llvm-capstone/mlir/lib/Pass/IRPrinting.cpp
2020-06-24 17:02:44 -07:00

275 lines
10 KiB
C++

//===- IRPrinting.cpp -----------------------------------------------------===//
//
// 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
//
//===----------------------------------------------------------------------===//
#include "PassDetail.h"
#include "mlir/IR/Module.h"
#include "mlir/Pass/PassManager.h"
#include "llvm/Support/Format.h"
#include "llvm/Support/FormatVariadic.h"
#include "llvm/Support/SHA1.h"
using namespace mlir;
using namespace mlir::detail;
namespace {
//===----------------------------------------------------------------------===//
// OperationFingerPrint
//===----------------------------------------------------------------------===//
/// A unique fingerprint for a specific operation, and all of it's internal
/// operations.
class OperationFingerPrint {
public:
OperationFingerPrint(Operation *topOp) {
llvm::SHA1 hasher;
// Hash each of the operations based upon their mutable bits:
topOp->walk([&](Operation *op) {
// - Operation pointer
addDataToHash(hasher, op);
// - Attributes
addDataToHash(hasher, op->getMutableAttrDict());
// - Blocks in Regions
for (Region &region : op->getRegions()) {
for (Block &block : region) {
addDataToHash(hasher, &block);
for (BlockArgument arg : block.getArguments())
addDataToHash(hasher, arg);
}
}
// - Location
addDataToHash(hasher, op->getLoc().getAsOpaquePointer());
// - Operands
for (Value operand : op->getOperands())
addDataToHash(hasher, operand);
// - Successors
for (unsigned i = 0, e = op->getNumSuccessors(); i != e; ++i)
addDataToHash(hasher, op->getSuccessor(i));
});
hash = hasher.result();
}
bool operator==(const OperationFingerPrint &other) const {
return hash == other.hash;
}
bool operator!=(const OperationFingerPrint &other) const {
return !(*this == other);
}
private:
template <typename T> void addDataToHash(llvm::SHA1 &hasher, const T &data) {
hasher.update(
ArrayRef<uint8_t>(reinterpret_cast<const uint8_t *>(&data), sizeof(T)));
}
SmallString<20> hash;
};
//===----------------------------------------------------------------------===//
// IRPrinter
//===----------------------------------------------------------------------===//
class IRPrinterInstrumentation : public PassInstrumentation {
public:
IRPrinterInstrumentation(std::unique_ptr<PassManager::IRPrinterConfig> config)
: config(std::move(config)) {}
private:
/// Instrumentation hooks.
void runBeforePass(Pass *pass, Operation *op) override;
void runAfterPass(Pass *pass, Operation *op) override;
void runAfterPassFailed(Pass *pass, Operation *op) override;
/// Configuration to use.
std::unique_ptr<PassManager::IRPrinterConfig> config;
/// The following is a set of fingerprints for operations that are currently
/// being operated on in a pass. This field is only used when the
/// configuration asked for change detection.
DenseMap<Pass *, OperationFingerPrint> beforePassFingerPrints;
};
} // end anonymous namespace
/// Returns true if the given pass is hidden from IR printing.
static bool isHiddenPass(Pass *pass) {
return isa<OpToOpPassAdaptor, VerifierPass>(pass);
}
static void printIR(Operation *op, bool printModuleScope, raw_ostream &out,
OpPrintingFlags flags) {
// Check to see if we are printing the top-level module.
auto module = dyn_cast<ModuleOp>(op);
if (module && !op->getBlock())
return module.print(out << "\n", flags);
// Otherwise, check to see if we are not printing at module scope.
if (!printModuleScope)
return op->print(out << "\n", flags.useLocalScope());
// Otherwise, we are printing at module scope.
out << " ('" << op->getName() << "' operation";
if (auto symbolName =
op->getAttrOfType<StringAttr>(SymbolTable::getSymbolAttrName()))
out << ": @" << symbolName.getValue();
out << ")\n";
// Find the top-level module operation.
auto *topLevelOp = op;
while (auto *parentOp = topLevelOp->getParentOp())
topLevelOp = parentOp;
// Check to see if the top-level operation is actually a module in the case of
// invalid-ir.
if (auto module = dyn_cast<ModuleOp>(topLevelOp))
module.print(out, flags);
else
topLevelOp->print(out, flags);
}
/// Instrumentation hooks.
void IRPrinterInstrumentation::runBeforePass(Pass *pass, Operation *op) {
if (isHiddenPass(pass))
return;
// If the config asked to detect changes, record the current fingerprint.
if (config->shouldPrintAfterOnlyOnChange())
beforePassFingerPrints.try_emplace(pass, op);
config->printBeforeIfEnabled(pass, op, [&](raw_ostream &out) {
out << formatv("// *** IR Dump Before {0} ***", pass->getName());
printIR(op, config->shouldPrintAtModuleScope(), out, OpPrintingFlags());
out << "\n\n";
});
}
void IRPrinterInstrumentation::runAfterPass(Pass *pass, Operation *op) {
if (isHiddenPass(pass))
return;
// If the config asked to detect changes, compare the current fingerprint with
// the previous.
if (config->shouldPrintAfterOnlyOnChange()) {
auto fingerPrintIt = beforePassFingerPrints.find(pass);
assert(fingerPrintIt != beforePassFingerPrints.end() &&
"expected valid fingerprint");
// If the fingerprints are the same, we don't print the IR.
if (fingerPrintIt->second == OperationFingerPrint(op)) {
beforePassFingerPrints.erase(fingerPrintIt);
return;
}
beforePassFingerPrints.erase(fingerPrintIt);
}
config->printAfterIfEnabled(pass, op, [&](raw_ostream &out) {
out << formatv("// *** IR Dump After {0} ***", pass->getName());
printIR(op, config->shouldPrintAtModuleScope(), out, OpPrintingFlags());
out << "\n\n";
});
}
void IRPrinterInstrumentation::runAfterPassFailed(Pass *pass, Operation *op) {
if (isa<OpToOpPassAdaptor>(pass))
return;
if (config->shouldPrintAfterOnlyOnChange())
beforePassFingerPrints.erase(pass);
config->printAfterIfEnabled(pass, op, [&](raw_ostream &out) {
out << formatv("// *** IR Dump After {0} Failed ***", pass->getName());
printIR(op, config->shouldPrintAtModuleScope(), out,
OpPrintingFlags().printGenericOpForm());
out << "\n\n";
});
}
//===----------------------------------------------------------------------===//
// IRPrinterConfig
//===----------------------------------------------------------------------===//
/// Initialize the configuration.
PassManager::IRPrinterConfig::IRPrinterConfig(bool printModuleScope,
bool printAfterOnlyOnChange)
: printModuleScope(printModuleScope),
printAfterOnlyOnChange(printAfterOnlyOnChange) {}
PassManager::IRPrinterConfig::~IRPrinterConfig() {}
/// A hook that may be overridden by a derived config that checks if the IR
/// of 'operation' should be dumped *before* the pass 'pass' has been
/// executed. If the IR should be dumped, 'printCallback' should be invoked
/// with the stream to dump into.
void PassManager::IRPrinterConfig::printBeforeIfEnabled(
Pass *pass, Operation *operation, PrintCallbackFn printCallback) {
// By default, never print.
}
/// A hook that may be overridden by a derived config that checks if the IR
/// of 'operation' should be dumped *after* the pass 'pass' has been
/// executed. If the IR should be dumped, 'printCallback' should be invoked
/// with the stream to dump into.
void PassManager::IRPrinterConfig::printAfterIfEnabled(
Pass *pass, Operation *operation, PrintCallbackFn printCallback) {
// By default, never print.
}
//===----------------------------------------------------------------------===//
// PassManager
//===----------------------------------------------------------------------===//
namespace {
/// Simple wrapper config that allows for the simpler interface defined above.
struct BasicIRPrinterConfig : public PassManager::IRPrinterConfig {
BasicIRPrinterConfig(
std::function<bool(Pass *, Operation *)> shouldPrintBeforePass,
std::function<bool(Pass *, Operation *)> shouldPrintAfterPass,
bool printModuleScope, bool printAfterOnlyOnChange, raw_ostream &out)
: IRPrinterConfig(printModuleScope, printAfterOnlyOnChange),
shouldPrintBeforePass(shouldPrintBeforePass),
shouldPrintAfterPass(shouldPrintAfterPass), out(out) {
assert((shouldPrintBeforePass || shouldPrintAfterPass) &&
"expected at least one valid filter function");
}
void printBeforeIfEnabled(Pass *pass, Operation *operation,
PrintCallbackFn printCallback) final {
if (shouldPrintBeforePass && shouldPrintBeforePass(pass, operation))
printCallback(out);
}
void printAfterIfEnabled(Pass *pass, Operation *operation,
PrintCallbackFn printCallback) final {
if (shouldPrintAfterPass && shouldPrintAfterPass(pass, operation))
printCallback(out);
}
/// Filter functions for before and after pass execution.
std::function<bool(Pass *, Operation *)> shouldPrintBeforePass;
std::function<bool(Pass *, Operation *)> shouldPrintAfterPass;
/// The stream to output to.
raw_ostream &out;
};
} // end anonymous namespace
/// Add an instrumentation to print the IR before and after pass execution,
/// using the provided configuration.
void PassManager::enableIRPrinting(std::unique_ptr<IRPrinterConfig> config) {
if (config->shouldPrintAtModuleScope() &&
getContext()->isMultithreadingEnabled())
llvm::report_fatal_error("IR printing can't be setup on a pass-manager "
"without disabling multi-threading first.");
addInstrumentation(
std::make_unique<IRPrinterInstrumentation>(std::move(config)));
}
/// Add an instrumentation to print the IR before and after pass execution.
void PassManager::enableIRPrinting(
std::function<bool(Pass *, Operation *)> shouldPrintBeforePass,
std::function<bool(Pass *, Operation *)> shouldPrintAfterPass,
bool printModuleScope, bool printAfterOnlyOnChange, raw_ostream &out) {
enableIRPrinting(std::make_unique<BasicIRPrinterConfig>(
std::move(shouldPrintBeforePass), std::move(shouldPrintAfterPass),
printModuleScope, printAfterOnlyOnChange, out));
}