//===- KernelOutlining.cpp - Implementation of GPU kernel outlining -------===// // // 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 the GPU dialect kernel outlining pass. // //===----------------------------------------------------------------------===// #include "PassDetail.h" #include "mlir/Dialect/Arithmetic/IR/Arithmetic.h" #include "mlir/Dialect/ControlFlow/IR/ControlFlowOps.h" #include "mlir/Dialect/DLTI/DLTI.h" #include "mlir/Dialect/Func/IR/FuncOps.h" #include "mlir/Dialect/GPU/GPUDialect.h" #include "mlir/Dialect/GPU/Passes.h" #include "mlir/Dialect/GPU/Utils.h" #include "mlir/Dialect/MemRef/IR/MemRef.h" #include "mlir/IR/BlockAndValueMapping.h" #include "mlir/IR/Builders.h" #include "mlir/IR/Matchers.h" #include "mlir/IR/SymbolTable.h" #include "mlir/Parser/Parser.h" #include "mlir/Support/LLVM.h" #include "mlir/Transforms/RegionUtils.h" using namespace mlir; template static void createForAllDimensions(OpBuilder &builder, Location loc, SmallVectorImpl &values) { for (auto dim : {gpu::Dimension::x, gpu::Dimension::y, gpu::Dimension::z}) values.push_back(builder.create(loc, builder.getIndexType(), dim)); } /// Adds operations generating block/thread ids and grid/block dimensions at the /// beginning of the `launchFuncOpBody` region. Add mapping from argument in /// entry block of `launchOpBody`, to the corresponding result value of the /// added operations. static void injectGpuIndexOperations(Location loc, Region &launchFuncOpBody, Region &launchOpBody, BlockAndValueMapping &map) { OpBuilder builder(loc->getContext()); Block &firstBlock = launchOpBody.front(); builder.setInsertionPointToStart(&launchFuncOpBody.front()); SmallVector indexOps; createForAllDimensions(builder, loc, indexOps); createForAllDimensions(builder, loc, indexOps); createForAllDimensions(builder, loc, indexOps); createForAllDimensions(builder, loc, indexOps); // Replace the leading 12 function args with the respective thread/block index // operations. Iterate backwards since args are erased and indices change. for (const auto &indexOp : enumerate(indexOps)) map.map(firstBlock.getArgument(indexOp.index()), indexOp.value()); } /// Identifies operations that are beneficial to sink into kernels. These /// operations may not have side-effects, as otherwise sinking (and hence /// duplicating them) is not legal. static bool isLikelyAnIndexComputation(Operation *op) { return matchPattern(op, m_Constant()) || isa(op); } /// For a given operation `op`, computes whether it is beneficial to sink the /// operation into the kernel. An operation can be sunk if doing so does not /// introduce new kernel arguments. Whether a value is already available in the /// kernel (and hence does not introduce new arguments) is checked by /// querying `existingDependencies` and `availableValues`. /// If an operand is not yet available, we recursively check whether it can be /// made available by siking its defining op. /// Operations that are indentified for sinking are added to `beneficiaryOps` in /// the order they should appear in the kernel. Furthermore, `availableValues` /// is updated with results that will be available after sinking the identified /// ops. static bool extractBeneficiaryOps( Operation *op, const SetVector &existingDependencies, SetVector &beneficiaryOps, llvm::SmallPtrSetImpl &availableValues, llvm::function_ref isSinkingBeneficiary) { if (beneficiaryOps.count(op)) return true; if (!isSinkingBeneficiary(op)) return false; for (Value operand : op->getOperands()) { // It is already visible in the kernel, keep going. if (availableValues.count(operand)) continue; // Else check whether it can be made available via sinking or already is a // dependency. Operation *definingOp = operand.getDefiningOp(); if ((!definingOp || !extractBeneficiaryOps(definingOp, existingDependencies, beneficiaryOps, availableValues, isSinkingBeneficiary)) && !existingDependencies.count(operand)) return false; } // We will sink the operation, mark its results as now available. beneficiaryOps.insert(op); for (Value result : op->getResults()) availableValues.insert(result); return true; } LogicalResult mlir::sinkOperationsIntoLaunchOp( gpu::LaunchOp launchOp, llvm::function_ref isSinkingBeneficiary) { assert(isSinkingBeneficiary); Region &launchOpBody = launchOp.body(); // Identify uses from values defined outside of the scope of the launch // operation. SetVector sinkCandidates; getUsedValuesDefinedAbove(launchOpBody, sinkCandidates); SetVector toBeSunk; llvm::SmallPtrSet availableValues; for (Value operand : sinkCandidates) { Operation *operandOp = operand.getDefiningOp(); if (!operandOp) continue; extractBeneficiaryOps(operandOp, sinkCandidates, toBeSunk, availableValues, isSinkingBeneficiary); } // Insert operations so that the defs get cloned before uses. BlockAndValueMapping map; OpBuilder builder(launchOpBody); for (Operation *op : toBeSunk) { Operation *clonedOp = builder.clone(*op, map); // Only replace uses within the launch op. for (auto pair : llvm::zip(op->getResults(), clonedOp->getResults())) replaceAllUsesInRegionWith(std::get<0>(pair), std::get<1>(pair), launchOp.body()); } return success(); } /// Outline the `gpu.launch` operation body into a kernel function. Replace /// `gpu.terminator` operations by `gpu.return` in the generated function. static gpu::GPUFuncOp outlineKernelFuncImpl(gpu::LaunchOp launchOp, StringRef kernelFnName, SetVector &operands) { Location loc = launchOp.getLoc(); // Create a builder with no insertion point, insertion will happen separately // due to symbol table manipulation. OpBuilder builder(launchOp.getContext()); Region &launchOpBody = launchOp.body(); // Identify uses from values defined outside of the scope of the launch // operation. getUsedValuesDefinedAbove(launchOpBody, operands); // Create the gpu.func operation. SmallVector kernelOperandTypes; kernelOperandTypes.reserve(operands.size()); for (Value operand : operands) { kernelOperandTypes.push_back(operand.getType()); } FunctionType type = FunctionType::get(launchOp.getContext(), kernelOperandTypes, {}); auto outlinedFunc = builder.create(loc, kernelFnName, type); outlinedFunc->setAttr(gpu::GPUDialect::getKernelFuncAttrName(), builder.getUnitAttr()); BlockAndValueMapping map; // Map the arguments corresponding to the launch parameters like blockIdx, // threadIdx, etc. Region &outlinedFuncBody = outlinedFunc.body(); injectGpuIndexOperations(loc, outlinedFuncBody, launchOpBody, map); // Map arguments from gpu.launch region to the arguments of the gpu.func // operation. Block &entryBlock = outlinedFuncBody.front(); for (const auto &operand : enumerate(operands)) map.map(operand.value(), entryBlock.getArgument(operand.index())); // Clone the region of the gpu.launch operation into the gpu.func operation. // TODO: If cloneInto can be modified such that if a mapping for // a block exists, that block will be used to clone operations into (at the // end of the block), instead of creating a new block, this would be much // cleaner. launchOpBody.cloneInto(&outlinedFuncBody, map); // Branch from entry of the gpu.func operation to the block that is cloned // from the entry block of the gpu.launch operation. Block &launchOpEntry = launchOpBody.front(); Block *clonedLaunchOpEntry = map.lookup(&launchOpEntry); builder.setInsertionPointToEnd(&entryBlock); builder.create(loc, clonedLaunchOpEntry); outlinedFunc.walk([](gpu::TerminatorOp op) { OpBuilder replacer(op); replacer.create(op.getLoc()); op.erase(); }); return outlinedFunc; } gpu::GPUFuncOp mlir::outlineKernelFunc(gpu::LaunchOp launchOp, StringRef kernelFnName, llvm::SmallVectorImpl &operands) { DenseSet inputOperandSet; inputOperandSet.insert(operands.begin(), operands.end()); SetVector operandSet(operands.begin(), operands.end()); auto funcOp = outlineKernelFuncImpl(launchOp, kernelFnName, operandSet); for (auto operand : operandSet) { if (!inputOperandSet.count(operand)) operands.push_back(operand); } return funcOp; } /// Replace `gpu.launch` operations with an `gpu.launch_func` operation /// launching `kernelFunc`. The kernel func contains the body of the /// `gpu.launch` with constant region arguments inlined. static void convertToLaunchFuncOp(gpu::LaunchOp launchOp, gpu::GPUFuncOp kernelFunc, ValueRange operands) { OpBuilder builder(launchOp); // The launch op has an optional dynamic shared memory size. If it doesn't // exist, we use zero. builder.create( launchOp.getLoc(), kernelFunc, launchOp.getGridSizeOperandValues(), launchOp.getBlockSizeOperandValues(), launchOp.dynamicSharedMemorySize(), operands); launchOp.erase(); } namespace { /// Pass that moves ops which are likely an index computation into gpu.launch /// body. class GpuLaunchSinkIndexComputationsPass : public GpuLaunchSinkIndexComputationsBase< GpuLaunchSinkIndexComputationsPass> { public: void runOnOperation() override { Operation *op = getOperation(); if (op->walk([](gpu::LaunchOp launch) { // Pull in instructions that can be sunk if (failed(sinkOperationsIntoLaunchOp(launch, isLikelyAnIndexComputation))) return WalkResult::interrupt(); return WalkResult::advance(); }).wasInterrupted()) signalPassFailure(); } }; /// Pass that moves the kernel of each LaunchOp into its separate nested module. /// /// This pass moves the kernel code of each LaunchOp into a function created /// inside a nested module. It also creates an external function of the same /// name in the parent module. /// /// The gpu.modules are intended to be compiled to a cubin blob independently in /// a separate pass. The external functions can then be annotated with the /// symbol of the cubin accessor function. class GpuKernelOutliningPass : public GpuKernelOutliningBase { public: GpuKernelOutliningPass(StringRef dlStr) { if (!dlStr.empty() && !dataLayoutStr.hasValue()) dataLayoutStr = dlStr.str(); } GpuKernelOutliningPass(const GpuKernelOutliningPass &other) : dataLayoutSpec(other.dataLayoutSpec) { dataLayoutStr = other.dataLayoutStr; } LogicalResult initialize(MLIRContext *context) override { // Initialize the data layout specification from the data layout string. if (!dataLayoutStr.empty()) { Attribute resultAttr = mlir::parseAttribute(dataLayoutStr, context); if (!resultAttr) return failure(); dataLayoutSpec = resultAttr.dyn_cast(); if (!dataLayoutSpec) return failure(); } return success(); } void runOnOperation() override { SymbolTable symbolTable(getOperation()); bool modified = false; for (auto func : getOperation().getOps()) { // Insert just after the function. Block::iterator insertPt(func->getNextNode()); auto funcWalkResult = func.walk([&](gpu::LaunchOp op) { SetVector operands; std::string kernelFnName = Twine(op->getParentOfType().getName(), "_kernel").str(); gpu::GPUFuncOp outlinedFunc = outlineKernelFuncImpl(op, kernelFnName, operands); // Create nested module and insert outlinedFunc. The module will // originally get the same name as the function, but may be renamed on // insertion into the parent module. auto kernelModule = createKernelModule(outlinedFunc, symbolTable); symbolTable.insert(kernelModule, insertPt); // Potentially changes signature, pulling in constants. convertToLaunchFuncOp(op, outlinedFunc, operands.getArrayRef()); modified = true; return WalkResult::advance(); }); if (funcWalkResult.wasInterrupted()) return signalPassFailure(); } // If any new module was inserted in this module, annotate this module as // a container module. if (modified) getOperation()->setAttr(gpu::GPUDialect::getContainerModuleAttrName(), UnitAttr::get(&getContext())); } private: /// Returns a gpu.module containing kernelFunc and all callees (recursive). gpu::GPUModuleOp createKernelModule(gpu::GPUFuncOp kernelFunc, const SymbolTable &parentSymbolTable) { // TODO: This code cannot use an OpBuilder because it must be inserted into // a SymbolTable by the caller. SymbolTable needs to be refactored to // prevent manual building of Ops with symbols in code using SymbolTables // and then this needs to use the OpBuilder. auto *context = getOperation().getContext(); OpBuilder builder(context); auto kernelModule = builder.create(kernelFunc.getLoc(), kernelFunc.getName()); // If a valid data layout spec was provided, attach it to the kernel module. // Otherwise, the default data layout will be used. if (dataLayoutSpec) kernelModule->setAttr(DLTIDialect::kDataLayoutAttrName, dataLayoutSpec); SymbolTable symbolTable(kernelModule); symbolTable.insert(kernelFunc); SmallVector symbolDefWorklist = {kernelFunc}; while (!symbolDefWorklist.empty()) { if (Optional symbolUses = SymbolTable::getSymbolUses(symbolDefWorklist.pop_back_val())) { for (SymbolTable::SymbolUse symbolUse : *symbolUses) { StringRef symbolName = symbolUse.getSymbolRef().cast().getValue(); if (symbolTable.lookup(symbolName)) continue; Operation *symbolDefClone = parentSymbolTable.lookup(symbolName)->clone(); symbolDefWorklist.push_back(symbolDefClone); symbolTable.insert(symbolDefClone); } } } return kernelModule; } Option dataLayoutStr{ *this, "data-layout-str", llvm::cl::desc("String containing the data layout specification to be " "attached to the GPU kernel module")}; DataLayoutSpecInterface dataLayoutSpec; }; } // namespace std::unique_ptr mlir::createGpuLauchSinkIndexComputationsPass() { return std::make_unique(); } std::unique_ptr> mlir::createGpuKernelOutliningPass(StringRef dataLayoutStr) { return std::make_unique(dataLayoutStr); }