LanguageFeatures/Subtyping/dynamic/generated/positional_function_types_arguments_binding_A42_t01.dart - co19 - Git at Google

 /*
  * Copyright (c) 2018, 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.
  */
 /**
  * @assertionA type T0 is a subtype of a type T1 (written T0 <: T1) when:
  * Positional Function Types: T0 is U0 Function<X0 extends B00, ... ,
  * Xk extends B0k>(V0 x0, ..., Vn xn, [Vn+1 xn+1, ..., Vm xm])
  *
  *  and T1 is U1 Function<Y0 extends B10, ..., Yk extends B1k>(S0 y0, ...,
  *  Sp yp, [Sp+1 yp+1, ..., Sq yq])
  *  and p >= n
  *  and m >= q
  *  and Si[Z0/Y0, ..., Zk/Yk] <: Vi[Z0/X0, ..., Zk/Xk] for i in 0...q
  *  and U0[Z0/X0, ..., Zk/Xk] <: U1[Z0/Y0, ..., Zk/Yk]
  *  and B0i[Z0/X0, ..., Zk/Xk] === B1i[Z0/Y0, ..., Zk/Yk] for i in 0...k
  *  where the Zi are fresh type variables with bounds B0i[Z0/X0, ..., Zk/Xk]
  * @description Check that if T0 and T1 satisfies the rules above, then T0 is
  * subtype of T1. Test generic types when p > n and m > q
  * @author sgrekhov@unipro.ru
  */
 /**
  * @description Check that if type T0 is a subtype of a type T1, then instance
  * of T0 can be be used as an argument of type T1
  * @author sgrekhov@unipro.ru
  */
 /*
  * This test is generated from positional_function_types_A42.dart and
  * arguments_binding_x01.dart.
  * Don't modify it. If you want to change this file, change one of the files
  * above and then run generator.dart to regenerate the tests.
  */


 import '../../utils/common.dart';

 class A {}

 class C extends A {}

 class U<X, Y, Z> {}

 class B0<X, Y, Z> {}

 class B1<X, Y, Z> {}

 class V0<X, Y, Z> {}

 class V1<X, Y, Z> {}

 class V2<X, Y, Z> {}

 class V3<X, Y, Z> {}

 class V4<X, Y, Z> {}

 typedef T0 = U<C, List<String>, int> Function<X extends B0, Y extends B1>(
     V0<A, List, num> x0, V1<A, List, num> x1,
     [V2<A, List, num> x2, V3<A, List, num> x3, V4<A, List, num> x4]);
 typedef T1 = U<A, List, num> Function<X extends B0, Y extends B1>(
     V0<C, List<String>, int> y0, V1<C, List<String>, int> y1,
     V2<C, List<String>, int> x2, [V3<C, List<String>, int> x3]);

 U<C, List<String>, int> t0Func<X extends B0, Y extends B1>(
         V0<A, List, num> x0, V1<A, List, num> x1,
         [V2<A, List, num> x2, V3<A, List, num> x3, V4<A, List, num> x4]) =>
     null;
 U<A, List, num> t1Func<X extends B0, Y extends B1>(
         V0<C, List<String>, int> y0, V1<C, List<String>, int> y1,
         V2<C, List<String>, int> x2, [V3<C, List<String>, int> x3]) =>
     null;

 T0 t0Instance = t0Func;
 T1 t1Instance = t1Func;


 namedArgumentsFunc1(T1 t1, {T1 t2 = t1Default}) {}
 positionalArgumentsFunc1(T1 t1, [T1 t2 = t1Default]) {}

 namedArgumentsFunc2<X>(X t1, {required X t2}) {}

 class ArgumentsBindingClass {
   ArgumentsBindingClass(T1 t1) {}

   ArgumentsBindingClass.named(T1 t1, {T1 t2 = t1Default}) {}
   ArgumentsBindingClass.positional(T1 t1, [T1 t2 = t1Default]) {}

   factory ArgumentsBindingClass.fNamed(T1 t1, {T1 t2  = t1Default}) {
     return new ArgumentsBindingClass.named(t1, t2: t2);
   }
   factory ArgumentsBindingClass.fPositional(T1 t1, [T1 t2 = t1Default]) {
     return new ArgumentsBindingClass.positional(t1, t2);
   }

   static namedArgumentsStaticMethod(T1 t1, {T1 t2 = t1Default}) {}
   static positionalArgumentsStaticMethod(T1 t1, [T1 t2 = t1Default]) {}

   namedArgumentsMethod(T1 t1, {T1 t2 = t1Default}) {}
   positionalArgumentsMethod(T1 t1, [T1 t2 = t1Default]) {}

   set testSetter(T1 val) {}
 }

 class ArgumentsBindingGen<X>  {
   ArgumentsBindingGen(X t1) {}

   ArgumentsBindingGen.named(X t1, {required X t2}) {}

   factory ArgumentsBindingGen.fNamed(X t1, {required X t2}) {
     return new ArgumentsBindingGen.named(t1, t2: t2);
   }

   namedArgumentsMethod(X t1, {required X t2}) {}

   set testSetter(X val) {}
 }

 main() {
   // test functions
   namedArgumentsFunc1(forgetType(t0Instance), t2: forgetType(t0Instance));
   positionalArgumentsFunc1(forgetType(t0Instance), forgetType(t0Instance));

   // test class constructors
   ArgumentsBindingClass instance1 =
       new ArgumentsBindingClass(forgetType(t0Instance));
   instance1 = new ArgumentsBindingClass.fNamed(forgetType(t0Instance),
       t2: forgetType(t0Instance));
   instance1 = new ArgumentsBindingClass.named(forgetType(t0Instance),
       t2: forgetType(t0Instance));
   instance1 = new ArgumentsBindingClass.positional(forgetType(t0Instance),
       forgetType(t0Instance));

   // tests methods and setters
   instance1.namedArgumentsMethod(forgetType(t0Instance),
       t2: forgetType(t0Instance));
   instance1.positionalArgumentsMethod(forgetType(t0Instance),
       forgetType(t0Instance));
   instance1.testSetter = forgetType(t0Instance);

   // test static methods
   ArgumentsBindingClass.namedArgumentsStaticMethod(forgetType(t0Instance),
       t2: forgetType(t0Instance));
   ArgumentsBindingClass.positionalArgumentsStaticMethod(
       forgetType(t0Instance), forgetType(t0Instance));

   // Test type parameters

 }
	/*
	* Copyright (c) 2018, 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.
	*/
	/**
	* @assertionA type T0 is a subtype of a type T1 (written T0 <: T1) when:
	* Positional Function Types: T0 is U0 Function<X0 extends B00, ... ,
	* Xk extends B0k>(V0 x0, ..., Vn xn, [Vn+1 xn+1, ..., Vm xm])
	*
	* and T1 is U1 Function<Y0 extends B10, ..., Yk extends B1k>(S0 y0, ...,
	* Sp yp, [Sp+1 yp+1, ..., Sq yq])
	* and p >= n
	* and m >= q
	* and Si[Z0/Y0, ..., Zk/Yk] <: Vi[Z0/X0, ..., Zk/Xk] for i in 0...q
	* and U0[Z0/X0, ..., Zk/Xk] <: U1[Z0/Y0, ..., Zk/Yk]
	* and B0i[Z0/X0, ..., Zk/Xk] === B1i[Z0/Y0, ..., Zk/Yk] for i in 0...k
	* where the Zi are fresh type variables with bounds B0i[Z0/X0, ..., Zk/Xk]
	* @description Check that if T0 and T1 satisfies the rules above, then T0 is
	* subtype of T1. Test generic types when p > n and m > q
	* @author sgrekhov@unipro.ru
	*/
	/**
	* @description Check that if type T0 is a subtype of a type T1, then instance
	* of T0 can be be used as an argument of type T1
	* @author sgrekhov@unipro.ru
	*/
	/*
	* This test is generated from positional_function_types_A42.dart and
	* arguments_binding_x01.dart.
	* Don't modify it. If you want to change this file, change one of the files
	* above and then run generator.dart to regenerate the tests.
	*/


	import '../../utils/common.dart';

	class A {}

	class C extends A {}

	class U<X, Y, Z> {}

	class B0<X, Y, Z> {}

	class B1<X, Y, Z> {}

	class V0<X, Y, Z> {}

	class V1<X, Y, Z> {}

	class V2<X, Y, Z> {}

	class V3<X, Y, Z> {}

	class V4<X, Y, Z> {}

	typedef T0 = U<C, List<String>, int> Function<X extends B0, Y extends B1>(
	V0<A, List, num> x0, V1<A, List, num> x1,
	[V2<A, List, num> x2, V3<A, List, num> x3, V4<A, List, num> x4]);
	typedef T1 = U<A, List, num> Function<X extends B0, Y extends B1>(
	V0<C, List<String>, int> y0, V1<C, List<String>, int> y1,
	V2<C, List<String>, int> x2, [V3<C, List<String>, int> x3]);

	U<C, List<String>, int> t0Func<X extends B0, Y extends B1>(
	V0<A, List, num> x0, V1<A, List, num> x1,
	[V2<A, List, num> x2, V3<A, List, num> x3, V4<A, List, num> x4]) =>
	null;
	U<A, List, num> t1Func<X extends B0, Y extends B1>(
	V0<C, List<String>, int> y0, V1<C, List<String>, int> y1,
	V2<C, List<String>, int> x2, [V3<C, List<String>, int> x3]) =>
	null;

	T0 t0Instance = t0Func;
	T1 t1Instance = t1Func;


	namedArgumentsFunc1(T1 t1, {T1 t2 = t1Default}) {}
	positionalArgumentsFunc1(T1 t1, [T1 t2 = t1Default]) {}

	namedArgumentsFunc2<X>(X t1, {required X t2}) {}

	class ArgumentsBindingClass {
	ArgumentsBindingClass(T1 t1) {}

	ArgumentsBindingClass.named(T1 t1, {T1 t2 = t1Default}) {}
	ArgumentsBindingClass.positional(T1 t1, [T1 t2 = t1Default]) {}

	factory ArgumentsBindingClass.fNamed(T1 t1, {T1 t2 = t1Default}) {
	return new ArgumentsBindingClass.named(t1, t2: t2);
	}
	factory ArgumentsBindingClass.fPositional(T1 t1, [T1 t2 = t1Default]) {
	return new ArgumentsBindingClass.positional(t1, t2);
	}

	static namedArgumentsStaticMethod(T1 t1, {T1 t2 = t1Default}) {}
	static positionalArgumentsStaticMethod(T1 t1, [T1 t2 = t1Default]) {}

	namedArgumentsMethod(T1 t1, {T1 t2 = t1Default}) {}
	positionalArgumentsMethod(T1 t1, [T1 t2 = t1Default]) {}

	set testSetter(T1 val) {}
	}

	class ArgumentsBindingGen<X> {
	ArgumentsBindingGen(X t1) {}

	ArgumentsBindingGen.named(X t1, {required X t2}) {}

	factory ArgumentsBindingGen.fNamed(X t1, {required X t2}) {
	return new ArgumentsBindingGen.named(t1, t2: t2);
	}

	namedArgumentsMethod(X t1, {required X t2}) {}

	set testSetter(X val) {}
	}

	main() {
	// test functions
	namedArgumentsFunc1(forgetType(t0Instance), t2: forgetType(t0Instance));
	positionalArgumentsFunc1(forgetType(t0Instance), forgetType(t0Instance));

	// test class constructors
	ArgumentsBindingClass instance1 =
	new ArgumentsBindingClass(forgetType(t0Instance));
	instance1 = new ArgumentsBindingClass.fNamed(forgetType(t0Instance),
	t2: forgetType(t0Instance));
	instance1 = new ArgumentsBindingClass.named(forgetType(t0Instance),
	t2: forgetType(t0Instance));
	instance1 = new ArgumentsBindingClass.positional(forgetType(t0Instance),
	forgetType(t0Instance));

	// tests methods and setters
	instance1.namedArgumentsMethod(forgetType(t0Instance),
	t2: forgetType(t0Instance));
	instance1.positionalArgumentsMethod(forgetType(t0Instance),
	forgetType(t0Instance));
	instance1.testSetter = forgetType(t0Instance);

	// test static methods
	ArgumentsBindingClass.namedArgumentsStaticMethod(forgetType(t0Instance),
	t2: forgetType(t0Instance));
	ArgumentsBindingClass.positionalArgumentsStaticMethod(
	forgetType(t0Instance), forgetType(t0Instance));

	// Test type parameters

	}