src/v8/test/mjsunit/compiler/number-divide.js - cobalt - Git at Google

 // Copyright 2018 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // Flags: --allow-natives-syntax --opt --noalways-opt

 // Test that NumberDivide with Number feedback works if only in the
 // end SimplifiedLowering figures out that the inputs to this operation
 // are actually Unsigned32.
 (function() {
   // We need a separately polluted % with NumberOrOddball feedback.
   function bar(x) { return x / 2; }
   bar(undefined);  // The % feedback is now NumberOrOddball.

   // Now just use the gadget above in a way that only after RETYPE
   // in SimplifiedLowering we find out that the `x` is actually in
   // Unsigned32 range (based on taking the SignedSmall feedback on
   // the + operator).
   function foo(x) {
     x = (x >>> 0) + 1;
     return bar(x) | 0;
   }

   %PrepareFunctionForOptimization(foo);
   assertEquals(1, foo(1));
   assertEquals(1, foo(2));
   assertEquals(2, foo(3));
   assertEquals(2, foo(4));
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(1, foo(1));
   assertEquals(1, foo(2));
   assertEquals(2, foo(3));
   assertEquals(2, foo(4));
   assertOptimized(foo);
 })();

 // Test that NumberDivide with Number feedback works if only in the
 // end SimplifiedLowering figures out that the inputs to this operation
 // are actually Signed32.
 (function() {
   // We need a separately polluted % with NumberOrOddball feedback.
   function bar(x) { return x / 2; }
   bar(undefined);  // The % feedback is now NumberOrOddball.

   // Now just use the gadget above in a way that only after RETYPE
   // in SimplifiedLowering we find out that the `x` is actually in
   // Signed32 range (based on taking the SignedSmall feedback on
   // the + operator).
   function foo(x) {
     x = (x | 0) + 1;
     return bar(x) | 0;
   }

   %PrepareFunctionForOptimization(foo);
   assertEquals(1, foo(1));
   assertEquals(1, foo(2));
   assertEquals(2, foo(3));
   assertEquals(2, foo(4));
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(1, foo(1));
   assertEquals(1, foo(2));
   assertEquals(2, foo(3));
   assertEquals(2, foo(4));
   assertOptimized(foo);
 })();

 // Test that SpeculativeNumberDivide turns into CheckedInt32Div, and
 // that the "known power of two divisor" optimization works correctly.
 (function() {
   function foo(x) { return (x | 0) / 2; }

   // Warmup with proper int32 divisions.
   %PrepareFunctionForOptimization(foo);
   assertEquals(1, foo(2));
   assertEquals(2, foo(4));
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(3, foo(6));
   assertOptimized(foo);

   // Make optimized code fail.
   assertEquals(0.5, foo(1));
   assertUnoptimized(foo);

   // Try again with the new feedback, and now it should stay optimized.
   %PrepareFunctionForOptimization(foo);
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(4, foo(8));
   assertOptimized(foo);
   assertEquals(0.5, foo(1));
   assertOptimized(foo);
 })();

 // Test that SpeculativeNumberDivide turns into CheckedInt32Div, and
 // that the optimized code properly bails out on "division by zero".
 (function() {
   function foo(x, y) { return x / y; }

   // Warmup with proper int32 divisions.
   %PrepareFunctionForOptimization(foo);
   assertEquals(2, foo(4, 2));
   assertEquals(2, foo(8, 4));
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(1, foo(2, 2));
   assertOptimized(foo);

   // Make optimized code fail.
   assertEquals(Infinity, foo(1, 0));
   assertUnoptimized(foo);

   // Try again with the new feedback, and now it should stay optimized.
   %PrepareFunctionForOptimization(foo);
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(2, foo(2, 1));
   assertOptimized(foo);
   assertEquals(Infinity, foo(1, 0));
   assertOptimized(foo);
 })();

 // Test that SpeculativeNumberDivide turns into CheckedInt32Div, and
 // that the optimized code properly bails out on minus zero.
 (function() {
   function foo(x, y) { return x / y; }

   // Warmup with proper int32 divisions.
   %PrepareFunctionForOptimization(foo);
   assertEquals(2, foo(4, 2));
   assertEquals(2, foo(8, 4));
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(1, foo(2, 2));
   assertOptimized(foo);

   // Make optimized code fail.
   assertEquals(-0, foo(0, -1));
   assertUnoptimized(foo);

   // Try again with the new feedback, and now it should stay optimized.
   %PrepareFunctionForOptimization(foo);
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(2, foo(2, 1));
   assertOptimized(foo);
   assertEquals(-0, foo(0, -1));
   assertOptimized(foo);
 })();

 // Test that SpeculativeNumberDivide turns into CheckedInt32Div, and
 // that the optimized code properly bails out if result is -kMinInt.
 (function() {
   function foo(x, y) { return x / y; }

   // Warmup with proper int32 divisions.
   %PrepareFunctionForOptimization(foo);
   assertEquals(2, foo(4, 2));
   assertEquals(2, foo(8, 4));
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(1, foo(2, 2));
   assertOptimized(foo);

   // Make optimized code fail.
   assertEquals(2147483648, foo(-2147483648, -1));
   assertUnoptimized(foo);

   // Try again with the new feedback, and now it should stay optimized.
   %PrepareFunctionForOptimization(foo);
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(2, foo(2, 1));
   assertOptimized(foo);
   assertEquals(2147483648, foo(-2147483648, -1));
   assertOptimized(foo);
 })();

 // Test that SpeculativeNumberDivide turns into CheckedUint32Div, and
 // that the "known power of two divisor" optimization works correctly.
 (function() {
   function foo(s) { return s.length / 2; }

   // Warmup with proper uint32 divisions.
   %PrepareFunctionForOptimization(foo);
   assertEquals(1, foo("ab".repeat(1)));
   assertEquals(2, foo("ab".repeat(2)));
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(3, foo("ab".repeat(3)));
   assertOptimized(foo);

   // Make optimized code fail.
   assertEquals(0.5, foo("a"));
   assertUnoptimized(foo);

   // Try again with the new feedback, and now it should stay optimized.
   %PrepareFunctionForOptimization(foo);
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(4, foo("ab".repeat(4)));
   assertOptimized(foo);
   assertEquals(0.5, foo("a"));
   assertOptimized(foo);
 })();

 // Test that SpeculativeNumberDivide turns into CheckedUint32Div, and
 // that the optimized code properly bails out on "division by zero".
 (function() {
   function foo(x, y) { return (x >>> 0) / (y >>> 0); }

   // Warmup with proper uint32 divisions.
   %PrepareFunctionForOptimization(foo);
   assertEquals(2, foo(4, 2));
   assertEquals(2, foo(8, 4));
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(1, foo(2, 2));
   assertOptimized(foo);

   // Make optimized code fail.
   assertEquals(Infinity, foo(1, 0));
   assertUnoptimized(foo);

   // Try again with the new feedback, and now it should stay optimized.
   %PrepareFunctionForOptimization(foo);
   %OptimizeFunctionOnNextCall(foo);
   assertEquals(2, foo(2, 1));
   assertOptimized(foo);
   assertEquals(Infinity, foo(1, 0));
   assertOptimized(foo);
 })();
	// Copyright 2018 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// Flags: --allow-natives-syntax --opt --noalways-opt

	// Test that NumberDivide with Number feedback works if only in the
	// end SimplifiedLowering figures out that the inputs to this operation
	// are actually Unsigned32.
	(function() {
	// We need a separately polluted % with NumberOrOddball feedback.
	function bar(x) { return x / 2; }
	bar(undefined); // The % feedback is now NumberOrOddball.

	// Now just use the gadget above in a way that only after RETYPE
	// in SimplifiedLowering we find out that the `x` is actually in
	// Unsigned32 range (based on taking the SignedSmall feedback on
	// the + operator).
	function foo(x) {
	x = (x >>> 0) + 1;
	return bar(x) \| 0;
	}

	%PrepareFunctionForOptimization(foo);
	assertEquals(1, foo(1));
	assertEquals(1, foo(2));
	assertEquals(2, foo(3));
	assertEquals(2, foo(4));
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(1, foo(1));
	assertEquals(1, foo(2));
	assertEquals(2, foo(3));
	assertEquals(2, foo(4));
	assertOptimized(foo);
	})();

	// Test that NumberDivide with Number feedback works if only in the
	// end SimplifiedLowering figures out that the inputs to this operation
	// are actually Signed32.
	(function() {
	// We need a separately polluted % with NumberOrOddball feedback.
	function bar(x) { return x / 2; }
	bar(undefined); // The % feedback is now NumberOrOddball.

	// Now just use the gadget above in a way that only after RETYPE
	// in SimplifiedLowering we find out that the `x` is actually in
	// Signed32 range (based on taking the SignedSmall feedback on
	// the + operator).
	function foo(x) {
	x = (x \| 0) + 1;
	return bar(x) \| 0;
	}

	%PrepareFunctionForOptimization(foo);
	assertEquals(1, foo(1));
	assertEquals(1, foo(2));
	assertEquals(2, foo(3));
	assertEquals(2, foo(4));
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(1, foo(1));
	assertEquals(1, foo(2));
	assertEquals(2, foo(3));
	assertEquals(2, foo(4));
	assertOptimized(foo);
	})();

	// Test that SpeculativeNumberDivide turns into CheckedInt32Div, and
	// that the "known power of two divisor" optimization works correctly.
	(function() {
	function foo(x) { return (x \| 0) / 2; }

	// Warmup with proper int32 divisions.
	%PrepareFunctionForOptimization(foo);
	assertEquals(1, foo(2));
	assertEquals(2, foo(4));
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(3, foo(6));
	assertOptimized(foo);

	// Make optimized code fail.
	assertEquals(0.5, foo(1));
	assertUnoptimized(foo);

	// Try again with the new feedback, and now it should stay optimized.
	%PrepareFunctionForOptimization(foo);
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(4, foo(8));
	assertOptimized(foo);
	assertEquals(0.5, foo(1));
	assertOptimized(foo);
	})();

	// Test that SpeculativeNumberDivide turns into CheckedInt32Div, and
	// that the optimized code properly bails out on "division by zero".
	(function() {
	function foo(x, y) { return x / y; }

	// Warmup with proper int32 divisions.
	%PrepareFunctionForOptimization(foo);
	assertEquals(2, foo(4, 2));
	assertEquals(2, foo(8, 4));
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(1, foo(2, 2));
	assertOptimized(foo);

	// Make optimized code fail.
	assertEquals(Infinity, foo(1, 0));
	assertUnoptimized(foo);

	// Try again with the new feedback, and now it should stay optimized.
	%PrepareFunctionForOptimization(foo);
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(2, foo(2, 1));
	assertOptimized(foo);
	assertEquals(Infinity, foo(1, 0));
	assertOptimized(foo);
	})();

	// Test that SpeculativeNumberDivide turns into CheckedInt32Div, and
	// that the optimized code properly bails out on minus zero.
	(function() {
	function foo(x, y) { return x / y; }

	// Warmup with proper int32 divisions.
	%PrepareFunctionForOptimization(foo);
	assertEquals(2, foo(4, 2));
	assertEquals(2, foo(8, 4));
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(1, foo(2, 2));
	assertOptimized(foo);

	// Make optimized code fail.
	assertEquals(-0, foo(0, -1));
	assertUnoptimized(foo);

	// Try again with the new feedback, and now it should stay optimized.
	%PrepareFunctionForOptimization(foo);
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(2, foo(2, 1));
	assertOptimized(foo);
	assertEquals(-0, foo(0, -1));
	assertOptimized(foo);
	})();

	// Test that SpeculativeNumberDivide turns into CheckedInt32Div, and
	// that the optimized code properly bails out if result is -kMinInt.
	(function() {
	function foo(x, y) { return x / y; }

	// Warmup with proper int32 divisions.
	%PrepareFunctionForOptimization(foo);
	assertEquals(2, foo(4, 2));
	assertEquals(2, foo(8, 4));
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(1, foo(2, 2));
	assertOptimized(foo);

	// Make optimized code fail.
	assertEquals(2147483648, foo(-2147483648, -1));
	assertUnoptimized(foo);

	// Try again with the new feedback, and now it should stay optimized.
	%PrepareFunctionForOptimization(foo);
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(2, foo(2, 1));
	assertOptimized(foo);
	assertEquals(2147483648, foo(-2147483648, -1));
	assertOptimized(foo);
	})();

	// Test that SpeculativeNumberDivide turns into CheckedUint32Div, and
	// that the "known power of two divisor" optimization works correctly.
	(function() {
	function foo(s) { return s.length / 2; }

	// Warmup with proper uint32 divisions.
	%PrepareFunctionForOptimization(foo);
	assertEquals(1, foo("ab".repeat(1)));
	assertEquals(2, foo("ab".repeat(2)));
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(3, foo("ab".repeat(3)));
	assertOptimized(foo);

	// Make optimized code fail.
	assertEquals(0.5, foo("a"));
	assertUnoptimized(foo);

	// Try again with the new feedback, and now it should stay optimized.
	%PrepareFunctionForOptimization(foo);
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(4, foo("ab".repeat(4)));
	assertOptimized(foo);
	assertEquals(0.5, foo("a"));
	assertOptimized(foo);
	})();

	// Test that SpeculativeNumberDivide turns into CheckedUint32Div, and
	// that the optimized code properly bails out on "division by zero".
	(function() {
	function foo(x, y) { return (x >>> 0) / (y >>> 0); }

	// Warmup with proper uint32 divisions.
	%PrepareFunctionForOptimization(foo);
	assertEquals(2, foo(4, 2));
	assertEquals(2, foo(8, 4));
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(1, foo(2, 2));
	assertOptimized(foo);

	// Make optimized code fail.
	assertEquals(Infinity, foo(1, 0));
	assertUnoptimized(foo);

	// Try again with the new feedback, and now it should stay optimized.
	%PrepareFunctionForOptimization(foo);
	%OptimizeFunctionOnNextCall(foo);
	assertEquals(2, foo(2, 1));
	assertOptimized(foo);
	assertEquals(Infinity, foo(1, 0));
	assertOptimized(foo);
	})();