// Copyright 2012 the V8 project authors. All rights reserved. // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following // disclaimer in the documentation and/or other materials provided // with the distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived // from this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // Flags: --allow-natives-syntax --expose-gc --opt --no-always-opt var elements_kind = { fast_smi_only : 'fast smi only elements', fast : 'fast elements', fast_double : 'fast double elements', dictionary : 'dictionary elements', external_byte : 'external byte elements', external_unsigned_byte : 'external unsigned byte elements', external_short : 'external short elements', external_unsigned_short : 'external unsigned short elements', external_int : 'external int elements', external_unsigned_int : 'external unsigned int elements', external_float : 'external float elements', external_double : 'external double elements', external_pixel : 'external pixel elements' } function getKind(obj) { if (%HasSmiElements(obj)) return elements_kind.fast_smi_only; if (%HasObjectElements(obj)) return elements_kind.fast; if (%HasDoubleElements(obj)) return elements_kind.fast_double; if (%HasDictionaryElements(obj)) return elements_kind.dictionary; } function isHoley(obj) { if (%HasHoleyElements(obj)) return true; return false; } function assertKind(expected, obj, name_opt) { assertEquals(expected, getKind(obj), name_opt); } function assertHoley(obj, name_opt) { assertEquals(true, isHoley(obj), name_opt); } function assertNotHoley(obj, name_opt) { assertEquals(false, isHoley(obj), name_opt); } obj = []; assertNotHoley(obj); assertKind(elements_kind.fast_smi_only, obj); obj = [1, 2, 3]; assertNotHoley(obj); assertKind(elements_kind.fast_smi_only, obj); obj = new Array(); assertNotHoley(obj); assertKind(elements_kind.fast_smi_only, obj); obj = new Array(0); assertHoley(obj); assertKind(elements_kind.fast_smi_only, obj); obj = new Array(2); assertHoley(obj); assertKind(elements_kind.fast_smi_only, obj); obj = new Array(1,2,3); assertNotHoley(obj); assertKind(elements_kind.fast_smi_only, obj); obj = new Array(1, "hi", 2, undefined); assertNotHoley(obj); assertKind(elements_kind.fast, obj); function fastliteralcase(literal, value) { literal[0] = value; return literal; } function get_standard_literal() { var literal = [1, 2, 3]; return literal; } %PrepareFunctionForOptimization(get_standard_literal); // Case: [1,2,3] as allocation site obj = fastliteralcase(get_standard_literal(), 1); assertKind(elements_kind.fast_smi_only, obj); obj = fastliteralcase(get_standard_literal(), 1.5); assertKind(elements_kind.fast_double, obj); obj = fastliteralcase(get_standard_literal(), 2); assertKind(elements_kind.fast_double, obj); // The test below is in a loop because arrays that live // at global scope without the chance of being recreated // don't have allocation site information attached. for (i = 0; i < 2; i++) { obj = fastliteralcase([5, 3, 2], 1.5); assertKind(elements_kind.fast_double, obj); obj = fastliteralcase([3, 6, 2], 1.5); assertKind(elements_kind.fast_double, obj); // Note: thanks to pessimistic transition store stubs, we'll attempt // to transition to the most general elements kind seen at a particular // store site. So, the elements kind will be double. obj = fastliteralcase([2, 6, 3], 2); assertKind(elements_kind.fast_double, obj); } // Verify that we will not pretransition the double->fast path. obj = fastliteralcase(get_standard_literal(), "elliot"); assertKind(elements_kind.fast, obj); obj = fastliteralcase(get_standard_literal(), 3); assertKind(elements_kind.fast, obj); // Make sure this works in optimized code too. %OptimizeFunctionOnNextCall(get_standard_literal); get_standard_literal(); obj = get_standard_literal(); assertKind(elements_kind.fast, obj); function fastliteralcase_smifast(value) { var literal = [1, 2, 3, 4]; literal[0] = value; return literal; } obj = fastliteralcase_smifast(1); assertKind(elements_kind.fast_smi_only, obj); obj = fastliteralcase_smifast("carter"); assertKind(elements_kind.fast, obj); obj = fastliteralcase_smifast(2); assertKind(elements_kind.fast, obj); // Case: make sure transitions from packed to holey are tracked function fastliteralcase_smiholey(index, value) { var literal = [1, 2, 3, 4]; literal[index] = value; return literal; } obj = fastliteralcase_smiholey(5, 1); assertKind(elements_kind.fast_smi_only, obj); assertHoley(obj); obj = fastliteralcase_smiholey(0, 1); assertKind(elements_kind.fast_smi_only, obj); assertHoley(obj); function newarraycase_smidouble(value) { var a = new Array(); a[0] = value; return a; } // Case: new Array() as allocation site, smi->double obj = newarraycase_smidouble(1); assertKind(elements_kind.fast_smi_only, obj); obj = newarraycase_smidouble(1.5); assertKind(elements_kind.fast_double, obj); obj = newarraycase_smidouble(2); assertKind(elements_kind.fast_double, obj); function newarraycase_smiobj(value) { var a = new Array(); a[0] = value; return a; } // Case: new Array() as allocation site, smi->fast obj = newarraycase_smiobj(1); assertKind(elements_kind.fast_smi_only, obj); obj = newarraycase_smiobj("gloria"); assertKind(elements_kind.fast, obj); obj = newarraycase_smiobj(2); assertKind(elements_kind.fast, obj); function newarraycase_length_smidouble(value) { var a = new Array(3); a[0] = value; return a; } // Case: new Array(length) as allocation site obj = newarraycase_length_smidouble(1); assertKind(elements_kind.fast_smi_only, obj); obj = newarraycase_length_smidouble(1.5); assertKind(elements_kind.fast_double, obj); obj = newarraycase_length_smidouble(2); assertKind(elements_kind.fast_double, obj); // Try to continue the transition to fast object. // TODO(mvstanton): re-enable commented out code when // FLAG_pretenuring_call_new is turned on in the build. obj = newarraycase_length_smidouble("coates"); assertKind(elements_kind.fast, obj); obj = newarraycase_length_smidouble(2); // assertKind(elements_kind.fast, obj); function newarraycase_length_smiobj(value) { var a = new Array(3); a[0] = value; return a; } // Case: new Array() as allocation site, smi->fast obj = newarraycase_length_smiobj(1); assertKind(elements_kind.fast_smi_only, obj); obj = newarraycase_length_smiobj("gloria"); assertKind(elements_kind.fast, obj); obj = newarraycase_length_smiobj(2); assertKind(elements_kind.fast, obj); function newarraycase_list_smidouble(value) { var a = new Array(1, 2, 3); a[0] = value; return a; } obj = newarraycase_list_smidouble(1); assertKind(elements_kind.fast_smi_only, obj); obj = newarraycase_list_smidouble(1.5); assertKind(elements_kind.fast_double, obj); obj = newarraycase_list_smidouble(2); assertKind(elements_kind.fast_double, obj); function newarraycase_list_smiobj(value) { var a = new Array(4, 5, 6); a[0] = value; return a; } obj = newarraycase_list_smiobj(1); assertKind(elements_kind.fast_smi_only, obj); obj = newarraycase_list_smiobj("coates"); assertKind(elements_kind.fast, obj); obj = newarraycase_list_smiobj(2); assertKind(elements_kind.fast, obj); // Perform a gc because without it the test below can experience an // allocation failure at an inconvenient point. Allocation mementos get // cleared on gc, and they can't deliver elements kind feedback when that // happens. gc(); // Case: array constructor calls with out of date feedback. // The boilerplate should incorporate all feedback, but the input array // should be minimally transitioned based on immediate need. (function() { function foo(i) { // We have two cases, one for literals one for constructed arrays. var a = (i == 0) ? [1, 2, 3] : new Array(1, 2, 3); return a; } for (var i = 0; i < 2; i++) { a = foo(i); b = foo(i); b[5] = 1; // boilerplate goes holey assertHoley(foo(i)); a[0] = 3.5; // boilerplate goes holey double assertKind(elements_kind.fast_double, a); assertNotHoley(a); var c = foo(i); assertKind(elements_kind.fast_double, c); assertHoley(c); } })(); function newarraycase_onearg(len, value) { var a = new Array(len); a[0] = value; return a; } obj = newarraycase_onearg(5, 3.5); assertKind(elements_kind.fast_double, obj); obj = newarraycase_onearg(10, 5); assertKind(elements_kind.fast_double, obj); obj = newarraycase_onearg(0, 5); assertKind(elements_kind.fast_double, obj); // Verify that cross context calls work var realmA = Realm.current(); var realmB = Realm.create(); assertEquals(0, realmA); assertEquals(1, realmB); function instanceof_check(type) { assertTrue(new type() instanceof type); assertTrue(new type(5) instanceof type); assertTrue(new type(1,2,3) instanceof type); } function instanceof_check2(type) { assertTrue(new type() instanceof type); assertTrue(new type(5) instanceof type); assertTrue(new type(1,2,3) instanceof type); } %PrepareFunctionForOptimization(instanceof_check); var realmBArray = Realm.eval(realmB, "Array"); // Two calls with Array because ES6 instanceof desugars into a load of Array, // and load has a premonomorphic state. instanceof_check(Array); instanceof_check(Array); instanceof_check(realmBArray); // instanceof_check2 is here because the call site goes through a state. // Since instanceof_check(Array) was first called with the current context // Array function, it went from (uninit->Array) then (Array->megamorphic). // We'll get a different state traversal if we start with realmBArray. // It'll go (uninit->realmBArray) then (realmBArray->megamorphic). Recognize // that state "Array" implies an AllocationSite is present, and code is // configured to use it. // Two calls with realmBArray because ES6 instanceof desugars into a load of // realmBArray, and load has a premonomorphic state. instanceof_check2(realmBArray); instanceof_check2(realmBArray); instanceof_check2(Array); %OptimizeFunctionOnNextCall(instanceof_check); // No de-opt will occur because HCallNewArray wasn't selected, on account of // the call site not being monomorphic to Array. instanceof_check(Array); assertOptimized(instanceof_check); instanceof_check(realmBArray); assertOptimized(instanceof_check); // Try to optimize again, but first clear all type feedback, and allow it // to be monomorphic on first call. Only after optimizing do we introduce // realmBArray. This should deopt the method. %PrepareFunctionForOptimization(instanceof_check); %DeoptimizeFunction(instanceof_check); %ClearFunctionFeedback(instanceof_check); instanceof_check(Array); instanceof_check(Array); %PrepareFunctionForOptimization(instanceof_check); %OptimizeFunctionOnNextCall(instanceof_check); instanceof_check(Array); assertOptimized(instanceof_check); instanceof_check(realmBArray); assertUnoptimized(instanceof_check); // Perform a gc because without it the test below can experience an // allocation failure at an inconvenient point. Allocation mementos get // cleared on gc, and they can't deliver elements kind feedback when that // happens. gc(); // Case: make sure nested arrays benefit from allocation site feedback as // well. (function() { // Make sure we handle nested arrays function get_nested_literal() { var literal = [[1,2,3,4], [2], [3]]; return literal; } obj = get_nested_literal(); assertKind(elements_kind.fast, obj); obj[0][0] = 3.5; obj[2][0] = "hello"; obj = get_nested_literal(); assertKind(elements_kind.fast_double, obj[0]); assertKind(elements_kind.fast_smi_only, obj[1]); assertKind(elements_kind.fast, obj[2]); // A more complex nested literal case. function get_deep_nested_literal() { var literal = [[1], [[2], "hello"], 3, [4]]; return literal; } obj = get_deep_nested_literal(); assertKind(elements_kind.fast_smi_only, obj[1][0]); obj[0][0] = 3.5; obj[1][0][0] = "goodbye"; assertKind(elements_kind.fast_double, obj[0]); assertKind(elements_kind.fast, obj[1][0]); obj = get_deep_nested_literal(); assertKind(elements_kind.fast_double, obj[0]); assertKind(elements_kind.fast, obj[1][0]); })(); // Perform a gc because without it the test below can experience an // allocation failure at an inconvenient point. Allocation mementos get // cleared on gc, and they can't deliver elements kind feedback when that // happens. gc(); // Make sure object literals with array fields benefit from the type feedback // that allocation mementos provide. (function() { // A literal in an object function get_object_literal() { var literal = { array: [1,2,3], data: 3.5 }; return literal; } obj = get_object_literal(); assertKind(elements_kind.fast_smi_only, obj.array); // Force double transition. obj.array[1] = 3.5; assertKind(elements_kind.fast_double, obj.array); // Transition information should be fed back to the inner literal. obj = get_object_literal(); assertKind(elements_kind.fast_double, obj.array); function get_nested_object_literal() { var literal = { array: [[1],[2],[3]], data: 3.5 }; return literal; } obj = get_nested_object_literal(); assertKind(elements_kind.fast, obj.array); assertKind(elements_kind.fast_smi_only, obj.array[1]); obj.array[1][0] = 3.5; assertKind(elements_kind.fast_double, obj.array[1]); obj = get_nested_object_literal(); assertKind(elements_kind.fast_double, obj.array[1]); %OptimizeFunctionOnNextCall(get_nested_object_literal); get_nested_object_literal(); obj = get_nested_object_literal(); assertKind(elements_kind.fast_double, obj.array[1]); // Make sure we handle nested arrays function get_nested_literal() { var literal = [[1,2,3,4], [2], [3]]; return literal; } obj = get_nested_literal(); assertKind(elements_kind.fast, obj); obj[0][0] = 3.5; obj[2][0] = "hello"; obj = get_nested_literal(); assertKind(elements_kind.fast_double, obj[0]); assertKind(elements_kind.fast_smi_only, obj[1]); assertKind(elements_kind.fast, obj[2]); // A more complex nested literal case. function get_deep_nested_literal() { var literal = [[1], [[2], "hello"], 3, [4]]; return literal; } obj = get_deep_nested_literal(); assertKind(elements_kind.fast_smi_only, obj[1][0]); obj[0][0] = 3.5; obj[1][0][0] = "goodbye"; assertKind(elements_kind.fast_double, obj[0]); assertKind(elements_kind.fast, obj[1][0]); obj = get_deep_nested_literal(); assertKind(elements_kind.fast_double, obj[0]); assertKind(elements_kind.fast, obj[1][0]); })(); // Test gathering allocation site feedback for generic ics. (function() { function make() { return new Array(); } function foo(a, i) { a[0] = i; } var a = make(); assertKind(elements_kind.fast_smi_only, a); // Make the keyed store ic go generic. foo("howdy", 1); foo(a, 3.5); var b = make(); assertKind(elements_kind.fast_double, b); })(); (function TestBoilerplateMapDeprecation() { function literal() { return { a: 1, b: 2 }; } literal(); literal(); let instance = literal(); assertKind(elements_kind.fast_smi_only, [instance.a, instance.b]); // Create literal instances with double insteand of smi values. for (let i = 0; i < 1000; i++) { instance = literal(); instance.a = 1.2; assertKind(elements_kind.fast_double, [instance.a, instance.b]); } // After deprecating the original boilerplate map we should get heap numbers // back for the original unmodified literal as well. for (let i =0; i < 100; i++) { instance = literal(); assertKind(elements_kind.fast_double, [instance.a, instance.b]); } })(); (function TestInnerBoilerplateMapDeprecation() { // Create a literal where the inner literals cause a map deprecation of the // previous inner literal. function literal() { return [ {xA2A:false, a: 1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1.1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1.1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1.1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1.1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1.1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1.1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1.1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1.1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1.1, b: 2, c: 3, d: 4.1}, {xA2A:false, a: 1.1, b: 2, c: 3, d: 4.1} ]; }; let instance = literal(); // Make sure all sub-literals are migrated properly. for (let i = 0; i < instance.length; i++) { let sub_literal = instance[i]; assertKind(elements_kind.fast_double, [sub_literal.a]); assertKind(elements_kind.fast_smi_only, [sub_literal.b]); assertKind(elements_kind.fast_smi_only, [sub_literal.c]); assertKind(elements_kind.fast_double, [sub_literal.d]); } instance = literal(); instance = literal(); instance = literal(); for (let i = 0; i < instance.length; i++) { let sub_literal = instance[i]; assertKind(elements_kind.fast_double, [sub_literal.a]); assertKind(elements_kind.fast_smi_only, [sub_literal.b]); assertKind(elements_kind.fast_smi_only, [sub_literal.c]); assertKind(elements_kind.fast_double, [sub_literal.d]); } })();