flang/unittests/Optimizer/Builder/Runtime/RuntimeCallTestBase.h - llvm-project - Git at Google

 //===- RuntimeCallTestBase.cpp -- Base for runtime call generation tests --===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 #ifndef FORTRAN_OPTIMIZER_BUILDER_RUNTIME_RUNTIMECALLTESTBASE_H
 #define FORTRAN_OPTIMIZER_BUILDER_RUNTIME_RUNTIMECALLTESTBASE_H

 #include "gtest/gtest.h"
 #include "flang/Optimizer/Builder/FIRBuilder.h"
 #include "flang/Optimizer/Support/InitFIR.h"
 #include "flang/Optimizer/Support/KindMapping.h"

 struct RuntimeCallTest : public testing::Test {
 public:
   void SetUp() override {
     mlir::OpBuilder builder(&context);
     auto loc = builder.getUnknownLoc();

     // Set up a Module with a dummy function operation inside.
     // Set the insertion point in the function entry block.
     mlir::ModuleOp mod = builder.create<mlir::ModuleOp>(loc);
     mlir::FuncOp func = mlir::FuncOp::create(loc, "runtime_unit_tests_func",
         builder.getFunctionType(llvm::None, llvm::None));
     auto *entryBlock = func.addEntryBlock();
     mod.push_back(mod);
     builder.setInsertionPointToStart(entryBlock);

     fir::support::loadDialects(context);
     kindMap = std::make_unique<fir::KindMapping>(&context);
     firBuilder = std::make_unique<fir::FirOpBuilder>(mod, *kindMap);

     i8Ty = firBuilder->getI8Type();
     i16Ty = firBuilder->getIntegerType(16);
     i32Ty = firBuilder->getI32Type();
     i64Ty = firBuilder->getI64Type();
     i128Ty = firBuilder->getIntegerType(128);

     f32Ty = firBuilder->getF32Type();
     f64Ty = firBuilder->getF64Type();
     f80Ty = firBuilder->getF80Type();
     f128Ty = firBuilder->getF128Type();

     c4Ty = fir::ComplexType::get(firBuilder->getContext(), 4);
     c8Ty = fir::ComplexType::get(firBuilder->getContext(), 8);
     c10Ty = fir::ComplexType::get(firBuilder->getContext(), 10);
     c16Ty = fir::ComplexType::get(firBuilder->getContext(), 16);
   }

   mlir::MLIRContext context;
   std::unique_ptr<fir::KindMapping> kindMap;
   std::unique_ptr<fir::FirOpBuilder> firBuilder;

   // Commonly used types
   mlir::Type i8Ty;
   mlir::Type i16Ty;
   mlir::Type i32Ty;
   mlir::Type i64Ty;
   mlir::Type i128Ty;
   mlir::Type f32Ty;
   mlir::Type f64Ty;
   mlir::Type f80Ty;
   mlir::Type f128Ty;
   mlir::Type c4Ty;
   mlir::Type c8Ty;
   mlir::Type c10Ty;
   mlir::Type c16Ty;
 };

 /// Check that the \p op is a `fir::CallOp` operation and its name matches
 /// \p fctName and the number of arguments is equal to \p nbArgs.
 /// Most runtime calls have two additional location arguments added. These are
 /// added in this check when \p addLocArgs is true.
 static void checkCallOp(mlir::Operation *op, llvm::StringRef fctName,
     unsigned nbArgs, bool addLocArgs = true) {
   EXPECT_TRUE(mlir::isa<fir::CallOp>(*op));
   auto callOp = mlir::dyn_cast<fir::CallOp>(*op);
   EXPECT_TRUE(callOp.callee().hasValue());
   mlir::SymbolRefAttr callee = *callOp.callee();
   EXPECT_EQ(fctName, callee.getRootReference().getValue());
   // sourceFile and sourceLine are added arguments.
   if (addLocArgs)
     nbArgs += 2;
   EXPECT_EQ(nbArgs, callOp.args().size());
 }

 /// Check the call operation from the \p result value. In some cases the
 /// value is directly used in the call and sometimes there is an indirection
 /// through a `fir.convert` operation. Once the `fir.call` operation is
 /// retrieved the check is made by `checkCallOp`.
 ///
 /// Directly used in `fir.call`.
 /// ```
 /// %result = arith.constant 1 : i32
 /// %0 = fir.call @foo(%result) : (i32) -> i1
 /// ```
 ///
 /// Value used in `fir.call` through `fir.convert` indirection.
 /// ```
 /// %result = arith.constant 1 : i32
 /// %arg = fir.convert %result : (i32) -> i16
 /// %0 = fir.call @foo(%arg) : (i16) -> i1
 /// ```
 static void checkCallOpFromResultBox(mlir::Value result,
     llvm::StringRef fctName, unsigned nbArgs, bool addLocArgs = true) {
   EXPECT_TRUE(result.hasOneUse());
   const auto &u = result.user_begin();
   if (mlir::isa<fir::CallOp>(*u))
     return checkCallOp(*u, fctName, nbArgs, addLocArgs);
   auto convOp = mlir::dyn_cast<fir::ConvertOp>(*u);
   EXPECT_NE(nullptr, convOp);
   checkCallOpFromResultBox(convOp.getResult(), fctName, nbArgs, addLocArgs);
 }

 #endif // FORTRAN_OPTIMIZER_BUILDER_RUNTIME_RUNTIMECALLTESTBASE_H
	//===- RuntimeCallTestBase.cpp -- Base for runtime call generation tests --===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	#ifndef FORTRAN_OPTIMIZER_BUILDER_RUNTIME_RUNTIMECALLTESTBASE_H
	#define FORTRAN_OPTIMIZER_BUILDER_RUNTIME_RUNTIMECALLTESTBASE_H

	#include "gtest/gtest.h"
	#include "flang/Optimizer/Builder/FIRBuilder.h"
	#include "flang/Optimizer/Support/InitFIR.h"
	#include "flang/Optimizer/Support/KindMapping.h"

	struct RuntimeCallTest : public testing::Test {
	public:
	void SetUp() override {
	mlir::OpBuilder builder(&context);
	auto loc = builder.getUnknownLoc();

	// Set up a Module with a dummy function operation inside.
	// Set the insertion point in the function entry block.
	mlir::ModuleOp mod = builder.create<mlir::ModuleOp>(loc);
	mlir::FuncOp func = mlir::FuncOp::create(loc, "runtime_unit_tests_func",
	builder.getFunctionType(llvm::None, llvm::None));
	auto *entryBlock = func.addEntryBlock();
	mod.push_back(mod);
	builder.setInsertionPointToStart(entryBlock);

	fir::support::loadDialects(context);
	kindMap = std::make_unique<fir::KindMapping>(&context);
	firBuilder = std::make_unique<fir::FirOpBuilder>(mod, *kindMap);

	i8Ty = firBuilder->getI8Type();
	i16Ty = firBuilder->getIntegerType(16);
	i32Ty = firBuilder->getI32Type();
	i64Ty = firBuilder->getI64Type();
	i128Ty = firBuilder->getIntegerType(128);

	f32Ty = firBuilder->getF32Type();
	f64Ty = firBuilder->getF64Type();
	f80Ty = firBuilder->getF80Type();
	f128Ty = firBuilder->getF128Type();

	c4Ty = fir::ComplexType::get(firBuilder->getContext(), 4);
	c8Ty = fir::ComplexType::get(firBuilder->getContext(), 8);
	c10Ty = fir::ComplexType::get(firBuilder->getContext(), 10);
	c16Ty = fir::ComplexType::get(firBuilder->getContext(), 16);
	}

	mlir::MLIRContext context;
	std::unique_ptr<fir::KindMapping> kindMap;
	std::unique_ptr<fir::FirOpBuilder> firBuilder;

	// Commonly used types
	mlir::Type i8Ty;
	mlir::Type i16Ty;
	mlir::Type i32Ty;
	mlir::Type i64Ty;
	mlir::Type i128Ty;
	mlir::Type f32Ty;
	mlir::Type f64Ty;
	mlir::Type f80Ty;
	mlir::Type f128Ty;
	mlir::Type c4Ty;
	mlir::Type c8Ty;
	mlir::Type c10Ty;
	mlir::Type c16Ty;
	};

	/// Check that the \p op is a `fir::CallOp` operation and its name matches
	/// \p fctName and the number of arguments is equal to \p nbArgs.
	/// Most runtime calls have two additional location arguments added. These are
	/// added in this check when \p addLocArgs is true.
	static void checkCallOp(mlir::Operation *op, llvm::StringRef fctName,
	unsigned nbArgs, bool addLocArgs = true) {
	EXPECT_TRUE(mlir::isa<fir::CallOp>(*op));
	auto callOp = mlir::dyn_cast<fir::CallOp>(*op);
	EXPECT_TRUE(callOp.callee().hasValue());
	mlir::SymbolRefAttr callee = *callOp.callee();
	EXPECT_EQ(fctName, callee.getRootReference().getValue());
	// sourceFile and sourceLine are added arguments.
	if (addLocArgs)
	nbArgs += 2;
	EXPECT_EQ(nbArgs, callOp.args().size());
	}

	/// Check the call operation from the \p result value. In some cases the
	/// value is directly used in the call and sometimes there is an indirection
	/// through a `fir.convert` operation. Once the `fir.call` operation is
	/// retrieved the check is made by `checkCallOp`.
	///
	/// Directly used in `fir.call`.
	/// ```
	/// %result = arith.constant 1 : i32
	/// %0 = fir.call @foo(%result) : (i32) -> i1
	/// ```
	///
	/// Value used in `fir.call` through `fir.convert` indirection.
	/// ```
	/// %result = arith.constant 1 : i32
	/// %arg = fir.convert %result : (i32) -> i16
	/// %0 = fir.call @foo(%arg) : (i16) -> i1
	/// ```
	static void checkCallOpFromResultBox(mlir::Value result,
	llvm::StringRef fctName, unsigned nbArgs, bool addLocArgs = true) {
	EXPECT_TRUE(result.hasOneUse());
	const auto &u = result.user_begin();
	if (mlir::isa<fir::CallOp>(*u))
	return checkCallOp(*u, fctName, nbArgs, addLocArgs);
	auto convOp = mlir::dyn_cast<fir::ConvertOp>(*u);
	EXPECT_NE(nullptr, convOp);
	checkCallOpFromResultBox(convOp.getResult(), fctName, nbArgs, addLocArgs);
	}

	#endif // FORTRAN_OPTIMIZER_BUILDER_RUNTIME_RUNTIMECALLTESTBASE_H