// 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/array_accessor_expression.h" #include "src/ast/as_expression.h" #include "src/ast/bool_literal.h" #include "src/ast/cast_expression.h" #include "src/ast/identifier_expression.h" #include "src/ast/int_literal.h" #include "src/ast/scalar_constructor_expression.h" #include "src/ast/type/f32_type.h" #include "src/ast/type/i32_type.h" #include "src/ast/type_constructor_expression.h" #include "src/ast/unary_derivative_expression.h" #include "src/ast/unary_method_expression.h" #include "src/ast/unary_op_expression.h" #include "src/reader/wgsl/parser_impl.h" #include "src/reader/wgsl/parser_impl_test_helper.h" #include "src/type_manager.h" namespace tint { namespace reader { namespace wgsl { namespace { TEST_F(ParserImplTest, PrimaryExpression_Ident) { auto p = parser("a"); auto e = p->primary_expression(); ASSERT_FALSE(p->has_error()) << p->error(); ASSERT_NE(e, nullptr); ASSERT_TRUE(e->IsIdentifier()); auto ident = e->AsIdentifier(); ASSERT_EQ(ident->name().size(), 1); EXPECT_EQ(ident->name()[0], "a"); } TEST_F(ParserImplTest, PrimaryExpression_Ident_WithNamespace) { auto p = parser("a::b::c::d"); auto e = p->primary_expression(); ASSERT_FALSE(p->has_error()) << p->error(); ASSERT_NE(e, nullptr); ASSERT_TRUE(e->IsIdentifier()); auto ident = e->AsIdentifier(); ASSERT_EQ(ident->name().size(), 4); EXPECT_EQ(ident->name()[0], "a"); EXPECT_EQ(ident->name()[1], "b"); EXPECT_EQ(ident->name()[2], "c"); EXPECT_EQ(ident->name()[3], "d"); } TEST_F(ParserImplTest, PrimaryExpression_Ident_MissingIdent) { auto p = parser("a::"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:4: identifier expected"); } TEST_F(ParserImplTest, PrimaryExpression_TypeDecl) { auto p = parser("vec4(1, 2, 3, 4))"); auto e = p->primary_expression(); ASSERT_FALSE(p->has_error()) << p->error(); ASSERT_NE(e, nullptr); ASSERT_TRUE(e->IsConstructor()); ASSERT_TRUE(e->AsConstructor()->IsTypeConstructor()); auto ty = e->AsConstructor()->AsTypeConstructor(); ASSERT_EQ(ty->values().size(), 4); const auto& val = ty->values(); ASSERT_TRUE(val[0]->IsConstructor()); ASSERT_TRUE(val[0]->AsConstructor()->IsScalarConstructor()); auto ident = val[0]->AsConstructor()->AsScalarConstructor(); ASSERT_TRUE(ident->literal()->IsInt()); EXPECT_EQ(ident->literal()->AsInt()->value(), 1); ASSERT_TRUE(val[1]->IsConstructor()); ASSERT_TRUE(val[1]->AsConstructor()->IsScalarConstructor()); ident = val[1]->AsConstructor()->AsScalarConstructor(); ASSERT_TRUE(ident->literal()->IsInt()); EXPECT_EQ(ident->literal()->AsInt()->value(), 2); ASSERT_TRUE(val[2]->IsConstructor()); ASSERT_TRUE(val[2]->AsConstructor()->IsScalarConstructor()); ident = val[2]->AsConstructor()->AsScalarConstructor(); ASSERT_TRUE(ident->literal()->IsInt()); EXPECT_EQ(ident->literal()->AsInt()->value(), 3); ASSERT_TRUE(val[3]->IsConstructor()); ASSERT_TRUE(val[3]->AsConstructor()->IsScalarConstructor()); ident = val[3]->AsConstructor()->AsScalarConstructor(); ASSERT_TRUE(ident->literal()->IsInt()); EXPECT_EQ(ident->literal()->AsInt()->value(), 4); } TEST_F(ParserImplTest, PrimaryExpression_TypeDecl_InvalidTypeDecl) { auto p = parser("vec4(2., 3., 4., 5.)"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:6: unable to determine subtype for vector"); } TEST_F(ParserImplTest, PrimaryExpression_TypeDecl_MissingLeftParen) { auto p = parser("vec4 2., 3., 4., 5.)"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:11: missing ( for type constructor"); } TEST_F(ParserImplTest, PrimaryExpression_TypeDecl_MissingRightParen) { auto p = parser("vec4(2., 3., 4., 5."); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:25: missing ) for type constructor"); } TEST_F(ParserImplTest, PrimaryExpression_TypeDecl_InvalidValue) { auto p = parser("i32(if(a) {})"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:5: unable to parse argument expression"); } TEST_F(ParserImplTest, PrimaryExpression_ConstLiteral_True) { auto p = parser("true"); auto e = p->primary_expression(); ASSERT_FALSE(p->has_error()); ASSERT_NE(e, nullptr); ASSERT_TRUE(e->IsConstructor()); ASSERT_TRUE(e->AsConstructor()->IsScalarConstructor()); auto init = e->AsConstructor()->AsScalarConstructor(); ASSERT_TRUE(init->literal()->IsBool()); EXPECT_TRUE(init->literal()->AsBool()->IsTrue()); } TEST_F(ParserImplTest, PrimaryExpression_ParenExpr) { auto p = parser("(a == b)"); auto e = p->primary_expression(); ASSERT_FALSE(p->has_error()) << p->error(); ASSERT_NE(e, nullptr); ASSERT_TRUE(e->IsBinary()); } TEST_F(ParserImplTest, PrimaryExpression_ParenExpr_MissingRightParen) { auto p = parser("(a == b"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:8: expected )"); } TEST_F(ParserImplTest, PrimaryExpression_ParenExpr_MissingExpr) { auto p = parser("()"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:2: unable to parse expression"); } TEST_F(ParserImplTest, PrimaryExpression_ParenExpr_InvalidExpr) { auto p = parser("(if (a) {})"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:2: unable to parse expression"); } TEST_F(ParserImplTest, PrimaryExpression_Cast) { auto f32_type = tm()->Get(std::make_unique()); auto p = parser("cast(1)"); auto e = p->primary_expression(); ASSERT_FALSE(p->has_error()) << p->error(); ASSERT_NE(e, nullptr); ASSERT_TRUE(e->IsCast()); auto c = e->AsCast(); ASSERT_EQ(c->type(), f32_type); ASSERT_TRUE(c->expr()->IsConstructor()); ASSERT_TRUE(c->expr()->AsConstructor()->IsScalarConstructor()); } TEST_F(ParserImplTest, PrimaryExpression_Cast_MissingGreaterThan) { auto p = parser("castprimary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:9: missing > for cast expression"); } TEST_F(ParserImplTest, PrimaryExpression_Cast_MissingType) { auto p = parser("cast<>(1)"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:6: missing type for cast expression"); } TEST_F(ParserImplTest, PrimaryExpression_Cast_InvalidType) { auto p = parser("cast(1)"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:6: unknown type alias 'invalid'"); } TEST_F(ParserImplTest, PrimaryExpression_Cast_MissingLeftParen) { auto p = parser("cast1)"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:10: expected ("); } TEST_F(ParserImplTest, PrimaryExpression_Cast_MissingRightParen) { auto p = parser("cast(1"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:12: expected )"); } TEST_F(ParserImplTest, PrimaryExpression_Cast_MissingExpression) { auto p = parser("cast()"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:11: unable to parse expression"); } TEST_F(ParserImplTest, PrimaryExpression_Cast_InvalidExpression) { auto p = parser("cast(if (a) {})"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:11: unable to parse expression"); } TEST_F(ParserImplTest, PrimaryExpression_As) { auto f32_type = tm()->Get(std::make_unique()); auto p = parser("as(1)"); auto e = p->primary_expression(); ASSERT_FALSE(p->has_error()) << p->error(); ASSERT_NE(e, nullptr); ASSERT_TRUE(e->IsAs()); auto c = e->AsAs(); ASSERT_EQ(c->type(), f32_type); ASSERT_TRUE(c->expr()->IsConstructor()); ASSERT_TRUE(c->expr()->AsConstructor()->IsScalarConstructor()); } TEST_F(ParserImplTest, PrimaryExpression_As_MissingGreaterThan) { auto p = parser("asprimary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:7: missing > for as expression"); } TEST_F(ParserImplTest, PrimaryExpression_As_MissingType) { auto p = parser("as<>(1)"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:4: missing type for as expression"); } TEST_F(ParserImplTest, PrimaryExpression_As_InvalidType) { auto p = parser("as(1)"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:4: unknown type alias 'invalid'"); } TEST_F(ParserImplTest, PrimaryExpression_As_MissingLeftParen) { auto p = parser("as1)"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:8: expected ("); } TEST_F(ParserImplTest, PrimaryExpression_As_MissingRightParen) { auto p = parser("as(1"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:10: expected )"); } TEST_F(ParserImplTest, PrimaryExpression_As_MissingExpression) { auto p = parser("as()"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:9: unable to parse expression"); } TEST_F(ParserImplTest, PrimaryExpression_As_InvalidExpression) { auto p = parser("as(if (a) {})"); auto e = p->primary_expression(); ASSERT_TRUE(p->has_error()); ASSERT_EQ(e, nullptr); EXPECT_EQ(p->error(), "1:9: unable to parse expression"); } } // namespace } // namespace wgsl } // namespace reader } // namespace tint