Files
clang-p2996/mlir/lib/Pass/Pass.cpp
River Riddle d7eba20052 [mlir][Inliner] Refactor the inliner to use nested pass pipelines instead of just canonicalization
Now that passes have support for running nested pipelines, the inliner can now allow for users to provide proper nested pipelines to use for optimization during inlining. This revision also changes the behavior of optimization during inlining to optimize before attempting to inline, which should lead to a more accurate cost model and prevents the need for users to schedule additional duplicate cleanup passes before/after the inliner that would already be run during inlining.

Differential Revision: https://reviews.llvm.org/D91211
2020-12-14 18:09:47 -08:00

1001 lines
37 KiB
C++

//===- Pass.cpp - Pass infrastructure implementation ----------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file implements common pass infrastructure.
//
//===----------------------------------------------------------------------===//
#include "mlir/Pass/Pass.h"
#include "PassDetail.h"
#include "mlir/IR/Diagnostics.h"
#include "mlir/IR/Dialect.h"
#include "mlir/IR/Verifier.h"
#include "mlir/Support/FileUtilities.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/ScopeExit.h"
#include "llvm/ADT/SetVector.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/CrashRecoveryContext.h"
#include "llvm/Support/Mutex.h"
#include "llvm/Support/Parallel.h"
#include "llvm/Support/Signals.h"
#include "llvm/Support/Threading.h"
#include "llvm/Support/ToolOutputFile.h"
using namespace mlir;
using namespace mlir::detail;
//===----------------------------------------------------------------------===//
// Pass
//===----------------------------------------------------------------------===//
/// Out of line virtual method to ensure vtables and metadata are emitted to a
/// single .o file.
void Pass::anchor() {}
/// Attempt to initialize the options of this pass from the given string.
LogicalResult Pass::initializeOptions(StringRef options) {
return passOptions.parseFromString(options);
}
/// Copy the option values from 'other', which is another instance of this
/// pass.
void Pass::copyOptionValuesFrom(const Pass *other) {
passOptions.copyOptionValuesFrom(other->passOptions);
}
/// Prints out the pass in the textual representation of pipelines. If this is
/// an adaptor pass, print with the op_name(sub_pass,...) format.
void Pass::printAsTextualPipeline(raw_ostream &os) {
// Special case for adaptors to use the 'op_name(sub_passes)' format.
if (auto *adaptor = dyn_cast<OpToOpPassAdaptor>(this)) {
llvm::interleaveComma(adaptor->getPassManagers(), os,
[&](OpPassManager &pm) {
os << pm.getOpName() << "(";
pm.printAsTextualPipeline(os);
os << ")";
});
return;
}
// Otherwise, print the pass argument followed by its options. If the pass
// doesn't have an argument, print the name of the pass to give some indicator
// of what pass was run.
StringRef argument = getArgument();
if (!argument.empty())
os << argument;
else
os << "unknown<" << getName() << ">";
passOptions.print(os);
}
//===----------------------------------------------------------------------===//
// OpPassManagerImpl
//===----------------------------------------------------------------------===//
namespace mlir {
namespace detail {
struct OpPassManagerImpl {
OpPassManagerImpl(Identifier identifier, OpPassManager::Nesting nesting)
: name(identifier.str()), identifier(identifier), nesting(nesting) {}
OpPassManagerImpl(StringRef name, OpPassManager::Nesting nesting)
: name(name), nesting(nesting) {}
/// Merge the passes of this pass manager into the one provided.
void mergeInto(OpPassManagerImpl &rhs);
/// Nest a new operation pass manager for the given operation kind under this
/// pass manager.
OpPassManager &nest(Identifier nestedName);
OpPassManager &nest(StringRef nestedName);
/// Add the given pass to this pass manager. If this pass has a concrete
/// operation type, it must be the same type as this pass manager.
void addPass(std::unique_ptr<Pass> pass);
/// Coalesce adjacent AdaptorPasses into one large adaptor. This runs
/// recursively through the pipeline graph.
void coalesceAdjacentAdaptorPasses();
/// Split all of AdaptorPasses such that each adaptor only contains one leaf
/// pass.
void splitAdaptorPasses();
Identifier getOpName(MLIRContext &context) {
if (!identifier)
identifier = Identifier::get(name, &context);
return *identifier;
}
/// The name of the operation that passes of this pass manager operate on.
std::string name;
/// The cached identifier (internalized in the context) for the name of the
/// operation that passes of this pass manager operate on.
Optional<Identifier> identifier;
/// The set of passes to run as part of this pass manager.
std::vector<std::unique_ptr<Pass>> passes;
/// Control the implicit nesting of passes that mismatch the name set for this
/// OpPassManager.
OpPassManager::Nesting nesting;
};
} // end namespace detail
} // end namespace mlir
void OpPassManagerImpl::mergeInto(OpPassManagerImpl &rhs) {
assert(name == rhs.name && "merging unrelated pass managers");
for (auto &pass : passes)
rhs.passes.push_back(std::move(pass));
passes.clear();
}
OpPassManager &OpPassManagerImpl::nest(Identifier nestedName) {
OpPassManager nested(nestedName, nesting);
auto *adaptor = new OpToOpPassAdaptor(std::move(nested));
addPass(std::unique_ptr<Pass>(adaptor));
return adaptor->getPassManagers().front();
}
OpPassManager &OpPassManagerImpl::nest(StringRef nestedName) {
OpPassManager nested(nestedName, nesting);
auto *adaptor = new OpToOpPassAdaptor(std::move(nested));
addPass(std::unique_ptr<Pass>(adaptor));
return adaptor->getPassManagers().front();
}
void OpPassManagerImpl::addPass(std::unique_ptr<Pass> pass) {
// If this pass runs on a different operation than this pass manager, then
// implicitly nest a pass manager for this operation if enabled.
auto passOpName = pass->getOpName();
if (passOpName && passOpName->str() != name) {
if (nesting == OpPassManager::Nesting::Implicit)
return nest(*passOpName).addPass(std::move(pass));
llvm::report_fatal_error(llvm::Twine("Can't add pass '") + pass->getName() +
"' restricted to '" + *passOpName +
"' on a PassManager intended to run on '" + name +
"', did you intend to nest?");
}
passes.emplace_back(std::move(pass));
}
void OpPassManagerImpl::coalesceAdjacentAdaptorPasses() {
// Bail out early if there are no adaptor passes.
if (llvm::none_of(passes, [](std::unique_ptr<Pass> &pass) {
return isa<OpToOpPassAdaptor>(pass.get());
}))
return;
// Walk the pass list and merge adjacent adaptors.
OpToOpPassAdaptor *lastAdaptor = nullptr;
for (auto it = passes.begin(), e = passes.end(); it != e; ++it) {
// Check to see if this pass is an adaptor.
if (auto *currentAdaptor = dyn_cast<OpToOpPassAdaptor>(it->get())) {
// If it is the first adaptor in a possible chain, remember it and
// continue.
if (!lastAdaptor) {
lastAdaptor = currentAdaptor;
continue;
}
// Otherwise, merge into the existing adaptor and delete the current one.
currentAdaptor->mergeInto(*lastAdaptor);
it->reset();
} else if (lastAdaptor) {
// If this pass is not an adaptor, then coalesce and forget any existing
// adaptor.
for (auto &pm : lastAdaptor->getPassManagers())
pm.getImpl().coalesceAdjacentAdaptorPasses();
lastAdaptor = nullptr;
}
}
// If there was an adaptor at the end of the manager, coalesce it as well.
if (lastAdaptor) {
for (auto &pm : lastAdaptor->getPassManagers())
pm.getImpl().coalesceAdjacentAdaptorPasses();
}
// Now that the adaptors have been merged, erase the empty slot corresponding
// to the merged adaptors that were nulled-out in the loop above.
llvm::erase_if(passes, std::logical_not<std::unique_ptr<Pass>>());
}
void OpPassManagerImpl::splitAdaptorPasses() {
std::vector<std::unique_ptr<Pass>> oldPasses;
std::swap(passes, oldPasses);
for (std::unique_ptr<Pass> &pass : oldPasses) {
// If this pass isn't an adaptor, move it directly to the new pass list.
auto *currentAdaptor = dyn_cast<OpToOpPassAdaptor>(pass.get());
if (!currentAdaptor) {
addPass(std::move(pass));
continue;
}
// Otherwise, split the adaptors of each manager within the adaptor.
for (OpPassManager &adaptorPM : currentAdaptor->getPassManagers()) {
adaptorPM.getImpl().splitAdaptorPasses();
for (std::unique_ptr<Pass> &nestedPass : adaptorPM.getImpl().passes)
nest(adaptorPM.getOpName()).addPass(std::move(nestedPass));
}
}
}
//===----------------------------------------------------------------------===//
// OpPassManager
//===----------------------------------------------------------------------===//
OpPassManager::OpPassManager(Identifier name, Nesting nesting)
: impl(new OpPassManagerImpl(name, nesting)) {}
OpPassManager::OpPassManager(StringRef name, Nesting nesting)
: impl(new OpPassManagerImpl(name, nesting)) {}
OpPassManager::OpPassManager(OpPassManager &&rhs) : impl(std::move(rhs.impl)) {}
OpPassManager::OpPassManager(const OpPassManager &rhs) { *this = rhs; }
OpPassManager &OpPassManager::operator=(const OpPassManager &rhs) {
impl.reset(new OpPassManagerImpl(rhs.impl->name, rhs.impl->nesting));
for (auto &pass : rhs.impl->passes)
impl->passes.emplace_back(pass->clone());
return *this;
}
OpPassManager::~OpPassManager() {}
OpPassManager::pass_iterator OpPassManager::begin() {
return MutableArrayRef<std::unique_ptr<Pass>>{impl->passes}.begin();
}
OpPassManager::pass_iterator OpPassManager::end() {
return MutableArrayRef<std::unique_ptr<Pass>>{impl->passes}.end();
}
OpPassManager::const_pass_iterator OpPassManager::begin() const {
return ArrayRef<std::unique_ptr<Pass>>{impl->passes}.begin();
}
OpPassManager::const_pass_iterator OpPassManager::end() const {
return ArrayRef<std::unique_ptr<Pass>>{impl->passes}.end();
}
/// Nest a new operation pass manager for the given operation kind under this
/// pass manager.
OpPassManager &OpPassManager::nest(Identifier nestedName) {
return impl->nest(nestedName);
}
OpPassManager &OpPassManager::nest(StringRef nestedName) {
return impl->nest(nestedName);
}
/// Add the given pass to this pass manager. If this pass has a concrete
/// operation type, it must be the same type as this pass manager.
void OpPassManager::addPass(std::unique_ptr<Pass> pass) {
impl->addPass(std::move(pass));
}
/// Returns the number of passes held by this manager.
size_t OpPassManager::size() const { return impl->passes.size(); }
/// Returns the internal implementation instance.
OpPassManagerImpl &OpPassManager::getImpl() { return *impl; }
/// Return the operation name that this pass manager operates on.
StringRef OpPassManager::getOpName() const { return impl->name; }
/// Return the operation name that this pass manager operates on.
Identifier OpPassManager::getOpName(MLIRContext &context) const {
return impl->getOpName(context);
}
/// Prints out the given passes as the textual representation of a pipeline.
static void printAsTextualPipeline(ArrayRef<std::unique_ptr<Pass>> passes,
raw_ostream &os) {
llvm::interleaveComma(passes, os, [&](const std::unique_ptr<Pass> &pass) {
pass->printAsTextualPipeline(os);
});
}
/// Prints out the passes of the pass manager as the textual representation
/// of pipelines.
void OpPassManager::printAsTextualPipeline(raw_ostream &os) {
::printAsTextualPipeline(impl->passes, os);
}
void OpPassManager::dump() {
llvm::errs() << "Pass Manager with " << impl->passes.size() << " passes: ";
::printAsTextualPipeline(impl->passes, llvm::errs());
llvm::errs() << "\n";
}
static void registerDialectsForPipeline(const OpPassManager &pm,
DialectRegistry &dialects) {
for (const Pass &pass : pm.getPasses())
pass.getDependentDialects(dialects);
}
void OpPassManager::getDependentDialects(DialectRegistry &dialects) const {
registerDialectsForPipeline(*this, dialects);
}
OpPassManager::Nesting OpPassManager::getNesting() { return impl->nesting; }
void OpPassManager::setNesting(Nesting nesting) { impl->nesting = nesting; }
//===----------------------------------------------------------------------===//
// OpToOpPassAdaptor
//===----------------------------------------------------------------------===//
LogicalResult OpToOpPassAdaptor::run(Pass *pass, Operation *op,
AnalysisManager am, bool verifyPasses) {
if (!op->getName().getAbstractOperation())
return op->emitOpError()
<< "trying to schedule a pass on an unregistered operation";
if (!op->getName().getAbstractOperation()->hasProperty(
OperationProperty::IsolatedFromAbove))
return op->emitOpError() << "trying to schedule a pass on an operation not "
"marked as 'IsolatedFromAbove'";
// Initialize the pass state with a callback for the pass to dynamically
// execute a pipeline on the currently visited operation.
PassInstrumentor *pi = am.getPassInstrumentor();
PassInstrumentation::PipelineParentInfo parentInfo = {llvm::get_threadid(),
pass};
auto dynamic_pipeline_callback = [&](OpPassManager &pipeline,
Operation *root) -> LogicalResult {
if (!op->isAncestor(root))
return root->emitOpError()
<< "Trying to schedule a dynamic pipeline on an "
"operation that isn't "
"nested under the current operation the pass is processing";
assert(pipeline.getOpName() == root->getName().getStringRef());
AnalysisManager nestedAm = root == op ? am : am.nest(root);
return OpToOpPassAdaptor::runPipeline(pipeline.getPasses(), root, nestedAm,
verifyPasses, pi, &parentInfo);
};
pass->passState.emplace(op, am, dynamic_pipeline_callback);
// Instrument before the pass has run.
if (pi)
pi->runBeforePass(pass, op);
// Invoke the virtual runOnOperation method.
if (auto *adaptor = dyn_cast<OpToOpPassAdaptor>(pass))
adaptor->runOnOperation(verifyPasses);
else
pass->runOnOperation();
bool passFailed = pass->passState->irAndPassFailed.getInt();
// Invalidate any non preserved analyses.
am.invalidate(pass->passState->preservedAnalyses);
// Run the verifier if this pass didn't fail already.
if (!passFailed && verifyPasses)
passFailed = failed(verify(op));
// Instrument after the pass has run.
if (pi) {
if (passFailed)
pi->runAfterPassFailed(pass, op);
else
pi->runAfterPass(pass, op);
}
// Return if the pass signaled a failure.
return failure(passFailed);
}
/// Run the given operation and analysis manager on a provided op pass manager.
LogicalResult OpToOpPassAdaptor::runPipeline(
iterator_range<OpPassManager::pass_iterator> passes, Operation *op,
AnalysisManager am, bool verifyPasses, PassInstrumentor *instrumentor,
const PassInstrumentation::PipelineParentInfo *parentInfo) {
assert((!instrumentor || parentInfo) &&
"expected parent info if instrumentor is provided");
auto scope_exit = llvm::make_scope_exit([&] {
// Clear out any computed operation analyses. These analyses won't be used
// any more in this pipeline, and this helps reduce the current working set
// of memory. If preserving these analyses becomes important in the future
// we can re-evaluate this.
am.clear();
});
// Run the pipeline over the provided operation.
if (instrumentor)
instrumentor->runBeforePipeline(op->getName().getIdentifier(), *parentInfo);
for (Pass &pass : passes)
if (failed(run(&pass, op, am, verifyPasses)))
return failure();
if (instrumentor)
instrumentor->runAfterPipeline(op->getName().getIdentifier(), *parentInfo);
return success();
}
/// Find an operation pass manager that can operate on an operation of the given
/// type, or nullptr if one does not exist.
static OpPassManager *findPassManagerFor(MutableArrayRef<OpPassManager> mgrs,
StringRef name) {
auto it = llvm::find_if(
mgrs, [&](OpPassManager &mgr) { return mgr.getOpName() == name; });
return it == mgrs.end() ? nullptr : &*it;
}
/// Find an operation pass manager that can operate on an operation of the given
/// type, or nullptr if one does not exist.
static OpPassManager *findPassManagerFor(MutableArrayRef<OpPassManager> mgrs,
Identifier name,
MLIRContext &context) {
auto it = llvm::find_if(
mgrs, [&](OpPassManager &mgr) { return mgr.getOpName(context) == name; });
return it == mgrs.end() ? nullptr : &*it;
}
OpToOpPassAdaptor::OpToOpPassAdaptor(OpPassManager &&mgr) {
mgrs.emplace_back(std::move(mgr));
}
void OpToOpPassAdaptor::getDependentDialects(DialectRegistry &dialects) const {
for (auto &pm : mgrs)
pm.getDependentDialects(dialects);
}
/// Merge the current pass adaptor into given 'rhs'.
void OpToOpPassAdaptor::mergeInto(OpToOpPassAdaptor &rhs) {
for (auto &pm : mgrs) {
// If an existing pass manager exists, then merge the given pass manager
// into it.
if (auto *existingPM = findPassManagerFor(rhs.mgrs, pm.getOpName())) {
pm.getImpl().mergeInto(existingPM->getImpl());
} else {
// Otherwise, add the given pass manager to the list.
rhs.mgrs.emplace_back(std::move(pm));
}
}
mgrs.clear();
// After coalescing, sort the pass managers within rhs by name.
llvm::array_pod_sort(rhs.mgrs.begin(), rhs.mgrs.end(),
[](const OpPassManager *lhs, const OpPassManager *rhs) {
return lhs->getOpName().compare(rhs->getOpName());
});
}
/// Returns the adaptor pass name.
std::string OpToOpPassAdaptor::getAdaptorName() {
std::string name = "Pipeline Collection : [";
llvm::raw_string_ostream os(name);
llvm::interleaveComma(getPassManagers(), os, [&](OpPassManager &pm) {
os << '\'' << pm.getOpName() << '\'';
});
os << ']';
return os.str();
}
void OpToOpPassAdaptor::runOnOperation() {
llvm_unreachable(
"Unexpected call to Pass::runOnOperation() on OpToOpPassAdaptor");
}
/// Run the held pipeline over all nested operations.
void OpToOpPassAdaptor::runOnOperation(bool verifyPasses) {
if (getContext().isMultithreadingEnabled())
runOnOperationAsyncImpl(verifyPasses);
else
runOnOperationImpl(verifyPasses);
}
/// Run this pass adaptor synchronously.
void OpToOpPassAdaptor::runOnOperationImpl(bool verifyPasses) {
auto am = getAnalysisManager();
PassInstrumentation::PipelineParentInfo parentInfo = {llvm::get_threadid(),
this};
auto *instrumentor = am.getPassInstrumentor();
for (auto &region : getOperation()->getRegions()) {
for (auto &block : region) {
for (auto &op : block) {
auto *mgr = findPassManagerFor(mgrs, op.getName().getIdentifier(),
*op.getContext());
if (!mgr)
continue;
// Run the held pipeline over the current operation.
if (failed(runPipeline(mgr->getPasses(), &op, am.nest(&op),
verifyPasses, instrumentor, &parentInfo)))
return signalPassFailure();
}
}
}
}
/// Utility functor that checks if the two ranges of pass managers have a size
/// mismatch.
static bool hasSizeMismatch(ArrayRef<OpPassManager> lhs,
ArrayRef<OpPassManager> rhs) {
return lhs.size() != rhs.size() ||
llvm::any_of(llvm::seq<size_t>(0, lhs.size()),
[&](size_t i) { return lhs[i].size() != rhs[i].size(); });
}
/// Run this pass adaptor synchronously.
void OpToOpPassAdaptor::runOnOperationAsyncImpl(bool verifyPasses) {
AnalysisManager am = getAnalysisManager();
// Create the async executors if they haven't been created, or if the main
// pipeline has changed.
if (asyncExecutors.empty() || hasSizeMismatch(asyncExecutors.front(), mgrs))
asyncExecutors.assign(llvm::hardware_concurrency().compute_thread_count(),
mgrs);
// Run a prepass over the operation to collect the nested operations to
// execute over. This ensures that an analysis manager exists for each
// operation, as well as providing a queue of operations to execute over.
std::vector<std::pair<Operation *, AnalysisManager>> opAMPairs;
for (auto &region : getOperation()->getRegions()) {
for (auto &block : region) {
for (auto &op : block) {
// Add this operation iff the name matches any of the pass managers.
if (findPassManagerFor(mgrs, op.getName().getIdentifier(),
getContext()))
opAMPairs.emplace_back(&op, am.nest(&op));
}
}
}
// A parallel diagnostic handler that provides deterministic diagnostic
// ordering.
ParallelDiagnosticHandler diagHandler(&getContext());
// An index for the current operation/analysis manager pair.
std::atomic<unsigned> opIt(0);
// Get the current thread for this adaptor.
PassInstrumentation::PipelineParentInfo parentInfo = {llvm::get_threadid(),
this};
auto *instrumentor = am.getPassInstrumentor();
// An atomic failure variable for the async executors.
std::atomic<bool> passFailed(false);
llvm::parallelForEach(
asyncExecutors.begin(),
std::next(asyncExecutors.begin(),
std::min(asyncExecutors.size(), opAMPairs.size())),
[&](MutableArrayRef<OpPassManager> pms) {
for (auto e = opAMPairs.size(); !passFailed && opIt < e;) {
// Get the next available operation index.
unsigned nextID = opIt++;
if (nextID >= e)
break;
// Set the order id for this thread in the diagnostic handler.
diagHandler.setOrderIDForThread(nextID);
// Get the pass manager for this operation and execute it.
auto &it = opAMPairs[nextID];
auto *pm = findPassManagerFor(
pms, it.first->getName().getIdentifier(), getContext());
assert(pm && "expected valid pass manager for operation");
LogicalResult pipelineResult =
runPipeline(pm->getPasses(), it.first, it.second, verifyPasses,
instrumentor, &parentInfo);
// Drop this thread from being tracked by the diagnostic handler.
// After this task has finished, the thread may be used outside of
// this pass manager context meaning that we don't want to track
// diagnostics from it anymore.
diagHandler.eraseOrderIDForThread();
// Handle a failed pipeline result.
if (failed(pipelineResult)) {
passFailed = true;
break;
}
}
});
// Signal a failure if any of the executors failed.
if (passFailed)
signalPassFailure();
}
//===----------------------------------------------------------------------===//
// PassCrashReproducer
//===----------------------------------------------------------------------===//
namespace {
/// This class contains all of the context for generating a recovery reproducer.
/// Each recovery context is registered globally to allow for generating
/// reproducers when a signal is raised, such as a segfault.
struct RecoveryReproducerContext {
RecoveryReproducerContext(MutableArrayRef<std::unique_ptr<Pass>> passes,
Operation *op, StringRef filename,
bool disableThreads, bool verifyPasses);
~RecoveryReproducerContext();
/// Generate a reproducer with the current context.
LogicalResult generate(std::string &error);
private:
/// This function is invoked in the event of a crash.
static void crashHandler(void *);
/// Register a signal handler to run in the event of a crash.
static void registerSignalHandler();
/// The textual description of the currently executing pipeline.
std::string pipeline;
/// The MLIR operation representing the IR before the crash.
Operation *preCrashOperation;
/// The filename to use when generating the reproducer.
StringRef filename;
/// Various pass manager and context flags.
bool disableThreads;
bool verifyPasses;
/// The current set of active reproducer contexts. This is used in the event
/// of a crash. This is not thread_local as the pass manager may produce any
/// number of child threads. This uses a set to allow for multiple MLIR pass
/// managers to be running at the same time.
static llvm::ManagedStatic<llvm::sys::SmartMutex<true>> reproducerMutex;
static llvm::ManagedStatic<
llvm::SmallSetVector<RecoveryReproducerContext *, 1>>
reproducerSet;
};
} // end anonymous namespace
llvm::ManagedStatic<llvm::sys::SmartMutex<true>>
RecoveryReproducerContext::reproducerMutex;
llvm::ManagedStatic<llvm::SmallSetVector<RecoveryReproducerContext *, 1>>
RecoveryReproducerContext::reproducerSet;
RecoveryReproducerContext::RecoveryReproducerContext(
MutableArrayRef<std::unique_ptr<Pass>> passes, Operation *op,
StringRef filename, bool disableThreads, bool verifyPasses)
: preCrashOperation(op->clone()), filename(filename),
disableThreads(disableThreads), verifyPasses(verifyPasses) {
// Grab the textual pipeline being executed..
{
llvm::raw_string_ostream pipelineOS(pipeline);
::printAsTextualPipeline(passes, pipelineOS);
}
// Make sure that the handler is registered, and update the current context.
llvm::sys::SmartScopedLock<true> producerLock(*reproducerMutex);
if (reproducerSet->empty())
llvm::CrashRecoveryContext::Enable();
registerSignalHandler();
reproducerSet->insert(this);
}
RecoveryReproducerContext::~RecoveryReproducerContext() {
// Erase the cloned preCrash IR that we cached.
preCrashOperation->erase();
llvm::sys::SmartScopedLock<true> producerLock(*reproducerMutex);
reproducerSet->remove(this);
if (reproducerSet->empty())
llvm::CrashRecoveryContext::Disable();
}
LogicalResult RecoveryReproducerContext::generate(std::string &error) {
std::unique_ptr<llvm::ToolOutputFile> outputFile =
mlir::openOutputFile(filename, &error);
if (!outputFile)
return failure();
auto &outputOS = outputFile->os();
// Output the current pass manager configuration.
outputOS << "// configuration: -pass-pipeline='" << pipeline << "'";
if (disableThreads)
outputOS << " -mlir-disable-threading";
// TODO: Should this also be configured with a pass manager flag?
outputOS << "\n// note: verifyPasses=" << (verifyPasses ? "true" : "false")
<< "\n";
// Output the .mlir module.
preCrashOperation->print(outputOS);
outputFile->keep();
return success();
}
void RecoveryReproducerContext::crashHandler(void *) {
// Walk the current stack of contexts and generate a reproducer for each one.
// We can't know for certain which one was the cause, so we need to generate
// a reproducer for all of them.
std::string ignored;
for (RecoveryReproducerContext *context : *reproducerSet)
context->generate(ignored);
}
void RecoveryReproducerContext::registerSignalHandler() {
// Ensure that the handler is only registered once.
static bool registered =
(llvm::sys::AddSignalHandler(crashHandler, nullptr), false);
(void)registered;
}
/// Run the pass manager with crash recover enabled.
LogicalResult PassManager::runWithCrashRecovery(Operation *op,
AnalysisManager am) {
// If this isn't a local producer, run all of the passes in recovery mode.
if (!localReproducer)
return runWithCrashRecovery(impl->passes, op, am);
// Split the passes within adaptors to ensure that each pass can be run in
// isolation.
impl->splitAdaptorPasses();
// If this is a local producer, run each of the passes individually.
MutableArrayRef<std::unique_ptr<Pass>> passes = impl->passes;
for (std::unique_ptr<Pass> &pass : passes)
if (failed(runWithCrashRecovery(pass, op, am)))
return failure();
return success();
}
/// Run the given passes with crash recover enabled.
LogicalResult
PassManager::runWithCrashRecovery(MutableArrayRef<std::unique_ptr<Pass>> passes,
Operation *op, AnalysisManager am) {
RecoveryReproducerContext context(passes, op, *crashReproducerFileName,
!getContext()->isMultithreadingEnabled(),
verifyPasses);
// Safely invoke the passes within a recovery context.
LogicalResult passManagerResult = failure();
llvm::CrashRecoveryContext recoveryContext;
recoveryContext.RunSafelyOnThread([&] {
for (std::unique_ptr<Pass> &pass : passes)
if (failed(OpToOpPassAdaptor::run(pass.get(), op, am, verifyPasses)))
return;
passManagerResult = success();
});
if (succeeded(passManagerResult))
return success();
std::string error;
if (failed(context.generate(error)))
return op->emitError("<MLIR-PassManager-Crash-Reproducer>: ") << error;
bool shouldPrintOnOp = op->getContext()->shouldPrintOpOnDiagnostic();
op->getContext()->printOpOnDiagnostic(false);
op->emitError()
<< "A failure has been detected while processing the MLIR module, a "
"reproducer has been generated in '"
<< *crashReproducerFileName << "'";
op->getContext()->printOpOnDiagnostic(shouldPrintOnOp);
return failure();
}
//===----------------------------------------------------------------------===//
// PassManager
//===----------------------------------------------------------------------===//
PassManager::PassManager(MLIRContext *ctx, Nesting nesting,
StringRef operationName)
: OpPassManager(Identifier::get(operationName, ctx), nesting), context(ctx),
passTiming(false), localReproducer(false), verifyPasses(true) {}
PassManager::~PassManager() {}
void PassManager::enableVerifier(bool enabled) { verifyPasses = enabled; }
/// Run the passes within this manager on the provided operation.
LogicalResult PassManager::run(Operation *op) {
MLIRContext *context = getContext();
assert(op->getName().getIdentifier() == getOpName(*context) &&
"operation has a different name than the PassManager");
// Before running, make sure to coalesce any adjacent pass adaptors in the
// pipeline.
getImpl().coalesceAdjacentAdaptorPasses();
// Register all dialects for the current pipeline.
DialectRegistry dependentDialects;
getDependentDialects(dependentDialects);
dependentDialects.loadAll(context);
// Construct a top level analysis manager for the pipeline.
ModuleAnalysisManager am(op, instrumentor.get());
// Notify the context that we start running a pipeline for book keeping.
context->enterMultiThreadedExecution();
// If reproducer generation is enabled, run the pass manager with crash
// handling enabled.
LogicalResult result =
crashReproducerFileName
? runWithCrashRecovery(op, am)
: OpToOpPassAdaptor::runPipeline(getPasses(), op, am, verifyPasses);
// Notify the context that the run is done.
context->exitMultiThreadedExecution();
// Dump all of the pass statistics if necessary.
if (passStatisticsMode)
dumpStatistics();
return result;
}
/// Enable support for the pass manager to generate a reproducer on the event
/// of a crash or a pass failure. `outputFile` is a .mlir filename used to write
/// the generated reproducer. If `genLocalReproducer` is true, the pass manager
/// will attempt to generate a local reproducer that contains the smallest
/// pipeline.
void PassManager::enableCrashReproducerGeneration(StringRef outputFile,
bool genLocalReproducer) {
crashReproducerFileName = std::string(outputFile);
localReproducer = genLocalReproducer;
}
/// Add the provided instrumentation to the pass manager.
void PassManager::addInstrumentation(std::unique_ptr<PassInstrumentation> pi) {
if (!instrumentor)
instrumentor = std::make_unique<PassInstrumentor>();
instrumentor->addInstrumentation(std::move(pi));
}
//===----------------------------------------------------------------------===//
// AnalysisManager
//===----------------------------------------------------------------------===//
/// Get an analysis manager for the given operation, which must be a proper
/// descendant of the current operation represented by this analysis manager.
AnalysisManager AnalysisManager::nest(Operation *op) {
Operation *currentOp = impl->getOperation();
assert(currentOp->isProperAncestor(op) &&
"expected valid descendant operation");
// Check for the base case where the provided operation is immediately nested.
if (currentOp == op->getParentOp())
return nestImmediate(op);
// Otherwise, we need to collect all ancestors up to the current operation.
SmallVector<Operation *, 4> opAncestors;
do {
opAncestors.push_back(op);
op = op->getParentOp();
} while (op != currentOp);
AnalysisManager result = *this;
for (Operation *op : llvm::reverse(opAncestors))
result = result.nestImmediate(op);
return result;
}
/// Get an analysis manager for the given immediately nested child operation.
AnalysisManager AnalysisManager::nestImmediate(Operation *op) {
assert(impl->getOperation() == op->getParentOp() &&
"expected immediate child operation");
auto it = impl->childAnalyses.find(op);
if (it == impl->childAnalyses.end())
it = impl->childAnalyses
.try_emplace(op, std::make_unique<NestedAnalysisMap>(op, impl))
.first;
return {it->second.get()};
}
/// Invalidate any non preserved analyses.
void detail::NestedAnalysisMap::invalidate(
const detail::PreservedAnalyses &pa) {
// If all analyses were preserved, then there is nothing to do here.
if (pa.isAll())
return;
// Invalidate the analyses for the current operation directly.
analyses.invalidate(pa);
// If no analyses were preserved, then just simply clear out the child
// analysis results.
if (pa.isNone()) {
childAnalyses.clear();
return;
}
// Otherwise, invalidate each child analysis map.
SmallVector<NestedAnalysisMap *, 8> mapsToInvalidate(1, this);
while (!mapsToInvalidate.empty()) {
auto *map = mapsToInvalidate.pop_back_val();
for (auto &analysisPair : map->childAnalyses) {
analysisPair.second->invalidate(pa);
if (!analysisPair.second->childAnalyses.empty())
mapsToInvalidate.push_back(analysisPair.second.get());
}
}
}
//===----------------------------------------------------------------------===//
// PassInstrumentation
//===----------------------------------------------------------------------===//
PassInstrumentation::~PassInstrumentation() {}
//===----------------------------------------------------------------------===//
// PassInstrumentor
//===----------------------------------------------------------------------===//
namespace mlir {
namespace detail {
struct PassInstrumentorImpl {
/// Mutex to keep instrumentation access thread-safe.
llvm::sys::SmartMutex<true> mutex;
/// Set of registered instrumentations.
std::vector<std::unique_ptr<PassInstrumentation>> instrumentations;
};
} // end namespace detail
} // end namespace mlir
PassInstrumentor::PassInstrumentor() : impl(new PassInstrumentorImpl()) {}
PassInstrumentor::~PassInstrumentor() {}
/// See PassInstrumentation::runBeforePipeline for details.
void PassInstrumentor::runBeforePipeline(
Identifier name,
const PassInstrumentation::PipelineParentInfo &parentInfo) {
llvm::sys::SmartScopedLock<true> instrumentationLock(impl->mutex);
for (auto &instr : impl->instrumentations)
instr->runBeforePipeline(name, parentInfo);
}
/// See PassInstrumentation::runAfterPipeline for details.
void PassInstrumentor::runAfterPipeline(
Identifier name,
const PassInstrumentation::PipelineParentInfo &parentInfo) {
llvm::sys::SmartScopedLock<true> instrumentationLock(impl->mutex);
for (auto &instr : llvm::reverse(impl->instrumentations))
instr->runAfterPipeline(name, parentInfo);
}
/// See PassInstrumentation::runBeforePass for details.
void PassInstrumentor::runBeforePass(Pass *pass, Operation *op) {
llvm::sys::SmartScopedLock<true> instrumentationLock(impl->mutex);
for (auto &instr : impl->instrumentations)
instr->runBeforePass(pass, op);
}
/// See PassInstrumentation::runAfterPass for details.
void PassInstrumentor::runAfterPass(Pass *pass, Operation *op) {
llvm::sys::SmartScopedLock<true> instrumentationLock(impl->mutex);
for (auto &instr : llvm::reverse(impl->instrumentations))
instr->runAfterPass(pass, op);
}
/// See PassInstrumentation::runAfterPassFailed for details.
void PassInstrumentor::runAfterPassFailed(Pass *pass, Operation *op) {
llvm::sys::SmartScopedLock<true> instrumentationLock(impl->mutex);
for (auto &instr : llvm::reverse(impl->instrumentations))
instr->runAfterPassFailed(pass, op);
}
/// See PassInstrumentation::runBeforeAnalysis for details.
void PassInstrumentor::runBeforeAnalysis(StringRef name, TypeID id,
Operation *op) {
llvm::sys::SmartScopedLock<true> instrumentationLock(impl->mutex);
for (auto &instr : impl->instrumentations)
instr->runBeforeAnalysis(name, id, op);
}
/// See PassInstrumentation::runAfterAnalysis for details.
void PassInstrumentor::runAfterAnalysis(StringRef name, TypeID id,
Operation *op) {
llvm::sys::SmartScopedLock<true> instrumentationLock(impl->mutex);
for (auto &instr : llvm::reverse(impl->instrumentations))
instr->runAfterAnalysis(name, id, op);
}
/// Add the given instrumentation to the collection.
void PassInstrumentor::addInstrumentation(
std::unique_ptr<PassInstrumentation> pi) {
llvm::sys::SmartScopedLock<true> instrumentationLock(impl->mutex);
impl->instrumentations.emplace_back(std::move(pi));
}