tests/language_2/generic/function_bounds_test.dart - sdk.git - 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.

 // @dart = 2.9

 // VMOptions=--lazy-dispatchers
 // VMOptions=--no-lazy-dispatchers

 import 'dart:math';
 import 'package:expect/expect.dart';

 Type getType<T>() => T;

 void testInstantiateToBounds() {
   f<T extends num, U extends T>() => [T, U];
   g<T extends List<U>, U extends int>() => [T, U];
   h<T extends U, U extends num>(T x, U y) => [T, U];

   // Check that instantiate to bounds creates the correct type arguments
   // during dynamic calls.
   Expect.listEquals([num, num], (f as dynamic)());
   Expect.listEquals([getType<List<int>>(), int], (g as dynamic)());
   Expect.listEquals([num, num], (h as dynamic)(null, null));

   // Check that when instantiate to bounds creates a super-bounded type argument
   // during a dynamic call, an error is thrown.
   i<T extends Iterable<T>>() => null;
   j<T extends Iterable<S>, S extends T>() => null;
   Expect.throwsTypeError(() => (i as dynamic)(), "Super bounded type argument");
   Expect.throwsTypeError(() => (j as dynamic)(), "Super bounded type argument");
 }

 void testChecksBound() {
   f<T extends num>(T x) => x;
   g<T extends U, U extends num>(T x, U y) => x;

   // Check that arguments are checked against the correct types when instantiate
   // to bounds produces a type argument during a dynamic call.
   Expect.equals((f as dynamic)(42), 42);
   Expect.equals((g as dynamic)(42.0, 100), 42.0);
   Expect.throwsTypeError(() => (f as dynamic)('42'), "Argument check");
   Expect.throwsTypeError(() => (g as dynamic)('hi', 100), "Argument check");

   // Check that an actual type argument is checked against the bound during a
   // dynamic call.
   Expect.equals((f as dynamic)<int>(42), 42);
   Expect.equals((g as dynamic)<double, num>(42.0, 100), 42.0);
   Expect.throwsTypeError(() => (g as dynamic)<double, int>(42.0, 100),
       "Type argument bounds check");
   Expect.throwsTypeError(
       () => (f as dynamic)<Object>(42), "Type argument bounds check");
   Expect.throwsTypeError(() => (g as dynamic)<double, int>(42.0, 100),
       "Type argument bounds check");
   Expect.throwsTypeError(() => (g as dynamic)<num, Object>(42.0, 100),
       "Type argument bounds check");
 }

 typedef G<U> = num Function<T extends U>(T x);

 typedef F<U> = Object Function<T extends U>(T x);

 void testSubtype() {
   num f<T extends num>(T x) => x + 2;
   dynamic d = f;

   // Check that casting to an equal generic function type works
   Expect.equals((f as G<num>)(40), 42);
   Expect.equals((d as G<num>)(40), 42);

   // Check that casting to a more general generic function type works
   Expect.equals((f as F<num>)(40), 42);
   Expect.equals((d as F<num>)(40), 42);

   // Check that casting to a generic function with more specific bounds fails
   Expect.throwsTypeError(
       () => (f as G<int>), "Generic functions are invariant");
   Expect.throwsTypeError(
       () => (d as G<int>), "Generic functions are invariant");
   Expect.throwsTypeError(
       () => (f as G<double>), "Generic functions are invariant");
   Expect.throwsTypeError(
       () => (d as G<double>), "Generic functions are invariant");
   Expect.throwsTypeError(
       () => (f as G<Null>), "Generic functions are invariant");
   Expect.throwsTypeError(
       () => (d as G<Null>), "Generic functions are invariant");

   // Check that casting to a generic function with a more general bound fails
   Expect.throwsTypeError(
       () => (f as G<Object>), "Generic functions are invariant");
   Expect.throwsTypeError(
       () => (d as G<Object>), "Generic functions are invariant");

   // Check that casting to a generic function with an unrelated bound fails
   Expect.throwsTypeError(
       () => (f as G<String>), "Generic functions are invariant");
   Expect.throwsTypeError(
       () => (d as G<String>), "Generic functions are invariant");
 }

 void testToString() {
   num f<T extends num, U extends T>(T x, U y) => min(x, y);
   num g<T, U>(T x, U y) => max(x as num, y as num);
   String h<T, U>(T x, U y) => h.runtimeType.toString();

   // Check that generic method types are printed in a reasonable way
   Expect.isTrue(
       new RegExp(r'<(\w+) extends num, (\w+) extends \1>\(\1, \2\) => num')
           .hasMatch(f.runtimeType.toString()));
   Expect.isTrue(new RegExp(r'<(\w+), (\w+)>\(\1, \2\) => num')
       .hasMatch(g.runtimeType.toString()));
   Expect.isTrue(
       new RegExp(r'<(\w+), (\w+)>\(\1, \2\) => String').hasMatch(h(42, 123.0)));
 }

 main() {
   testInstantiateToBounds(); //# 01: ok
   testToString(); //# 02: ok
   testChecksBound(); //# 03: ok
   testSubtype(); //# 04: ok
 }
	// 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.

	// @dart = 2.9

	// VMOptions=--lazy-dispatchers
	// VMOptions=--no-lazy-dispatchers

	import 'dart:math';
	import 'package:expect/expect.dart';

	Type getType<T>() => T;

	void testInstantiateToBounds() {
	f<T extends num, U extends T>() => [T, U];
	g<T extends List<U>, U extends int>() => [T, U];
	h<T extends U, U extends num>(T x, U y) => [T, U];

	// Check that instantiate to bounds creates the correct type arguments
	// during dynamic calls.
	Expect.listEquals([num, num], (f as dynamic)());
	Expect.listEquals([getType<List<int>>(), int], (g as dynamic)());
	Expect.listEquals([num, num], (h as dynamic)(null, null));

	// Check that when instantiate to bounds creates a super-bounded type argument
	// during a dynamic call, an error is thrown.
	i<T extends Iterable<T>>() => null;
	j<T extends Iterable<S>, S extends T>() => null;
	Expect.throwsTypeError(() => (i as dynamic)(), "Super bounded type argument");
	Expect.throwsTypeError(() => (j as dynamic)(), "Super bounded type argument");
	}

	void testChecksBound() {
	f<T extends num>(T x) => x;
	g<T extends U, U extends num>(T x, U y) => x;

	// Check that arguments are checked against the correct types when instantiate
	// to bounds produces a type argument during a dynamic call.
	Expect.equals((f as dynamic)(42), 42);
	Expect.equals((g as dynamic)(42.0, 100), 42.0);
	Expect.throwsTypeError(() => (f as dynamic)('42'), "Argument check");
	Expect.throwsTypeError(() => (g as dynamic)('hi', 100), "Argument check");

	// Check that an actual type argument is checked against the bound during a
	// dynamic call.
	Expect.equals((f as dynamic)<int>(42), 42);
	Expect.equals((g as dynamic)<double, num>(42.0, 100), 42.0);
	Expect.throwsTypeError(() => (g as dynamic)<double, int>(42.0, 100),
	"Type argument bounds check");
	Expect.throwsTypeError(
	() => (f as dynamic)<Object>(42), "Type argument bounds check");
	Expect.throwsTypeError(() => (g as dynamic)<double, int>(42.0, 100),
	"Type argument bounds check");
	Expect.throwsTypeError(() => (g as dynamic)<num, Object>(42.0, 100),
	"Type argument bounds check");
	}

	typedef G<U> = num Function<T extends U>(T x);

	typedef F<U> = Object Function<T extends U>(T x);

	void testSubtype() {
	num f<T extends num>(T x) => x + 2;
	dynamic d = f;

	// Check that casting to an equal generic function type works
	Expect.equals((f as G<num>)(40), 42);
	Expect.equals((d as G<num>)(40), 42);

	// Check that casting to a more general generic function type works
	Expect.equals((f as F<num>)(40), 42);
	Expect.equals((d as F<num>)(40), 42);

	// Check that casting to a generic function with more specific bounds fails
	Expect.throwsTypeError(
	() => (f as G<int>), "Generic functions are invariant");
	Expect.throwsTypeError(
	() => (d as G<int>), "Generic functions are invariant");
	Expect.throwsTypeError(
	() => (f as G<double>), "Generic functions are invariant");
	Expect.throwsTypeError(
	() => (d as G<double>), "Generic functions are invariant");
	Expect.throwsTypeError(
	() => (f as G<Null>), "Generic functions are invariant");
	Expect.throwsTypeError(
	() => (d as G<Null>), "Generic functions are invariant");

	// Check that casting to a generic function with a more general bound fails
	Expect.throwsTypeError(
	() => (f as G<Object>), "Generic functions are invariant");
	Expect.throwsTypeError(
	() => (d as G<Object>), "Generic functions are invariant");

	// Check that casting to a generic function with an unrelated bound fails
	Expect.throwsTypeError(
	() => (f as G<String>), "Generic functions are invariant");
	Expect.throwsTypeError(
	() => (d as G<String>), "Generic functions are invariant");
	}

	void testToString() {
	num f<T extends num, U extends T>(T x, U y) => min(x, y);
	num g<T, U>(T x, U y) => max(x as num, y as num);
	String h<T, U>(T x, U y) => h.runtimeType.toString();

	// Check that generic method types are printed in a reasonable way
	Expect.isTrue(
	new RegExp(r'<(\w+) extends num, (\w+) extends \1>\(\1, \2\) => num')
	.hasMatch(f.runtimeType.toString()));
	Expect.isTrue(new RegExp(r'<(\w+), (\w+)>\(\1, \2\) => num')
	.hasMatch(g.runtimeType.toString()));
	Expect.isTrue(
	new RegExp(r'<(\w+), (\w+)>\(\1, \2\) => String').hasMatch(h(42, 123.0)));
	}

	main() {
	testInstantiateToBounds(); //# 01: ok
	testToString(); //# 02: ok
	testChecksBound(); //# 03: ok
	testSubtype(); //# 04: ok
	}