//===- TransformationalTest.cpp -- Transformational intrinsic generation --===// // // 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 "flang/Optimizer/Builder/Runtime/Transformational.h" #include "RuntimeCallTestBase.h" #include "gtest/gtest.h" TEST_F(RuntimeCallTest, genCshiftTest) { auto loc = firBuilder->getUnknownLoc(); mlir::Type seqTy = fir::SequenceType::get(fir::SequenceType::Shape(1, 10), i32Ty); mlir::Value result = firBuilder->create(loc, seqTy); mlir::Value array = firBuilder->create(loc, seqTy); mlir::Value shift = firBuilder->create(loc, seqTy); mlir::Value dim = firBuilder->create(loc, seqTy); fir::runtime::genCshift(*firBuilder, loc, result, array, shift, dim); checkCallOpFromResultBox(result, "_FortranACshift", 4); } TEST_F(RuntimeCallTest, genCshiftVectorTest) { auto loc = firBuilder->getUnknownLoc(); mlir::Type seqTy = fir::SequenceType::get(fir::SequenceType::Shape(1, 10), i32Ty); mlir::Value result = firBuilder->create(loc, seqTy); mlir::Value array = firBuilder->create(loc, seqTy); mlir::Value shift = firBuilder->create(loc, seqTy); fir::runtime::genCshiftVector(*firBuilder, loc, result, array, shift); checkCallOpFromResultBox(result, "_FortranACshiftVector", 3); } TEST_F(RuntimeCallTest, genEoshiftTest) { auto loc = firBuilder->getUnknownLoc(); mlir::Type seqTy = fir::SequenceType::get(fir::SequenceType::Shape(1, 10), i32Ty); mlir::Value result = firBuilder->create(loc, seqTy); mlir::Value array = firBuilder->create(loc, seqTy); mlir::Value shift = firBuilder->create(loc, seqTy); mlir::Value bound = firBuilder->create(loc, seqTy); mlir::Value dim = firBuilder->create(loc, seqTy); fir::runtime::genEoshift(*firBuilder, loc, result, array, shift, bound, dim); checkCallOpFromResultBox(result, "_FortranAEoshift", 5); } TEST_F(RuntimeCallTest, genEoshiftVectorTest) { auto loc = firBuilder->getUnknownLoc(); mlir::Type seqTy = fir::SequenceType::get(fir::SequenceType::Shape(1, 10), i32Ty); mlir::Value result = firBuilder->create(loc, seqTy); mlir::Value array = firBuilder->create(loc, seqTy); mlir::Value shift = firBuilder->create(loc, seqTy); mlir::Value bound = firBuilder->create(loc, seqTy); fir::runtime::genEoshiftVector(*firBuilder, loc, result, array, shift, bound); checkCallOpFromResultBox(result, "_FortranAEoshiftVector", 4); } TEST_F(RuntimeCallTest, genMatmulTest) { auto loc = firBuilder->getUnknownLoc(); mlir::Type seqTy = fir::SequenceType::get(fir::SequenceType::Shape(1, 10), i32Ty); mlir::Value result = firBuilder->create(loc, seqTy); mlir::Value matrixA = firBuilder->create(loc, seqTy); mlir::Value matrixB = firBuilder->create(loc, seqTy); fir::runtime::genMatmul(*firBuilder, loc, matrixA, matrixB, result); checkCallOpFromResultBox(result, "_FortranAMatmul", 3); } TEST_F(RuntimeCallTest, genPackTest) { auto loc = firBuilder->getUnknownLoc(); mlir::Type seqTy = fir::SequenceType::get(fir::SequenceType::Shape(1, 10), i32Ty); mlir::Value result = firBuilder->create(loc, seqTy); mlir::Value array = firBuilder->create(loc, seqTy); mlir::Value mask = firBuilder->create(loc, seqTy); mlir::Value vector = firBuilder->create(loc, seqTy); fir::runtime::genPack(*firBuilder, loc, result, array, mask, vector); checkCallOpFromResultBox(result, "_FortranAPack", 4); } TEST_F(RuntimeCallTest, genReshapeTest) { auto loc = firBuilder->getUnknownLoc(); mlir::Type seqTy = fir::SequenceType::get(fir::SequenceType::Shape(1, 10), i32Ty); mlir::Value result = firBuilder->create(loc, seqTy); mlir::Value source = firBuilder->create(loc, seqTy); mlir::Value shape = firBuilder->create(loc, seqTy); mlir::Value pad = firBuilder->create(loc, seqTy); mlir::Value order = firBuilder->create(loc, seqTy); fir::runtime::genReshape(*firBuilder, loc, result, source, shape, pad, order); checkCallOpFromResultBox(result, "_FortranAReshape", 5); } TEST_F(RuntimeCallTest, genSpreadTest) { auto loc = firBuilder->getUnknownLoc(); mlir::Type seqTy = fir::SequenceType::get(fir::SequenceType::Shape(1, 10), i32Ty); mlir::Value result = firBuilder->create(loc, seqTy); mlir::Value source = firBuilder->create(loc, seqTy); mlir::Value dim = firBuilder->create(loc, seqTy); mlir::Value ncopies = firBuilder->create(loc, seqTy); fir::runtime::genSpread(*firBuilder, loc, result, source, dim, ncopies); checkCallOpFromResultBox(result, "_FortranASpread", 4); } TEST_F(RuntimeCallTest, genTransposeTest) { auto loc = firBuilder->getUnknownLoc(); mlir::Type seqTy = fir::SequenceType::get(fir::SequenceType::Shape(1, 10), i32Ty); mlir::Value result = firBuilder->create(loc, seqTy); mlir::Value source = firBuilder->create(loc, seqTy); fir::runtime::genTranspose(*firBuilder, loc, result, source); checkCallOpFromResultBox(result, "_FortranATranspose", 2); } TEST_F(RuntimeCallTest, genUnpack) { auto loc = firBuilder->getUnknownLoc(); mlir::Type seqTy = fir::SequenceType::get(fir::SequenceType::Shape(1, 10), i32Ty); mlir::Value result = firBuilder->create(loc, seqTy); mlir::Value vector = firBuilder->create(loc, seqTy); mlir::Value mask = firBuilder->create(loc, seqTy); mlir::Value field = firBuilder->create(loc, seqTy); fir::runtime::genUnpack(*firBuilder, loc, result, vector, mask, field); checkCallOpFromResultBox(result, "_FortranAUnpack", 4); }