'use strict'; function factory (type, config, load, typed) { var latex = require('../../utils/latex'); var matrix = load(require('../../type/matrix/function/matrix')); var algorithm03 = load(require('../../type/matrix/utils/algorithm03')); var algorithm07 = load(require('../../type/matrix/utils/algorithm07')); var algorithm12 = load(require('../../type/matrix/utils/algorithm12')); var algorithm13 = load(require('../../type/matrix/utils/algorithm13')); var algorithm14 = load(require('../../type/matrix/utils/algorithm14')); /** * Logical `xor`. Test whether one and only one value is defined with a nonzero/nonempty value. * For matrices, the function is evaluated element wise. * * Syntax: * * math.xor(x, y) * * Examples: * * math.xor(2, 4); // returns false * * a = [2, 0, 0]; * b = [2, 7, 0]; * c = 0; * * math.xor(a, b); // returns [false, true, false] * math.xor(a, c); // returns [true, false, false] * * See also: * * and, not, or * * @param {number | BigNumber | Complex | Unit | Array | Matrix} x First value to check * @param {number | BigNumber | Complex | Unit | Array | Matrix} y Second value to check * @return {boolean | Array | Matrix} * Returns true when one and only one input is defined with a nonzero/nonempty value. */ var xor = typed('xor', { 'number, number': function (x, y) { return !!(!!x ^ !!y); }, 'Complex, Complex': function (x, y) { return !!((x.re !== 0 || x.im !== 0) ^ (y.re !== 0 || y.im !== 0)); }, 'BigNumber, BigNumber': function (x, y) { return !!((!x.isZero() && !x.isNaN()) ^ (!y.isZero() && !y.isNaN())); }, 'Unit, Unit': function (x, y) { return !!((x.value !== 0 && x.value !== null) ^ (y.value !== 0 && y.value !== null)); }, 'Matrix, Matrix': function (x, y) { // result var c; // process matrix storage switch (x.storage()) { case 'sparse': switch (y.storage()) { case 'sparse': // sparse + sparse c = algorithm07(x, y, xor); break; default: // sparse + dense c = algorithm03(y, x, xor, true); break; } break; default: switch (y.storage()) { case 'sparse': // dense + sparse c = algorithm03(x, y, xor, false); break; default: // dense + dense c = algorithm13(x, y, xor); break; } break; } return c; }, 'Array, Array': function (x, y) { // use matrix implementation return xor(matrix(x), matrix(y)).valueOf(); }, 'Array, Matrix': function (x, y) { // use matrix implementation return xor(matrix(x), y); }, 'Matrix, Array': function (x, y) { // use matrix implementation return xor(x, matrix(y)); }, 'Matrix, any': function (x, y) { // result var c; // check storage format switch (x.storage()) { case 'sparse': c = algorithm12(x, y, xor, false); break; default: c = algorithm14(x, y, xor, false); break; } return c; }, 'any, Matrix': function (x, y) { // result var c; // check storage format switch (y.storage()) { case 'sparse': c = algorithm12(y, x, xor, true); break; default: c = algorithm14(y, x, xor, true); break; } return c; }, 'Array, any': function (x, y) { // use matrix implementation return algorithm14(matrix(x), y, xor, false).valueOf(); }, 'any, Array': function (x, y) { // use matrix implementation return algorithm14(matrix(y), x, xor, true).valueOf(); } }); xor.toTex = '\\left(${args[0]}' + latex.operators['xor'] + '${args[1]}\\right)'; return xor; } exports.name = 'xor'; exports.factory = factory;