mlir/lib/Conversion/GPUToVulkan/ConvertGPULaunchFuncToVulkanLaunchFunc.cpp - llvm-project - Git at Google

 //===- ConvertGPULaunchFuncToVulkanLaunchFunc.cpp - MLIR conversion pass --===//
 //
 // 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 a pass to convert gpu launch function into a vulkan
 // launch function. Creates a SPIR-V binary shader from the `spirv::ModuleOp`
 // using `spirv::serialize` function, attaches binary data and entry point name
 // as an attributes to vulkan launch call op.
 //
 //===----------------------------------------------------------------------===//

 #include "../PassDetail.h"
 #include "mlir/Conversion/GPUToVulkan/ConvertGPUToVulkanPass.h"
 #include "mlir/Dialect/GPU/GPUDialect.h"
 #include "mlir/Dialect/SPIRV/IR/SPIRVDialect.h"
 #include "mlir/Dialect/SPIRV/IR/SPIRVOps.h"
 #include "mlir/Dialect/StandardOps/IR/Ops.h"
 #include "mlir/IR/Attributes.h"
 #include "mlir/IR/Builders.h"
 #include "mlir/IR/BuiltinOps.h"
 #include "mlir/IR/BuiltinTypes.h"
 #include "mlir/Target/SPIRV/Serialization.h"

 using namespace mlir;

 static constexpr const char *kSPIRVBlobAttrName = "spirv_blob";
 static constexpr const char *kSPIRVEntryPointAttrName = "spirv_entry_point";
 static constexpr const char *kVulkanLaunch = "vulkanLaunch";

 namespace {

 /// A pass to convert gpu launch op to vulkan launch call op, by creating a
 /// SPIR-V binary shader from `spirv::ModuleOp` using `spirv::serialize`
 /// function and attaching binary data and entry point name as an attributes to
 /// created vulkan launch call op.
 class ConvertGpuLaunchFuncToVulkanLaunchFunc
     : public ConvertGpuLaunchFuncToVulkanLaunchFuncBase<
           ConvertGpuLaunchFuncToVulkanLaunchFunc> {
 public:
   void runOnOperation() override;

 private:
   /// Creates a SPIR-V binary shader from the given `module` using
   /// `spirv::serialize` function.
   LogicalResult createBinaryShader(ModuleOp module,
                                    std::vector<char> &binaryShader);

   /// Converts the given `launchOp` to vulkan launch call.
   void convertGpuLaunchFunc(gpu::LaunchFuncOp launchOp);

   /// Checks where the given type is supported by Vulkan runtime.
   bool isSupportedType(Type type) {
     if (auto memRefType = type.dyn_cast_or_null<MemRefType>()) {
       auto elementType = memRefType.getElementType();
       return memRefType.hasRank() &&
              (memRefType.getRank() >= 1 && memRefType.getRank() <= 3) &&
              (elementType.isIntOrFloat());
     }
     return false;
   }

   /// Declares the vulkan launch function. Returns an error if the any type of
   /// operand is unsupported by Vulkan runtime.
   LogicalResult declareVulkanLaunchFunc(Location loc,
                                         gpu::LaunchFuncOp launchOp);

 private:
   /// The number of vulkan launch configuration operands, placed at the leading
   /// positions of the operand list.
   static constexpr unsigned kVulkanLaunchNumConfigOperands = 3;
 };

 } // anonymous namespace

 void ConvertGpuLaunchFuncToVulkanLaunchFunc::runOnOperation() {
   bool done = false;
   getOperation().walk([this, &done](gpu::LaunchFuncOp op) {
     if (done) {
       op.emitError("should only contain one 'gpu::LaunchFuncOp' op");
       return signalPassFailure();
     }
     done = true;
     convertGpuLaunchFunc(op);
   });

   // Erase `gpu::GPUModuleOp` and `spirv::Module` operations.
   for (auto gpuModule :
        llvm::make_early_inc_range(getOperation().getOps<gpu::GPUModuleOp>()))
     gpuModule.erase();

   for (auto spirvModule :
        llvm::make_early_inc_range(getOperation().getOps<spirv::ModuleOp>()))
     spirvModule.erase();
 }

 LogicalResult ConvertGpuLaunchFuncToVulkanLaunchFunc::declareVulkanLaunchFunc(
     Location loc, gpu::LaunchFuncOp launchOp) {
   auto builder = OpBuilder::atBlockEnd(getOperation().getBody());

   // Workgroup size is written into the kernel. So to properly modelling
   // vulkan launch, we have to skip local workgroup size configuration here.
   SmallVector<Type, 8> gpuLaunchTypes(launchOp.getOperandTypes());
   // The first kVulkanLaunchNumConfigOperands of the gpu.launch_func op are the
   // same as the config operands for the vulkan launch call op.
   SmallVector<Type, 8> vulkanLaunchTypes(gpuLaunchTypes.begin(),
                                          gpuLaunchTypes.begin() +
                                              kVulkanLaunchNumConfigOperands);
   vulkanLaunchTypes.append(gpuLaunchTypes.begin() +
                                gpu::LaunchOp::kNumConfigOperands,
                            gpuLaunchTypes.end());

   // Check that all operands have supported types except those for the
   // launch configuration.
   for (auto type :
        llvm::drop_begin(vulkanLaunchTypes, kVulkanLaunchNumConfigOperands)) {
     if (!isSupportedType(type))
       return launchOp.emitError() << type << " is unsupported to run on Vulkan";
   }

   // Declare vulkan launch function.
   auto funcType = builder.getFunctionType(vulkanLaunchTypes, {});
   builder.create<FuncOp>(loc, kVulkanLaunch, funcType).setPrivate();

   return success();
 }

 LogicalResult ConvertGpuLaunchFuncToVulkanLaunchFunc::createBinaryShader(
     ModuleOp module, std::vector<char> &binaryShader) {
   bool done = false;
   SmallVector<uint32_t, 0> binary;
   for (auto spirvModule : module.getOps<spirv::ModuleOp>()) {
     if (done)
       return spirvModule.emitError("should only contain one 'spv.module' op");
     done = true;

     if (failed(spirv::serialize(spirvModule, binary)))
       return failure();
   }
   binaryShader.resize(binary.size() * sizeof(uint32_t));
   std::memcpy(binaryShader.data(), reinterpret_cast<char *>(binary.data()),
               binaryShader.size());
   return success();
 }

 void ConvertGpuLaunchFuncToVulkanLaunchFunc::convertGpuLaunchFunc(
     gpu::LaunchFuncOp launchOp) {
   ModuleOp module = getOperation();
   OpBuilder builder(launchOp);
   Location loc = launchOp.getLoc();

   // Serialize `spirv::Module` into binary form.
   std::vector<char> binary;
   if (failed(createBinaryShader(module, binary)))
     return signalPassFailure();

   // Declare vulkan launch function.
   if (failed(declareVulkanLaunchFunc(loc, launchOp)))
     return signalPassFailure();

   SmallVector<Value, 8> gpuLaunchOperands(launchOp.getOperands());
   SmallVector<Value, 8> vulkanLaunchOperands(
       gpuLaunchOperands.begin(),
       gpuLaunchOperands.begin() + kVulkanLaunchNumConfigOperands);
   vulkanLaunchOperands.append(gpuLaunchOperands.begin() +
                                   gpu::LaunchOp::kNumConfigOperands,
                               gpuLaunchOperands.end());

   // Create vulkan launch call op.
   auto vulkanLaunchCallOp = builder.create<CallOp>(
       loc, TypeRange{}, SymbolRefAttr::get(builder.getContext(), kVulkanLaunch),
       vulkanLaunchOperands);

   // Set SPIR-V binary shader data as an attribute.
   vulkanLaunchCallOp->setAttr(
       kSPIRVBlobAttrName,
       builder.getStringAttr(StringRef(binary.data(), binary.size())));

   // Set entry point name as an attribute.
   vulkanLaunchCallOp->setAttr(kSPIRVEntryPointAttrName,
                               launchOp.getKernelName());

   launchOp.erase();
 }

 std::unique_ptr<mlir::OperationPass<mlir::ModuleOp>>
 mlir::createConvertGpuLaunchFuncToVulkanLaunchFuncPass() {
   return std::make_unique<ConvertGpuLaunchFuncToVulkanLaunchFunc>();
 }
	//===- ConvertGPULaunchFuncToVulkanLaunchFunc.cpp - MLIR conversion pass --===//
	//
	// 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 a pass to convert gpu launch function into a vulkan
	// launch function. Creates a SPIR-V binary shader from the `spirv::ModuleOp`
	// using `spirv::serialize` function, attaches binary data and entry point name
	// as an attributes to vulkan launch call op.
	//
	//===----------------------------------------------------------------------===//

	#include "../PassDetail.h"
	#include "mlir/Conversion/GPUToVulkan/ConvertGPUToVulkanPass.h"
	#include "mlir/Dialect/GPU/GPUDialect.h"
	#include "mlir/Dialect/SPIRV/IR/SPIRVDialect.h"
	#include "mlir/Dialect/SPIRV/IR/SPIRVOps.h"
	#include "mlir/Dialect/StandardOps/IR/Ops.h"
	#include "mlir/IR/Attributes.h"
	#include "mlir/IR/Builders.h"
	#include "mlir/IR/BuiltinOps.h"
	#include "mlir/IR/BuiltinTypes.h"
	#include "mlir/Target/SPIRV/Serialization.h"

	using namespace mlir;

	static constexpr const char *kSPIRVBlobAttrName = "spirv_blob";
	static constexpr const char *kSPIRVEntryPointAttrName = "spirv_entry_point";
	static constexpr const char *kVulkanLaunch = "vulkanLaunch";

	namespace {

	/// A pass to convert gpu launch op to vulkan launch call op, by creating a
	/// SPIR-V binary shader from `spirv::ModuleOp` using `spirv::serialize`
	/// function and attaching binary data and entry point name as an attributes to
	/// created vulkan launch call op.
	class ConvertGpuLaunchFuncToVulkanLaunchFunc
	: public ConvertGpuLaunchFuncToVulkanLaunchFuncBase<
	ConvertGpuLaunchFuncToVulkanLaunchFunc> {
	public:
	void runOnOperation() override;

	private:
	/// Creates a SPIR-V binary shader from the given `module` using
	/// `spirv::serialize` function.
	LogicalResult createBinaryShader(ModuleOp module,
	std::vector<char> &binaryShader);

	/// Converts the given `launchOp` to vulkan launch call.
	void convertGpuLaunchFunc(gpu::LaunchFuncOp launchOp);

	/// Checks where the given type is supported by Vulkan runtime.
	bool isSupportedType(Type type) {
	if (auto memRefType = type.dyn_cast_or_null<MemRefType>()) {
	auto elementType = memRefType.getElementType();
	return memRefType.hasRank() &&
	(memRefType.getRank() >= 1 && memRefType.getRank() <= 3) &&
	(elementType.isIntOrFloat());
	}
	return false;
	}

	/// Declares the vulkan launch function. Returns an error if the any type of
	/// operand is unsupported by Vulkan runtime.
	LogicalResult declareVulkanLaunchFunc(Location loc,
	gpu::LaunchFuncOp launchOp);

	private:
	/// The number of vulkan launch configuration operands, placed at the leading
	/// positions of the operand list.
	static constexpr unsigned kVulkanLaunchNumConfigOperands = 3;
	};

	} // anonymous namespace

	void ConvertGpuLaunchFuncToVulkanLaunchFunc::runOnOperation() {
	bool done = false;
	getOperation().walk([this, &done](gpu::LaunchFuncOp op) {
	if (done) {
	op.emitError("should only contain one 'gpu::LaunchFuncOp' op");
	return signalPassFailure();
	}
	done = true;
	convertGpuLaunchFunc(op);
	});

	// Erase `gpu::GPUModuleOp` and `spirv::Module` operations.
	for (auto gpuModule :
	llvm::make_early_inc_range(getOperation().getOps<gpu::GPUModuleOp>()))
	gpuModule.erase();

	for (auto spirvModule :
	llvm::make_early_inc_range(getOperation().getOps<spirv::ModuleOp>()))
	spirvModule.erase();
	}

	LogicalResult ConvertGpuLaunchFuncToVulkanLaunchFunc::declareVulkanLaunchFunc(
	Location loc, gpu::LaunchFuncOp launchOp) {
	auto builder = OpBuilder::atBlockEnd(getOperation().getBody());

	// Workgroup size is written into the kernel. So to properly modelling
	// vulkan launch, we have to skip local workgroup size configuration here.
	SmallVector<Type, 8> gpuLaunchTypes(launchOp.getOperandTypes());
	// The first kVulkanLaunchNumConfigOperands of the gpu.launch_func op are the
	// same as the config operands for the vulkan launch call op.
	SmallVector<Type, 8> vulkanLaunchTypes(gpuLaunchTypes.begin(),
	gpuLaunchTypes.begin() +
	kVulkanLaunchNumConfigOperands);
	vulkanLaunchTypes.append(gpuLaunchTypes.begin() +
	gpu::LaunchOp::kNumConfigOperands,
	gpuLaunchTypes.end());

	// Check that all operands have supported types except those for the
	// launch configuration.
	for (auto type :
	llvm::drop_begin(vulkanLaunchTypes, kVulkanLaunchNumConfigOperands)) {
	if (!isSupportedType(type))
	return launchOp.emitError() << type << " is unsupported to run on Vulkan";
	}

	// Declare vulkan launch function.
	auto funcType = builder.getFunctionType(vulkanLaunchTypes, {});
	builder.create<FuncOp>(loc, kVulkanLaunch, funcType).setPrivate();

	return success();
	}

	LogicalResult ConvertGpuLaunchFuncToVulkanLaunchFunc::createBinaryShader(
	ModuleOp module, std::vector<char> &binaryShader) {
	bool done = false;
	SmallVector<uint32_t, 0> binary;
	for (auto spirvModule : module.getOps<spirv::ModuleOp>()) {
	if (done)
	return spirvModule.emitError("should only contain one 'spv.module' op");
	done = true;

	if (failed(spirv::serialize(spirvModule, binary)))
	return failure();
	}
	binaryShader.resize(binary.size() * sizeof(uint32_t));
	std::memcpy(binaryShader.data(), reinterpret_cast<char *>(binary.data()),
	binaryShader.size());
	return success();
	}

	void ConvertGpuLaunchFuncToVulkanLaunchFunc::convertGpuLaunchFunc(
	gpu::LaunchFuncOp launchOp) {
	ModuleOp module = getOperation();
	OpBuilder builder(launchOp);
	Location loc = launchOp.getLoc();

	// Serialize `spirv::Module` into binary form.
	std::vector<char> binary;
	if (failed(createBinaryShader(module, binary)))
	return signalPassFailure();

	// Declare vulkan launch function.
	if (failed(declareVulkanLaunchFunc(loc, launchOp)))
	return signalPassFailure();

	SmallVector<Value, 8> gpuLaunchOperands(launchOp.getOperands());
	SmallVector<Value, 8> vulkanLaunchOperands(
	gpuLaunchOperands.begin(),
	gpuLaunchOperands.begin() + kVulkanLaunchNumConfigOperands);
	vulkanLaunchOperands.append(gpuLaunchOperands.begin() +
	gpu::LaunchOp::kNumConfigOperands,
	gpuLaunchOperands.end());

	// Create vulkan launch call op.
	auto vulkanLaunchCallOp = builder.create<CallOp>(
	loc, TypeRange{}, SymbolRefAttr::get(builder.getContext(), kVulkanLaunch),
	vulkanLaunchOperands);

	// Set SPIR-V binary shader data as an attribute.
	vulkanLaunchCallOp->setAttr(
	kSPIRVBlobAttrName,
	builder.getStringAttr(StringRef(binary.data(), binary.size())));

	// Set entry point name as an attribute.
	vulkanLaunchCallOp->setAttr(kSPIRVEntryPointAttrName,
	launchOp.getKernelName());

	launchOp.erase();
	}

	std::unique_ptr<mlir::OperationPass<mlir::ModuleOp>>
	mlir::createConvertGpuLaunchFuncToVulkanLaunchFuncPass() {
	return std::make_unique<ConvertGpuLaunchFuncToVulkanLaunchFunc>();
	}