tests/language_2/async_congruence_method_test.dart - sdk - Git at Google

 // Copyright (c) 2017, 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.

 // This test verifies that for an async method, the following three
 // types are all appropriately matched:
 // - The static return type
 // - The return type of reified runtime type of a tearoff of the function or
 //   method
 // - The reified type of the future returned by the function or method
 //
 // Specific attention is paid to the following conditions:
 // - The static return type is determined by type inference
 // - The static return type is `dynamic`
 // - The function or method immediately returns a value or future with a
 //   different type (possibly using `=>` syntax)

 import 'dart:async';

 import 'package:expect/expect.dart';

 class A {}

 class B extends A {}

 class B2 extends A {}

 Future quick() async {}

 Future<B> futureB() => new Future<B>.value(new B());

 abstract class I {
   dynamic f_inferred_dynamic();
   Future<A> f_inferred_A();
 }

 class C implements I {
   f_inferred_dynamic() async {
     await quick();
     return new B();
   }

   f_inferred_A() async {
     await quick();
     return new B();
   }

   dynamic f_dynamic() async {
     await quick();
     return new B();
   }

   Future<A> f_A() async {
     await quick();
     return new B();
   }

   Future<A> f_immediateReturn_B() async {
     return new B();
   }

   Future<A> f_immediateReturn_FutureB() async {
     return futureB();
   }

   Future<A> f_expressionSyntax_B() async => new B();

   Future<A> f_expressionSyntax_FutureB() async => futureB();
 }

 // Not executed
 void checkStaticTypes(C c) {
   // Check that f_inferred_dynamic's static return type is `dynamic`, by
   // verifying that no error occurs if we try to call `foo` on its return value.
   c.f_inferred_dynamic().foo();

   // Check that f_inferred_A's static return type is `Future<A>`, by verifying
   // that its return value can be assigned to `Future<B2>` but not
   // `Future<int>`.
   Future<B2> v1 = c.f_inferred_A();
   Future<int> v2 = c.f_inferred_A(); //# 01: compile-time error
 }

 void checkDynamic(dynamic tearoff) {
   Expect.isTrue(tearoff is dynamic Function());
   Expect.isFalse(tearoff is Future<dynamic> Function());
   dynamic f = tearoff();
   Expect.isTrue(f is Future<dynamic>);
   Expect.isFalse(f is Future<A>);
 }

 void checkFutureA(dynamic tearoff) {
   Expect.isTrue(tearoff is Future<A> Function());
   Expect.isFalse(tearoff is Future<B> Function());
   dynamic f = tearoff();
   Expect.isTrue(f is Future<A>);
   Expect.isFalse(f is Future<B>);
 }

 void test(C c) {
   checkDynamic(c.f_inferred_dynamic);
   checkFutureA(c.f_inferred_A);
   checkDynamic(c.f_dynamic);
   checkFutureA(c.f_A);
   checkFutureA(c.f_immediateReturn_B);
   checkFutureA(c.f_immediateReturn_FutureB);
   checkFutureA(c.f_expressionSyntax_B);
   checkFutureA(c.f_expressionSyntax_FutureB);
 }

 main() {
   test(new C());
 }
	// Copyright (c) 2017, 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.

	// This test verifies that for an async method, the following three
	// types are all appropriately matched:
	// - The static return type
	// - The return type of reified runtime type of a tearoff of the function or
	// method
	// - The reified type of the future returned by the function or method
	//
	// Specific attention is paid to the following conditions:
	// - The static return type is determined by type inference
	// - The static return type is `dynamic`
	// - The function or method immediately returns a value or future with a
	// different type (possibly using `=>` syntax)

	import 'dart:async';

	import 'package:expect/expect.dart';

	class A {}

	class B extends A {}

	class B2 extends A {}

	Future quick() async {}

	Future<B> futureB() => new Future<B>.value(new B());

	abstract class I {
	dynamic f_inferred_dynamic();
	Future<A> f_inferred_A();
	}

	class C implements I {
	f_inferred_dynamic() async {
	await quick();
	return new B();
	}

	f_inferred_A() async {
	await quick();
	return new B();
	}

	dynamic f_dynamic() async {
	await quick();
	return new B();
	}

	Future<A> f_A() async {
	await quick();
	return new B();
	}

	Future<A> f_immediateReturn_B() async {
	return new B();
	}

	Future<A> f_immediateReturn_FutureB() async {
	return futureB();
	}

	Future<A> f_expressionSyntax_B() async => new B();

	Future<A> f_expressionSyntax_FutureB() async => futureB();
	}

	// Not executed
	void checkStaticTypes(C c) {
	// Check that f_inferred_dynamic's static return type is `dynamic`, by
	// verifying that no error occurs if we try to call `foo` on its return value.
	c.f_inferred_dynamic().foo();

	// Check that f_inferred_A's static return type is `Future<A>`, by verifying
	// that its return value can be assigned to `Future<B2>` but not
	// `Future<int>`.
	Future<B2> v1 = c.f_inferred_A();
	Future<int> v2 = c.f_inferred_A(); //# 01: compile-time error
	}

	void checkDynamic(dynamic tearoff) {
	Expect.isTrue(tearoff is dynamic Function());
	Expect.isFalse(tearoff is Future<dynamic> Function());
	dynamic f = tearoff();
	Expect.isTrue(f is Future<dynamic>);
	Expect.isFalse(f is Future<A>);
	}

	void checkFutureA(dynamic tearoff) {
	Expect.isTrue(tearoff is Future<A> Function());
	Expect.isFalse(tearoff is Future<B> Function());
	dynamic f = tearoff();
	Expect.isTrue(f is Future<A>);
	Expect.isFalse(f is Future<B>);
	}

	void test(C c) {
	checkDynamic(c.f_inferred_dynamic);
	checkFutureA(c.f_inferred_A);
	checkDynamic(c.f_dynamic);
	checkFutureA(c.f_A);
	checkFutureA(c.f_immediateReturn_B);
	checkFutureA(c.f_immediateReturn_FutureB);
	checkFutureA(c.f_expressionSyntax_B);
	checkFutureA(c.f_expressionSyntax_FutureB);
	}

	main() {
	test(new C());
	}