fbaf016b6d
BUG= R=danno@chromium.org Review URL: https://codereview.chromium.org/32643004 git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@17335 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
550 lines
18 KiB
JavaScript
550 lines
18 KiB
JavaScript
// Copyright 2012 the V8 project authors. All rights reserved.
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// Redistribution and use in source and binary forms, with or without
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// modification, are permitted provided that the following conditions are
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// met:
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//
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// * Redistributions of source code must retain the above copyright
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// notice, this list of conditions and the following disclaimer.
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// * Redistributions in binary form must reproduce the above
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// copyright notice, this list of conditions and the following
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// disclaimer in the documentation and/or other materials provided
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// with the distribution.
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// * Neither the name of Google Inc. nor the names of its
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// contributors may be used to endorse or promote products derived
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// from this software without specific prior written permission.
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//
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// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
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// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
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// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
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// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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// Test dictionary -> double elements -> dictionary elements round trip
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// Flags: --allow-natives-syntax --unbox-double-arrays --expose-gc
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var large_array_size = 100000;
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var approx_dict_to_elements_threshold = 70000;
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var name = 0;
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function expected_array_value(i) {
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if ((i % 50) != 0) {
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return i;
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} else {
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return i + 0.5;
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}
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}
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function force_to_fast_double_array(a) {
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a[large_array_size - 2] = 1;
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for (var i= 0; i < approx_dict_to_elements_threshold; ++i ) {
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a[i] = expected_array_value(i);
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}
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assertTrue(%HasFastDoubleElements(a));
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}
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function make_object_like_array(size) {
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obj = new Object();
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obj.length = size;
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return obj;
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}
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function testOneArrayType(allocator) {
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var large_array = new allocator(large_array_size);
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force_to_fast_double_array(large_array);
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var six = 6;
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for (var i= 0; i < approx_dict_to_elements_threshold; i += 501 ) {
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assertEquals(expected_array_value(i), large_array[i]);
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}
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// This function has a constant and won't get inlined.
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function computed_6() {
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return six;
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}
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// Multiple versions of the test function makes sure that IC/Crankshaft state
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// doesn't get reused.
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function test_various_loads(a, value_5, value_6, value_7) {
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assertTrue(%HasFastDoubleElements(a));
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assertEquals(value_5, a[5]);
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assertEquals(value_6, a[6]);
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assertEquals(value_6, a[computed_6()]); // Test non-constant key
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assertEquals(value_7, a[7]);
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assertEquals(large_array_size, a.length);
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assertTrue(%HasFastDoubleElements(a));
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}
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function test_various_loads2(a, value_5, value_6, value_7) {
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assertTrue(%HasFastDoubleElements(a));
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assertEquals(value_5, a[5]);
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assertEquals(value_6, a[6]);
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assertEquals(value_6, a[computed_6()]); // Test non-constant key
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assertEquals(value_7, a[7]);
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assertEquals(large_array_size, a.length);
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assertTrue(%HasFastDoubleElements(a));
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}
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function test_various_loads3(a, value_5, value_6, value_7) {
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assertTrue(%HasFastDoubleElements(a));
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assertEquals(value_5, a[5]);
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assertEquals(value_6, a[6]);
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assertEquals(value_6, a[computed_6()]); // Test non-constant key
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assertEquals(value_7, a[7]);
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assertEquals(large_array_size, a.length);
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assertTrue(%HasFastDoubleElements(a));
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}
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function test_various_loads4(a, value_5, value_6, value_7) {
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assertTrue(%HasFastDoubleElements(a));
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assertEquals(value_5, a[5]);
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assertEquals(value_6, a[6]);
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assertEquals(value_6, a[computed_6()]); // Test non-constant key
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assertEquals(value_7, a[7]);
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assertEquals(large_array_size, a.length);
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assertTrue(%HasFastDoubleElements(a));
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}
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function test_various_loads5(a, value_5, value_6, value_7) {
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assertTrue(%HasFastDoubleElements(a));
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if (value_5 != undefined) {
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assertEquals(value_5, a[5]);
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};
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if (value_6 != undefined) {
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assertEquals(value_6, a[6]);
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assertEquals(value_6, a[computed_6()]); // Test non-constant key
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}
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assertEquals(value_7, a[7]);
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assertEquals(large_array_size, a.length);
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assertTrue(%HasFastDoubleElements(a));
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}
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function test_various_loads6(a, value_5, value_6, value_7) {
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assertTrue(%HasFastDoubleElements(a));
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assertEquals(value_5, a[5]);
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assertEquals(value_6, a[6]);
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assertEquals(value_6, a[computed_6()]); // Test non-constant key
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assertEquals(value_7, a[7]);
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assertEquals(large_array_size, a.length);
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assertTrue(%HasFastDoubleElements(a));
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}
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function test_various_loads7(a, value_5, value_6, value_7) {
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assertTrue(%HasFastDoubleElements(a));
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assertEquals(value_5, a[5]);
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assertEquals(value_6, a[6]);
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assertEquals(value_6, a[computed_6()]); // Test non-constant key
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assertEquals(value_7, a[7]);
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assertEquals(large_array_size, a.length);
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assertTrue(%HasFastDoubleElements(a));
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}
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function test_various_stores(a, value_5, value_6, value_7) {
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assertTrue(%HasFastDoubleElements(a));
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a[5] = value_5;
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a[computed_6()] = value_6;
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a[7] = value_7;
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assertTrue(%HasFastDoubleElements(a));
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}
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// Test double and integer values
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test_various_loads(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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test_various_loads(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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test_various_loads(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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%OptimizeFunctionOnNextCall(test_various_loads);
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test_various_loads(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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// Test NaN values
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test_various_stores(large_array, NaN, -NaN, expected_array_value(7));
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test_various_loads2(large_array,
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NaN,
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-NaN,
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expected_array_value(7));
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test_various_loads2(large_array,
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NaN,
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-NaN,
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expected_array_value(7));
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test_various_loads2(large_array,
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NaN,
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-NaN,
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expected_array_value(7));
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%OptimizeFunctionOnNextCall(test_various_loads2);
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test_various_loads2(large_array,
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NaN,
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-NaN,
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expected_array_value(7));
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// Test Infinity values
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test_various_stores(large_array,
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Infinity,
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-Infinity,
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expected_array_value(7));
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test_various_loads3(large_array,
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Infinity,
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-Infinity,
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expected_array_value(7));
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test_various_loads3(large_array,
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Infinity,
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-Infinity,
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expected_array_value(7));
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test_various_loads3(large_array,
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Infinity,
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-Infinity,
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expected_array_value(7));
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%OptimizeFunctionOnNextCall(test_various_loads3);
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test_various_loads3(large_array,
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Infinity,
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-Infinity,
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expected_array_value(7));
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// Test the hole for the default runtime implementation.
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delete large_array[5];
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delete large_array[6];
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test_various_loads4(large_array,
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undefined,
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undefined,
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expected_array_value(7));
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// Test the keyed load IC implementation when the value is the hole.
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test_various_stores(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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test_various_loads5(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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test_various_loads5(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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delete large_array[5];
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delete large_array[6];
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test_various_loads5(large_array,
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undefined,
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undefined,
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expected_array_value(7));
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test_various_loads5(large_array,
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undefined,
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undefined,
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expected_array_value(7));
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// Make sure Crankshaft code handles the hole correctly (bailout)
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var large_array = new allocator(large_array_size);
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force_to_fast_double_array(large_array);
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test_various_stores(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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test_various_loads6(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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test_various_loads6(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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%OptimizeFunctionOnNextCall(test_various_loads6);
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test_various_loads6(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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delete large_array[5];
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delete large_array[6];
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test_various_loads6(large_array,
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undefined,
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undefined,
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expected_array_value(7));
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%DeoptimizeFunction(test_various_loads6);
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%ClearFunctionTypeFeedback(test_various_stores);
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%ClearFunctionTypeFeedback(test_various_loads7);
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// Test stores for non-NaN.
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var large_array = new allocator(large_array_size);
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force_to_fast_double_array(large_array);
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%OptimizeFunctionOnNextCall(test_various_stores);
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test_various_stores(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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test_various_stores(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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test_various_loads7(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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test_various_loads7(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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%OptimizeFunctionOnNextCall(test_various_loads7);
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test_various_loads7(large_array,
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expected_array_value(5),
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expected_array_value(6),
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expected_array_value(7));
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// Test NaN behavior for stores.
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test_various_stores(large_array,
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NaN,
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-NaN,
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expected_array_value(7));
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test_various_stores(large_array,
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NaN,
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-NaN,
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expected_array_value(7));
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test_various_loads7(large_array,
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NaN,
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-NaN,
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expected_array_value(7));
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// Test Infinity behavior for stores.
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test_various_stores(large_array,
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Infinity,
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-Infinity,
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expected_array_value(7));
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test_various_stores(large_array,
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Infinity,
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-Infinity,
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expected_array_value(7));
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test_various_loads7(large_array,
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Infinity,
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-Infinity,
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expected_array_value(7));
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// Make sure that we haven't converted from fast double.
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assertTrue(%HasFastDoubleElements(large_array));
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}
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// Force gc here to start with a clean heap if we repeat this test multiple
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// times.
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gc();
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testOneArrayType(make_object_like_array);
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testOneArrayType(Array);
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var large_array = new Array(large_array_size);
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force_to_fast_double_array(large_array);
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assertTrue(%HasFastDoubleElements(large_array));
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// Cause the array to grow beyond it's JSArray length. This will double the
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// size of the capacity and force the array into "slow" dictionary case.
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large_array[5] = Infinity;
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large_array[large_array_size+10001] = 50;
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assertTrue(%HasDictionaryElements(large_array));
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assertEquals(50, large_array[large_array_size+10001]);
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assertEquals(large_array_size+10002, large_array.length);
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assertEquals(Infinity, large_array[5]);
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assertEquals(undefined, large_array[large_array_size-1]);
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assertEquals(undefined, large_array[-1]);
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assertEquals(large_array_size+10002, large_array.length);
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// Test dictionary -> double elements -> fast elements.
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var large_array2 = new Array(large_array_size);
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force_to_fast_double_array(large_array2);
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delete large_array2[5];
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// Convert back to fast elements and make sure the contents of the array are
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// unchanged.
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large_array2[25] = new Object();
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assertTrue(%HasFastObjectElements(large_array2));
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for (var i= 0; i < approx_dict_to_elements_threshold; i += 500 ) {
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if (i != 25 && i != 5) {
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assertEquals(expected_array_value(i), large_array2[i]);
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}
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}
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assertEquals(undefined, large_array2[5]);
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assertEquals(undefined, large_array2[large_array_size-1]);
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assertEquals(undefined, large_array2[-1]);
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assertEquals(large_array_size, large_array2.length);
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// Make sure it's possible to change the array's length and that array is still
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// intact after the resize.
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var large_array3 = new Array(large_array_size);
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force_to_fast_double_array(large_array3);
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large_array3.length = 60000;
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assertEquals(60000, large_array3.length);
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assertEquals(undefined, large_array3[60000]);
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assertTrue(%HasFastDoubleElements(large_array3));
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assertEquals(expected_array_value(5), large_array3[5]);
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assertEquals(expected_array_value(6), large_array3[6]);
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assertEquals(expected_array_value(7), large_array3[7]);
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assertEquals(expected_array_value(large_array3.length-1),
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large_array3[large_array3.length-1]);
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assertEquals(undefined, large_array3[large_array_size-1]);
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assertEquals(undefined, large_array3[-1]);
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gc();
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for (var i= 0; i < large_array3.length; i += 501 ) {
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assertEquals(expected_array_value(i), large_array3[i]);
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}
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large_array3.length = 25;
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assertEquals(25, large_array3.length);
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assertTrue(%HasFastDoubleElements(large_array3));
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assertEquals(undefined, large_array3[25]);
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assertEquals(expected_array_value(5), large_array3[5]);
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assertEquals(expected_array_value(6), large_array3[6]);
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assertEquals(expected_array_value(7), large_array3[7]);
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assertEquals(expected_array_value(large_array3.length-1),
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large_array3[large_array3.length-1]);
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assertEquals(undefined, large_array3[large_array_size-1]);
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assertEquals(undefined, large_array3[-1]);
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gc();
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for (var i= 0; i < large_array3.length; ++i) {
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assertEquals(expected_array_value(i), large_array3[i]);
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}
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large_array3.length = 100;
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assertEquals(100, large_array3.length);
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large_array3[95] = 95;
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assertTrue(%HasFastDoubleElements(large_array3));
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assertEquals(undefined, large_array3[100]);
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assertEquals(95, large_array3[95]);
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assertEquals(expected_array_value(5), large_array3[5]);
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assertEquals(expected_array_value(6), large_array3[6]);
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assertEquals(expected_array_value(7), large_array3[7]);
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assertEquals(undefined, large_array3[large_array3.length-1]);
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assertEquals(undefined, large_array3[large_array_size-1]);
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assertEquals(undefined, large_array3[-1]);
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gc();
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// Test apply on arrays backed by double elements.
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function called_by_apply(arg0, arg1, arg2, arg3, arg4, arg5, arg6) {
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assertEquals(expected_array_value(0), arg0);
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assertEquals(NaN, arg1);
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assertEquals(-NaN, arg2);
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assertEquals(Infinity, arg3);
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assertEquals(-Infinity, arg4);
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assertEquals(expected_array_value(5), arg5);
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}
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large_array3[1] = NaN;
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large_array3[2] = -NaN;
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large_array3[3] = Infinity;
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large_array3[4] = -Infinity;
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function call_apply() {
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called_by_apply.apply({}, large_array3);
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}
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call_apply();
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call_apply();
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call_apply();
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%OptimizeFunctionOnNextCall(call_apply);
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call_apply();
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call_apply();
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call_apply();
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function test_for_in() {
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// Due to previous tests, keys 0..25 and 95 should be present.
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next_expected = 0;
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for (x in large_array3) {
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assertTrue(next_expected++ == x);
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if (next_expected == 25) {
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next_expected = 95;
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}
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}
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assertTrue(next_expected == 96);
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}
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test_for_in();
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test_for_in();
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test_for_in();
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%OptimizeFunctionOnNextCall(test_for_in);
|
|
test_for_in();
|
|
test_for_in();
|
|
test_for_in();
|
|
|
|
function test_get_property_names() {
|
|
names = %GetPropertyNames(large_array3);
|
|
property_name_count = 0;
|
|
for (x in names) { property_name_count++; };
|
|
assertEquals(26, property_name_count);
|
|
}
|
|
|
|
test_get_property_names();
|
|
test_get_property_names();
|
|
test_get_property_names();
|
|
|
|
// Test elements getters.
|
|
assertEquals(expected_array_value(10), large_array3[10]);
|
|
assertEquals(expected_array_value(-NaN), large_array3[2]);
|
|
large_array3.__defineGetter__("2", function(){
|
|
return expected_array_value(10);
|
|
});
|
|
|
|
function test_getter() {
|
|
assertEquals(expected_array_value(10), large_array3[10]);
|
|
assertEquals(expected_array_value(10), large_array3[2]);
|
|
}
|
|
|
|
test_getter();
|
|
test_getter();
|
|
test_getter();
|
|
%OptimizeFunctionOnNextCall(test_getter);
|
|
test_getter();
|
|
test_getter();
|
|
test_getter();
|
|
|
|
// Test element setters.
|
|
large_array4 = new Array(large_array_size);
|
|
force_to_fast_double_array(large_array4);
|
|
|
|
var setter_called = false;
|
|
|
|
assertEquals(expected_array_value(10), large_array4[10]);
|
|
assertEquals(expected_array_value(2), large_array4[2]);
|
|
large_array4.__defineSetter__("10", function(value){
|
|
setter_called = true;
|
|
});
|
|
|
|
function test_setter() {
|
|
setter_called = false;
|
|
large_array4[10] = 119;
|
|
assertTrue(setter_called);
|
|
assertEquals(undefined, large_array4[10]);
|
|
assertEquals(expected_array_value(2), large_array4[2]);
|
|
}
|
|
|
|
test_setter();
|
|
test_setter();
|
|
test_setter();
|
|
%OptimizeFunctionOnNextCall(test_setter);
|
|
test_setter();
|
|
test_setter();
|
|
test_setter();
|