tests/compiler/dart2js_extra/js_array_index_error_test.dart - sdk.git - Git at Google

 // Copyright (c) 2015, 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.

 // Test that optimized JSArray indexers enerate the same error as dyncamically
 // dispatched calls.

 import 'package:expect/expect.dart';

 @NoInline()
 @AssumeDynamic()
 confuse(x) => x;

 Error getError(action(), name, part) {
   try {
     action();
   } catch (e) {
     return e;
   }
   Expect.fail('must throw: $name: $part');
 }

 indexErrorContainsIndex() {
   makeFault(i) => () => confuse([])[i];

   var name = 'index error contains index';
   var e1 = getError(makeFault(1234), name, 'small');
   var e2 = getError(makeFault(1234000), name, 'medium');
   var e3 = getError(makeFault(1234000000000), name, 'large');

   Expect.equals('$e1', '$e2'.replaceAll('000', ''));
   Expect.equals('$e1', '$e3'.replaceAll('000', ''));
   Expect.equals('$e1'.length + 3, '$e2'.length);
   Expect.equals('$e1'.length + 9, '$e3'.length);
 }

 compare(name, fault1(), fault2(), fault3()) {
   var e1 = getError(fault1, name, 'fault1');
   var e2 = getError(fault2, name, 'fault2');
   var e3 = getError(fault3, name, 'fault3');

   Expect.equals('$e1', '$e2', '$name: fault1 vs fault2');
   Expect.equals('$e1', '$e3', '$name: fault1 vs fault3');
 }

 // These tests are a bit tedious and avoid common helpers with higher order
 // functions to keep the type inference for each test independent from the
 // others.
 //
 // The 'constant' tests have a constant index which might permit different
 // optimizations to a variable index.  e.g. the compiler might determine HUGE is
 // always out of range since the maximum JavaScript Array length is 2^32.
 //
 // The 'variable' forms take the index as an argument.

 const int HUGE = 1000000000000;

 constantIndexEmpty() {
   // Single dynamic receiver indexing might go via one-shot interceptor that
   // might have an accelerated path.
   fault1() => confuse([])[0];

   fault2() {
     var a = [];
     while (confuse(false)) a.add(1);
     // Easily inferred type and open coded indexer.
     return a[0];
   }

   fault3() {
     var a = confuse([]);
     // Multiple indexing might go via shared interceptor.
     return [a[0], a[1], a[2]];
   }

   compare('constant index on empty list', fault1, fault2, fault3);
 }

 constantIndexHugeEmpty() {
   // Single dynamic receiver indexing might go via one-shot interceptor that
   // might have an accelerated path.
   fault1() => confuse([])[HUGE];

   fault2() {
     var a = [];
     while (confuse(false)) a.add(1);
     return a[HUGE];
   }

   fault3() {
     var a = confuse([]);
     return [a[HUGE], a[1], a[2]];
   }

   compare(
       'constant index on empty list with huge index', fault1, fault2, fault3);
 }

 constantIndexNonempty() {
   // Single dynamic receiver indexing might go via one-shot interceptor that
   // might have an accelerated path.
   fault1() => confuse([1])[1];

   fault2() {
     var a = [1];
     while (confuse(false)) a.add(1);
     // Easily inferred type and open coded indexer.
     return a[1];
   }

   fault3() {
     var a = confuse([1]);
     // Multiple indexing might go via shared interceptor.
     return [a[1], a[2], a[3]];
   }

   compare('constant index on non-empty list', fault1, fault2, fault3);
 }

 constantIndexHugeNonempty() {
   // Single dynamic receiver indexing might go via one-shot interceptor that
   // might have an accelerated path.
   fault1() => confuse([1])[HUGE];

   fault2() {
     var a = [1];
     while (confuse(false)) a.add(1);
     // Easily inferred type and open coded indexer.
     return a[HUGE];
   }

   fault3() {
     var a = confuse([1]);
     // Multiple indexing might go via shared interceptor.
     return [a[HUGE], a[1], a[2]];
   }

   compare('constant index on non-empty list with huge index', fault1, fault2,
       fault3);
 }

 constantIndexSetEmpty() {
   fault1() {
     // Single dynamic receiver indexing might go via one-shot interceptor that
     // might have an accelerated path.
     confuse([])[0] = 0;
   }

   fault2() {
     var a = [];
     while (confuse(false)) a.add(1);
     // Easily inferred type and open coded indexer.
     a[0] = 0;
     return a;
   }

   fault3() {
     var a = confuse([]);
     // Multiple indexing might go via shared interceptor.
     a[0] = 0;
     a[1] = 0;
     a[2] = 0;
     return a;
   }

   compare('coinstant index-set on empty list', fault1, fault2, fault3);
 }

 constantIndexSetNonempty() {
   fault1() {
     // Single dynamic receiver indexing might go via one-shot interceptor that
     // might have an accelerated path.
     confuse([1])[1] = 0;
   }

   fault2() {
     var a = [1];
     while (confuse(false)) a.add(1);
     // Easily inferred type and open coded indexer.
     a[1] = 0;
     return a;
   }

   fault3() {
     var a = confuse([1]);
     // Multiple indexing might go via shared interceptor.
     a[0] = 0;
     a[1] = 0;
     a[2] = 0;
     return a;
   }

   compare('constant index-set on non-empty list', fault1, fault2, fault3);
 }

 variableIndexEmpty(index, qualifier) {
   // Single dynamic receiver indexing might go via one-shot interceptor that
   // might have an accelerated path.
   fault1() => confuse([])[index];

   fault2() {
     var a = [];
     while (confuse(false)) a.add(1);
     // Easily inferred type and open coded indexer.
     return a[index];
   }

   fault3() {
     var a = confuse([]);
     // Multiple indexing might go via shared interceptor.
     return [a[index], a[1], a[2]];
   }

   compare('general index on empty list $qualifier', fault1, fault2, fault3);
 }

 variableIndexNonempty(index, qualifier) {
   // Single dynamic receiver indexing might go via one-shot interceptor that
   // might have an accelerated path.
   fault1() => confuse([1])[index];

   fault2() {
     var a = [1];
     while (confuse(false)) a.add(1);
     // Easily inferred type and open coded indexer.
     return a[index];
   }

   fault3() {
     var a = confuse([1]);
     // Multiple indexing might go via shared interceptor.
     return [a[index], a[1], a[2]];
   }

   compare(
       'variable index on non-empty list $qualifier', fault1, fault2, fault3);
 }

 variableIndexSetEmpty(index, qualifier) {
   fault1() {
     var a = confuse([]);
     // Single dynamic receiver indexing might go via one-shot interceptor that
     // might have an accelerated path.
     a[index] = 1;
     return a;
   }

   fault2() {
     var a = [];
     while (confuse(false)) a.add(1);
     // Easily inferred type and open coded indexer.
     a[index] = 1;
     return a;
   }

   fault3() {
     var a = confuse([]);
     // Multiple indexing might go via shared interceptor.
     a[index] = 1;
     a[2] = 2;
     a[3] = 3;
     return a;
   }

   compare(
       'variable index-set on empty list $qualifier', fault1, fault2, fault3);
 }

 variableIndexSetNonempty(index, qualifier) {
   fault1() {
     var a = confuse([1]);
     // Single dynamic receiver indexing might go via one-shot interceptor that
     // might have an accelerated path.
     a[index] = 1;
     return a;
   }

   fault2() {
     var a = [1];
     while (confuse(false)) a.add(1);
     // Easily inferred type and open coded indexer.
     a[index] = 1;
     return a;
   }

   fault3() {
     var a = confuse([1]);
     // Multiple indexing might go via shared interceptor.
     a[index] = 1;
     a[2] = 2;
     a[3] = 3;
     return a;
   }

   compare('variable index-set on non-empty list $qualifier', fault1, fault2,
       fault3);
 }

 main() {
   indexErrorContainsIndex();

   constantIndexEmpty();
   constantIndexHugeEmpty();
   constantIndexNonempty();
   constantIndexHugeNonempty();
   constantIndexSetEmpty();
   constantIndexSetNonempty();

   variableIndexEmpty(0, 'zero index');
   variableIndexEmpty(10, 'small index');
   variableIndexEmpty(-1, 'negative index');
   variableIndexEmpty(HUGE, 'huge index');

   variableIndexNonempty(10, 'small index');
   variableIndexNonempty(-1, 'negative index');
   variableIndexNonempty(HUGE, 'huge index');

   variableIndexSetEmpty(0, 'zero index');
   variableIndexSetEmpty(10, 'small index');
   variableIndexSetEmpty(-1, 'negative index');
   variableIndexSetEmpty(HUGE, 'huge index');

   variableIndexSetNonempty(10, 'small index');
   variableIndexSetNonempty(-1, 'negative index');
   variableIndexSetNonempty(HUGE, 'huge index');
 }
	// Copyright (c) 2015, 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.

	// Test that optimized JSArray indexers enerate the same error as dyncamically
	// dispatched calls.

	import 'package:expect/expect.dart';

	@NoInline()
	@AssumeDynamic()
	confuse(x) => x;

	Error getError(action(), name, part) {
	try {
	action();
	} catch (e) {
	return e;
	}
	Expect.fail('must throw: $name: $part');
	}

	indexErrorContainsIndex() {
	makeFault(i) => () => confuse([])[i];

	var name = 'index error contains index';
	var e1 = getError(makeFault(1234), name, 'small');
	var e2 = getError(makeFault(1234000), name, 'medium');
	var e3 = getError(makeFault(1234000000000), name, 'large');

	Expect.equals('$e1', '$e2'.replaceAll('000', ''));
	Expect.equals('$e1', '$e3'.replaceAll('000', ''));
	Expect.equals('$e1'.length + 3, '$e2'.length);
	Expect.equals('$e1'.length + 9, '$e3'.length);
	}

	compare(name, fault1(), fault2(), fault3()) {
	var e1 = getError(fault1, name, 'fault1');
	var e2 = getError(fault2, name, 'fault2');
	var e3 = getError(fault3, name, 'fault3');

	Expect.equals('$e1', '$e2', '$name: fault1 vs fault2');
	Expect.equals('$e1', '$e3', '$name: fault1 vs fault3');
	}

	// These tests are a bit tedious and avoid common helpers with higher order
	// functions to keep the type inference for each test independent from the
	// others.
	//
	// The 'constant' tests have a constant index which might permit different
	// optimizations to a variable index. e.g. the compiler might determine HUGE is
	// always out of range since the maximum JavaScript Array length is 2^32.
	//
	// The 'variable' forms take the index as an argument.

	const int HUGE = 1000000000000;

	constantIndexEmpty() {
	// Single dynamic receiver indexing might go via one-shot interceptor that
	// might have an accelerated path.
	fault1() => confuse([])[0];

	fault2() {
	var a = [];
	while (confuse(false)) a.add(1);
	// Easily inferred type and open coded indexer.
	return a[0];
	}

	fault3() {
	var a = confuse([]);
	// Multiple indexing might go via shared interceptor.
	return [a[0], a[1], a[2]];
	}

	compare('constant index on empty list', fault1, fault2, fault3);
	}

	constantIndexHugeEmpty() {
	// Single dynamic receiver indexing might go via one-shot interceptor that
	// might have an accelerated path.
	fault1() => confuse([])[HUGE];

	fault2() {
	var a = [];
	while (confuse(false)) a.add(1);
	return a[HUGE];
	}

	fault3() {
	var a = confuse([]);
	return [a[HUGE], a[1], a[2]];
	}

	compare(
	'constant index on empty list with huge index', fault1, fault2, fault3);
	}

	constantIndexNonempty() {
	// Single dynamic receiver indexing might go via one-shot interceptor that
	// might have an accelerated path.
	fault1() => confuse([1])[1];

	fault2() {
	var a = [1];
	while (confuse(false)) a.add(1);
	// Easily inferred type and open coded indexer.
	return a[1];
	}

	fault3() {
	var a = confuse([1]);
	// Multiple indexing might go via shared interceptor.
	return [a[1], a[2], a[3]];
	}

	compare('constant index on non-empty list', fault1, fault2, fault3);
	}

	constantIndexHugeNonempty() {
	// Single dynamic receiver indexing might go via one-shot interceptor that
	// might have an accelerated path.
	fault1() => confuse([1])[HUGE];

	fault2() {
	var a = [1];
	while (confuse(false)) a.add(1);
	// Easily inferred type and open coded indexer.
	return a[HUGE];
	}

	fault3() {
	var a = confuse([1]);
	// Multiple indexing might go via shared interceptor.
	return [a[HUGE], a[1], a[2]];
	}

	compare('constant index on non-empty list with huge index', fault1, fault2,
	fault3);
	}

	constantIndexSetEmpty() {
	fault1() {
	// Single dynamic receiver indexing might go via one-shot interceptor that
	// might have an accelerated path.
	confuse([])[0] = 0;
	}

	fault2() {
	var a = [];
	while (confuse(false)) a.add(1);
	// Easily inferred type and open coded indexer.
	a[0] = 0;
	return a;
	}

	fault3() {
	var a = confuse([]);
	// Multiple indexing might go via shared interceptor.
	a[0] = 0;
	a[1] = 0;
	a[2] = 0;
	return a;
	}

	compare('coinstant index-set on empty list', fault1, fault2, fault3);
	}

	constantIndexSetNonempty() {
	fault1() {
	// Single dynamic receiver indexing might go via one-shot interceptor that
	// might have an accelerated path.
	confuse([1])[1] = 0;
	}

	fault2() {
	var a = [1];
	while (confuse(false)) a.add(1);
	// Easily inferred type and open coded indexer.
	a[1] = 0;
	return a;
	}

	fault3() {
	var a = confuse([1]);
	// Multiple indexing might go via shared interceptor.
	a[0] = 0;
	a[1] = 0;
	a[2] = 0;
	return a;
	}

	compare('constant index-set on non-empty list', fault1, fault2, fault3);
	}

	variableIndexEmpty(index, qualifier) {
	// Single dynamic receiver indexing might go via one-shot interceptor that
	// might have an accelerated path.
	fault1() => confuse([])[index];

	fault2() {
	var a = [];
	while (confuse(false)) a.add(1);
	// Easily inferred type and open coded indexer.
	return a[index];
	}

	fault3() {
	var a = confuse([]);
	// Multiple indexing might go via shared interceptor.
	return [a[index], a[1], a[2]];
	}

	compare('general index on empty list $qualifier', fault1, fault2, fault3);
	}

	variableIndexNonempty(index, qualifier) {
	// Single dynamic receiver indexing might go via one-shot interceptor that
	// might have an accelerated path.
	fault1() => confuse([1])[index];

	fault2() {
	var a = [1];
	while (confuse(false)) a.add(1);
	// Easily inferred type and open coded indexer.
	return a[index];
	}

	fault3() {
	var a = confuse([1]);
	// Multiple indexing might go via shared interceptor.
	return [a[index], a[1], a[2]];
	}

	compare(
	'variable index on non-empty list $qualifier', fault1, fault2, fault3);
	}

	variableIndexSetEmpty(index, qualifier) {
	fault1() {
	var a = confuse([]);
	// Single dynamic receiver indexing might go via one-shot interceptor that
	// might have an accelerated path.
	a[index] = 1;
	return a;
	}

	fault2() {
	var a = [];
	while (confuse(false)) a.add(1);
	// Easily inferred type and open coded indexer.
	a[index] = 1;
	return a;
	}

	fault3() {
	var a = confuse([]);
	// Multiple indexing might go via shared interceptor.
	a[index] = 1;
	a[2] = 2;
	a[3] = 3;
	return a;
	}

	compare(
	'variable index-set on empty list $qualifier', fault1, fault2, fault3);
	}

	variableIndexSetNonempty(index, qualifier) {
	fault1() {
	var a = confuse([1]);
	// Single dynamic receiver indexing might go via one-shot interceptor that
	// might have an accelerated path.
	a[index] = 1;
	return a;
	}

	fault2() {
	var a = [1];
	while (confuse(false)) a.add(1);
	// Easily inferred type and open coded indexer.
	a[index] = 1;
	return a;
	}

	fault3() {
	var a = confuse([1]);
	// Multiple indexing might go via shared interceptor.
	a[index] = 1;
	a[2] = 2;
	a[3] = 3;
	return a;
	}

	compare('variable index-set on non-empty list $qualifier', fault1, fault2,
	fault3);
	}

	main() {
	indexErrorContainsIndex();

	constantIndexEmpty();
	constantIndexHugeEmpty();
	constantIndexNonempty();
	constantIndexHugeNonempty();
	constantIndexSetEmpty();
	constantIndexSetNonempty();

	variableIndexEmpty(0, 'zero index');
	variableIndexEmpty(10, 'small index');
	variableIndexEmpty(-1, 'negative index');
	variableIndexEmpty(HUGE, 'huge index');

	variableIndexNonempty(10, 'small index');
	variableIndexNonempty(-1, 'negative index');
	variableIndexNonempty(HUGE, 'huge index');

	variableIndexSetEmpty(0, 'zero index');
	variableIndexSetEmpty(10, 'small index');
	variableIndexSetEmpty(-1, 'negative index');
	variableIndexSetEmpty(HUGE, 'huge index');

	variableIndexSetNonempty(10, 'small index');
	variableIndexSetNonempty(-1, 'negative index');
	variableIndexSetNonempty(HUGE, 'huge index');
	}