llvm-project/mlir/lib/Pass/Pass.cpp

856 lines
32 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/Threading.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/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(StringAttr identifier, OpPassManager::Nesting nesting)
: name(identifier.str()), identifier(identifier),
initializationGeneration(0), nesting(nesting) {}
OpPassManagerImpl(StringRef name, OpPassManager::Nesting nesting)
: name(name), initializationGeneration(0), 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(StringAttr 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);
/// Clear the list of passes in this pass manager, other options are
/// preserved.
void clear();
/// Coalesce adjacent AdaptorPasses into one large adaptor. This runs
/// recursively through the pipeline graph.
void coalesceAdjacentAdaptorPasses();
/// Return the operation name of this pass manager as an identifier.
StringAttr getOpName(MLIRContext &context) {
if (!identifier)
identifier = StringAttr::get(&context, name);
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<StringAttr> identifier;
/// The set of passes to run as part of this pass manager.
std::vector<std::unique_ptr<Pass>> passes;
/// The current initialization generation of this pass manager. This is used
/// to indicate when a pass manager should be reinitialized.
unsigned initializationGeneration;
/// Control the implicit nesting of passes that mismatch the name set for this
/// OpPassManager.
OpPassManager::Nesting nesting;
};
} // namespace detail
} // 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(StringAttr 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::clear() { passes.clear(); }
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 &passe : passes) {
// Check to see if this pass is an adaptor.
if (auto *currentAdaptor = dyn_cast<OpToOpPassAdaptor>(passe.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);
passe.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>>());
}
//===----------------------------------------------------------------------===//
// OpPassManager
//===----------------------------------------------------------------------===//
OpPassManager::OpPassManager(StringAttr 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 = std::make_unique<OpPassManagerImpl>(rhs.impl->name, rhs.impl->nesting);
impl->initializationGeneration = rhs.impl->initializationGeneration;
for (auto &pass : rhs.impl->passes) {
auto newPass = pass->clone();
newPass->threadingSibling = pass.get();
impl->passes.push_back(std::move(newPass));
}
return *this;
}
OpPassManager::~OpPassManager() = default;
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(StringAttr 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));
}
void OpPassManager::clear() { impl->clear(); }
/// 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.
StringAttr 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);
}
void OpPassManager::setNesting(Nesting nesting) { impl->nesting = nesting; }
OpPassManager::Nesting OpPassManager::getNesting() { return impl->nesting; }
LogicalResult OpPassManager::initialize(MLIRContext *context,
unsigned newInitGeneration) {
if (impl->initializationGeneration == newInitGeneration)
return success();
impl->initializationGeneration = newInitGeneration;
for (Pass &pass : getPasses()) {
// If this pass isn't an adaptor, directly initialize it.
auto *adaptor = dyn_cast<OpToOpPassAdaptor>(&pass);
if (!adaptor) {
if (failed(pass.initialize(context)))
return failure();
continue;
}
// Otherwise, initialize each of the adaptors pass managers.
for (OpPassManager &adaptorPM : adaptor->getPassManagers())
if (failed(adaptorPM.initialize(context, newInitGeneration)))
return failure();
}
return success();
}
//===----------------------------------------------------------------------===//
// OpToOpPassAdaptor
//===----------------------------------------------------------------------===//
LogicalResult OpToOpPassAdaptor::run(Pass *pass, Operation *op,
AnalysisManager am, bool verifyPasses,
unsigned parentInitGeneration) {
if (!op->isRegistered())
return op->emitOpError()
<< "trying to schedule a pass on an unregistered operation";
if (!op->hasTrait<OpTrait::IsIsolatedFromAbove>())
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 dynamicPipelineCallback = [&](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());
// Before running, make sure to coalesce any adjacent pass adaptors in the
// pipeline.
pipeline.getImpl().coalesceAdjacentAdaptorPasses();
// Initialize the user provided pipeline and execute the pipeline.
if (failed(pipeline.initialize(root->getContext(), parentInitGeneration)))
return failure();
AnalysisManager nestedAm = root == op ? am : am.nest(root);
return OpToOpPassAdaptor::runPipeline(pipeline.getPasses(), root, nestedAm,
verifyPasses, parentInitGeneration,
pi, &parentInfo);
};
pass->passState.emplace(op, am, dynamicPipelineCallback);
// 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);
// When verifyPasses is specified, we run the verifier (unless the pass
// failed).
if (!passFailed && verifyPasses) {
bool runVerifierNow = true;
// Reduce compile time by avoiding running the verifier if the pass didn't
// change the IR since the last time the verifier was run:
//
// 1) If the pass said that it preserved all analyses then it can't have
// permuted the IR.
// 2) If we just ran an OpToOpPassAdaptor (e.g. to run function passes
// within a module) then each sub-unit will have been verified on the
// subunit (and those passes aren't allowed to modify the parent).
//
// We run these checks in EXPENSIVE_CHECKS mode out of caution.
#ifndef EXPENSIVE_CHECKS
runVerifierNow = !isa<OpToOpPassAdaptor>(pass) &&
!pass->passState->preservedAnalyses.isAll();
#endif
if (runVerifierNow)
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, unsigned parentInitGeneration,
PassInstrumentor *instrumentor,
const PassInstrumentation::PipelineParentInfo *parentInfo) {
assert((!instrumentor || parentInfo) &&
"expected parent info if instrumentor is provided");
auto scopeExit = 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, parentInitGeneration)))
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,
StringAttr 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.
unsigned initGeneration = mgr->impl->initializationGeneration;
if (failed(runPipeline(mgr->getPasses(), &op, am.nest(&op),
verifyPasses, initGeneration, 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();
MLIRContext *context = &getContext();
// 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(context->getThreadPool().getThreadCount(), 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(), *context))
opAMPairs.emplace_back(&op, am.nest(&op));
}
}
}
// 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::vector<std::atomic<bool>> activePMs(asyncExecutors.size());
std::fill(activePMs.begin(), activePMs.end(), false);
auto processFn = [&](auto &opPMPair) {
// Find a pass manager for this operation.
auto it = llvm::find_if(activePMs, [](std::atomic<bool> &isActive) {
bool expectedInactive = false;
return isActive.compare_exchange_strong(expectedInactive, true);
});
unsigned pmIndex = it - activePMs.begin();
// Get the pass manager for this operation and execute it.
auto *pm =
findPassManagerFor(asyncExecutors[pmIndex],
opPMPair.first->getName().getIdentifier(), *context);
assert(pm && "expected valid pass manager for operation");
unsigned initGeneration = pm->impl->initializationGeneration;
LogicalResult pipelineResult =
runPipeline(pm->getPasses(), opPMPair.first, opPMPair.second,
verifyPasses, initGeneration, instrumentor, &parentInfo);
// Reset the active bit for this pass manager.
activePMs[pmIndex].store(false);
return pipelineResult;
};
// Signal a failure if any of the executors failed.
if (failed(failableParallelForEach(context, opAMPairs, processFn)))
signalPassFailure();
}
//===----------------------------------------------------------------------===//
// PassManager
//===----------------------------------------------------------------------===//
PassManager::PassManager(MLIRContext *ctx, Nesting nesting,
StringRef operationName)
: OpPassManager(StringAttr::get(ctx, operationName), nesting), context(ctx),
initializationKey(DenseMapInfo<llvm::hash_code>::getTombstoneKey()),
passTiming(false), verifyPasses(true) {}
PassManager::~PassManager() = default;
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 or is from a "
"different context");
// 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);
context->appendDialectRegistry(dependentDialects);
for (StringRef name : dependentDialects.getDialectNames())
context->getOrLoadDialect(name);
// Initialize all of the passes within the pass manager with a new generation.
llvm::hash_code newInitKey = context->getRegistryHash();
if (newInitKey != initializationKey) {
if (failed(initialize(context, impl->initializationGeneration + 1)))
return failure();
initializationKey = newInitKey;
}
// 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 =
crashReproGenerator ? runWithCrashRecovery(op, am) : runPasses(op, am);
// Notify the context that the run is done.
context->exitMultiThreadedExecution();
// Dump all of the pass statistics if necessary.
if (passStatisticsMode)
dumpStatistics();
return result;
}
/// 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));
}
LogicalResult PassManager::runPasses(Operation *op, AnalysisManager am) {
return OpToOpPassAdaptor::runPipeline(getPasses(), op, am, verifyPasses,
impl->initializationGeneration);
}
//===----------------------------------------------------------------------===//
// 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() = default;
//===----------------------------------------------------------------------===//
// 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;
};
} // namespace detail
} // namespace mlir
PassInstrumentor::PassInstrumentor() : impl(new PassInstrumentorImpl()) {}
PassInstrumentor::~PassInstrumentor() = default;
/// See PassInstrumentation::runBeforePipeline for details.
void PassInstrumentor::runBeforePipeline(
StringAttr 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(
StringAttr 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));
}