This reverts commit 2e43acfed8.
LLVMCoroutines (the library which contains Coroutines.h) depends on LLVMipo (the
library which contains SampleProfile.cpp). It is inappropriate for
SampleProfile.cpp to depent on Coroutines.h (circular dependency).
The test inverted dependencies as well:
llvm/test/Transforms/Coroutines/coro-inline.ll uses -sample-profile.
summary:
When callee coroutine function is inlined into caller coroutine
function before coro-split pass, llvm will emits "coroutine should
have exactly one defining @llvm.coro.begin". It seems that coro-early
pass can not handle this quiet well.
So we believe that unsplited coroutine function should not be inlined.
This patch fix such issue by not inlining function if it has attribute
"coroutine.presplit" (it means the function has not been splited) to
fix this issue
TestPlan: check-llvm
Reviewed By: wenlei
Differential Revision: https://reviews.llvm.org/D85812
Summary:
If we ever assign co_await to a temporary variable, such as foo(co_await expr),
we generate AST that looks like this: MaterializedTemporaryExpr(CoawaitExpr(...)).
MaterializedTemporaryExpr would emit an intrinsics that marks the lifetime start of the
temporary storage. However such temporary storage will not be used until co_await is ready
to write the result. Marking the lifetime start way too early causes extra storage to be
put in the coroutine frame instead of the stack.
As you can see from https://godbolt.org/z/zVx_eB, the frame generated for get_big_object2 is 12K, which contains a big_object object unnecessarily.
After this patch, the frame size for get_big_object2 is now only 8K. There are still room for improvements, in particular, GCC has a 4K frame for this function. But that's a separate problem and not addressed in this patch.
The basic idea of this patch is during CoroSplit, look for every local variable in the coroutine created through AllocaInst, identify all the lifetime start/end markers and the use of the variables, and sink the lifetime.start maker to the places as close to the first-ever use as possible.
Reviewers: lewissbaker, modocache, junparser
Reviewed By: junparser
Subscribers: hiraditya, llvm-commits, rsmith, ChuanqiXu, cfe-commits
Tags: #clang, #llvm
Differential Revision: https://reviews.llvm.org/D82314
Summary:
For retcon and retcon.once coroutines we assume that all uses of spills
can be sunk past coro.begin. This simplifies handling of instructions
that escape the address of an alloca.
The current implementation would have issues if the address of the
alloca is escaped before coro.begin. (It also has issues with casts before and
uses of those casts after the coro.begin instruction)
%alloca_addr = alloca ...
%escape = ptrtoint %alloca_addr
coro.begin
store %escape to %alloca_addr
rdar://60272809
Subscribers: hiraditya, modocache, mgrang, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D81023
Previously, we would ignore alloca alignment when building the frame
and just use the natural alignment of the allocated type. If an alloca
is over-aligned for its IR type, this could lead to a frame entry with
inadequate alignment for the downstream uses of the alloca.
Since highly-aligned fields also tend to produce poor layouts under a
naive layout algorithm, I've also switched coroutine frames to use the
new optimal struct layout algorithm.
In order to communicate the frame size and alignment to later passes,
I needed to set align+dereferenceable attributes on the frame-pointer
parameter of the resume function. This is clearly the right thing to
do, but the align attribute currently seems to result in assumptions
being added during inlining that the optimizer cannot easily remove.
coroutine frame
Currently we move all allocas into the frame when build coroutine frame in
CoroSplit pass. However, this can be relaxed.
Since CoroSplit pass run after Inline pass, we can use lifetime intrinsic to
do such analysis: If the scope of lifetime intrinsic is not across any suspend
point, rather than move the allocas to frame, we can just move them to entry bb
of corresponding function. This reduce the frame size.
More importantly, this also avoid data race in multithread environment.
Consider one inline function by coroutine: it starts a thread which access
local variables, while after inline the movement of allocs to frame also access
them. cause data race.
Differential Revision: https://reviews.llvm.org/D75664
For now, when final suspend can be simplified by simplifySuspendPoint,
handleFinalSuspend is executed as well to remove last case in switch
instruction. This patch fixes it.
Differential Revision: https://reviews.llvm.org/D76345
Summary:
https://gist.github.com/modocache/ed7c62f6e570766c0f39b35dad675c2f
is an example of a small C++ program that uses C++20 coroutines that
is difficult to debug, due to the loss of debug info for variables that
"spill" across coroutine suspension boundaries. This patch addresses
that issue by inserting 'llvm.dbg.declare' intrinsics that point the
debugger to the variables' location at an offset to the coroutine frame.
With this patch, I confirmed that running the 'frame variable' commands in
https://gist.github.com/modocache/ed7c62f6e570766c0f39b35dad675c2f at
the specified breakpoints results in the correct values being printed
for coroutine frame variables 'i' and 'j' when using an lldb built from
trunk, as well as with gdb 8.3 (lldb 9.0.1, however, could not print the
values). The added test case also verifies this improved behavior.
The existing coro-debug.ll test case is also modified to reflect the
locations at which Clang actually places calls to 'dbg.declare', and
additional checks are added to ensure this patch works as intended in that
example as well.
Reviewers: vsk, jmorse, GorNishanov, lewissbaker, wenlei
Subscribers: EricWF, aprantl, hiraditya, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D75338
Summary:
Depends on https://reviews.llvm.org/D71901.
The fifth in a series of patches that ports the LLVM coroutines passes
to the new pass manager infrastructure.
The first 4 patches allow users to run coroutine passes by invoking, for
example `opt -passes=coro-early`. However, most of LLVM's tests for
coroutines use an option, `opt -enable-coroutines`, which adds all 4
coroutine passes to the appropriate legacy pass manager extension points.
This patch does the same, but using the new pass manager: when
coroutine features are enabled and the new pass manager is being used,
this adds the new-pass-manager-compliant coroutine passes to the pass
builder's pipeline.
This allows us to run all coroutine tests using the new pass manager
(besides those that use the coroutine retcon ABI used by the Swift
compiler, which is not yet supported in the new pass manager).
Reviewers: GorNishanov, lewissbaker, chandlerc, junparser, wenlei
Subscribers: wenlei, EricWF, Prazek, hiraditya, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D71902
Summary:
Depends on https://reviews.llvm.org/D71900.
The fourth in a series of patches that ports the LLVM coroutines passes
to the new pass manager infrastructure. This patch implements
'coro-cleanup'.
No existing regression tests check the behavior of coro-cleanup on its
own, so this patch adds one. (A test named 'coro-cleanup.ll' exists, but
it relies on the entire coroutines pipeline being run. It's updated to
test the new pass manager in the 5th patch of this series.)
Reviewers: GorNishanov, lewissbaker, chandlerc, junparser, deadalnix, wenlei
Reviewed By: wenlei
Subscribers: wenlei, EricWF, hiraditya, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D71901
Summary:
Depends on https://reviews.llvm.org/D71899.
The third in a series of patches that ports the LLVM coroutines passes
to the new pass manager infrastructure. This patch implements 'coro-elide'.
The new pass manager infrastructure does not implicitly repeat CGSCC
pass pipelines when a function is devirtualized, and so the tests
for the new pass manager that rely on that behavior now explicitly
specify `repeat<2>`.
Reviewers: GorNishanov, lewissbaker, chandlerc, jdoerfert, junparser, deadalnix, wenlei
Reviewed By: wenlei
Subscribers: wenlei, EricWF, Prazek, hiraditya, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D71900
Summary:
This patch has four dependencies:
1. The first in this series of patches that implement coroutine passes in the
new pass manager: https://reviews.llvm.org/D71898.
2. A patch that introduces an API for CGSCC passes to add new reference
edges to a `LazyCallGraph`, `updateCGAndAnalysisManagerForCGSCCPass`:
https://reviews.llvm.org/D72025.
3. A patch that introduces a `CallGraphUpdater` helper class that is
capable of mutating internal `LazyCallGraph` state in order to insert
new function nodes into a specific SCC: https://reviews.llvm.org/D70927.
4. And finally, a small edge case fix for updating `LazyCallGraph` that
patch 3 above happens to run into: https://reviews.llvm.org/D72226.
This is the second in a series of patches that ports the LLVM coroutines
passes to the new pass manager infrastructure. This patch implements
'coro-split'.
Some notes:
* Using the new CGSCC pass manager resulted in IR being printed in the
reverse order in some tests. To prevent FileCheck checks from failing due
to these reversed orders, this patch splits up test files that test
multiple different coroutine functions: specifically
coro-alloc-with-param.ll, coro-split-eh.ll, and coro-eh-aware-edge-split.ll.
* CoroSplit.cpp contained 2 overloads of `splitCoroutine`, one of which
dispatched to the other based on the coroutine ABI being used (C++20
switch-based versus Swift returned-continuation-based). I found this
confusing, especially with the additional branching based on `CallGraph`
vs. `LazyCallGraph`, so I removed the ABI-checking overload of
`splitCoroutine`.
Reviewers: GorNishanov, lewissbaker, chandlerc, jdoerfert, junparser, deadalnix, wenlei
Reviewed By: wenlei
Subscribers: wenlei, qcolombet, EricWF, hiraditya, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D71899
Summary:
The first in a series of patches that ports the LLVM coroutines passes
to the new pass manager infrastructure. This patch implements
'coro-early'.
NB: All coroutines passes begin by checking that coroutine intrinsics are
declared within the LLVM IR module they're operating on. To do so, they call
`coro::declaresIntrinsics`. The next 3 patches in this series, which add new
pass manager implementations of the 'coro-split', 'coro-elide', and
'coro-cleanup' passes, use a similar pattern as the one used here: a static
function is shared across both old and new passes to detect if relevant
coroutine intrinsics are delcared. To make this pattern easier to read, this
patch adds `const` keywords to the parameters of `coro::declaresIntrinsics`.
Reviewers: GorNishanov, lewissbaker, junparser, chandlerc, deadalnix, wenlei
Reviewed By: wenlei
Subscribers: ychen, wenlei, EricWF, hiraditya, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D71898
Summary:
In addMustTailToCoroResumes, we set musttail on those resume instructions that are followed by a ret instruction. This is done by simplifyTerminatorLeadingToRet which replace a sequence of branches leading to a ret with a clone of the ret.
However it forgets to remove corresponding PHI values that come from basic block of replaced branch, and may cause jumpthreading pass hangs (https://bugs.llvm.org/show_bug.cgi?id=43720)
This patch fix this issue
Test Plan:
cppcoro library with O3+flto
check-llvm
Reviewers: modocache, GorNishanov, lewissbaker
Reviewed By: modocache
Subscribers: mehdi_amini, EricWF, hiraditya, dexonsmith, jfb, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D71826
Patch by junparser (JunMa)!
If the pointer was loaded/stored before the null check, the check
is redundant and can be removed. For now the optimizers do not
remove the nullptr check, see https://gcc.godbolt.org/z/H2r5GG.
The patch allows to use more nonnull constraints. Also, it found
one more optimization in some PowerPC test. This is my first llvm
review, I am free to any comments.
Differential Revision: https://reviews.llvm.org/D71177
Summary:
Fixes https://bugs.llvm.org/show_bug.cgi?id=36578 and https://bugs.llvm.org/show_bug.cgi?id=36296.
Supersedes: https://reviews.llvm.org/D55966
One of the fundamental transformation that CoroSplit pass performs before splitting the coroutine is to find which values need to survive between suspend and resume and provide a slot for them in the coroutine frame to spill and restore the value as needed.
Coroutine frame becomes available once the storage for it was allocated and that point is marked in the pre-split coroutine with a llvm.coro.begin intrinsic.
FE normally puts all of the user-authored code that would be accessing those values after llvm.coro.begin, however, sometimes instructions accessing those values would end up prior to coro.begin. For example, writing out a value of the parameter into the alloca done by the FE or instructions that are added by the optimization passes such as SROA when it rewrites allocas.
Prior to this change, CoroSplit pass would try to move instructions that may end up accessing the values in the coroutine frame after CoroBegin. However it would run into problems (report_fatal_error) if some of the values would be used both in the allocation function (for example allocator is passed as a parameter to a coroutine) and in the use-authored body of the coroutine.
To handle this case and to simplify the instruction moving logic, this change removes all of the instruction moving. Instead, we only change the uses of the spilled values that are dominated by coro.begin and leave other instructions intact.
Before:
```
%var = alloca i32
%1 = getelementptr .. %var; ; will move this one after coro.begin
%f = call i8* @llvm.coro.begin(
```
After:
```
%var = alloca i32
%1 = getelementptr .. %var; stays put
%f = call i8* @llvm.coro.begin(
```
If we discover that there is a potential write into an alloca, prior to coro.begin we would copy its value from the alloca into the spill slot in the coroutine frame.
Before:
```
%var = alloca i32
store .. %var ; will move this one after coro.begin
%f = call i8* @llvm.coro.begin(
```
After:
```
%var = alloca i32
store .. %var ;stays put
%f = call i8* @llvm.coro.begin(
%tmp = load %var
store %tmp, %spill.slot.for.var
```
Note: This change does not handle array allocas as that is something that C++ FE does not produce, but, it can be added in the future if need arises
Reviewers: llvm-commits, modocache, ben-clayton, tks2103, rjmccall
Reviewed By: modocache
Subscribers: bartdesmet
Differential Revision: https://reviews.llvm.org/D66230
llvm-svn: 368949
The support for swifterror allocas should work in all lowerings.
The support for swifterror arguments only really works in a lowering
with prototypes where you can ensure that the prototype also has a
swifterror argument; I'm not really sure how it could possibly be
made to work in the switch lowering.
llvm-svn: 368795
A quick contrast of this ABI with the currently-implemented ABI:
- Allocation is implicitly managed by the lowering passes, which is fine
for frontends that are fine with assuming that allocation cannot fail.
This assumption is necessary to implement dynamic allocas anyway.
- The lowering attempts to fit the coroutine frame into an opaque,
statically-sized buffer before falling back on allocation; the same
buffer must be provided to every resume point. A buffer must be at
least pointer-sized.
- The resume and destroy functions have been combined; the continuation
function takes a parameter indicating whether it has succeeded.
- Conversely, every suspend point begins its own continuation function.
- The continuation function pointer is directly returned to the caller
instead of being stored in the frame. The continuation can therefore
directly destroy the frame when exiting the coroutine instead of having
to leave it in a defunct state.
- Other values can be returned directly to the caller instead of going
through a promise allocation. The frontend provides a "prototype"
function declaration from which the type, calling convention, and
attributes of the continuation functions are taken.
- On the caller side, the frontend can generate natural IR that directly
uses the continuation functions as long as it prevents IPO with the
coroutine until lowering has happened. In combination with the point
above, the frontend is almost totally in charge of the ABI of the
coroutine.
- Unique-yield coroutines are given some special treatment.
llvm-svn: 368788
For consistency with normal instructions and clarity when reading IR,
it's best to print the %0, %1, ... names of function arguments in
definitions.
Also modifies the parser to accept IR in that form for obvious reasons.
llvm-svn: 367755
Summary:
CoroFrame was not considering static array allocas, and was only ever reserving a single element in the coroutine frame.
This meant that stores to the non-zero'th element would corrupt later frame data.
Store static array allocas as field arrays in the coroutine frame.
Added test.
Committed by Gor Nishanov on behalf of ben-clayton
Reviewers: GorNishanov, modocache
Reviewed By: GorNishanov
Subscribers: Orlando, capn, EricWF, llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D61372
llvm-svn: 360636
As it's causing some bot failures (and per request from kbarton).
This reverts commit r358543/ab70da07286e618016e78247e4a24fcb84077fda.
llvm-svn: 358546
Summary:
Depends on https://reviews.llvm.org/D59069.
https://bugs.llvm.org/show_bug.cgi?id=40979 describes a bug in which the
-coro-split pass would assert that a use was across a suspend point from
a definition. Normally this would mean that a value would "spill" across
a suspend point and thus need to be stored in the coroutine frame. However,
in this case the use was unreachable, and so it would not be necessary
to store the definition on the frame.
To prevent the assert, simply remove unreachable basic blocks from a
coroutine function before computing spills. This avoids the assert
reported in PR40979.
Reviewers: GorNishanov, tks2103
Reviewed By: GorNishanov
Subscribers: EricWF, jdoerfert, llvm-commits, lewissbaker
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D59068
llvm-svn: 355852
compiler identification lines in test-cases.
(Doing so only because it's then easier to search for references which
are actually important and need fixing.)
llvm-svn: 351200
Summary:
Enable suspend point simplification for cases where:
* coro.save and coro.suspend are in different basic blocks
* where there are intervening intrinsics
Reviewers: modocache, tks2103, lewissbaker
Reviewed By: modocache
Subscribers: EricWF, llvm-commits
Differential Revision: https://reviews.llvm.org/D55160
llvm-svn: 348897
Summary:
https://bugs.llvm.org/show_bug.cgi?id=34897 demonstrates an incorrect
coroutine frame allocation elision in the coro-elide pass. The elision
is performed on the basis that the SSA variables from all llvm.coro.begin
are directly referenced in subsequent llvm.coro.destroy instructions.
However, this ignores the fact that the function may exit through paths
that do not run these destroy instructions. In the sample program from
PR34897, for example, the llvm.coro.destroy instruction is only
executed in exception handling code. When the coroutine function exits
normally, llvm.coro.destroy is not called. Eliding the allocation in
this case causes a subsequent reference to the coroutine handle from
outside of the function to access freed memory.
To fix the issue, when finding an llvm.coro.destroy for each llvm.coro.begin,
only consider llvm.coro.destroy that are executed along non-exceptional paths.
Test Plan:
1. Download the sample program from
https://bugs.llvm.org/show_bug.cgi?id=34897, compile it with
`clang++ -fcoroutines-ts -stdlib=libc++ -std=c++1z -O2`, and run it.
It should print `"run1\ncheck1\nrun2\ncheck2"` and then exit
successfully.
2. Compile https://godbolt.org/g/mCKfnr and confirm it is still
optimized to a single instruction, 'return 1190'.
3. `check-llvm`
Reviewers: rsmith, GorNishanov, eric_niebler
Reviewed By: GorNishanov
Subscribers: andrewrk, lewissbaker, EricWF, llvm-commits
Differential Revision: https://reviews.llvm.org/D43242
llvm-svn: 332077
In order to set breakpoints on labels and list source code around
labels, we need collect debug information for labels, i.e., label
name, the function label belong, line number in the file, and the
address label located. In order to keep these information in LLVM
IR and to allow backend to generate debug information correctly.
We create a new kind of metadata for labels, DILabel. The format
of DILabel is
!DILabel(scope: !1, name: "foo", file: !2, line: 3)
We hope to keep debug information as much as possible even the
code is optimized. So, we create a new kind of intrinsic for label
metadata to avoid the metadata is eliminated with basic block.
The intrinsic will keep existing if we keep it from optimized out.
The format of the intrinsic is
llvm.dbg.label(metadata !1)
It has only one argument, that is the DILabel metadata. The
intrinsic will follow the label immediately. Backend could get the
label metadata through the intrinsic's parameter.
We also create DIBuilder API for labels to be used by Frontend.
Frontend could use createLabel() to allocate DILabel objects, and use
insertLabel() to insert llvm.dbg.label intrinsic in LLVM IR.
Differential Revision: https://reviews.llvm.org/D45024
Patch by Hsiangkai Wang.
llvm-svn: 331841
Summary:
If an alloca need to be stored in the coroutine frame and it has an alignment specified and the alignment does not match the natural alignment of the alloca type. Insert appropriate padding into the coroutine frame to make sure that it gets requested alignment.
For example for a packet type (which natural alignment is 1), but alloca alignment is 8, we may need to insert a padding field with required number of bytes to make sure it is properly aligned.
```
%PackedStruct = type <{ i64 }>
...
%data = alloca %PackedStruct, align 8
```
If the previous field in the coroutine frame had alignment 2, we would have [6 x i8] inserted before %PackedStruct in the coroutine frame:
```
%f.Frame = type { ..., i16, [6 x i8], %PackedStruct }
```
Reviewers: rnk, lewissbaker, modocache
Reviewed By: modocache
Subscribers: EricWF, llvm-commits
Differential Revision: https://reviews.llvm.org/D45221
llvm-svn: 329112
Summary:
When attempting to split a coroutine with 'hidden' visibility (for
example, a C++ coroutine that is inlined when compiled with the option
'-fvisibility-inlines-hidden'), LLVM would hit an assertion in
include/llvm/IR/GlobalValue.h:240: "local linkage requires default
visibility". The issue is that the visibility is copied from the source
of the function split in the `CloneFunctionInto` function, but the linkage
is not. To fix, create the new function first with external linkage,
then copy the linkage from the original function *after* `CloneFunctionInto`
is called.
Since `GlobalValue::setLinkage` in turn calls `maybeSetDsoLocal`, the
explicit call to `setDSOLocal` can be removed in CoroSplit.cpp.
Test Plan: check-llvm
Reviewers: GorNishanov, lewissbaker, EricWF, majnemer, rnk
Reviewed By: rnk
Subscribers: llvm-commits, eric_niebler
Differential Revision: https://reviews.llvm.org/D44185
llvm-svn: 329033
Summary:
A recent addition to Coroutines TS (https://wg21.link/p0913) adds a pre-defined coroutine noop_coroutine that does nothing.
To implement this feature, we implemented an llvm.coro.noop intrinsic that returns a coroutine handle to a coroutine that does nothing when resumed or destroyed.
Reviewers: EricWF, modocache, rnk, lewissbaker
Reviewed By: modocache
Subscribers: llvm-commits
Differential Revision: https://reviews.llvm.org/D45114
llvm-svn: 328986
Summary:
The behavior described in Coroutines TS `[dcl.fct.def.coroutine]/7`
allows coroutine parameters to be passed into allocator functions.
The instructions to store values into the alloca'd parameters must not
be moved past the frame allocation, otherwise uninitialized values are
passed to the allocator.
Test Plan: `check-llvm`
Reviewers: rsmith, GorNishanov, eric_niebler
Reviewed By: GorNishanov
Subscribers: compnerd, EricWF, llvm-commits
Differential Revision: https://reviews.llvm.org/D43000
llvm-svn: 325285