src/third_party/mozjs-45/js/src/jit-test/tests/ion/testFloat32-correctness.js - cobalt - Git at Google

 setJitCompilerOption("ion.warmup.trigger", 50);

 var f32 = new Float32Array(10);

 function test(setup, f) {
     if (f === undefined) {
         f = setup;
         setup = function(){};
     }
     setup();
     for(var n = 200; n; --n) {
         f();
     }
 }

 // Basic arithmetic
 function setupBasicArith() {
     f32[0] = -Infinity;
     f32[1] = -1;
     f32[2] = -0;
     f32[3] = 0;
     f32[4] = 1.337;
     f32[5] = 42;
     f32[6] = Infinity;
     f32[7] = NaN;
 }
 function basicArith() {
     for (var i = 0; i < 7; ++i) {
         var opf = Math.fround(f32[i] + f32[i+1]);
         var opd = (1 / (1 / f32[i])) + f32[i+1];
         assertFloat32(opf, true);
         assertFloat32(opd, false);
         assertEq(opf, Math.fround(opd));

         opf = Math.fround(f32[i] - f32[i+1]);
         opd = (1 / (1 / f32[i])) - f32[i+1];
         assertFloat32(opf, true);
         assertFloat32(opd, false);
         assertEq(opf, Math.fround(opd));

         opf = Math.fround(f32[i] * f32[i+1]);
         opd = (1 / (1 / f32[i])) * f32[i+1];
         assertFloat32(opf, true);
         assertFloat32(opd, false);
         assertEq(opf, Math.fround(opd));

         opf = Math.fround(f32[i] / f32[i+1]);
         opd = (1 / (1 / f32[i])) / f32[i+1];
         assertFloat32(opf, true);
         assertFloat32(opd, false);
         assertEq(opf, Math.fround(opd));
     }
 }
 test(setupBasicArith, basicArith);

 // MAbs
 function setupAbs() {
     f32[0] = -0;
     f32[1] = 0;
     f32[2] = -3.14159;
     f32[3] = 3.14159;
     f32[4] = -Infinity;
     f32[5] = Infinity;
     f32[6] = NaN;
 }
 function abs() {
     for(var i = 0; i < 7; ++i) {
         assertEq( Math.fround(Math.abs(f32[i])), Math.abs(f32[i]) );
     }
 }
 test(setupAbs, abs);

 // MSqrt
 function setupSqrt() {
     f32[0] = 0;
     f32[1] = 1;
     f32[2] = 4;
     f32[3] = -1;
     f32[4] = Infinity;
     f32[5] = NaN;
     f32[6] = 13.37;
 }
 function sqrt() {
     for(var i = 0; i < 7; ++i) {
         var sqrtf = Math.fround(Math.sqrt(f32[i]));
         var sqrtd = 1 + Math.sqrt(f32[i]) - 1; // force no float32 by chaining arith ops
         assertEq( sqrtf, Math.fround(sqrtd) );
     }
 }
 test(setupSqrt, sqrt);

 // MMinMax
 function setupMinMax() {
     f32[0] = -0;
     f32[1] = 0;
     f32[2] = 1;
     f32[3] = 4;
     f32[4] = -1;
     f32[5] = Infinity;
     f32[6] = NaN;
     f32[7] = 13.37;
     f32[8] = -Infinity;
     f32[9] = Math.pow(2,31) - 1;
 }
 function minMax() {
     for(var i = 0; i < 9; ++i) {
         for(var j = 0; j < 9; j++) {
             var minf = Math.fround(Math.min(f32[i], f32[j]));
             var mind = 1 / (1 / Math.min(f32[i], f32[j])); // force no float32 by chaining arith ops
             assertFloat32(minf, true);
             assertFloat32(mind, false);
             assertEq( minf, Math.fround(mind) );

             var maxf = Math.fround(Math.max(f32[i], f32[j]));
             var maxd = 1 / (1 / Math.max(f32[i], f32[j])); // force no float32 by chaining arith ops
             assertFloat32(maxf, true);
             assertFloat32(maxd, false);
             assertEq( maxf, Math.fround(maxd) );
         }
     }
 }
 test(setupMinMax, minMax);

 // MTruncateToInt32
 // The only way to get a MTruncateToInt32 with a Float32 input is to use Math.imul
 function setupTruncateToInt32() {
     f32[0] = -1;
     f32[1] = 4;
     f32[2] = 5.13;
 }
 function truncateToInt32() {
     assertEq( Math.imul(f32[0], f32[1]), Math.imul(-1, 4) );
     assertEq( Math.imul(f32[1], f32[2]), Math.imul(4, 5) );
 }
 test(setupTruncateToInt32, truncateToInt32);

 // MCompare
 function comp() {
     for(var i = 0; i < 9; ++i) {
         assertEq( f32[i] < f32[i+1], true );
     }
 }
 function setupComp() {
     f32[0] = -Infinity;
     f32[1] = -1;
     f32[2] = -0.01;
     f32[3] = 0;
     f32[4] = 0.01;
     f32[5] = 1;
     f32[6] = 10;
     f32[7] = 13.37;
     f32[8] = 42;
     f32[9] = Infinity;
 }
 test(setupComp, comp);

 // MNot
 function setupNot() {
     f32[0] = -0;
     f32[1] = 0;
     f32[2] = 1;
     f32[3] = NaN;
     f32[4] = Infinity;
     f32[5] = 42;
     f32[5] = -23;
 }
 function not() {
     assertEq( !f32[0], true );
     assertEq( !f32[1], true );
     assertEq( !f32[2], false );
     assertEq( !f32[3], true );
     assertEq( !f32[4], false );
     assertEq( !f32[5], false );
     assertEq( !f32[6], false );
 }
 test(setupNot, not);

 // MToInt32
 var str = "can haz cheezburger? okthxbye;";
 function setupToInt32() {
     f32[0] = 0;
     f32[1] = 1;
     f32[2] = 2;
     f32[3] = 4;
     f32[4] = 5;
 }
 function testToInt32() {
     assertEq(str[f32[0]], 'c');
     assertEq(str[f32[1]], 'a');
     assertEq(str[f32[2]], 'n');
     assertEq(str[f32[3]], 'h');
     assertEq(str[f32[4]], 'a');
 }
 test(setupToInt32, testToInt32);

 function setupBailoutToInt32() {
     f32[0] = .5;
 }
 function testBailoutToInt32() {
     assertEq(typeof str[f32[0]], 'undefined');
 }
 test(setupBailoutToInt32, testBailoutToInt32);

 // MMath (no trigo - see also testFloat32-trigo.js
 function assertNear(a, b) {
     var r = (a != a && b != b) || Math.abs(a-b) < 1e-1 || a === b;
     if (!r) {
         print('Precision error: ');
         print(new Error().stack);
         print('Got', a, ', expected near', b);
         assertEq(false, true);
     }
 }

 function setupOtherMath() {
     setupComp();
     f32[8] = 4.2;
 }
 function otherMath() {
     for (var i = 0; i < 9; ++i) {
         assertNear(Math.fround(Math.exp(f32[i])), Math.exp(f32[i]));
         assertNear(Math.fround(Math.log(f32[i])), Math.log(f32[i]));
     }
 };
 test(setupOtherMath, otherMath);

 function setupFloor() {
     f32[0] = -5.5;
     f32[1] = -0.5;
     f32[2] = 0;
     f32[3] = 1.5;
 }
 function setupFloorDouble() {
     f32[4] = NaN;
     f32[5] = -0;
     f32[6] = Infinity;
     f32[7] = -Infinity;
     f32[8] = Math.pow(2,31); // too big to fit into a int
 }
 function testFloor() {
     for (var i = 0; i < 4; ++i) {
         var f = Math.floor(f32[i]);
         assertFloat32(f, false); // f is an int32

         var g = Math.floor(-0 + f32[i]);
         assertFloat32(g, false);

         assertEq(f, g);
     }
 }
 function testFloorDouble() {
     for (var i = 4; i < 9; ++i) {
         var f = Math.fround(Math.floor(f32[i]));
         assertFloat32(f, true);

         var g = Math.floor(-0 + f32[i]);
         assertFloat32(g, false);

         assertEq(f, g);
     }
 }
 test(setupFloor, testFloor);
 test(setupFloorDouble, testFloorDouble);

 function setupRound() {
     f32[0] = -5.5;
     f32[1] = -0.6;
     f32[2] = 1.5;
     f32[3] = 1;
 }
 function setupRoundDouble() {
     f32[4] = NaN;
     f32[5] = -0.49;          // rounded to -0
     f32[6] = Infinity;
     f32[7] = -Infinity;
     f32[8] = Math.pow(2,31); // too big to fit into a int
     f32[9] = -0;
 }
 function testRound() {
     for (var i = 0; i < 4; ++i) {
         var r32 = Math.round(f32[i]);
         assertFloat32(r32, false); // r32 is an int32

         var r64 = Math.round(-0 + f32[i]);
         assertFloat32(r64, false);

         assertEq(r32, r64);
     }
 }
 function testRoundDouble() {
     for (var i = 4; i < 10; ++i) {
         var r32 = Math.fround(Math.round(f32[i]));
         assertFloat32(r32, true);

         var r64 = Math.round(-0 + f32[i]);
         assertFloat32(r64, false);

         assertEq(r32, r64);
     }
 }
 test(setupRound, testRound);
 test(setupRoundDouble, testRoundDouble);

 function setupCeil() {
     f32[0] = -5.5;
     f32[1] = -1.5;
     f32[2] = 0;
     f32[3] = 1.5;
 }
 function setupCeilDouble() {
     f32[4] = NaN;
     f32[5] = -0;
     f32[6] = Infinity;
     f32[7] = -Infinity;
     f32[8] = Math.pow(2,31); // too big to fit into a int
 }
 function testCeil() {
     for(var i = 0; i < 2; ++i) {
         var f = Math.ceil(f32[i]);
         assertFloat32(f, false);

         var g = Math.ceil(-0 + f32[i]);
         assertFloat32(g, false);

         assertEq(f, g);
     }
 }
 function testCeilDouble() {
     for(var i = 4; i < 9; ++i) {
         var f = Math.fround(Math.ceil(f32[i]));
         assertFloat32(f, true);

         var g = Math.ceil(-0 + f32[i]);
         assertFloat32(g, false);

         assertEq(f, g);
     }
 }
 test(setupCeil, testCeil);
 test(setupCeilDouble, testCeilDouble);
	setJitCompilerOption("ion.warmup.trigger", 50);

	var f32 = new Float32Array(10);

	function test(setup, f) {
	if (f === undefined) {
	f = setup;
	setup = function(){};
	}
	setup();
	for(var n = 200; n; --n) {
	f();
	}
	}

	// Basic arithmetic
	function setupBasicArith() {
	f32[0] = -Infinity;
	f32[1] = -1;
	f32[2] = -0;
	f32[3] = 0;
	f32[4] = 1.337;
	f32[5] = 42;
	f32[6] = Infinity;
	f32[7] = NaN;
	}
	function basicArith() {
	for (var i = 0; i < 7; ++i) {
	var opf = Math.fround(f32[i] + f32[i+1]);
	var opd = (1 / (1 / f32[i])) + f32[i+1];
	assertFloat32(opf, true);
	assertFloat32(opd, false);
	assertEq(opf, Math.fround(opd));

	opf = Math.fround(f32[i] - f32[i+1]);
	opd = (1 / (1 / f32[i])) - f32[i+1];
	assertFloat32(opf, true);
	assertFloat32(opd, false);
	assertEq(opf, Math.fround(opd));

	opf = Math.fround(f32[i] * f32[i+1]);
	opd = (1 / (1 / f32[i])) * f32[i+1];
	assertFloat32(opf, true);
	assertFloat32(opd, false);
	assertEq(opf, Math.fround(opd));

	opf = Math.fround(f32[i] / f32[i+1]);
	opd = (1 / (1 / f32[i])) / f32[i+1];
	assertFloat32(opf, true);
	assertFloat32(opd, false);
	assertEq(opf, Math.fround(opd));
	}
	}
	test(setupBasicArith, basicArith);

	// MAbs
	function setupAbs() {
	f32[0] = -0;
	f32[1] = 0;
	f32[2] = -3.14159;
	f32[3] = 3.14159;
	f32[4] = -Infinity;
	f32[5] = Infinity;
	f32[6] = NaN;
	}
	function abs() {
	for(var i = 0; i < 7; ++i) {
	assertEq( Math.fround(Math.abs(f32[i])), Math.abs(f32[i]) );
	}
	}
	test(setupAbs, abs);

	// MSqrt
	function setupSqrt() {
	f32[0] = 0;
	f32[1] = 1;
	f32[2] = 4;
	f32[3] = -1;
	f32[4] = Infinity;
	f32[5] = NaN;
	f32[6] = 13.37;
	}
	function sqrt() {
	for(var i = 0; i < 7; ++i) {
	var sqrtf = Math.fround(Math.sqrt(f32[i]));
	var sqrtd = 1 + Math.sqrt(f32[i]) - 1; // force no float32 by chaining arith ops
	assertEq( sqrtf, Math.fround(sqrtd) );
	}
	}
	test(setupSqrt, sqrt);

	// MMinMax
	function setupMinMax() {
	f32[0] = -0;
	f32[1] = 0;
	f32[2] = 1;
	f32[3] = 4;
	f32[4] = -1;
	f32[5] = Infinity;
	f32[6] = NaN;
	f32[7] = 13.37;
	f32[8] = -Infinity;
	f32[9] = Math.pow(2,31) - 1;
	}
	function minMax() {
	for(var i = 0; i < 9; ++i) {
	for(var j = 0; j < 9; j++) {
	var minf = Math.fround(Math.min(f32[i], f32[j]));
	var mind = 1 / (1 / Math.min(f32[i], f32[j])); // force no float32 by chaining arith ops
	assertFloat32(minf, true);
	assertFloat32(mind, false);
	assertEq( minf, Math.fround(mind) );

	var maxf = Math.fround(Math.max(f32[i], f32[j]));
	var maxd = 1 / (1 / Math.max(f32[i], f32[j])); // force no float32 by chaining arith ops
	assertFloat32(maxf, true);
	assertFloat32(maxd, false);
	assertEq( maxf, Math.fround(maxd) );
	}
	}
	}
	test(setupMinMax, minMax);

	// MTruncateToInt32
	// The only way to get a MTruncateToInt32 with a Float32 input is to use Math.imul
	function setupTruncateToInt32() {
	f32[0] = -1;
	f32[1] = 4;
	f32[2] = 5.13;
	}
	function truncateToInt32() {
	assertEq( Math.imul(f32[0], f32[1]), Math.imul(-1, 4) );
	assertEq( Math.imul(f32[1], f32[2]), Math.imul(4, 5) );
	}
	test(setupTruncateToInt32, truncateToInt32);

	// MCompare
	function comp() {
	for(var i = 0; i < 9; ++i) {
	assertEq( f32[i] < f32[i+1], true );
	}
	}
	function setupComp() {
	f32[0] = -Infinity;
	f32[1] = -1;
	f32[2] = -0.01;
	f32[3] = 0;
	f32[4] = 0.01;
	f32[5] = 1;
	f32[6] = 10;
	f32[7] = 13.37;
	f32[8] = 42;
	f32[9] = Infinity;
	}
	test(setupComp, comp);

	// MNot
	function setupNot() {
	f32[0] = -0;
	f32[1] = 0;
	f32[2] = 1;
	f32[3] = NaN;
	f32[4] = Infinity;
	f32[5] = 42;
	f32[5] = -23;
	}
	function not() {
	assertEq( !f32[0], true );
	assertEq( !f32[1], true );
	assertEq( !f32[2], false );
	assertEq( !f32[3], true );
	assertEq( !f32[4], false );
	assertEq( !f32[5], false );
	assertEq( !f32[6], false );
	}
	test(setupNot, not);

	// MToInt32
	var str = "can haz cheezburger? okthxbye;";
	function setupToInt32() {
	f32[0] = 0;
	f32[1] = 1;
	f32[2] = 2;
	f32[3] = 4;
	f32[4] = 5;
	}
	function testToInt32() {
	assertEq(str[f32[0]], 'c');
	assertEq(str[f32[1]], 'a');
	assertEq(str[f32[2]], 'n');
	assertEq(str[f32[3]], 'h');
	assertEq(str[f32[4]], 'a');
	}
	test(setupToInt32, testToInt32);

	function setupBailoutToInt32() {
	f32[0] = .5;
	}
	function testBailoutToInt32() {
	assertEq(typeof str[f32[0]], 'undefined');
	}
	test(setupBailoutToInt32, testBailoutToInt32);

	// MMath (no trigo - see also testFloat32-trigo.js
	function assertNear(a, b) {
	var r = (a != a && b != b) \|\| Math.abs(a-b) < 1e-1 \|\| a === b;
	if (!r) {
	print('Precision error: ');
	print(new Error().stack);
	print('Got', a, ', expected near', b);
	assertEq(false, true);
	}
	}

	function setupOtherMath() {
	setupComp();
	f32[8] = 4.2;
	}
	function otherMath() {
	for (var i = 0; i < 9; ++i) {
	assertNear(Math.fround(Math.exp(f32[i])), Math.exp(f32[i]));
	assertNear(Math.fround(Math.log(f32[i])), Math.log(f32[i]));
	}
	};
	test(setupOtherMath, otherMath);

	function setupFloor() {
	f32[0] = -5.5;
	f32[1] = -0.5;
	f32[2] = 0;
	f32[3] = 1.5;
	}
	function setupFloorDouble() {
	f32[4] = NaN;
	f32[5] = -0;
	f32[6] = Infinity;
	f32[7] = -Infinity;
	f32[8] = Math.pow(2,31); // too big to fit into a int
	}
	function testFloor() {
	for (var i = 0; i < 4; ++i) {
	var f = Math.floor(f32[i]);
	assertFloat32(f, false); // f is an int32

	var g = Math.floor(-0 + f32[i]);
	assertFloat32(g, false);

	assertEq(f, g);
	}
	}
	function testFloorDouble() {
	for (var i = 4; i < 9; ++i) {
	var f = Math.fround(Math.floor(f32[i]));
	assertFloat32(f, true);

	var g = Math.floor(-0 + f32[i]);
	assertFloat32(g, false);

	assertEq(f, g);
	}
	}
	test(setupFloor, testFloor);
	test(setupFloorDouble, testFloorDouble);

	function setupRound() {
	f32[0] = -5.5;
	f32[1] = -0.6;
	f32[2] = 1.5;
	f32[3] = 1;
	}
	function setupRoundDouble() {
	f32[4] = NaN;
	f32[5] = -0.49; // rounded to -0
	f32[6] = Infinity;
	f32[7] = -Infinity;
	f32[8] = Math.pow(2,31); // too big to fit into a int
	f32[9] = -0;
	}
	function testRound() {
	for (var i = 0; i < 4; ++i) {
	var r32 = Math.round(f32[i]);
	assertFloat32(r32, false); // r32 is an int32

	var r64 = Math.round(-0 + f32[i]);
	assertFloat32(r64, false);

	assertEq(r32, r64);
	}
	}
	function testRoundDouble() {
	for (var i = 4; i < 10; ++i) {
	var r32 = Math.fround(Math.round(f32[i]));
	assertFloat32(r32, true);

	var r64 = Math.round(-0 + f32[i]);
	assertFloat32(r64, false);

	assertEq(r32, r64);
	}
	}
	test(setupRound, testRound);
	test(setupRoundDouble, testRoundDouble);

	function setupCeil() {
	f32[0] = -5.5;
	f32[1] = -1.5;
	f32[2] = 0;
	f32[3] = 1.5;
	}
	function setupCeilDouble() {
	f32[4] = NaN;
	f32[5] = -0;
	f32[6] = Infinity;
	f32[7] = -Infinity;
	f32[8] = Math.pow(2,31); // too big to fit into a int
	}
	function testCeil() {
	for(var i = 0; i < 2; ++i) {
	var f = Math.ceil(f32[i]);
	assertFloat32(f, false);

	var g = Math.ceil(-0 + f32[i]);
	assertFloat32(g, false);

	assertEq(f, g);
	}
	}
	function testCeilDouble() {
	for(var i = 4; i < 9; ++i) {
	var f = Math.fround(Math.ceil(f32[i]));
	assertFloat32(f, true);

	var g = Math.ceil(-0 + f32[i]);
	assertFloat32(g, false);

	assertEq(f, g);
	}
	}
	test(setupCeil, testCeil);
	test(setupCeilDouble, testCeilDouble);