pkg/analyzer/test/generated/function_reference_parser_test.dart - sdk.git - Git at Google

 // Copyright (c) 2021, the Dart project authors. Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 import 'package:analyzer/dart/ast/ast.dart';
 import 'package:analyzer/src/dart/error/syntactic_errors.dart';
 import 'package:test/test.dart';
 import 'package:test_reflective_loader/test_reflective_loader.dart';

 import '../util/feature_sets.dart';
 import 'parser_test_base.dart';

 main() {
   defineReflectiveSuite(() {
     defineReflectiveTests(FunctionReferenceParserTest);
   });
 }

 /// Tests exercising the fasta parser's handling of generic instantiations.
 @reflectiveTest
 class FunctionReferenceParserTest extends FastaParserTestCase {
   /// Verifies that the given [node] matches `f<a, b>`.
   void expect_f_a_b(AstNode node) {
     var functionReference = node as FunctionReference;
     expect((functionReference.function as SimpleIdentifier).name, 'f');
     var typeArgs = functionReference.typeArguments!.arguments;
     expect(typeArgs, hasLength(2));
     expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
     expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
   }

   void expect_two_args(MethodInvocation methodInvocation) {
     var arguments = methodInvocation.argumentList.arguments;
     expect(arguments, hasLength(2));
     expect(arguments[0], TypeMatcher<BinaryExpression>());
     expect(arguments[1], TypeMatcher<BinaryExpression>());
   }

   void test_feature_disabled() {
     expect_f_a_b(
       (parseStatement('f<a, b>;', featureSet: FeatureSets.language_2_13)
               as ExpressionStatement)
           .expression,
     );
     listener.assertErrors([
       expectedError(ParserErrorCode.EXPERIMENT_NOT_ENABLED, 1, 6),
     ]);
   }

   void test_followingToken_accepted_closeBrace() {
     expect_f_a_b((parseExpression('{f<a, b>}') as SetOrMapLiteral).elements[0]);
   }

   void test_followingToken_accepted_closeBracket() {
     expect_f_a_b((parseExpression('[f<a, b>]') as ListLiteral).elements[0]);
   }

   void test_followingToken_accepted_closeParen() {
     expect_f_a_b(
       (parseExpression('g(f<a, b>)') as MethodInvocation)
           .argumentList
           .arguments[0],
     );
   }

   void test_followingToken_accepted_colon() {
     expect_f_a_b(
       ((parseExpression('{f<a, b>: null}') as SetOrMapLiteral).elements[0]
               as MapLiteralEntry)
           .key,
     );
   }

   void test_followingToken_accepted_comma() {
     expect_f_a_b(
       (parseExpression('[f<a, b>, null]') as ListLiteral).elements[0],
     );
   }

   void test_followingToken_accepted_equals() {
     expect_f_a_b(
       (parseExpression('f<a, b> == null') as BinaryExpression).leftOperand,
     );
   }

   void test_followingToken_accepted_not_equals() {
     expect_f_a_b(
       (parseExpression('f<a, b> != null') as BinaryExpression).leftOperand,
     );
   }

   void test_followingToken_accepted_openParen() {
     // This is a special case because when a `(` follows `<typeArguments>` it is
     // parsed as a MethodInvocation rather than a GenericInstantiation.
     var methodInvocation = parseExpression('f<a, b>()') as MethodInvocation;
     expect(methodInvocation.methodName.name, 'f');
     var typeArgs = methodInvocation.typeArguments!.arguments;
     expect(typeArgs, hasLength(2));
     expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
     expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
     expect(methodInvocation.argumentList.arguments, isEmpty);
   }

   void test_followingToken_accepted_period_methodInvocation() {
     // This is a special case because `f<a, b>.methodName(...)` is parsed as an
     // InstanceCreationExpression.
     var instanceCreationExpression =
         parseExpression('f<a, b>.toString()') as InstanceCreationExpression;
     var constructorName = instanceCreationExpression.constructorName;
     var type = constructorName.type;
     expect(type.name2.lexeme, 'f');
     var typeArgs = type.typeArguments!.arguments;
     expect(typeArgs, hasLength(2));
     expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
     expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
     expect(constructorName.name!.name, 'toString');
     expect(instanceCreationExpression.argumentList.arguments, isEmpty);
   }

   void test_followingToken_accepted_period_methodInvocation_generic() {
     expect_f_a_b(
       (parseExpression('f<a, b>.foo<c>()') as MethodInvocation).target!,
     );
   }

   void test_followingToken_accepted_period_propertyAccess() {
     expect_f_a_b(
       (parseExpression('f<a, b>.hashCode') as PropertyAccess).target!,
     );
   }

   void test_followingToken_accepted_semicolon() {
     expect_f_a_b(
       (parseStatement('f<a, b>;') as ExpressionStatement).expression,
     );
     listener.assertNoErrors();
   }

   void test_followingToken_rejected_ampersand() {
     expect_two_args(
       parseExpression(
             'f(a<b,c>&d)',
             errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
           )
           as MethodInvocation,
     );
   }

   void test_followingToken_rejected_as() {
     expect_two_args(parseExpression('f(a<b,c>as)') as MethodInvocation);
   }

   void test_followingToken_rejected_asterisk() {
     expect_two_args(
       parseExpression(
             'f(a<b,c>*d)',
             errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
           )
           as MethodInvocation,
     );
   }

   void test_followingToken_rejected_bang_openBracket() {
     expect_two_args(parseExpression('f(a<b,c>![d])') as MethodInvocation);
   }

   void test_followingToken_rejected_bang_paren() {
     expect_two_args(parseExpression('f(a<b,c>!(d))') as MethodInvocation);
   }

   void test_followingToken_rejected_bar() {
     expect_two_args(
       parseExpression(
             'f(a<b,c>|d)',
             errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
           )
           as MethodInvocation,
     );
   }

   void test_followingToken_rejected_caret() {
     expect_two_args(
       parseExpression(
             'f(a<b,c>^d)',
             errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
           )
           as MethodInvocation,
     );
   }

   void test_followingToken_rejected_is() {
     var methodInvocation =
         parseExpression(
               'f(a<b,c> is int)',
               errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 9, 2)],
             )
             as MethodInvocation;
     var arguments = methodInvocation.argumentList.arguments;
     expect(arguments, hasLength(2));
     expect(arguments[0], TypeMatcher<BinaryExpression>());
     expect(arguments[1], TypeMatcher<IsExpression>());
   }

   void test_followingToken_rejected_lessThan() {
     // Note: in principle we could parse this as a generic instantiation of a
     // generic instantiation, but such an expression would be meaningless so we
     // reject it at the parser level.
     parseExpression(
       'f<a><b>',
       errors: [
         expectedError(
           ParserErrorCode.EQUALITY_CANNOT_BE_EQUALITY_OPERAND,
           3,
           1,
         ),
         expectedError(ParserErrorCode.EXPECTED_TOKEN, 7, 0),
       ],
     );
   }

   void test_followingToken_rejected_minus() {
     expect_two_args(parseExpression('f(a<b,c>-d)') as MethodInvocation);
   }

   void test_followingToken_rejected_openBracket() {
     expect_two_args(parseExpression('f(a<b,c>[d])') as MethodInvocation);
   }

   void test_followingToken_rejected_openBracket_error() {
     // Note that theoretically this could be successfully parsed by interpreting
     // `<` and `>` as delimiting type arguments, but the parser doesn't have
     // enough lookahead to see that this is the only possible error-free parse;
     // it commits to interpreting `<` and `>` as operators when it sees the `[`.
     expect_two_args(
       parseExpression(
             'f(a<b,c>[d]>e)',
             errors: [
               expectedError(
                 ParserErrorCode.EQUALITY_CANNOT_BE_EQUALITY_OPERAND,
                 11,
                 1,
               ),
             ],
           )
           as MethodInvocation,
     );
   }

   void test_followingToken_rejected_openBracket_unambiguous() {
     expect_two_args(parseExpression('f(a<b,c>[d, e])') as MethodInvocation);
   }

   void test_followingToken_rejected_percent() {
     expect_two_args(
       parseExpression(
             'f(a<b,c>%d)',
             errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
           )
           as MethodInvocation,
     );
   }

   void test_followingToken_rejected_period_period() {
     var methodInvocation =
         parseExpression(
               'f(a<b,c>..toString())',
               errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 2)],
             )
             as MethodInvocation;
     var arguments = methodInvocation.argumentList.arguments;
     expect(arguments, hasLength(2));
     expect(arguments[0], TypeMatcher<BinaryExpression>());
     expect(arguments[1], TypeMatcher<CascadeExpression>());
   }

   void test_followingToken_rejected_plus() {
     expect_two_args(
       parseExpression(
             'f(a<b,c>+d)',
             errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
           )
           as MethodInvocation,
     );
   }

   void test_followingToken_rejected_question() {
     var methodInvocation =
         parseExpression(
               'f(a<b,c> ? null : null)',
               errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 9, 1)],
             )
             as MethodInvocation;
     var arguments = methodInvocation.argumentList.arguments;
     expect(arguments, hasLength(2));
     expect(arguments[0], TypeMatcher<BinaryExpression>());
     expect(arguments[1], TypeMatcher<ConditionalExpression>());
   }

   void test_followingToken_rejected_question_period_methodInvocation() {
     expect_two_args(
       parseExpression(
             'f(a<b,c>?.toString())',
             errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 2)],
           )
           as MethodInvocation,
     );
   }

   void test_followingToken_rejected_question_period_methodInvocation_generic() {
     expect_two_args(
       parseExpression(
             'f(a<b,c>?.foo<c>())',
             errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 2)],
           )
           as MethodInvocation,
     );
   }

   void test_followingToken_rejected_question_period_period() {
     var methodInvocation =
         parseExpression(
               'f(a<b,c>?..toString())',
               errors: [
                 expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 3),
                 expectedError(ParserErrorCode.EXPECTED_TOKEN, 11, 8),
               ],
             )
             as MethodInvocation;
     var arguments = methodInvocation.argumentList.arguments;
     expect(arguments, hasLength(3));
     expect(arguments[0], TypeMatcher<BinaryExpression>());
     expect(arguments[1], TypeMatcher<BinaryExpression>());
     expect(arguments[2], TypeMatcher<MethodInvocation>());
   }

   void test_followingToken_rejected_question_period_propertyAccess() {
     expect_two_args(
       parseExpression(
             'f(a<b,c>?.hashCode)',
             errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 2)],
           )
           as MethodInvocation,
     );
   }

   void test_followingToken_rejected_question_question() {
     expect_two_args(
       parseExpression(
             'f(a<b,c> ?? d)',
             errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 9, 2)],
           )
           as MethodInvocation,
     );
   }

   void test_followingToken_rejected_slash() {
     expect_two_args(
       parseExpression(
             'f(a<b,c>/d)',
             errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
           )
           as MethodInvocation,
     );
   }

   void test_followingToken_rejected_tilde_slash() {
     expect_two_args(
       parseExpression(
             'f(a<b,c>~/d)',
             errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 2)],
           )
           as MethodInvocation,
     );
   }

   void test_functionReference_after_indexExpression() {
     // Note: this is not legal Dart, but it's important that we do error
     // recovery and don't crash the parser.
     var functionReference = parseExpression('x[0]<a, b>') as FunctionReference;
     expect(functionReference.function, TypeMatcher<IndexExpression>());
     var typeArgs = functionReference.typeArguments!.arguments;
     expect(typeArgs, hasLength(2));
     expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
     expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
   }

   void test_functionReference_after_indexExpression_bang() {
     // Note: this is not legal Dart, but it's important that we do error
     // recovery and don't crash the parser.
     var functionReference = parseExpression('x[0]!<a, b>') as FunctionReference;
     expect(functionReference.function, TypeMatcher<PostfixExpression>());
     var typeArgs = functionReference.typeArguments!.arguments;
     expect(typeArgs, hasLength(2));
     expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
     expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
   }

   void test_functionReference_after_indexExpression_functionCall() {
     // Note: this is not legal Dart, but it's important that we do error
     // recovery and don't crash the parser.
     var functionReference =
         parseExpression('x[0]()<a, b>') as FunctionReference;
     expect(
       functionReference.function,
       TypeMatcher<FunctionExpressionInvocation>(),
     );
     var typeArgs = functionReference.typeArguments!.arguments;
     expect(typeArgs, hasLength(2));
     expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
     expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
   }

   void test_functionReference_after_indexExpression_nullAware() {
     // Note: this is not legal Dart, but it's important that we do error
     // recovery and don't crash the parser.
     var functionReference = parseExpression('x?[0]<a, b>') as FunctionReference;
     expect(functionReference.function, TypeMatcher<IndexExpression>());
     var typeArgs = functionReference.typeArguments!.arguments;
     expect(typeArgs, hasLength(2));
     expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
     expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
   }

   void test_methodTearoff() {
     var functionReference = parseExpression('f().m<a, b>') as FunctionReference;
     var function = functionReference.function as PropertyAccess;
     var target = function.target as MethodInvocation;
     expect(target.methodName.name, 'f');
     expect(function.propertyName.name, 'm');
     var typeArgs = functionReference.typeArguments!.arguments;
     expect(typeArgs, hasLength(2));
     expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
     expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
   }

   void test_methodTearoff_cascaded() {
     var cascadeExpression =
         parseExpression('f()..m<a, b>') as CascadeExpression;
     var functionReference =
         cascadeExpression.cascadeSections[0] as FunctionReference;
     var function = functionReference.function as PropertyAccess;
     expect(function.target, isNull);
     expect(function.propertyName.name, 'm');
     var typeArgs = functionReference.typeArguments!.arguments;
     expect(typeArgs, hasLength(2));
     expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
     expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
   }

   void test_prefixedIdentifier() {
     var functionReference =
         parseExpression('prefix.f<a, b>') as FunctionReference;
     var function = functionReference.function as PrefixedIdentifier;
     expect(function.prefix.name, 'prefix');
     expect(function.identifier.name, 'f');
     var typeArgs = functionReference.typeArguments!.arguments;
     expect(typeArgs, hasLength(2));
     expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
     expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
   }

   void test_three_identifiers() {
     var functionReference =
         parseExpression('prefix.ClassName.m<a, b>') as FunctionReference;
     var function = functionReference.function as PropertyAccess;
     var target = function.target as PrefixedIdentifier;
     expect(target.prefix.name, 'prefix');
     expect(target.identifier.name, 'ClassName');
     expect(function.propertyName.name, 'm');
     var typeArgs = functionReference.typeArguments!.arguments;
     expect(typeArgs, hasLength(2));
     expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
     expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
   }
 }
	// Copyright (c) 2021, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	import 'package:analyzer/dart/ast/ast.dart';
	import 'package:analyzer/src/dart/error/syntactic_errors.dart';
	import 'package:test/test.dart';
	import 'package:test_reflective_loader/test_reflective_loader.dart';

	import '../util/feature_sets.dart';
	import 'parser_test_base.dart';

	main() {
	defineReflectiveSuite(() {
	defineReflectiveTests(FunctionReferenceParserTest);
	});
	}

	/// Tests exercising the fasta parser's handling of generic instantiations.
	@reflectiveTest
	class FunctionReferenceParserTest extends FastaParserTestCase {
	/// Verifies that the given [node] matches `f<a, b>`.
	void expect_f_a_b(AstNode node) {
	var functionReference = node as FunctionReference;
	expect((functionReference.function as SimpleIdentifier).name, 'f');
	var typeArgs = functionReference.typeArguments!.arguments;
	expect(typeArgs, hasLength(2));
	expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
	expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
	}

	void expect_two_args(MethodInvocation methodInvocation) {
	var arguments = methodInvocation.argumentList.arguments;
	expect(arguments, hasLength(2));
	expect(arguments[0], TypeMatcher<BinaryExpression>());
	expect(arguments[1], TypeMatcher<BinaryExpression>());
	}

	void test_feature_disabled() {
	expect_f_a_b(
	(parseStatement('f<a, b>;', featureSet: FeatureSets.language_2_13)
	as ExpressionStatement)
	.expression,
	);
	listener.assertErrors([
	expectedError(ParserErrorCode.EXPERIMENT_NOT_ENABLED, 1, 6),
	]);
	}

	void test_followingToken_accepted_closeBrace() {
	expect_f_a_b((parseExpression('{f<a, b>}') as SetOrMapLiteral).elements[0]);
	}

	void test_followingToken_accepted_closeBracket() {
	expect_f_a_b((parseExpression('[f<a, b>]') as ListLiteral).elements[0]);
	}

	void test_followingToken_accepted_closeParen() {
	expect_f_a_b(
	(parseExpression('g(f<a, b>)') as MethodInvocation)
	.argumentList
	.arguments[0],
	);
	}

	void test_followingToken_accepted_colon() {
	expect_f_a_b(
	((parseExpression('{f<a, b>: null}') as SetOrMapLiteral).elements[0]
	as MapLiteralEntry)
	.key,
	);
	}

	void test_followingToken_accepted_comma() {
	expect_f_a_b(
	(parseExpression('[f<a, b>, null]') as ListLiteral).elements[0],
	);
	}

	void test_followingToken_accepted_equals() {
	expect_f_a_b(
	(parseExpression('f<a, b> == null') as BinaryExpression).leftOperand,
	);
	}

	void test_followingToken_accepted_not_equals() {
	expect_f_a_b(
	(parseExpression('f<a, b> != null') as BinaryExpression).leftOperand,
	);
	}

	void test_followingToken_accepted_openParen() {
	// This is a special case because when a `(` follows `<typeArguments>` it is
	// parsed as a MethodInvocation rather than a GenericInstantiation.
	var methodInvocation = parseExpression('f<a, b>()') as MethodInvocation;
	expect(methodInvocation.methodName.name, 'f');
	var typeArgs = methodInvocation.typeArguments!.arguments;
	expect(typeArgs, hasLength(2));
	expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
	expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
	expect(methodInvocation.argumentList.arguments, isEmpty);
	}

	void test_followingToken_accepted_period_methodInvocation() {
	// This is a special case because `f<a, b>.methodName(...)` is parsed as an
	// InstanceCreationExpression.
	var instanceCreationExpression =
	parseExpression('f<a, b>.toString()') as InstanceCreationExpression;
	var constructorName = instanceCreationExpression.constructorName;
	var type = constructorName.type;
	expect(type.name2.lexeme, 'f');
	var typeArgs = type.typeArguments!.arguments;
	expect(typeArgs, hasLength(2));
	expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
	expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
	expect(constructorName.name!.name, 'toString');
	expect(instanceCreationExpression.argumentList.arguments, isEmpty);
	}

	void test_followingToken_accepted_period_methodInvocation_generic() {
	expect_f_a_b(
	(parseExpression('f<a, b>.foo<c>()') as MethodInvocation).target!,
	);
	}

	void test_followingToken_accepted_period_propertyAccess() {
	expect_f_a_b(
	(parseExpression('f<a, b>.hashCode') as PropertyAccess).target!,
	);
	}

	void test_followingToken_accepted_semicolon() {
	expect_f_a_b(
	(parseStatement('f<a, b>;') as ExpressionStatement).expression,
	);
	listener.assertNoErrors();
	}

	void test_followingToken_rejected_ampersand() {
	expect_two_args(
	parseExpression(
	'f(a<b,c>&d)',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
	)
	as MethodInvocation,
	);
	}

	void test_followingToken_rejected_as() {
	expect_two_args(parseExpression('f(a<b,c>as)') as MethodInvocation);
	}

	void test_followingToken_rejected_asterisk() {
	expect_two_args(
	parseExpression(
	'f(a<b,c>*d)',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
	)
	as MethodInvocation,
	);
	}

	void test_followingToken_rejected_bang_openBracket() {
	expect_two_args(parseExpression('f(a<b,c>![d])') as MethodInvocation);
	}

	void test_followingToken_rejected_bang_paren() {
	expect_two_args(parseExpression('f(a<b,c>!(d))') as MethodInvocation);
	}

	void test_followingToken_rejected_bar() {
	expect_two_args(
	parseExpression(
	'f(a<b,c>\|d)',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
	)
	as MethodInvocation,
	);
	}

	void test_followingToken_rejected_caret() {
	expect_two_args(
	parseExpression(
	'f(a<b,c>^d)',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
	)
	as MethodInvocation,
	);
	}

	void test_followingToken_rejected_is() {
	var methodInvocation =
	parseExpression(
	'f(a<b,c> is int)',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 9, 2)],
	)
	as MethodInvocation;
	var arguments = methodInvocation.argumentList.arguments;
	expect(arguments, hasLength(2));
	expect(arguments[0], TypeMatcher<BinaryExpression>());
	expect(arguments[1], TypeMatcher<IsExpression>());
	}

	void test_followingToken_rejected_lessThan() {
	// Note: in principle we could parse this as a generic instantiation of a
	// generic instantiation, but such an expression would be meaningless so we
	// reject it at the parser level.
	parseExpression(
	'f<a><b>',
	errors: [
	expectedError(
	ParserErrorCode.EQUALITY_CANNOT_BE_EQUALITY_OPERAND,
	3,
	1,
	),
	expectedError(ParserErrorCode.EXPECTED_TOKEN, 7, 0),
	],
	);
	}

	void test_followingToken_rejected_minus() {
	expect_two_args(parseExpression('f(a<b,c>-d)') as MethodInvocation);
	}

	void test_followingToken_rejected_openBracket() {
	expect_two_args(parseExpression('f(a<b,c>[d])') as MethodInvocation);
	}

	void test_followingToken_rejected_openBracket_error() {
	// Note that theoretically this could be successfully parsed by interpreting
	// `<` and `>` as delimiting type arguments, but the parser doesn't have
	// enough lookahead to see that this is the only possible error-free parse;
	// it commits to interpreting `<` and `>` as operators when it sees the `[`.
	expect_two_args(
	parseExpression(
	'f(a<b,c>[d]>e)',
	errors: [
	expectedError(
	ParserErrorCode.EQUALITY_CANNOT_BE_EQUALITY_OPERAND,
	11,
	1,
	),
	],
	)
	as MethodInvocation,
	);
	}

	void test_followingToken_rejected_openBracket_unambiguous() {
	expect_two_args(parseExpression('f(a<b,c>[d, e])') as MethodInvocation);
	}

	void test_followingToken_rejected_percent() {
	expect_two_args(
	parseExpression(
	'f(a<b,c>%d)',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
	)
	as MethodInvocation,
	);
	}

	void test_followingToken_rejected_period_period() {
	var methodInvocation =
	parseExpression(
	'f(a<b,c>..toString())',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 2)],
	)
	as MethodInvocation;
	var arguments = methodInvocation.argumentList.arguments;
	expect(arguments, hasLength(2));
	expect(arguments[0], TypeMatcher<BinaryExpression>());
	expect(arguments[1], TypeMatcher<CascadeExpression>());
	}

	void test_followingToken_rejected_plus() {
	expect_two_args(
	parseExpression(
	'f(a<b,c>+d)',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
	)
	as MethodInvocation,
	);
	}

	void test_followingToken_rejected_question() {
	var methodInvocation =
	parseExpression(
	'f(a<b,c> ? null : null)',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 9, 1)],
	)
	as MethodInvocation;
	var arguments = methodInvocation.argumentList.arguments;
	expect(arguments, hasLength(2));
	expect(arguments[0], TypeMatcher<BinaryExpression>());
	expect(arguments[1], TypeMatcher<ConditionalExpression>());
	}

	void test_followingToken_rejected_question_period_methodInvocation() {
	expect_two_args(
	parseExpression(
	'f(a<b,c>?.toString())',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 2)],
	)
	as MethodInvocation,
	);
	}

	void test_followingToken_rejected_question_period_methodInvocation_generic() {
	expect_two_args(
	parseExpression(
	'f(a<b,c>?.foo<c>())',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 2)],
	)
	as MethodInvocation,
	);
	}

	void test_followingToken_rejected_question_period_period() {
	var methodInvocation =
	parseExpression(
	'f(a<b,c>?..toString())',
	errors: [
	expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 3),
	expectedError(ParserErrorCode.EXPECTED_TOKEN, 11, 8),
	],
	)
	as MethodInvocation;
	var arguments = methodInvocation.argumentList.arguments;
	expect(arguments, hasLength(3));
	expect(arguments[0], TypeMatcher<BinaryExpression>());
	expect(arguments[1], TypeMatcher<BinaryExpression>());
	expect(arguments[2], TypeMatcher<MethodInvocation>());
	}

	void test_followingToken_rejected_question_period_propertyAccess() {
	expect_two_args(
	parseExpression(
	'f(a<b,c>?.hashCode)',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 2)],
	)
	as MethodInvocation,
	);
	}

	void test_followingToken_rejected_question_question() {
	expect_two_args(
	parseExpression(
	'f(a<b,c> ?? d)',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 9, 2)],
	)
	as MethodInvocation,
	);
	}

	void test_followingToken_rejected_slash() {
	expect_two_args(
	parseExpression(
	'f(a<b,c>/d)',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 1)],
	)
	as MethodInvocation,
	);
	}

	void test_followingToken_rejected_tilde_slash() {
	expect_two_args(
	parseExpression(
	'f(a<b,c>~/d)',
	errors: [expectedError(ParserErrorCode.MISSING_IDENTIFIER, 8, 2)],
	)
	as MethodInvocation,
	);
	}

	void test_functionReference_after_indexExpression() {
	// Note: this is not legal Dart, but it's important that we do error
	// recovery and don't crash the parser.
	var functionReference = parseExpression('x[0]<a, b>') as FunctionReference;
	expect(functionReference.function, TypeMatcher<IndexExpression>());
	var typeArgs = functionReference.typeArguments!.arguments;
	expect(typeArgs, hasLength(2));
	expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
	expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
	}

	void test_functionReference_after_indexExpression_bang() {
	// Note: this is not legal Dart, but it's important that we do error
	// recovery and don't crash the parser.
	var functionReference = parseExpression('x[0]!<a, b>') as FunctionReference;
	expect(functionReference.function, TypeMatcher<PostfixExpression>());
	var typeArgs = functionReference.typeArguments!.arguments;
	expect(typeArgs, hasLength(2));
	expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
	expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
	}

	void test_functionReference_after_indexExpression_functionCall() {
	// Note: this is not legal Dart, but it's important that we do error
	// recovery and don't crash the parser.
	var functionReference =
	parseExpression('x[0]()<a, b>') as FunctionReference;
	expect(
	functionReference.function,
	TypeMatcher<FunctionExpressionInvocation>(),
	);
	var typeArgs = functionReference.typeArguments!.arguments;
	expect(typeArgs, hasLength(2));
	expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
	expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
	}

	void test_functionReference_after_indexExpression_nullAware() {
	// Note: this is not legal Dart, but it's important that we do error
	// recovery and don't crash the parser.
	var functionReference = parseExpression('x?[0]<a, b>') as FunctionReference;
	expect(functionReference.function, TypeMatcher<IndexExpression>());
	var typeArgs = functionReference.typeArguments!.arguments;
	expect(typeArgs, hasLength(2));
	expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
	expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
	}

	void test_methodTearoff() {
	var functionReference = parseExpression('f().m<a, b>') as FunctionReference;
	var function = functionReference.function as PropertyAccess;
	var target = function.target as MethodInvocation;
	expect(target.methodName.name, 'f');
	expect(function.propertyName.name, 'm');
	var typeArgs = functionReference.typeArguments!.arguments;
	expect(typeArgs, hasLength(2));
	expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
	expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
	}

	void test_methodTearoff_cascaded() {
	var cascadeExpression =
	parseExpression('f()..m<a, b>') as CascadeExpression;
	var functionReference =
	cascadeExpression.cascadeSections[0] as FunctionReference;
	var function = functionReference.function as PropertyAccess;
	expect(function.target, isNull);
	expect(function.propertyName.name, 'm');
	var typeArgs = functionReference.typeArguments!.arguments;
	expect(typeArgs, hasLength(2));
	expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
	expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
	}

	void test_prefixedIdentifier() {
	var functionReference =
	parseExpression('prefix.f<a, b>') as FunctionReference;
	var function = functionReference.function as PrefixedIdentifier;
	expect(function.prefix.name, 'prefix');
	expect(function.identifier.name, 'f');
	var typeArgs = functionReference.typeArguments!.arguments;
	expect(typeArgs, hasLength(2));
	expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
	expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
	}

	void test_three_identifiers() {
	var functionReference =
	parseExpression('prefix.ClassName.m<a, b>') as FunctionReference;
	var function = functionReference.function as PropertyAccess;
	var target = function.target as PrefixedIdentifier;
	expect(target.prefix.name, 'prefix');
	expect(target.identifier.name, 'ClassName');
	expect(function.propertyName.name, 'm');
	var typeArgs = functionReference.typeArguments!.arguments;
	expect(typeArgs, hasLength(2));
	expect((typeArgs[0] as NamedType).name2.lexeme, 'a');
	expect((typeArgs[1] as NamedType).name2.lexeme, 'b');
	}
	}