For some reason we limited the epilogue VF to be fixed-width, but there
is not necessarily a reason for doing so. If the main VF=vscale x 16, the
epilogue VF could be either fixed-width, or a scalable VF upto vscale x 8.
Reviewed By: david-arm
Differential Revision: https://reviews.llvm.org/D118688
The code paths analyzed (all constructor invocations of fusion
candidate) pass in a non-null DT.
Adding this assert as requested in D118472 before converting this to a
reference argument.
Cleanup code in peelLoop API. We already have usage of DT without guarding
against a null DT, so this change constant folds the remaining null DT
checks.
Also make the argument a reference so that it is clear the argument is
a nonnull DT.
Extracted from D118472.
setjmp can return twice, but PostDominatorTree is unaware of this. as
such, it overestimates postdominance, leaving some cases (see attached
compiler-rt) where memory does not get untagged on return. this causes
false positives later in the program execution.
this is a crude workaround to unblock use-after-scope for now, in the
longer term PostDominatorTree should bemade aware of returns_twice
function, as this may cause problems elsewhere.
Reviewed By: eugenis
Differential Revision: https://reviews.llvm.org/D118647
We have an instCombine rule to remove identical consecutive fences.
We can extend this to remove weaker fences when we have consecutive stronger
fence.
As stated in the LangRef, a fence with a stronger ordering also implies
ordering weaker than itself: "A fence which has seq_cst ordering, in addition to
having both acquire and release semantics specified above, participates in the
global program order of other seq_cst operations and/or fences."
Reviewed-By: reames
Differential Revision: https://reviews.llvm.org/D118607
Generalize D99629 for ELF. A default visibility non-local symbol is preemptible
in a -shared link. `isInterposable` is an insufficient condition.
Moreover, a non-preemptible alias may be referenced in a sub constant expression
which intends to lower to a PC-relative relocation. Replacing the alias with a
preemptible aliasee may introduce a linker error.
Respect dso_preemptable and suppress optimization to fix the abose issues. With
the change, `alias = 345` will not be rewritten to use aliasee in a `-fpic`
compile.
```
int aliasee;
extern int alias __attribute__((alias("aliasee"), visibility("hidden")));
void foo() { alias = 345; } // intended to access the local copy
```
While here, refine the condition for the alias as well.
For some binary formats like COFF, `isInterposable` is a sufficient condition.
But I think canonicalization for the changed case has little advantage, so I
don't bother to add the `Triple(M.getTargetTriple()).isOSBinFormatELF()` or
`getPICLevel/getPIELevel` complexity.
For instrumentations, it's recommended not to create aliases that refer to
globals that have a weak linkage or is preemptible. However, the following is
supported and the IR needs to handle such cases.
```
int aliasee __attribute__((weak));
extern int alias __attribute__((alias("aliasee")));
```
There are other places where GlobalAlias isInterposable usage may need to be
fixed.
Reviewed By: rnk
Differential Revision: https://reviews.llvm.org/D107249
Added support for alternate ops vectorization of the cmp instructions.
It allows to vectorize either cmp instructions with same/swapped
predicate but different (swapped) operands kinds or cmp instructions
with different predicates and compatible operands kinds.
Differential Revision: https://reviews.llvm.org/D115955
We tracked down some non-determinism in compilation output to the
DFAJumpThreading pass. These changes fixed our issue:
* Make the DefMap type a MapVector to make its iteration order depend on
insertion order.
* Sort the values to be inserted into NewDefs by instruction order to
make the insertion order deterministic. Since these values come from
iterating over a ValueMap, which doesn't have deterministic iteration
order, I couldn't fix this at its source.
Reviewed By: alexey.zhikhar
Differential Revision: https://reviews.llvm.org/D118590
Constant expressions with a non-pointer result type used an early
exit that bypassed the later dead constant user check, and resulted
in different optimization outcomes depending on whether dead users
were present or not.
This fixes the issue reported in https://reviews.llvm.org/D117223#3287039.
This removes another instance of recipe execution still relying on
the cost model.
Depends on D116554.
Reviewed By: david-arm
Differential Revision: https://reviews.llvm.org/D116656
In some cases StructurizeCFG inserts i1 xor instructions to invert
predicates. Add a quick loop to clean these up afterwards if we can get
away with modifying an existing compare instruction instead.
(StructurizeCFG is generally run late in the pipeline so instcombine
does not clean them up for us.)
Differential Revision: https://reviews.llvm.org/D118623
A call base can be a floating value if we talk about the instruction and
not the return value. This distinction was not made before but is
important for liveness, e.g., a call site return value might be unused
(=dead) but the call site is not.
To make usage easier (compared to the many reachability related AAs),
this patch introduces a helper API, `AA::isPotentiallyReachable`, which
performs all the necessary steps. It also does the "backwards"
reachability (see D106720) as that simplifies the AA a lot (backwards
queries were somewhat different from the other query resolvers), and
ensures we use cached values in every stage.
To test inter-procedural reachability in a reasonable way this patch
includes an extension to `AAPointerInfo::forallInterferingWrites`.
Basically, we can exclude writes if they cannot reach a load "during the
lifetime" of the allocation. That is, we need to go up the call graph to
determine reachability until we can determine the allocation would be
dead in the caller. This leads to new constant propagations (through
memory) in `value-simplify-pointer-info-gpu.ll`.
Note: The new code contains plenty debug output to determine how
reachability queries are resolved.
Parts extracted from D110078.
Differential Revision: https://reviews.llvm.org/D118673
D106720 introduced features that did not work properly as we could add
new queries after a fixpoint was reached and which could not be answered
by the information gathered up to the fixpoint alone.
As an alternative to D110078, which forced eager computation where we
want to continue to be lazy, this patch fixes the problem.
QueryAAs are AAs that allow lazy queries during their lifetime. They are
never fixed if they have no outstanding dependences and always run as
part of the updates in an iteration. To determine if we are done, all
query AAs are asked if they received new queries, if not, we only need
to consider updated AAs, as before. If new queries are present we go for
another iteration.
Differential Revision: https://reviews.llvm.org/D118669
This patch implement instruction reachability for AAFunctionReachability
attribute. It is used to tell if a certain instruction can reach a function
transitively.
NOTE: I created a new commit based of D106720 and set the author back to
Kuter. Other metadata, etc. is wrong. I also addressed the
remaining review comments and fixed the unit test.
Differential Revision: https://reviews.llvm.org/D106720
We missed out on AANoRecurse in the module pass because we had no call
graph. With AAFunctionReachability we can simply ask if the function may
reach itself.
Differential Revision: https://reviews.llvm.org/D110099
genericValueTraversal can look through arguments and allow value
simplification across function boundaries. In fact, the latter already
happened unchecked. With this change we allow the user of
genericValueTraversal to opt-out of interprocedural traversal if
required. We explicitly look through arguments now which helps to do
various things, incl. the propagation of constants into OpenMP parallel
regions (on the host).
This fixes a conceptual problem with our AAIsDead usage which conflated
call site liveness with call site return value liveness. Without the
fix tests would obviously miscompile as we make genericValueTraversal
more powerful (in a follow up). The effects on the tests are mixed but
mostly marginal. The most prominent one is the lack of `noreturn` for
functions. The reason is that we make entire blocks live at the same
time (for time reasons). Now that we actually look at the block
liveness, which we need to do, the return instructions are live and
will survive. As an example, `noreturn_async.ll` has been modified
to retain the `noreturn` even with block granularity. We could address
this easily but there is little need in practice.
We have two attributes that can answer readnone queries. While there is
a dependence between them, it seems best to not force the users to know
what AA to ask. The helpers also allow to check for readonly nicely.
Test changes show where we now deduce readnone but haven't before,
mostly because we only asked AAMemoryBehavior and not AAMemoryLocation.
AANoAlias has not been ported to the new API yet.
Since D104432 we can look through memory by analyzing all writes that
might interfere with a load. This patch provides some logic to exclude
writes that cannot interfere with a location, due to CFG reasoning.
We make sure to avoid multi-thread write-read situations properly while
we ignore writes that cannot reach a load or writes that will be
overwritten before the load is reached.
Differential Revision: https://reviews.llvm.org/D106397
No-sync is a property that we need in more places as complex
transformations emerge. To simplify the query we provide an
`AA::isNoSyncInst` helper now and expose two existing helpers through
the `AANoSync` class.
Patch originally by Giorgis Georgakoudis (@ggeorgakoudis), typos and
bugs introduced later by me.
This patch allows us to remove redundant barriers if they are part
of a "consecutive" pair of barriers in a basic block with no impacted
memory effect (read or write) in-between them. Memory accesses to
local (=thread private) or constant memory are allowed to appear.
Technically we could also allow any other memory that is not used to
share information between threads, e.g., the result of a malloc that
is also not captured. However, it will be easier to do more reasoning
once the code is put into an AA. That will also allow us to look through
phis/selects reasonably. At that point we should also deal with calls,
barriers in different blocks, and other complexities.
Differential Revision: https://reviews.llvm.org/D118002
We used to remove noinline from known OpenMP runtime functions (which
are declared in OMPKinds.td). Now we remove noinline from all functions
with the proper prefixes: __kmpc, _ZN4_OMP (= namespace omp), omp_
PointerToBase is a mapping between potentially derived pointer to its base.
As soon as we are in SSA form if there is a base of derived pointer and it
is available at def of derived pointer, the same base will be available at any
point where derived pointer is alive.
So the mapping of derived pointer to base pointer is not a property
of a call site but the same on function level.
Reviewers: reames, yrouban
Reviewed By: reames
Subscribers: llvm-commits
Differential Revision: https://reviews.llvm.org/D118604
D116542 adds EmbedBufferInModule which introduces a layer violation
(https://llvm.org/docs/CodingStandards.html#library-layering).
See 2d5f857a1eaf5f7a806d12953c79b96ed8952da8 for detail.
EmbedBufferInModule does not use BitcodeWriter functionality and should be moved
LLVMTransformsUtils. While here, change the function case to the prevailing
convention.
It seems that EmbedBufferInModule just follows the steps of
EmbedBitcodeInModule. EmbedBitcodeInModule calls WriteBitcodeToFile but has IR
update operations which ideally should be refactored to another library.
Reviewed By: jhuber6
Differential Revision: https://reviews.llvm.org/D118666
When upgrading a loop of load/store to a memcpy, the existing pass does not keep existing aliasing information. This patch allows existing aliasing information to be kept.
Reviewed By: jeroen.dobbelaere
Differential Revision: https://reviews.llvm.org/D108221
Added support for alternate ops vectorization of the cmp instructions.
It allows to vectorize either cmp instructions with same/swapped
predicate but different (swapped) operands kinds or cmp instructions
with different predicates and compatible operands kinds.
Differential Revision: https://reviews.llvm.org/D115955
This reverts commit a6b54ddaba2d5dc0f72dcc4591c92b9544eb0016.
Apparently it is not safe to modify the condition even if it passes the
hasOneUse test, because StructurizeCFG might have other references to
the condition that are not manifest in the IR use-def chains.
This avoids various cases where StructurizeCFG would otherwise insert an
xor i1 instruction, and it since it generally runs late in the pipeline,
instcombine does not clean up the xor-of-cmp pattern.
Differential Revision: https://reviews.llvm.org/D118478
The pruning cloner already tries to remove unreachable blocks. The
original cloning process will simplify instructions and constant
terminators, and only clone blocks that are reachable at that point.
However, phi nodes can only be simplified after everything has been
cloned. For that reason, additional blocks may become unreachable
after phi simplification.
The code does try to handle this as well, but only removes blocks
that don't have predecessors. It misses unreachable cycles. This
can cause issues if SEH exception handling code is part of an
unreachable cycle, as the inliner is not prepared to deal with that.
This patch instead performs an explicit scan for reachable blocks,
and drops everything else.
Fixes https://github.com/llvm/llvm-project/issues/53206.
Differential Revision: https://reviews.llvm.org/D118449
Following Sanjay's proposal from discussion in D118317, this patch
generalizes and-reduce handling to fold the following pattern
```
icmp ne (bitcast(icmp ne (lhs, rhs)), 0)
```
into
```
icmp ne (bitcast(lhs), bitcast(rhs))
```
https://alive2.llvm.org/ce/z/WDcuJ_
Differential Revision: https://reviews.llvm.org/D118431
Reviewed By: lebedev.ri
Before this change, InstCombine was willing to fold atomic and
non-atomic loads through a PHI node as long as the first PHI argument
is not an atomic load. The combined load would be non-atomic, which is
incorrect.
Fix this by only combining the loads in a PHI node when all of the
arguments are non-atomic loads.
Thanks to Eli Friedman for pointing out the bug at
https://github.com/llvm/llvm-project/issues/50777#issuecomment-981045342!
Fixes#50777
Differential Revision: https://reviews.llvm.org/D115113
Uppercase some variable names, per LLVM coding standards. This change
intentionally does not rename every miscased variable, as a follow-up
change ( D116086 ) intends to eliminate many of those by switching
loops to range for loops.
Differential Revision: https://reviews.llvm.org/D118553
This removes the remaining dependence on LoopVectorizationCostModel from
buildScalarSteps and is required so it can be moved out of ILV.
It also improves allows us to remove a few unneeded instructions.
Reviewed By: Ayal
Differential Revision: https://reviews.llvm.org/D116554
gep(x, undef) carries the provenance of x, so we can't replace it with any
pointer like undef.
This leaves room for improvement for the poison case, but that's currently
not possible as the demanded bits API doesn't distinguish between undef &
poison bits.
Fixes#44790
phi([undef, A], [x, B]) -> x is only correct x is guaranteed to be
a non-poison value.
Otherwise we would be changing an undef to poison in the branch A.
Differential Revision: https://reviews.llvm.org/D117907
This patch tries to use an existing VPWidenCanonicalIVRecipe
instead of creating another step-vector for canonical
induction recipes in widenIntOrFpInduction.
This has the following benefits:
1. First step to avoid setting both vector and scalar values for the
same induction def.
2. Reducing complexity of widenIntOrFpInduction through making things
more explicit in VPlan
3. Only need to splat the vector IV for block in masks.
Reviewed By: Ayal
Differential Revision: https://reviews.llvm.org/D116123