src/writer/spirv/builder_cast_expression_test.cc - tint - Git at Google

 // Copyright 2020 The Tint Authors.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #include "gtest/gtest.h"
 #include "src/ast/cast_expression.h"
 #include "src/ast/float_literal.h"
 #include "src/ast/identifier_expression.h"
 #include "src/ast/module.h"
 #include "src/ast/scalar_constructor_expression.h"
 #include "src/ast/sint_literal.h"
 #include "src/ast/type/f32_type.h"
 #include "src/ast/type/i32_type.h"
 #include "src/ast/type/u32_type.h"
 #include "src/ast/uint_literal.h"
 #include "src/context.h"
 #include "src/type_determiner.h"
 #include "src/writer/spirv/builder.h"
 #include "src/writer/spirv/spv_dump.h"

 namespace tint {
 namespace writer {
 namespace spirv {
 namespace {

 using BuilderTest = testing::Test;

 TEST_F(BuilderTest, Cast_FloatToU32) {
   ast::type::U32Type u32;
   ast::type::F32Type f32;

   ast::CastExpression cast(&u32,
                            std::make_unique<ast::ScalarConstructorExpression>(
                                std::make_unique<ast::FloatLiteral>(&f32, 2.4)));

   Context ctx;
   ast::Module mod;
   TypeDeterminer td(&ctx, &mod);
   ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

   Builder b(&mod);
   b.push_function(Function{});
   EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

   EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 0
 %3 = OpTypeFloat 32
 %4 = OpConstant %3 2.4000001
 )");
   EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
             R"(%1 = OpConvertFToU %2 %4
 )");
 }

 TEST_F(BuilderTest, Cast_FloatToI32) {
   ast::type::I32Type i32;
   ast::type::F32Type f32;

   ast::CastExpression cast(&i32,
                            std::make_unique<ast::ScalarConstructorExpression>(
                                std::make_unique<ast::FloatLiteral>(&f32, 2.4)));

   Context ctx;
   ast::Module mod;
   TypeDeterminer td(&ctx, &mod);
   ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

   Builder b(&mod);
   b.push_function(Function{});
   EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

   EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
 %3 = OpTypeFloat 32
 %4 = OpConstant %3 2.4000001
 )");
   EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
             R"(%1 = OpConvertFToS %2 %4
 )");
 }

 TEST_F(BuilderTest, Cast_I32ToFloat) {
   ast::type::I32Type i32;
   ast::type::F32Type f32;

   ast::CastExpression cast(&f32,
                            std::make_unique<ast::ScalarConstructorExpression>(
                                std::make_unique<ast::SintLiteral>(&i32, 2)));

   Context ctx;
   ast::Module mod;
   TypeDeterminer td(&ctx, &mod);
   ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

   Builder b(&mod);
   b.push_function(Function{});
   EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

   EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
 %3 = OpTypeInt 32 1
 %4 = OpConstant %3 2
 )");
   EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
             R"(%1 = OpConvertSToF %2 %4
 )");
 }

 TEST_F(BuilderTest, Cast_U32ToFloat) {
   ast::type::U32Type u32;
   ast::type::F32Type f32;

   ast::CastExpression cast(&f32,
                            std::make_unique<ast::ScalarConstructorExpression>(
                                std::make_unique<ast::UintLiteral>(&u32, 2)));

   Context ctx;
   ast::Module mod;
   TypeDeterminer td(&ctx, &mod);
   ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

   Builder b(&mod);
   b.push_function(Function{});
   EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

   EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
 %3 = OpTypeInt 32 0
 %4 = OpConstant %3 2
 )");
   EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
             R"(%1 = OpConvertUToF %2 %4
 )");
 }

 TEST_F(BuilderTest, Cast_WithLoad) {
   ast::type::F32Type f32;
   ast::type::I32Type i32;

   // var i : i32 = 1;
   // cast<f32>(i);
   auto var =
       std::make_unique<ast::Variable>("i", ast::StorageClass::kPrivate, &i32);

   ast::CastExpression cast(&f32,
                            std::make_unique<ast::IdentifierExpression>("i"));

   Context ctx;
   ast::Module mod;
   TypeDeterminer td(&ctx, &mod);
   td.RegisterVariableForTesting(var.get());
   ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

   Builder b(&mod);
   b.push_function(Function{});
   ASSERT_TRUE(b.GenerateGlobalVariable(var.get())) << b.error();
   EXPECT_EQ(b.GenerateCastExpression(&cast), 5u) << b.error();

   EXPECT_EQ(DumpInstructions(b.types()), R"(%3 = OpTypeInt 32 1
 %2 = OpTypePointer Private %3
 %4 = OpConstantNull %3
 %1 = OpVariable %2 Private %4
 %6 = OpTypeFloat 32
 )");
   EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
             R"(%7 = OpLoad %3 %1
 %5 = OpConvertSToF %6 %7
 )");
 }

 TEST_F(BuilderTest, Cast_WithAlias) {
   ast::type::I32Type i32;
   ast::type::F32Type f32;

   // type Int = i32
   // cast<Int>(1.f)

   ast::type::AliasType alias("Int", &i32);

   ast::CastExpression cast(&alias,
                            std::make_unique<ast::ScalarConstructorExpression>(
                                std::make_unique<ast::FloatLiteral>(&f32, 2.3)));

   Context ctx;
   ast::Module mod;
   TypeDeterminer td(&ctx, &mod);
   ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

   Builder b(&mod);
   b.push_function(Function{});
   EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

   EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
 %3 = OpTypeFloat 32
 %4 = OpConstant %3 2.29999995
 )");
   EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
             R"(%1 = OpConvertFToS %2 %4
 )");
 }

 TEST_F(BuilderTest, Cast_I32ToU32) {
   ast::type::U32Type u32;
   ast::type::I32Type i32;

   ast::CastExpression cast(&u32,
                            std::make_unique<ast::ScalarConstructorExpression>(
                                std::make_unique<ast::SintLiteral>(&i32, 2)));

   Context ctx;
   ast::Module mod;
   TypeDeterminer td(&ctx, &mod);
   ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

   Builder b(&mod);
   b.push_function(Function{});
   EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

   EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 0
 %3 = OpTypeInt 32 1
 %4 = OpConstant %3 2
 )");
   EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
             R"(%1 = OpBitcast %2 %4
 )");
 }

 TEST_F(BuilderTest, Cast_U32ToI32) {
   ast::type::U32Type u32;
   ast::type::I32Type i32;

   ast::CastExpression cast(&i32,
                            std::make_unique<ast::ScalarConstructorExpression>(
                                std::make_unique<ast::UintLiteral>(&u32, 2)));

   Context ctx;
   ast::Module mod;
   TypeDeterminer td(&ctx, &mod);
   ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

   Builder b(&mod);
   b.push_function(Function{});
   EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

   EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
 %3 = OpTypeInt 32 0
 %4 = OpConstant %3 2
 )");
   EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
             R"(%1 = OpBitcast %2 %4
 )");
 }

 TEST_F(BuilderTest, Cast_I32ToI32) {
   ast::type::I32Type i32;

   ast::CastExpression cast(&i32,
                            std::make_unique<ast::ScalarConstructorExpression>(
                                std::make_unique<ast::SintLiteral>(&i32, 2)));

   Context ctx;
   ast::Module mod;
   TypeDeterminer td(&ctx, &mod);
   ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

   Builder b(&mod);
   b.push_function(Function{});
   EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

   EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
 %3 = OpConstant %2 2
 )");
   EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
             R"(%1 = OpCopyObject %2 %3
 )");
 }

 TEST_F(BuilderTest, Cast_U32ToU32) {
   ast::type::U32Type u32;

   ast::CastExpression cast(&u32,
                            std::make_unique<ast::ScalarConstructorExpression>(
                                std::make_unique<ast::UintLiteral>(&u32, 2)));

   Context ctx;
   ast::Module mod;
   TypeDeterminer td(&ctx, &mod);
   ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

   Builder b(&mod);
   b.push_function(Function{});
   EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

   EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 0
 %3 = OpConstant %2 2
 )");
   EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
             R"(%1 = OpCopyObject %2 %3
 )");
 }

 TEST_F(BuilderTest, Cast_F32ToF32) {
   ast::type::F32Type f32;

   ast::CastExpression cast(&f32,
                            std::make_unique<ast::ScalarConstructorExpression>(
                                std::make_unique<ast::FloatLiteral>(&f32, 2.0)));

   Context ctx;
   ast::Module mod;
   TypeDeterminer td(&ctx, &mod);
   ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

   Builder b(&mod);
   b.push_function(Function{});
   EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

   EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
 %3 = OpConstant %2 2
 )");
   EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
             R"(%1 = OpCopyObject %2 %3
 )");
 }

 }  // namespace
 }  // namespace spirv
 }  // namespace writer
 }  // namespace tint
	// Copyright 2020 The Tint Authors.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#include "gtest/gtest.h"
	#include "src/ast/cast_expression.h"
	#include "src/ast/float_literal.h"
	#include "src/ast/identifier_expression.h"
	#include "src/ast/module.h"
	#include "src/ast/scalar_constructor_expression.h"
	#include "src/ast/sint_literal.h"
	#include "src/ast/type/f32_type.h"
	#include "src/ast/type/i32_type.h"
	#include "src/ast/type/u32_type.h"
	#include "src/ast/uint_literal.h"
	#include "src/context.h"
	#include "src/type_determiner.h"
	#include "src/writer/spirv/builder.h"
	#include "src/writer/spirv/spv_dump.h"

	namespace tint {
	namespace writer {
	namespace spirv {
	namespace {

	using BuilderTest = testing::Test;

	TEST_F(BuilderTest, Cast_FloatToU32) {
	ast::type::U32Type u32;
	ast::type::F32Type f32;

	ast::CastExpression cast(&u32,
	std::make_unique<ast::ScalarConstructorExpression>(
	std::make_unique<ast::FloatLiteral>(&f32, 2.4)));

	Context ctx;
	ast::Module mod;
	TypeDeterminer td(&ctx, &mod);
	ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

	Builder b(&mod);
	b.push_function(Function{});
	EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

	EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 0
	%3 = OpTypeFloat 32
	%4 = OpConstant %3 2.4000001
	)");
	EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
	R"(%1 = OpConvertFToU %2 %4
	)");
	}

	TEST_F(BuilderTest, Cast_FloatToI32) {
	ast::type::I32Type i32;
	ast::type::F32Type f32;

	ast::CastExpression cast(&i32,
	std::make_unique<ast::ScalarConstructorExpression>(
	std::make_unique<ast::FloatLiteral>(&f32, 2.4)));

	Context ctx;
	ast::Module mod;
	TypeDeterminer td(&ctx, &mod);
	ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

	Builder b(&mod);
	b.push_function(Function{});
	EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

	EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
	%3 = OpTypeFloat 32
	%4 = OpConstant %3 2.4000001
	)");
	EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
	R"(%1 = OpConvertFToS %2 %4
	)");
	}

	TEST_F(BuilderTest, Cast_I32ToFloat) {
	ast::type::I32Type i32;
	ast::type::F32Type f32;

	ast::CastExpression cast(&f32,
	std::make_unique<ast::ScalarConstructorExpression>(
	std::make_unique<ast::SintLiteral>(&i32, 2)));

	Context ctx;
	ast::Module mod;
	TypeDeterminer td(&ctx, &mod);
	ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

	Builder b(&mod);
	b.push_function(Function{});
	EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

	EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
	%3 = OpTypeInt 32 1
	%4 = OpConstant %3 2
	)");
	EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
	R"(%1 = OpConvertSToF %2 %4
	)");
	}

	TEST_F(BuilderTest, Cast_U32ToFloat) {
	ast::type::U32Type u32;
	ast::type::F32Type f32;

	ast::CastExpression cast(&f32,
	std::make_unique<ast::ScalarConstructorExpression>(
	std::make_unique<ast::UintLiteral>(&u32, 2)));

	Context ctx;
	ast::Module mod;
	TypeDeterminer td(&ctx, &mod);
	ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

	Builder b(&mod);
	b.push_function(Function{});
	EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

	EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
	%3 = OpTypeInt 32 0
	%4 = OpConstant %3 2
	)");
	EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
	R"(%1 = OpConvertUToF %2 %4
	)");
	}

	TEST_F(BuilderTest, Cast_WithLoad) {
	ast::type::F32Type f32;
	ast::type::I32Type i32;

	// var i : i32 = 1;
	// cast<f32>(i);
	auto var =
	std::make_unique<ast::Variable>("i", ast::StorageClass::kPrivate, &i32);

	ast::CastExpression cast(&f32,
	std::make_unique<ast::IdentifierExpression>("i"));

	Context ctx;
	ast::Module mod;
	TypeDeterminer td(&ctx, &mod);
	td.RegisterVariableForTesting(var.get());
	ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

	Builder b(&mod);
	b.push_function(Function{});
	ASSERT_TRUE(b.GenerateGlobalVariable(var.get())) << b.error();
	EXPECT_EQ(b.GenerateCastExpression(&cast), 5u) << b.error();

	EXPECT_EQ(DumpInstructions(b.types()), R"(%3 = OpTypeInt 32 1
	%2 = OpTypePointer Private %3
	%4 = OpConstantNull %3
	%1 = OpVariable %2 Private %4
	%6 = OpTypeFloat 32
	)");
	EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
	R"(%7 = OpLoad %3 %1
	%5 = OpConvertSToF %6 %7
	)");
	}

	TEST_F(BuilderTest, Cast_WithAlias) {
	ast::type::I32Type i32;
	ast::type::F32Type f32;

	// type Int = i32
	// cast<Int>(1.f)

	ast::type::AliasType alias("Int", &i32);

	ast::CastExpression cast(&alias,
	std::make_unique<ast::ScalarConstructorExpression>(
	std::make_unique<ast::FloatLiteral>(&f32, 2.3)));

	Context ctx;
	ast::Module mod;
	TypeDeterminer td(&ctx, &mod);
	ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

	Builder b(&mod);
	b.push_function(Function{});
	EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

	EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
	%3 = OpTypeFloat 32
	%4 = OpConstant %3 2.29999995
	)");
	EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
	R"(%1 = OpConvertFToS %2 %4
	)");
	}

	TEST_F(BuilderTest, Cast_I32ToU32) {
	ast::type::U32Type u32;
	ast::type::I32Type i32;

	ast::CastExpression cast(&u32,
	std::make_unique<ast::ScalarConstructorExpression>(
	std::make_unique<ast::SintLiteral>(&i32, 2)));

	Context ctx;
	ast::Module mod;
	TypeDeterminer td(&ctx, &mod);
	ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

	Builder b(&mod);
	b.push_function(Function{});
	EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

	EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 0
	%3 = OpTypeInt 32 1
	%4 = OpConstant %3 2
	)");
	EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
	R"(%1 = OpBitcast %2 %4
	)");
	}

	TEST_F(BuilderTest, Cast_U32ToI32) {
	ast::type::U32Type u32;
	ast::type::I32Type i32;

	ast::CastExpression cast(&i32,
	std::make_unique<ast::ScalarConstructorExpression>(
	std::make_unique<ast::UintLiteral>(&u32, 2)));

	Context ctx;
	ast::Module mod;
	TypeDeterminer td(&ctx, &mod);
	ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

	Builder b(&mod);
	b.push_function(Function{});
	EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

	EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
	%3 = OpTypeInt 32 0
	%4 = OpConstant %3 2
	)");
	EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
	R"(%1 = OpBitcast %2 %4
	)");
	}

	TEST_F(BuilderTest, Cast_I32ToI32) {
	ast::type::I32Type i32;

	ast::CastExpression cast(&i32,
	std::make_unique<ast::ScalarConstructorExpression>(
	std::make_unique<ast::SintLiteral>(&i32, 2)));

	Context ctx;
	ast::Module mod;
	TypeDeterminer td(&ctx, &mod);
	ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

	Builder b(&mod);
	b.push_function(Function{});
	EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

	EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
	%3 = OpConstant %2 2
	)");
	EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
	R"(%1 = OpCopyObject %2 %3
	)");
	}

	TEST_F(BuilderTest, Cast_U32ToU32) {
	ast::type::U32Type u32;

	ast::CastExpression cast(&u32,
	std::make_unique<ast::ScalarConstructorExpression>(
	std::make_unique<ast::UintLiteral>(&u32, 2)));

	Context ctx;
	ast::Module mod;
	TypeDeterminer td(&ctx, &mod);
	ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

	Builder b(&mod);
	b.push_function(Function{});
	EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

	EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 0
	%3 = OpConstant %2 2
	)");
	EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
	R"(%1 = OpCopyObject %2 %3
	)");
	}

	TEST_F(BuilderTest, Cast_F32ToF32) {
	ast::type::F32Type f32;

	ast::CastExpression cast(&f32,
	std::make_unique<ast::ScalarConstructorExpression>(
	std::make_unique<ast::FloatLiteral>(&f32, 2.0)));

	Context ctx;
	ast::Module mod;
	TypeDeterminer td(&ctx, &mod);
	ASSERT_TRUE(td.DetermineResultType(&cast)) << td.error();

	Builder b(&mod);
	b.push_function(Function{});
	EXPECT_EQ(b.GenerateCastExpression(&cast), 1u);

	EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
	%3 = OpConstant %2 2
	)");
	EXPECT_EQ(DumpInstructions(b.functions()[0].instructions()),
	R"(%1 = OpCopyObject %2 %3
	)");
	}

	} // namespace
	} // namespace spirv
	} // namespace writer
	} // namespace tint