6071c6d8d6
Also, copying hints can be removed from literals. Shallow copying wasn't used for some time, because of the way we treat mutable heap numbers. Change-Id: Ieeba44a9f8e80c4183af8f4751f68dd3a542532e Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/3009230 Reviewed-by: Leszek Swirski <leszeks@chromium.org> Reviewed-by: Toon Verwaest <verwaest@chromium.org> Commit-Queue: Michael Stanton <mvstanton@chromium.org> Cr-Commit-Position: refs/heads/master@{#75717}
418 lines
11 KiB
JavaScript
418 lines
11 KiB
JavaScript
// Copyright 2013 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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// Flags: --allow-natives-syntax
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// Test transitions caused by changes to field representations.
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function create_smi_object() {
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var o = {};
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o.x = 1;
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o.y = 2;
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o.z = 3;
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return o;
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}
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var o1 = create_smi_object();
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var o2 = create_smi_object();
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// o1,o2 are smi, smi, smi
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assertTrue(%HaveSameMap(o1, o2));
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o1.y = 1.3;
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// o1 is smi, double, smi
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assertFalse(%HaveSameMap(o1, o2));
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o2.y = 1.5;
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// o2 is smi, double, smi
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assertTrue(%HaveSameMap(o1, o2));
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// o3 is initialized as smi, double, smi
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var o3 = create_smi_object();
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assertTrue(%HaveSameMap(o1, o3));
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function set_large(o, v) {
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o.x01 = v; o.x02 = v; o.x03 = v; o.x04 = v; o.x05 = v; o.x06 = v; o.x07 = v;
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o.x08 = v; o.x09 = v; o.x10 = v; o.x11 = v; o.x12 = v; o.x13 = v; o.x14 = v;
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o.x15 = v; o.x16 = v; o.x17 = v; o.x18 = v; o.x19 = v; o.x20 = v; o.x21 = v;
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o.x22 = v; o.x23 = v; o.x24 = v; o.x25 = v; o.x26 = v; o.x27 = v; o.x28 = v;
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o.x29 = v; o.x30 = v; o.x31 = v; o.x32 = v; o.x33 = v; o.x34 = v; o.x35 = v;
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o.x36 = v; o.x37 = v; o.x38 = v; o.x39 = v; o.x40 = v; o.x41 = v; o.x42 = v;
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o.y01 = v; o.y02 = v; o.y03 = v; o.y04 = v; o.y05 = v; o.y06 = v; o.y07 = v;
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o.y08 = v; o.y09 = v; o.y10 = v; o.y11 = v; o.y12 = v; o.y13 = v; o.y14 = v;
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o.y15 = v; o.y16 = v; o.y17 = v; o.y18 = v; o.y19 = v; o.y20 = v; o.y21 = v;
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}
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// Check that large object migrations work.
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var o4 = {};
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// All smi.
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set_large(o4, 0);
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assertTrue(%HasFastProperties(o4));
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// All double.
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set_large(o4, 1.5);
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// o5 is immediately allocated with doubles.
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var o5 = {};
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set_large(o5, 0);
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assertTrue(%HaveSameMap(o4, o5));
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function create_smi_object2() {
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var o = {};
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o.a = 1;
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o.b = 2;
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o.c = 3;
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return o;
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}
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// All smi
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var o6 = create_smi_object2();
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var o7 = create_smi_object2();
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assertTrue(%HaveSameMap(o6, o7));
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// Smi, double, smi.
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o6.b = 1.5;
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assertFalse(%HaveSameMap(o6, o7));
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// Smi, double, object.
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o7.c = {};
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assertTrue(%HaveSameMap(o6, o7));
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// Smi, double, object.
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o6.c = {};
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assertTrue(%HaveSameMap(o6, o7));
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function poly_load(o, b) {
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var v = o.field;
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if (b) {
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return v + 10;
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}
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return o;
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}
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var of1 = {a:0};
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of1.field = {};
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var of2 = {b:0};
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of2.field = 10;
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%PrepareFunctionForOptimization(poly_load);
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poly_load(of1, false);
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poly_load(of1, false);
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poly_load(of2, true);
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%OptimizeFunctionOnNextCall(poly_load);
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assertEquals("[object Object]10", poly_load(of1, true));
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// Ensure small object literals with doubles do not share double storage.
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function object_literal() { return {"a":1.5}; }
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var o8 = object_literal();
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var o9 = object_literal();
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o8.a = 4.6
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assertEquals(1.5, o9.a);
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// Ensure double storage is not leaked in the case of polymorphic loads.
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function load_poly(o) {
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return o.a;
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}
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%PrepareFunctionForOptimization(load_poly);
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var o10 = { "a": 1.6 };
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var o11 = { "b": 1, "a": 1.7 };
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load_poly(o10);
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load_poly(o10);
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load_poly(o11);
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%OptimizeFunctionOnNextCall(load_poly);
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var val = load_poly(o10);
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o10.a = 19.5;
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assertFalse(o10.a == val);
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// Ensure polymorphic loads only go monomorphic when the representations are
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// compatible.
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// Check polymorphic load from double + object fields.
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function load_mono(o) {
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return o.a1;
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}
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%PrepareFunctionForOptimization(load_mono);
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var object = {"x": 1};
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var o10 = { "a1": 1.6 };
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var o11 = { "a1": object, "b": 1 };
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load_mono(o10);
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load_mono(o10);
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load_mono(o11);
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%OptimizeFunctionOnNextCall(load_mono);
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assertEquals(object, load_mono(o11));
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// Check polymorphic load from smi + object fields.
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function load_mono2(o) {
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return o.a2;
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}
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%PrepareFunctionForOptimization(load_mono2);
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var o12 = { "a2": 5 };
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var o13 = { "a2": object, "b": 1 };
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load_mono2(o12);
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load_mono2(o12);
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load_mono2(o13);
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%OptimizeFunctionOnNextCall(load_mono2);
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assertEquals(object, load_mono2(o13));
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// Check polymorphic load from double + double fields.
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function load_mono3(o) {
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return o.a3;
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}
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%PrepareFunctionForOptimization(load_mono3);
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var o14 = { "a3": 1.6 };
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var o15 = { "a3": 1.8, "b": 1 };
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load_mono3(o14);
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load_mono3(o14);
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load_mono3(o15);
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%OptimizeFunctionOnNextCall(load_mono3);
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assertEquals(1.6, load_mono3(o14));
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assertEquals(1.8, load_mono3(o15));
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// Check that JSON parsing respects existing representations.
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var o16 = JSON.parse('{"a":1.5}');
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var o17 = JSON.parse('{"a":100}');
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assertTrue(%HaveSameMap(o16, o17));
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var o17_a = o17.a;
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assertEquals(100, o17_a);
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o17.a = 200;
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assertEquals(100, o17_a);
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assertEquals(200, o17.a);
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// Ensure normalizing results in ignored representations.
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var o18 = {};
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o18.field1 = 100;
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o18.field2 = 1;
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o18.to_delete = 100;
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var o19 = {};
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o19.field1 = 100;
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o19.field2 = 1.6;
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o19.to_delete = 100;
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assertFalse(%HaveSameMap(o18, o19));
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delete o18.to_delete;
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delete o19.to_delete;
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assertEquals(1, o18.field2);
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assertEquals(1.6, o19.field2);
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// Test megamorphic keyed stub behaviour in combination with representations.
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var some_object20 = {"a":1};
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var o20 = {};
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o20.smi = 1;
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o20.dbl = 1.5;
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o20.obj = some_object20;
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function keyed_load(o, k) {
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return o[k];
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}
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function keyed_store(o, k, v) {
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return o[k] = v;
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}
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var smi20 = keyed_load(o20, "smi");
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var dbl20 = keyed_load(o20, "dbl");
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var obj20 = keyed_load(o20, "obj");
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keyed_load(o20, "smi");
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keyed_load(o20, "dbl");
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keyed_load(o20, "obj");
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keyed_load(o20, "smi");
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keyed_load(o20, "dbl");
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keyed_load(o20, "obj");
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assertEquals(1, smi20);
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assertEquals(1.5, dbl20);
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assertEquals(some_object20, obj20);
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keyed_store(o20, "smi", 100);
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keyed_store(o20, "dbl", 100);
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keyed_store(o20, "obj", 100);
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keyed_store(o20, "smi", 100);
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keyed_store(o20, "dbl", 100);
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keyed_store(o20, "obj", 100);
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keyed_store(o20, "smi", 100);
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keyed_store(o20, "dbl", 100);
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keyed_store(o20, "obj", 100);
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assertEquals(1, smi20);
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assertEquals(1.5, dbl20);
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assertEquals(some_object20, obj20);
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assertEquals(100, o20.smi);
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assertEquals(100, o20.dbl);
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assertEquals(100, o20.dbl);
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function attr_mismatch_obj(v, writable) {
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var o = {};
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// Assign twice to make the field non-constant.
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o.some_value = 0;
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o.some_value = v;
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Object.defineProperty(o, "second_value", {value:10, writable:writable});
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return o;
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}
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function is_writable(o, p) {
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return Object.getOwnPropertyDescriptor(o,p).writable;
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}
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var writable = attr_mismatch_obj(10, true);
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var non_writable1 = attr_mismatch_obj(10.5, false);
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assertTrue(is_writable(writable,"second_value"));
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assertFalse(is_writable(non_writable1,"second_value"));
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writable.some_value = 20.5;
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assertTrue(is_writable(writable,"second_value"));
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var non_writable2 = attr_mismatch_obj(10.5, false);
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assertTrue(%HaveSameMap(non_writable1, non_writable2));
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function test_f(v) {
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var o = {};
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o.vbf = v;
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o.func = test_f;
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return o;
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}
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function test_fic(o) {
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return o.vbf;
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}
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var ftest1 = test_f(10);
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var ftest2 = test_f(10);
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var ftest3 = test_f(10.5);
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var ftest4 = test_f(10);
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assertFalse(%HaveSameMap(ftest1, ftest3));
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assertTrue(%HaveSameMap(ftest3, ftest4));
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ftest2.func = is_writable;
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test_fic(ftest1);
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test_fic(ftest2);
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test_fic(ftest3);
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test_fic(ftest4);
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assertTrue(%HaveSameMap(ftest1, ftest3));
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assertTrue(%HaveSameMap(ftest3, ftest4));
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// Test representations and transition conversions.
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function read_first_double(o) {
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return o.first_double;
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}
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var df1 = {};
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df1.first_double=1.6;
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read_first_double(df1);
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read_first_double(df1);
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function some_function1() { return 10; }
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var df2 = {};
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df2.first_double = 1.7;
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df2.second_function = some_function1;
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function some_function2() { return 20; }
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var df3 = {};
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df3.first_double = 1.7;
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df3.second_function = some_function2;
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df1.first_double = 10;
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read_first_double(df1);
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// Test boilerplates with computed values.
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function none_boilerplate(a) {
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return {"a_none":a};
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};
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%PrepareFunctionForOptimization(none_boilerplate);
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%OptimizeFunctionOnNextCall(none_boilerplate);
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var none_double1 = none_boilerplate(1.7);
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var none_double2 = none_boilerplate(1.9);
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assertTrue(%HaveSameMap(none_double1, none_double2));
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assertEquals(1.7, none_double1.a_none);
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assertEquals(1.9, none_double2.a_none);
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none_double2.a_none = 3.5;
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var none_double1 = none_boilerplate(1.7);
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var none_double2 = none_boilerplate(3.5);
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function none_to_smi(a) {
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return {"a_smi":a};
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}
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%PrepareFunctionForOptimization(none_to_smi);
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var none_smi1 = none_to_smi(1);
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var none_smi2 = none_to_smi(2);
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%OptimizeFunctionOnNextCall(none_to_smi);
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var none_smi3 = none_to_smi(3);
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assertTrue(%HaveSameMap(none_smi1, none_smi2));
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assertTrue(%HaveSameMap(none_smi1, none_smi3));
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assertEquals(1, none_smi1.a_smi);
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assertEquals(2, none_smi2.a_smi);
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assertEquals(3, none_smi3.a_smi);
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function none_to_double(a) {
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return {"a_double":a};
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}
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%PrepareFunctionForOptimization(none_to_double);
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var none_to_double1 = none_to_double(1.5);
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var none_to_double2 = none_to_double(2.8);
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%OptimizeFunctionOnNextCall(none_to_double);
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var none_to_double3 = none_to_double(3.7);
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assertTrue(%HaveSameMap(none_to_double1, none_to_double2));
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assertTrue(%HaveSameMap(none_to_double1, none_to_double3));
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assertEquals(1.5, none_to_double1.a_double);
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assertEquals(2.8, none_to_double2.a_double);
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assertEquals(3.7, none_to_double3.a_double);
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function none_to_object(a) {
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return {"an_object":a};
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}
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%PrepareFunctionForOptimization(none_to_object);
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var none_to_object1 = none_to_object(true);
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var none_to_object2 = none_to_object(false);
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%OptimizeFunctionOnNextCall(none_to_object);
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var none_to_object3 = none_to_object(3.7);
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assertTrue(%HaveSameMap(none_to_object1, none_to_object2));
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assertTrue(%HaveSameMap(none_to_object1, none_to_object3));
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assertEquals(true, none_to_object1.an_object);
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assertEquals(false, none_to_object2.an_object);
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assertEquals(3.7, none_to_object3.an_object);
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function double_to_object(a) {
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var o = {"d_to_h":1.8};
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o.d_to_h = a;
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return o;
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}
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var dh1 = double_to_object(true);
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var dh2 = double_to_object(false);
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assertTrue(%HaveSameMap(dh1, dh2));
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assertEquals(true, dh1.d_to_h);
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assertEquals(false, dh2.d_to_h);
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function smi_to_object(a) {
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var o = {"s_to_t":18};
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o.s_to_t = a;
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return o;
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}
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var st1 = smi_to_object(true);
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var st2 = smi_to_object(false);
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assertTrue(%HaveSameMap(st1, st2));
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assertEquals(true, st1.s_to_t);
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assertEquals(false, st2.s_to_t);
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