src/reader/wgsl/parser_impl_singular_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 "src/reader/wgsl/parser_impl_test_helper.h"

 namespace tint {
 namespace reader {
 namespace wgsl {
 namespace {

 TEST_F(ParserImplTest, SingularExpression_Array_ConstantIndex) {
   auto p = parser("a[1]");
   auto e = p->singular_expression();
   EXPECT_TRUE(e.matched);
   EXPECT_FALSE(e.errored);
   EXPECT_FALSE(p->has_error()) << p->error();
   ASSERT_NE(e.value, nullptr);

   ASSERT_TRUE(e->Is<ast::ArrayAccessorExpression>());
   auto* ary = e->As<ast::ArrayAccessorExpression>();

   ASSERT_TRUE(ary->array()->Is<ast::IdentifierExpression>());
   auto* ident = ary->array()->As<ast::IdentifierExpression>();
   EXPECT_EQ(ident->symbol(), p->builder().Symbols().Get("a"));

   ASSERT_TRUE(ary->idx_expr()->Is<ast::ConstructorExpression>());
   ASSERT_TRUE(ary->idx_expr()->Is<ast::ScalarConstructorExpression>());
   auto* c = ary->idx_expr()->As<ast::ScalarConstructorExpression>();
   ASSERT_TRUE(c->literal()->Is<ast::SintLiteral>());
   EXPECT_EQ(c->literal()->As<ast::SintLiteral>()->value(), 1);
 }

 TEST_F(ParserImplTest, SingularExpression_Array_ExpressionIndex) {
   auto p = parser("a[1 + b / 4]");
   auto e = p->singular_expression();
   EXPECT_TRUE(e.matched);
   EXPECT_FALSE(e.errored);
   EXPECT_FALSE(p->has_error()) << p->error();
   ASSERT_NE(e.value, nullptr);

   ASSERT_TRUE(e->Is<ast::ArrayAccessorExpression>());
   auto* ary = e->As<ast::ArrayAccessorExpression>();

   ASSERT_TRUE(ary->array()->Is<ast::IdentifierExpression>());
   auto* ident = ary->array()->As<ast::IdentifierExpression>();
   EXPECT_EQ(ident->symbol(), p->builder().Symbols().Get("a"));

   ASSERT_TRUE(ary->idx_expr()->Is<ast::BinaryExpression>());
 }

 TEST_F(ParserImplTest, SingularExpression_Array_MissingIndex) {
   auto p = parser("a[]");
   auto e = p->singular_expression();
   EXPECT_FALSE(e.matched);
   EXPECT_TRUE(e.errored);
   EXPECT_EQ(e.value, nullptr);
   EXPECT_TRUE(p->has_error());
   EXPECT_EQ(p->error(), "1:3: unable to parse expression inside []");
 }

 TEST_F(ParserImplTest, SingularExpression_Array_MissingRightBrace) {
   auto p = parser("a[1");
   auto e = p->singular_expression();
   EXPECT_FALSE(e.matched);
   EXPECT_TRUE(e.errored);
   EXPECT_EQ(e.value, nullptr);
   EXPECT_TRUE(p->has_error());
   EXPECT_EQ(p->error(), "1:4: expected ']' for array accessor");
 }

 TEST_F(ParserImplTest, SingularExpression_Array_InvalidIndex) {
   auto p = parser("a[if(a() {})]");
   auto e = p->singular_expression();
   EXPECT_FALSE(e.matched);
   EXPECT_TRUE(e.errored);
   EXPECT_EQ(e.value, nullptr);
   EXPECT_TRUE(p->has_error());
   EXPECT_EQ(p->error(), "1:3: unable to parse expression inside []");
 }

 TEST_F(ParserImplTest, SingularExpression_Call_Empty) {
   auto p = parser("a()");
   auto e = p->singular_expression();
   EXPECT_TRUE(e.matched);
   EXPECT_FALSE(e.errored);
   EXPECT_FALSE(p->has_error()) << p->error();
   ASSERT_NE(e.value, nullptr);

   ASSERT_TRUE(e->Is<ast::CallExpression>());
   auto* c = e->As<ast::CallExpression>();

   EXPECT_EQ(c->func()->symbol(), p->builder().Symbols().Get("a"));

   EXPECT_EQ(c->params().size(), 0u);
 }

 TEST_F(ParserImplTest, SingularExpression_Call_WithArgs) {
   auto p = parser("test(1, b, 2 + 3 / b)");
   auto e = p->singular_expression();
   EXPECT_TRUE(e.matched);
   EXPECT_FALSE(e.errored);
   EXPECT_FALSE(p->has_error()) << p->error();
   ASSERT_NE(e.value, nullptr);

   ASSERT_TRUE(e->Is<ast::CallExpression>());
   auto* c = e->As<ast::CallExpression>();

   EXPECT_EQ(c->func()->symbol(), p->builder().Symbols().Get("test"));

   EXPECT_EQ(c->params().size(), 3u);
   EXPECT_TRUE(c->params()[0]->Is<ast::ConstructorExpression>());
   EXPECT_TRUE(c->params()[1]->Is<ast::IdentifierExpression>());
   EXPECT_TRUE(c->params()[2]->Is<ast::BinaryExpression>());
 }

 TEST_F(ParserImplTest, SingularExpression_Call_TrailingComma) {
   auto p = parser("a(b, )");
   auto e = p->singular_expression();
   EXPECT_TRUE(e.matched);
   EXPECT_FALSE(e.errored);
   ASSERT_NE(e.value, nullptr);

   ASSERT_TRUE(e->Is<ast::CallExpression>());
   auto* c = e->As<ast::CallExpression>();
   EXPECT_EQ(c->params().size(), 1u);
 }

 TEST_F(ParserImplTest, SingularExpression_Call_InvalidArg) {
   auto p = parser("a(if(a) {})");
   auto e = p->singular_expression();
   EXPECT_FALSE(e.matched);
   EXPECT_TRUE(e.errored);
   EXPECT_EQ(e.value, nullptr);
   EXPECT_TRUE(p->has_error());
   EXPECT_EQ(p->error(), "1:3: expected ')' for function call");
 }

 TEST_F(ParserImplTest, SingularExpression_Call_MissingRightParen) {
   auto p = parser("a(");
   auto e = p->singular_expression();
   EXPECT_FALSE(e.matched);
   EXPECT_TRUE(e.errored);
   EXPECT_EQ(e.value, nullptr);
   EXPECT_TRUE(p->has_error());
   EXPECT_EQ(p->error(), "1:3: expected ')' for function call");
 }

 TEST_F(ParserImplTest, SingularExpression_MemberAccessor) {
   auto p = parser("a.b");
   auto e = p->singular_expression();
   EXPECT_TRUE(e.matched);
   EXPECT_FALSE(e.errored);
   EXPECT_FALSE(p->has_error()) << p->error();
   ASSERT_NE(e.value, nullptr);
   ASSERT_TRUE(e->Is<ast::MemberAccessorExpression>());

   auto* m = e->As<ast::MemberAccessorExpression>();
   ASSERT_TRUE(m->structure()->Is<ast::IdentifierExpression>());
   EXPECT_EQ(m->structure()->As<ast::IdentifierExpression>()->symbol(),
             p->builder().Symbols().Get("a"));

   ASSERT_TRUE(m->member()->Is<ast::IdentifierExpression>());
   EXPECT_EQ(m->member()->As<ast::IdentifierExpression>()->symbol(),
             p->builder().Symbols().Get("b"));
 }

 TEST_F(ParserImplTest, SingularExpression_MemberAccesssor_InvalidIdent) {
   auto p = parser("a.if");
   auto e = p->singular_expression();
   EXPECT_FALSE(e.matched);
   EXPECT_TRUE(e.errored);
   EXPECT_EQ(e.value, nullptr);
   EXPECT_TRUE(p->has_error());
   EXPECT_EQ(p->error(), "1:3: expected identifier for member accessor");
 }

 TEST_F(ParserImplTest, SingularExpression_MemberAccessor_MissingIdent) {
   auto p = parser("a.");
   auto e = p->singular_expression();
   EXPECT_FALSE(e.matched);
   EXPECT_TRUE(e.errored);
   EXPECT_EQ(e.value, nullptr);
   EXPECT_TRUE(p->has_error());
   EXPECT_EQ(p->error(), "1:3: expected identifier for member accessor");
 }

 TEST_F(ParserImplTest, SingularExpression_NonMatch_returnLHS) {
   auto p = parser("a b");
   auto e = p->singular_expression();
   EXPECT_TRUE(e.matched);
   EXPECT_FALSE(e.errored);
   EXPECT_FALSE(p->has_error()) << p->error();
   ASSERT_NE(e.value, nullptr);
   ASSERT_TRUE(e->Is<ast::IdentifierExpression>());
 }

 TEST_F(ParserImplTest, SingularExpression_Array_NestedArrayAccessor) {
   auto p = parser("a[b[c]]");
   auto e = p->singular_expression();
   EXPECT_TRUE(e.matched);
   EXPECT_FALSE(e.errored);
   EXPECT_FALSE(p->has_error()) << p->error();
   ASSERT_NE(e.value, nullptr);

   const auto* outer_accessor = e->As<ast::ArrayAccessorExpression>();
   ASSERT_TRUE(outer_accessor);

   const auto* outer_array =
       outer_accessor->array()->As<ast::IdentifierExpression>();
   ASSERT_TRUE(outer_array);
   EXPECT_EQ(outer_array->symbol(), p->builder().Symbols().Get("a"));

   const auto* inner_accessor =
       outer_accessor->idx_expr()->As<ast::ArrayAccessorExpression>();
   ASSERT_TRUE(inner_accessor);

   const auto* inner_array =
       inner_accessor->array()->As<ast::IdentifierExpression>();
   ASSERT_TRUE(inner_array);
   EXPECT_EQ(inner_array->symbol(), p->builder().Symbols().Get("b"));

   const auto* index_expr =
       inner_accessor->idx_expr()->As<ast::IdentifierExpression>();
   ASSERT_TRUE(index_expr);
   EXPECT_EQ(index_expr->symbol(), p->builder().Symbols().Get("c"));
 }

 TEST_F(ParserImplTest, SingularExpression_PostfixPlusPlus) {
   auto p = parser("a++");
   auto e = p->singular_expression();
   EXPECT_FALSE(e.matched);
   EXPECT_TRUE(e.errored);
   EXPECT_EQ(e.value, nullptr);
   EXPECT_TRUE(p->has_error());
   EXPECT_EQ(p->error(),
             "1:2: postfix increment and decrement operators are reserved for a "
             "future WGSL version");
 }

 TEST_F(ParserImplTest, SingularExpression_PostfixMinusMinus) {
   auto p = parser("a--");
   auto e = p->singular_expression();
   EXPECT_FALSE(e.matched);
   EXPECT_TRUE(e.errored);
   EXPECT_EQ(e.value, nullptr);
   EXPECT_TRUE(p->has_error());
   EXPECT_EQ(p->error(),
             "1:2: postfix increment and decrement operators are reserved for a "
             "future WGSL version");
 }

 }  // namespace
 }  // namespace wgsl
 }  // namespace reader
 }  // 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 "src/reader/wgsl/parser_impl_test_helper.h"

	namespace tint {
	namespace reader {
	namespace wgsl {
	namespace {

	TEST_F(ParserImplTest, SingularExpression_Array_ConstantIndex) {
	auto p = parser("a[1]");
	auto e = p->singular_expression();
	EXPECT_TRUE(e.matched);
	EXPECT_FALSE(e.errored);
	EXPECT_FALSE(p->has_error()) << p->error();
	ASSERT_NE(e.value, nullptr);

	ASSERT_TRUE(e->Is<ast::ArrayAccessorExpression>());
	auto* ary = e->As<ast::ArrayAccessorExpression>();

	ASSERT_TRUE(ary->array()->Is<ast::IdentifierExpression>());
	auto* ident = ary->array()->As<ast::IdentifierExpression>();
	EXPECT_EQ(ident->symbol(), p->builder().Symbols().Get("a"));

	ASSERT_TRUE(ary->idx_expr()->Is<ast::ConstructorExpression>());
	ASSERT_TRUE(ary->idx_expr()->Is<ast::ScalarConstructorExpression>());
	auto* c = ary->idx_expr()->As<ast::ScalarConstructorExpression>();
	ASSERT_TRUE(c->literal()->Is<ast::SintLiteral>());
	EXPECT_EQ(c->literal()->As<ast::SintLiteral>()->value(), 1);
	}

	TEST_F(ParserImplTest, SingularExpression_Array_ExpressionIndex) {
	auto p = parser("a[1 + b / 4]");
	auto e = p->singular_expression();
	EXPECT_TRUE(e.matched);
	EXPECT_FALSE(e.errored);
	EXPECT_FALSE(p->has_error()) << p->error();
	ASSERT_NE(e.value, nullptr);

	ASSERT_TRUE(e->Is<ast::ArrayAccessorExpression>());
	auto* ary = e->As<ast::ArrayAccessorExpression>();

	ASSERT_TRUE(ary->array()->Is<ast::IdentifierExpression>());
	auto* ident = ary->array()->As<ast::IdentifierExpression>();
	EXPECT_EQ(ident->symbol(), p->builder().Symbols().Get("a"));

	ASSERT_TRUE(ary->idx_expr()->Is<ast::BinaryExpression>());
	}

	TEST_F(ParserImplTest, SingularExpression_Array_MissingIndex) {
	auto p = parser("a[]");
	auto e = p->singular_expression();
	EXPECT_FALSE(e.matched);
	EXPECT_TRUE(e.errored);
	EXPECT_EQ(e.value, nullptr);
	EXPECT_TRUE(p->has_error());
	EXPECT_EQ(p->error(), "1:3: unable to parse expression inside []");
	}

	TEST_F(ParserImplTest, SingularExpression_Array_MissingRightBrace) {
	auto p = parser("a[1");
	auto e = p->singular_expression();
	EXPECT_FALSE(e.matched);
	EXPECT_TRUE(e.errored);
	EXPECT_EQ(e.value, nullptr);
	EXPECT_TRUE(p->has_error());
	EXPECT_EQ(p->error(), "1:4: expected ']' for array accessor");
	}

	TEST_F(ParserImplTest, SingularExpression_Array_InvalidIndex) {
	auto p = parser("a[if(a() {})]");
	auto e = p->singular_expression();
	EXPECT_FALSE(e.matched);
	EXPECT_TRUE(e.errored);
	EXPECT_EQ(e.value, nullptr);
	EXPECT_TRUE(p->has_error());
	EXPECT_EQ(p->error(), "1:3: unable to parse expression inside []");
	}

	TEST_F(ParserImplTest, SingularExpression_Call_Empty) {
	auto p = parser("a()");
	auto e = p->singular_expression();
	EXPECT_TRUE(e.matched);
	EXPECT_FALSE(e.errored);
	EXPECT_FALSE(p->has_error()) << p->error();
	ASSERT_NE(e.value, nullptr);

	ASSERT_TRUE(e->Is<ast::CallExpression>());
	auto* c = e->As<ast::CallExpression>();

	EXPECT_EQ(c->func()->symbol(), p->builder().Symbols().Get("a"));

	EXPECT_EQ(c->params().size(), 0u);
	}

	TEST_F(ParserImplTest, SingularExpression_Call_WithArgs) {
	auto p = parser("test(1, b, 2 + 3 / b)");
	auto e = p->singular_expression();
	EXPECT_TRUE(e.matched);
	EXPECT_FALSE(e.errored);
	EXPECT_FALSE(p->has_error()) << p->error();
	ASSERT_NE(e.value, nullptr);

	ASSERT_TRUE(e->Is<ast::CallExpression>());
	auto* c = e->As<ast::CallExpression>();

	EXPECT_EQ(c->func()->symbol(), p->builder().Symbols().Get("test"));

	EXPECT_EQ(c->params().size(), 3u);
	EXPECT_TRUE(c->params()[0]->Is<ast::ConstructorExpression>());
	EXPECT_TRUE(c->params()[1]->Is<ast::IdentifierExpression>());
	EXPECT_TRUE(c->params()[2]->Is<ast::BinaryExpression>());
	}

	TEST_F(ParserImplTest, SingularExpression_Call_TrailingComma) {
	auto p = parser("a(b, )");
	auto e = p->singular_expression();
	EXPECT_TRUE(e.matched);
	EXPECT_FALSE(e.errored);
	ASSERT_NE(e.value, nullptr);

	ASSERT_TRUE(e->Is<ast::CallExpression>());
	auto* c = e->As<ast::CallExpression>();
	EXPECT_EQ(c->params().size(), 1u);
	}

	TEST_F(ParserImplTest, SingularExpression_Call_InvalidArg) {
	auto p = parser("a(if(a) {})");
	auto e = p->singular_expression();
	EXPECT_FALSE(e.matched);
	EXPECT_TRUE(e.errored);
	EXPECT_EQ(e.value, nullptr);
	EXPECT_TRUE(p->has_error());
	EXPECT_EQ(p->error(), "1:3: expected ')' for function call");
	}

	TEST_F(ParserImplTest, SingularExpression_Call_MissingRightParen) {
	auto p = parser("a(");
	auto e = p->singular_expression();
	EXPECT_FALSE(e.matched);
	EXPECT_TRUE(e.errored);
	EXPECT_EQ(e.value, nullptr);
	EXPECT_TRUE(p->has_error());
	EXPECT_EQ(p->error(), "1:3: expected ')' for function call");
	}

	TEST_F(ParserImplTest, SingularExpression_MemberAccessor) {
	auto p = parser("a.b");
	auto e = p->singular_expression();
	EXPECT_TRUE(e.matched);
	EXPECT_FALSE(e.errored);
	EXPECT_FALSE(p->has_error()) << p->error();
	ASSERT_NE(e.value, nullptr);
	ASSERT_TRUE(e->Is<ast::MemberAccessorExpression>());

	auto* m = e->As<ast::MemberAccessorExpression>();
	ASSERT_TRUE(m->structure()->Is<ast::IdentifierExpression>());
	EXPECT_EQ(m->structure()->As<ast::IdentifierExpression>()->symbol(),
	p->builder().Symbols().Get("a"));

	ASSERT_TRUE(m->member()->Is<ast::IdentifierExpression>());
	EXPECT_EQ(m->member()->As<ast::IdentifierExpression>()->symbol(),
	p->builder().Symbols().Get("b"));
	}

	TEST_F(ParserImplTest, SingularExpression_MemberAccesssor_InvalidIdent) {
	auto p = parser("a.if");
	auto e = p->singular_expression();
	EXPECT_FALSE(e.matched);
	EXPECT_TRUE(e.errored);
	EXPECT_EQ(e.value, nullptr);
	EXPECT_TRUE(p->has_error());
	EXPECT_EQ(p->error(), "1:3: expected identifier for member accessor");
	}

	TEST_F(ParserImplTest, SingularExpression_MemberAccessor_MissingIdent) {
	auto p = parser("a.");
	auto e = p->singular_expression();
	EXPECT_FALSE(e.matched);
	EXPECT_TRUE(e.errored);
	EXPECT_EQ(e.value, nullptr);
	EXPECT_TRUE(p->has_error());
	EXPECT_EQ(p->error(), "1:3: expected identifier for member accessor");
	}

	TEST_F(ParserImplTest, SingularExpression_NonMatch_returnLHS) {
	auto p = parser("a b");
	auto e = p->singular_expression();
	EXPECT_TRUE(e.matched);
	EXPECT_FALSE(e.errored);
	EXPECT_FALSE(p->has_error()) << p->error();
	ASSERT_NE(e.value, nullptr);
	ASSERT_TRUE(e->Is<ast::IdentifierExpression>());
	}

	TEST_F(ParserImplTest, SingularExpression_Array_NestedArrayAccessor) {
	auto p = parser("a[b[c]]");
	auto e = p->singular_expression();
	EXPECT_TRUE(e.matched);
	EXPECT_FALSE(e.errored);
	EXPECT_FALSE(p->has_error()) << p->error();
	ASSERT_NE(e.value, nullptr);

	const auto* outer_accessor = e->As<ast::ArrayAccessorExpression>();
	ASSERT_TRUE(outer_accessor);

	const auto* outer_array =
	outer_accessor->array()->As<ast::IdentifierExpression>();
	ASSERT_TRUE(outer_array);
	EXPECT_EQ(outer_array->symbol(), p->builder().Symbols().Get("a"));

	const auto* inner_accessor =
	outer_accessor->idx_expr()->As<ast::ArrayAccessorExpression>();
	ASSERT_TRUE(inner_accessor);

	const auto* inner_array =
	inner_accessor->array()->As<ast::IdentifierExpression>();
	ASSERT_TRUE(inner_array);
	EXPECT_EQ(inner_array->symbol(), p->builder().Symbols().Get("b"));

	const auto* index_expr =
	inner_accessor->idx_expr()->As<ast::IdentifierExpression>();
	ASSERT_TRUE(index_expr);
	EXPECT_EQ(index_expr->symbol(), p->builder().Symbols().Get("c"));
	}

	TEST_F(ParserImplTest, SingularExpression_PostfixPlusPlus) {
	auto p = parser("a++");
	auto e = p->singular_expression();
	EXPECT_FALSE(e.matched);
	EXPECT_TRUE(e.errored);
	EXPECT_EQ(e.value, nullptr);
	EXPECT_TRUE(p->has_error());
	EXPECT_EQ(p->error(),
	"1:2: postfix increment and decrement operators are reserved for a "
	"future WGSL version");
	}

	TEST_F(ParserImplTest, SingularExpression_PostfixMinusMinus) {
	auto p = parser("a--");
	auto e = p->singular_expression();
	EXPECT_FALSE(e.matched);
	EXPECT_TRUE(e.errored);
	EXPECT_EQ(e.value, nullptr);
	EXPECT_TRUE(p->has_error());
	EXPECT_EQ(p->error(),
	"1:2: postfix increment and decrement operators are reserved for a "
	"future WGSL version");
	}

	} // namespace
	} // namespace wgsl
	} // namespace reader
	} // namespace tint