPTransformState as follow-up.
Reviewed By: Ayal
Differential Revision: https://reviews.llvm.org/D127966
The assert was added with 0399473de8 and is correct for that
pattern, but it is off-by-1 with the enhancement in d4f39d8333.
The transforms are still correct with the new pre-condition:
https://alive2.llvm.org/ce/z/6_6ghmhttps://alive2.llvm.org/ce/z/_GTBUt
And as shown in the new test, the transform is expected with
'ult' - in that case, the icmp reduces to test if the shift
amount is 0.
For instructions that don't need any special handling, use
ConstantFoldInstOperands(), rather than re-implementing individual
cases.
This is probably not NFC because it can handle cases the previous
code missed (e.g. vector operations).
Support compares in ConstantFoldInstOperands(), instead of
forcing the use of ConstantFoldCompareInstOperands(). Also handle
insertvalue (extractvalue was already handled).
This removes a footgun, where many uses of ConstantFoldInstOperands()
need a separate check for compares beforehand. It's particularly
insidious if called on a constant expression, because it doesn't
fail in that case, but will just not do DL-dependent folding.
In some cases, there may be widened users of inductions even though the
plan includes the scalar VF. In those cases, make sure we still replace
the VPWidenIntOrFpInductionRecipe with scalar steps, as otherwise we may
try to execute a VPWidenIntOrFpInductionRecipe with a scalar VF.
Alternatively the patch could also split the range if needed.
This fixes a crash exposed by D123720.
Reviewed By: Ayal
Differential Revision: https://reviews.llvm.org/D128755
Currently, we only remove dead blocks and non-feasible edges in
IPSCCP, but not in SCCP. I'm not aware of any strong reason for
that difference, so this patch updates SCCP to perform the CFG
cleanup as well.
Compile-time impact seems to be pretty minimal, in the 0.05%
geomean range on CTMark.
For the test case from https://reviews.llvm.org/D126962#3611579
the result after -sccp now looks like this:
define void @test(i1 %c) {
entry:
br i1 %c, label %unreachable, label %next
next:
unreachable
unreachable:
call void @bar()
unreachable
}
-jump-threading does nothing on this, but -simplifycfg will produce
the optimal result.
Differential Revision: https://reviews.llvm.org/D128796
enabled
The C++20 Coroutines couldn't be compiled to WebAssembly due to an
optimization named symmetric transfer requires the support for musttail
calls but WebAssembly doesn't support it yet.
This patch tries to fix the problem by adding a supportsTailCalls
method to TargetTransformImpl to skip the symmetric transfer when
tail-call feature is not supported.
Reviewed By: tlively
Differential Revision: https://reviews.llvm.org/D128794
ConnectProlog adds new incoming values to exit phi nodes which can
change the SCEV for the phi after 20d798bd47.
Fix is analog to cfc741bc0e.
Fixes#56286.
ConnectEpilog adds new incoming values to exit phi nodes which can
change the SCEV for the phi after 20d798bd47.
Fix is analog to cfc741bc0e.
Fixes#56282.
This code requires the result to be an UndefValue/ConstantInt
anyway (checked by getKnownConstant), so we are only interested
in the case where this folds.
AARGetter is an abstraction over a source of the `AAResults` introduced
to support the legacy pass manager as well as the modern one. Since the
Argument Promotion pass doesn't support the legacy pass manager anymore,
the abstraction is not required and `AAResults` may be used directly.
The instance of the `FunctionAnalysisManager` is passed through the
functions to get all the required analyses just wherever they are
required and do not use the awkward getter callbacks.
The `ReplaceCallSite` parameter was required for the legacy pass manager
only and isn't used anymore, so the parameter has been eliminated.
Differential Revision: https://reviews.llvm.org/D128727
The `isDenselyPacked` static member of the `ArgumentPromotionPass` class
is not used in the class itself anymore. The single known user of the
function is in the `AttributorAttributes.cpp` file, so the function has
been moved into the file.
Differential Revision: https://reviews.llvm.org/D128725
Extend the solution accepted in D127766 to strncmp and simplify
strncmp(A, B, N) calls with constant A and B and variable N to
the equivalent of
N <= Pos ? 0 : (A < B ? -1 : B < A ? +1 : 0)
where Pos is the offset of either the first mismatch between A
and B or the terminating null character if both A and B are equal
strings.
Reviewed By: courbet
Differential Revision: https://reviews.llvm.org/D128089
Enhance getConstantDataArrayInfo to let the memchr and memcmp library
call folders look through arbitrarily long sequences of bitcast and
GEP instructions.
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D128364
If the root order itself does not require reordering, we can just
remove its reorder mask safely (e.g., if the root node is a vector of
phis). But if this node is used as an operand in the graph, we cannot
delete the reordering, need to keep it. Otherwise the graph nodes are
not synchronized with the operands. It may cause an extra gather
instruction(s) or a compiler crash.
Also, need to be very careful when selecting the gather nodes for
reordering since there might several gather nodes with the same scalars
and we can try to reorder just the same node many times instead of
different nodes.
Differential Revision: https://reviews.llvm.org/D128680
This moves some code for getting PC and SP into their own functions. Since SP
is also retrieved in the prologue and getting the stack tag, we can cache the
SP if we get it once in the prologue. This caching will really only be relevant
in D128387 where StackBaseTag may not be set in the prologue if __hwasan_tls
is not used.
Differential Revision: https://reviews.llvm.org/D128551
It makes sense to handle byval promotion in the same way as non-byval
but also allowing `store` instructions. However, these should
use the same checks as the `load` instructions do, i.e. be part of the
`ArgsToPromote` collection. For these instructions, the check for
interfering modifications can be disabled, though. The promotion
algorithm itself has been modified a lot: all the accesses (i.e. loads
and stores) are rewritten to the emitted `alloca` instructions. To
optimize these new `alloca`s out, the `PromoteMemToReg` function from
`Transforms/Utils/PromoteMemoryToRegister.cpp` file is invoked after
promotion.
In order to let the `PromoteMemToReg` promote as many `alloca`s as it
is possible, there should be no `GEP`s from the `alloca`s. To
eliminate the `GEP`s, its own `alloca` is generated for every argument
part because a single `alloca` for the whole argument (that
significantly simplifies the code of the pass though) unfortunately
cannot be used.
The idea comes from the following discussion:
https://reviews.llvm.org/D124514#3479676
Differential Revision: https://reviews.llvm.org/D125485
This patch moves the code for recipe implementations to a separate file.
The benefits are:
* Keep VPlan.cpp smaller => faster compile-time during parallel builds.
* Keep code for logical units together
As a follow-up I am also planning on moving all ::execute
implemetnations from LoopVectorize.cpp over to the new file, which
should help to reduce the size of the file a bit.
Reviewed By: Ayal
Differential Revision: https://reviews.llvm.org/D127965
This removes the extractvalue constant expression, as part of
https://discourse.llvm.org/t/rfc-remove-most-constant-expressions/63179.
extractvalue is already not supported in bitcode, so we do not need
to worry about bitcode auto-upgrade.
Uses of ConstantExpr::getExtractValue() should be replaced with
IRBuilder::CreateExtractValue() (if the fact that the result is
constant is not important) or ConstantFoldExtractValueInstruction()
(if it is). Though for this particular case, it is also possible
and usually preferable to use getAggregateElement() instead.
The C API function LLVMConstExtractValue() is removed, as the
underlying constant expression no longer exists. Instead,
LLVMBuildExtractValue() should be used (which will constant fold
or create an instruction). Depending on the use-case,
LLVMGetAggregateElement() may also be used instead.
Differential Revision: https://reviews.llvm.org/D125795
`commonAlignment` is a shortcut to pick the smallest of two `Align`
objects. As-is it doesn't bring much value compared to `std::min`.
Differential Revision: https://reviews.llvm.org/D128345
This is the followup patch to https://reviews.llvm.org/D125246 for the `SampleContextTracker` part. Before the promotion and merging of the context is based on the SampleContext(the array of frame), this causes a lot of cost to the memory. This patch detaches the tracker from using the array ref instead to use the context trie itself. This can save a lot of memory usage and benefit both the compiler's CS inliner and llvm-profgen's pre-inliner.
One structure needs to be specially treated is the `FuncToCtxtProfiles`, this is used to get all the functionSamples for one function to do the merging and promoting. Before it search each functions' context and traverse the trie to get the node of the context. Now we don't have the context inside the profile, instead we directly use an auxiliary map `ProfileToNodeMap` for profile , it initialize to create the FunctionSamples to TrieNode relations and keep updating it during promoting and merging the node.
Moreover, I was expecting the results before and after remain the same, but I found that the order of FuncToCtxtProfiles matter and affect the results. This can happen on recursive context case, but the difference should be small. Now we don't have the context, so I just used a vector for the order, the result is still deterministic.
Measured on one huge size(12GB) profile from one of our internal service. The profile similarity difference is 99.999%, and the running time is improved by 3X(debug mode) and the memory is reduced from 170GB to 90GB.
Reviewed By: hoy, wenlei
Differential Revision: https://reviews.llvm.org/D127031
This is another attempt to land this patch.
The patch proposed to use a new cost model for loop interchange,
which is obtained from loop cache analysis.
Given a loopnest, what loop cache analysis returns is a vector of
loops [loop0, loop1, loop2, ...] where loop0 should be replaced as
the outermost loop, loop1 should be placed one more level inside, and
loop2 one more level inside, etc. What loop cache analysis does is not
only more comprehensive than the current cost model, it is also a "one-shot"
query which means that we only need to query it once during the entire
loop interchange pass, which is better than the current cost model where
we query it every time we check whether it is profitable to interchange
two loops. Thus complexity is reduced, especially after D120386 where we
do more interchanges to get the globally optimal loop access pattern.
Updates made to test cases are mostly minor changes and some
corrections. One change that applies to all tests is that we added an option
`-cache-line-size=64` to the RUN lines. This is ensure that loop
cache analysis receives a valid number of cache line size for correct
analysis. Test coverage for loop interchange is not reduced.
Currently we did not completely remove the legacy cost model, but
keep it as fall-back in case the new cost model did not run successfully.
This is because currently we have some limitations in delinearization, which
sometimes makes loop cache analysis bail out. The longer term goal is to
enhance delinearization and eventually remove the legacy cost model
compeletely.
Reviewed By: bmahjour, #loopoptwg
Differential Revision: https://reviews.llvm.org/D124926
Now that we have the sanitizer metadata that is actually on the global
variable, and now that we use debuginfo in order to do symbolization of
globals, we can delete the 'llvm.asan.globals' IR synthesis.
This patch deletes the 'location' part of the __asan_global that's
embedded in the binary as well, because it's unnecessary. This saves
about ~1.7% of the optimised non-debug with-asserts clang binary.
Reviewed By: vitalybuka
Differential Revision: https://reviews.llvm.org/D127911
This change is a bit subtle. If we have a type like <vscale x 1 x i64>, the vectorizer will currently reject vectorization. The reason is that a type like <1 x i64> is likely to get simply rescalarized, and the vectorizer doesn't want to be in the game of simple unrolling.
(I've given the example in terms of 1 x types which use a single register, but the same issue exists for any N x types which use N registers. e.g. RISCV LMULs.)
This change distinguishes scalable types from fixed types under the reasoning that converting to a scalable type isn't unrolling. Because the actual vscale isn't known until runtime, using a vscale type is potentially very profitable.
This makes an important, but unchecked, assumption. Specifically, the scalable type is assumed to only be legal per the cost model if there's actually a scalable register class which is distinct from the scalar domain. This is, to my knowledge, true for all targets which return non-invalid costs for scalable vector ops today, but in theory, we could have a target decide to lower scalable to fixed length vector or even scalar registers. If that ever happens, we'd need to revisit this code.
In practice, this patch unblocks scalable vectorization for ELEN types on RISCV.
Let me sketch one alternate implementation I considered. We could have restricted this to when we know a minimum value for vscale. Specifically, for the default +v extension for RISCV, we actually know that vscale >= 2 for ELEN types. However, doing it this way means we can't generate scalable vectors when using the various embedded vector extensions which have a minimum vscale of 1.
Differential Revision: https://reviews.llvm.org/D128542
Information in the function `Prologue Data` is intentionally opaque.
When a function with `Prologue Data` is duplicated. The self (global
value) references inside `Prologue Data` is still pointing to the
original function. This may cause errors like `fatal error: error in backend: Cannot represent a difference across sections`.
This patch detaches the information from function `Prologue Data`
and attaches it to a function metadata node.
This and D116130 fix https://github.com/llvm/llvm-project/issues/49689.
Reviewed By: pcc
Differential Revision: https://reviews.llvm.org/D115844
Summary:
Currently in OpenMPOpt we strip `noinline` attributes from runtime
functions. This is here because the device bitcode library that we link
has problems with needed definitions getting prematurely optimized out.
This is only necessary for OpenMP offloading to GPUs so we should narrow
the scope for where we spend time doing this. In the future this
shouldn't be necessary as we move to using a linked library rather than
pulling in a bitcode library in Clang.
The global ctor evaluator currently handles by checking whether the
memset memory is already zero, and skips it in that case. However,
it only actually checks the first byte of the memory being set.
This patch extends the code to check all bytes being set. This is
done byte-by-byte to avoid converting undef values to zeros in
larger reads. However, the handling is still not completely correct,
because there might still be padding bytes (though probably this
doesn't matter much in practice, as I'd expect global variable
padding to be zero-initialized in practice).
Mostly fixes https://github.com/llvm/llvm-project/issues/55859.
Differential Revision: https://reviews.llvm.org/D128532
These intrinsics are now fundemental for SVE code generation and have been
present for a year and a half, hence move them out of the experimental
namespace.
Differential Revision: https://reviews.llvm.org/D127976
Support for the legacy pass manager in ArgPromotion causes
complications in D125485. As the legacy pass manager for middle-end
optimizations is unsupported, drop ArgPromotion from the legacy
pipeline, rather than introducing additional complexity to deal
with it.
Differential Revision: https://reviews.llvm.org/D128536
Globals that shouldn't be sanitized are currently communicated to HWASan
through the use of the llvm.asan.globals IR metadata. Now that we have
an on-GV attribute, use it.
Reviewed By: pcc
Differential Revision: https://reviews.llvm.org/D127543
Improved/fixed cost modeling for shuffles by providing masks, improved
cost model for non-identity insertelements.
Differential Revision: https://reviews.llvm.org/D115462
This patch updates LV to generate runtime after the VF & IC are selected. It
allows deciding whether to vectorize with runtime checks or not based on
their cost compared to the vector loop.
It also updates VectorizationFactor to include the scalar cost.
Reviewed By: lebedev.ri, dmgreen
Differential Revision: https://reviews.llvm.org/D75981
Drop the requirement that getInitialValueOfAllocation() must be
passed an allocator function, shifting the responsibility for
checking that into the function (which it does anyway). The
motivation is to avoid some calls to isAllocationFn(), which has
somewhat ill-defined semantics (given the number of
allocator-related attributes we have floating around...)
(For this function, all we eventually need is an allockind of
zeroed or uninitialized.)
Differential Revision: https://reviews.llvm.org/D127274
This is the second attempt to land this patch.
The patch proposed to use a new cost model for loop interchange,
which is obtained from loop cache analysis.
Given a loopnest, what loop cache analysis returns is a vector of
loops [loop0, loop1, loop2, ...] where loop0 should be replaced as the
outermost loop, loop1 should be placed one more level inside, and loop2
one more level inside, etc. What loop cache analysis does is not only more
comprehensive than the current cost model, it is also a "one-shot" query
which means that we only need to query it once during the entire loop
interchange pass, which is better than the current cost model where we
query it every time we check whether it is profitable to interchange two
loops. Thus complexity is reduced, especially after D120386 where we do
more interchanges to get the globally optimal loop access pattern.
Updates made to test cases are mostly minor changes and some corrections.
One change that applies to all tests is that we added an option
`-cache-line-size=64` to the RUN lines. This is ensure that loop cache
analysis receives a valid number of cache line size for correct analysis.
Test coverage for loop interchange is not reduced.
Currently we did not completely remove the legacy cost model, but keep it
as fall-back in case the new cost model did not run successfully. This is
because currently we have some limitations in delinearization, which sometimes
makes loop cache analysis bail out. The longer term goal is to enhance
delinearization and eventually remove the legacy cost model compeletely.
Reviewed By: bmahjour, #loopoptwg
Differential Revision: https://reviews.llvm.org/D124926
If we have an unaligned uniform store, then when costing a scalable VF we can't emit code to scalarize it. (Well, we could, but we haven't implemented that case.) This change replaces an assert with a cost-model bailout such that we reject vectorization with the scalable VF instead of crashing.
If the masked gather nodes must be reordered, we can just reorder
scalars, just like for gather nodes. But if the node contains reused
scalars, it must be handled same way as a regular vectorizable node,
since need to reorder reused mask, not the scalars directly.
Differential Revision: https://reviews.llvm.org/D128360
If there are multiple constraints in the same block, at the moment the
order they are processed may be different depending on the sort
implementation.
Use stable_sort to ensure consistent ordering.
This reverts commit cac60940b7.
Caused -Os -fsanitize=memory -march=haswell miscompile to pytorch/cpuinfo.
See my latest comment (may update) on D115462.
Finding BDV for vector value does not handle freeze instruction.
Adding its handling as it is done for scalar case.
Reviewed By: apilipenko
Subscribers: llvm-commits
Differential Revision: https://reviews.llvm.org/D128254
The reachability queries default to "reachable" after exploring too many
basic blocks. LoopInfo helps it skip over the whole loop.
Reviewed By: eugenis
Differential Revision: https://reviews.llvm.org/D127917
StructurizeCFG linearizes the successors of branching basic block
by adding Flow blocks to record the true/false path for branches
and back edges. This patch reduces the number of Phi values needed
to capture the control flow path by improving the basic block
ordering.
Previously, StructurizeCFG adds loop exit blocks outside of the
loop. StructurizeCFG sets a boolean value to indicate the path
taken, and all exit block live values extend to after the loop.
For loops with a large number of exits blocks, this creates a
huge number of values that are maintained, which increases
compilation time and register pressure. This is problem
especially with ASAN, which adds early exits to blocks with
unreachable instructions for each instrumented check in the loop.
In specific cases, this patch reduces the number of values needed
after the loop by moving the exit block into the loop. This is
done for blocks that have a single predecessor and single successor
by moving the block to appear just after the predecessor.
Differential Revision: https://reviews.llvm.org/D123231
UnifyLoopExits creates a single exit, a control flow hub, for
loops with multiple exits. There is an input to the block for
each loop exiting block and an output from the block for each
loop exit block. Multiple checks, or guard blocks, are needed
to branch to the correct exit block.
For large loops with lots of exit blocks, all the extra guard
blocks cause problems for StructurizeCFG and subsequent passes.
This patch reduces the number of guard blocks needed when the
exit blocks branch to a common block (e.g., an unreachable
block). The guard blocks are reduced by changing the inputs
and outputs of the control flow hub. The inputs are the exit
blocks and the outputs are the common block.
Reducing the guard blocks enables StructurizeCFG to reorder the
basic blocks in the CFG to reduce the values that exit a loop
with multiple exits. This reduces the compile-time of
StructurizeCFG and also reduces register pressure.
Differential Revision: https://reviews.llvm.org/D123230
We were overly conservative and required a ret statement to be dominated
completely be a single lifetime.end marker. This is quite restrictive
and leads to two problems:
* limits coverage of use-after-scope, as we degenerate to
use-after-return;
* increases stack usage in programs, as we have to remove all lifetime
markers if we degenerate to use-after-return, which prevents
reuse of stack slots by the stack coloring algorithm.
Reviewed By: eugenis
Differential Revision: https://reviews.llvm.org/D127905
This was necessary for code reuse between the old and new passmanager.
With the old pass-manager gone, this is no longer necessary.
Reviewed By: eugenis, myhsu
Differential Revision: https://reviews.llvm.org/D127913
Binary size of `clang` is trivial; namely, numerical value doesn't
change when measured in MiB, and `.data` section increases from 139Ki to
173 Ki.
Differential Revision: https://reviews.llvm.org/D128070
Scale reg should never be zero, so when the quotient is zero, we
cannot assign it there. Limit this transform to avoid this situation.
Differential Revision: https://reviews.llvm.org/D128339
Reviewed By: eopXD
This patch adds a new transferToOtherSystem helper that tries to
transfer information from signed predicates to the unsigned system and
vice versa.
The initial version adds A >=u B for A >=s B && B >=s 0
https://alive2.llvm.org/ce/z/8b6F9i
As branch on undef is immediate undefined behavior, there is no need
to mark one of the edges as feasible. We can leave all the edges
non-feasible. In IPSCCP, we can replace the branch with an unreachable
terminator.
Differential Revision: https://reviews.llvm.org/D126962
The code has been reformatted in accordance with the code style. Some
function comments were extended to the Doxygen ones and reworded a bit
to eliminate the duplication of the function's/class' name in the
comment.
Differential Revision: https://reviews.llvm.org/D128168
NewGVN will find operator from other context. ValueTracking currently doesn't have a way to run completely without context instruction.
So it will use operator itself as conext instruction.
If the operator in another branch will never be executed but it has an assume, it may caused value tracking use the assume to do wrong simpilfy.
It would be better to make these simplification queries not use context at all, but that would require some API changes.
For now we just use the orignial instruction as context instruction to fix the issue.
Fix#56039
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D127942
createInductionResumeValues creates a phi node placeholder
without filling incoming values. Then it generates the incoming values.
It includes triggering of SCEV expander which may invoke SSAUpdater.
SSAUpdater has an optimization to detect number of predecessors
basing on incoming values if there is phi node.
In case phi node is not filled with incoming values - the number of predecessors
is detected as 0 and this leads to segmentation fault.
In other words SSAUpdater expects that phi is in good shape while
LoopVectorizer breaks this requirement.
The fix is just prepare all incoming values first and then build a phi node.
Reviewed By: fhahn
Subscribers: llvm-commits
Differential Revision: https://reviews.llvm.org/D128033
This avoid creating empty bins in AAPointerInfo which can lead to
segfaults. Also ensure we do not try to translate from callee to caller
except if we really take the argument state and move it to the call site
argument state.
Fixes: https://github.com/llvm/llvm-project/issues/55726
When determining liveness via Attributor::isAssumedDead(...) we might
end up without a liveness AA or with one pointing into another function.
Neither is helpful and we will avoid both from now on.
Reapplied after fixing the ASAN error which caused the revert:
db68a25ca9
During the reordering transformation we should try to avoid reordering bundles
like fadd,fsub because this may block them being matched into a single vector
instruction in x86.
We do this by checking if a TreeEntry is such a pattern and adding it to the
list of TreeEntries with orders that need to be considered.
Differential Revision: https://reviews.llvm.org/D125712
In some cases, a recurrence splice instructions needs to be inserted
between to regions, for example if the regions get re-arranged during
sinking.
Fixes#56146.
For non-mem-intrinsic and non-lifetime `CallBase`s, the current
`isRemovable` function only checks if the `CallBase` 1. has no uses 2.
will return 3. does not throw:
80fb782336/llvm/lib/Transforms/Scalar/DeadStoreElimination.cpp (L1017)
But we should also exclude invokes even in case they don't throw,
because they are terminators and thus cannot be removed. While it
doesn't seem to make much sense for `invoke`s to have an `nounwind`
target, this kind of code can be generated and is also valid bitcode.
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D128224
Remove the known limitation of the library function call folders to only
work with top-level arrays of characters (as per the TODO comment in
the code) and allows them to also fold calls involving subobjects of
constant aggregates such as member arrays.
ExtractElement does not produce a vector out of a vector, so there's no need to
call a gather once done.
Fix#54469
Credits to npopov@redhat.com for the original approach.
Differential Revision: https://reviews.llvm.org/D126012
If the OffsetBeg + InsertVecSz is greater than VecSz, need to estimate
the cost as shuffle of 2 vector, not as insert of subvector. Otherwise,
the inserted subvector is out of range and compiler may crash.
Differential Revision: https://reviews.llvm.org/D128071
Nikita Popov