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// Copyright 2009 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 fast div and mod.
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function divmod(div_func, mod_func, x, y) {
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var div_answer = (div_func)(x);
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assertEquals(x / y, div_answer, x + "/" + y);
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var mod_answer = (mod_func)(x);
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assertEquals(x % y, mod_answer, x + "%" + y);
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var minus_div_answer = (div_func)(-x);
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assertEquals(-x / y, minus_div_answer, "-" + x + "/" + y);
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var minus_mod_answer = (mod_func)(-x);
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assertEquals(-x % y, minus_mod_answer, "-" + x + "%" + y);
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}
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function run_tests_for(divisor) {
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print("(function(left) { return left / " + divisor + "; })");
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var div_func = this.eval("(function(left) { return left / " + divisor + "; })");
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var mod_func = this.eval("(function(left) { return left % " + divisor + "; })");
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var exp;
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// Strange number test.
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divmod(div_func, mod_func, 0, divisor);
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divmod(div_func, mod_func, 1 / 0, divisor);
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// Floating point number test.
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for (exp = -1024; exp <= 1024; exp += 8) {
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divmod(div_func, mod_func, Math.pow(2, exp), divisor);
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divmod(div_func, mod_func, 0.9999999 * Math.pow(2, exp), divisor);
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divmod(div_func, mod_func, 1.0000001 * Math.pow(2, exp), divisor);
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}
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// Integer number test.
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for (exp = 0; exp <= 32; exp++) {
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divmod(div_func, mod_func, 1 << exp, divisor);
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divmod(div_func, mod_func, (1 << exp) + 1, divisor);
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divmod(div_func, mod_func, (1 << exp) - 1, divisor);
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}
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divmod(div_func, mod_func, Math.floor(0x1fffffff / 3), divisor);
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divmod(div_func, mod_func, Math.floor(-0x20000000 / 3), divisor);
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}
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var divisors = [
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0,
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1,
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2,
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3,
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4,
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5,
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6,
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7,
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8,
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9,
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10,
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0x1000000,
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0x40000000,
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12,
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60,
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100,
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1000 * 60 * 60 * 24];
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for (var i = 0; i < divisors.length; i++) {
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run_tests_for(divisors[i]);
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}
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// Test extreme corner cases of modulo.
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// Computes the modulo by slow but lossless operations.
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function compute_mod(dividend, divisor) {
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// Return NaN if either operand is NaN, if divisor is 0 or
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// dividend is an infinity. Return dividend if divisor is an infinity.
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if (isNaN(dividend) || isNaN(divisor) || divisor == 0) { return NaN; }
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var sign = 1;
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if (dividend < 0) { dividend = -dividend; sign = -1; }
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if (dividend == Infinity) { return NaN; }
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if (divisor < 0) { divisor = -divisor; }
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if (divisor == Infinity) { return sign * dividend; }
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function rec_mod(a, b) {
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// Subtracts maximal possible multiplum of b from a.
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if (a >= b) {
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a = rec_mod(a, 2 * b);
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if (a >= b) { a -= b; }
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}
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return a;
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}
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return sign * rec_mod(dividend, divisor);
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}
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(function () {
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var large_non_smi = 1234567891234.12245;
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var small_non_smi = 43.2367243;
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var repeating_decimal = 0.3;
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var finite_decimal = 0.5;
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var smi = 43;
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var power_of_two = 64;
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var min_normal = Number.MIN_VALUE * Math.pow(2, 52);
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var max_denormal = Number.MIN_VALUE * (Math.pow(2, 52) - 1);
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// All combinations of NaN, Infinity, normal, denormal and zero.
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var example_numbers = [
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NaN,
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0,
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Number.MIN_VALUE,
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3 * Number.MIN_VALUE,
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max_denormal,
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min_normal,
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repeating_decimal,
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finite_decimal,
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smi,
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power_of_two,
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small_non_smi,
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large_non_smi,
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Number.MAX_VALUE,
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Infinity
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];
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function doTest(a, b) {
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var exp = compute_mod(a, b);
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var act = a % b;
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assertEquals(exp, act, a + " % " + b);
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}
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for (var i = 0; i < example_numbers.length; i++) {
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for (var j = 0; j < example_numbers.length; j++) {
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var a = example_numbers[i];
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var b = example_numbers[j];
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doTest(a,b);
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doTest(-a,b);
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doTest(a,-b);
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doTest(-a,-b);
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}
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}
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})();
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(function () {
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// Edge cases
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var zero = 0;
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var minsmi32 = -0x40000000;
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var minsmi64 = -0x80000000;
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var somenum = 3532;
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assertEquals(-0, zero / -1, "0 / -1");
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assertEquals(1, minsmi32 / -0x40000000, "minsmi/minsmi-32");
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assertEquals(1, minsmi64 / -0x80000000, "minsmi/minsmi-64");
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assertEquals(somenum, somenum % -0x40000000, "%minsmi-32");
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assertEquals(somenum, somenum % -0x80000000, "%minsmi-64");
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})();
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// Side-effect-free expressions containing bit operations use
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// an optimized compiler with int32 values. Ensure that modulus
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// produces negative zeros correctly.
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function negative_zero_modulus_test() {
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var x = 4;
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var y = -4;
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x = x + x - x;
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y = y + y - y;
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var z = (y | y | y | y) % x;
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assertEquals(-1 / 0, 1 / z);
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z = (x | x | x | x) % x;
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assertEquals(1 / 0, 1 / z);
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z = (y | y | y | y) % y;
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assertEquals(-1 / 0, 1 / z);
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z = (x | x | x | x) % y;
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assertEquals(1 / 0, 1 / z);
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}
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negative_zero_modulus_test();
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function lithium_integer_mod() {
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var left_operands = [
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0,
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305419896, // 0x12345678
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];
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// Test the standard lithium code for modulo opeartions.
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var mod_func;
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for (var i = 0; i < left_operands.length; i++) {
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for (var j = 0; j < divisors.length; j++) {
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mod_func = this.eval("(function(left) { return left % " + divisors[j]+ "; })");
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assertEquals((mod_func)(left_operands[i]), left_operands[i] % divisors[j]);
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assertEquals((mod_func)(-left_operands[i]), -left_operands[i] % divisors[j]);
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}
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}
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var results_powers_of_two = [
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// 0
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[0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0],
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// 305419896 == 0x12345678
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[0, 0, 0, 8, 24, 56, 120, 120, 120, 632, 1656, 1656, 5752, 5752, 22136, 22136, 22136, 22136, 284280, 284280, 1332856, 3430008, 3430008, 3430008, 3430008, 36984440, 36984440, 36984440, 305419896, 305419896, 305419896],
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];
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// Test the lithium code for modulo operations with a variable power of two
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// right hand side operand.
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for (var i = 0; i < left_operands.length; i++) {
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for (var j = 0; j < 31; j++) {
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assertEquals(results_powers_of_two[i][j], left_operands[i] % (2 << j));
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assertEquals(results_powers_of_two[i][j], left_operands[i] % -(2 << j));
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assertEquals(-results_powers_of_two[i][j], -left_operands[i] % (2 << j));
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assertEquals(-results_powers_of_two[i][j], -left_operands[i] % -(2 << j));
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}
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}
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// Test the lithium code for modulo operations with a constant power of two
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// right hand side operand.
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for (var i = 0; i < left_operands.length; i++) {
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// With positive left hand side operand.
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assertEquals(results_powers_of_two[i][0], left_operands[i] % -(2 << 0));
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assertEquals(results_powers_of_two[i][1], left_operands[i] % (2 << 1));
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assertEquals(results_powers_of_two[i][2], left_operands[i] % -(2 << 2));
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assertEquals(results_powers_of_two[i][3], left_operands[i] % (2 << 3));
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assertEquals(results_powers_of_two[i][4], left_operands[i] % -(2 << 4));
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assertEquals(results_powers_of_two[i][5], left_operands[i] % (2 << 5));
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assertEquals(results_powers_of_two[i][6], left_operands[i] % -(2 << 6));
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assertEquals(results_powers_of_two[i][7], left_operands[i] % (2 << 7));
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assertEquals(results_powers_of_two[i][8], left_operands[i] % -(2 << 8));
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assertEquals(results_powers_of_two[i][9], left_operands[i] % (2 << 9));
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assertEquals(results_powers_of_two[i][10], left_operands[i] % -(2 << 10));
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assertEquals(results_powers_of_two[i][11], left_operands[i] % (2 << 11));
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assertEquals(results_powers_of_two[i][12], left_operands[i] % -(2 << 12));
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assertEquals(results_powers_of_two[i][13], left_operands[i] % (2 << 13));
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assertEquals(results_powers_of_two[i][14], left_operands[i] % -(2 << 14));
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assertEquals(results_powers_of_two[i][15], left_operands[i] % (2 << 15));
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assertEquals(results_powers_of_two[i][16], left_operands[i] % -(2 << 16));
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assertEquals(results_powers_of_two[i][17], left_operands[i] % (2 << 17));
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assertEquals(results_powers_of_two[i][18], left_operands[i] % -(2 << 18));
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assertEquals(results_powers_of_two[i][19], left_operands[i] % (2 << 19));
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assertEquals(results_powers_of_two[i][20], left_operands[i] % -(2 << 20));
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assertEquals(results_powers_of_two[i][21], left_operands[i] % (2 << 21));
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assertEquals(results_powers_of_two[i][22], left_operands[i] % -(2 << 22));
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assertEquals(results_powers_of_two[i][23], left_operands[i] % (2 << 23));
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assertEquals(results_powers_of_two[i][24], left_operands[i] % -(2 << 24));
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assertEquals(results_powers_of_two[i][25], left_operands[i] % (2 << 25));
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assertEquals(results_powers_of_two[i][26], left_operands[i] % -(2 << 26));
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assertEquals(results_powers_of_two[i][27], left_operands[i] % (2 << 27));
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assertEquals(results_powers_of_two[i][28], left_operands[i] % -(2 << 28));
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assertEquals(results_powers_of_two[i][29], left_operands[i] % (2 << 29));
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assertEquals(results_powers_of_two[i][30], left_operands[i] % -(2 << 30));
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// With negative left hand side operand.
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assertEquals(-results_powers_of_two[i][0], -left_operands[i] % -(2 << 0));
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assertEquals(-results_powers_of_two[i][1], -left_operands[i] % (2 << 1));
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assertEquals(-results_powers_of_two[i][2], -left_operands[i] % -(2 << 2));
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assertEquals(-results_powers_of_two[i][3], -left_operands[i] % (2 << 3));
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assertEquals(-results_powers_of_two[i][4], -left_operands[i] % -(2 << 4));
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assertEquals(-results_powers_of_two[i][5], -left_operands[i] % (2 << 5));
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assertEquals(-results_powers_of_two[i][6], -left_operands[i] % -(2 << 6));
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assertEquals(-results_powers_of_two[i][7], -left_operands[i] % (2 << 7));
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assertEquals(-results_powers_of_two[i][8], -left_operands[i] % -(2 << 8));
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assertEquals(-results_powers_of_two[i][9], -left_operands[i] % (2 << 9));
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assertEquals(-results_powers_of_two[i][10], -left_operands[i] % -(2 << 10));
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assertEquals(-results_powers_of_two[i][11], -left_operands[i] % (2 << 11));
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assertEquals(-results_powers_of_two[i][12], -left_operands[i] % -(2 << 12));
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assertEquals(-results_powers_of_two[i][13], -left_operands[i] % (2 << 13));
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assertEquals(-results_powers_of_two[i][14], -left_operands[i] % -(2 << 14));
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assertEquals(-results_powers_of_two[i][15], -left_operands[i] % (2 << 15));
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assertEquals(-results_powers_of_two[i][16], -left_operands[i] % -(2 << 16));
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assertEquals(-results_powers_of_two[i][17], -left_operands[i] % (2 << 17));
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assertEquals(-results_powers_of_two[i][18], -left_operands[i] % -(2 << 18));
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assertEquals(-results_powers_of_two[i][19], -left_operands[i] % (2 << 19));
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assertEquals(-results_powers_of_two[i][20], -left_operands[i] % -(2 << 20));
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assertEquals(-results_powers_of_two[i][21], -left_operands[i] % (2 << 21));
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assertEquals(-results_powers_of_two[i][22], -left_operands[i] % -(2 << 22));
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assertEquals(-results_powers_of_two[i][23], -left_operands[i] % (2 << 23));
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assertEquals(-results_powers_of_two[i][24], -left_operands[i] % -(2 << 24));
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assertEquals(-results_powers_of_two[i][25], -left_operands[i] % (2 << 25));
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assertEquals(-results_powers_of_two[i][26], -left_operands[i] % -(2 << 26));
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assertEquals(-results_powers_of_two[i][27], -left_operands[i] % (2 << 27));
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assertEquals(-results_powers_of_two[i][28], -left_operands[i] % -(2 << 28));
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assertEquals(-results_powers_of_two[i][29], -left_operands[i] % (2 << 29));
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assertEquals(-results_powers_of_two[i][30], -left_operands[i] % -(2 << 30));
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}
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|
|
|
|
|
|
|
}
|
|
|
|
|
|
|
|
lithium_integer_mod();
|
|
|
|
%OptimizeFunctionOnNextCall(lithium_integer_mod)
|
|
|
|
lithium_integer_mod();
|