Here you can find the source of times()
Number.prototype.times = function () { var a = [];/*from w w w . j a v a2 s .c o m*/ var i = -1; while (++i < this) { a.push(i); } return a; };
Number.prototype.plus = function ( num ) { return this + num; }; Number.prototype.minus = function ( num ) { return this - num; }; Number.prototype.multiple = function ( num ) { return this * num; }; ...
Number.prototype.plus = function() { if ((arguments.length == 0) || (arguments.length > 1) || isNaN(arguments[0]))return; return Number(this.toString()) + Number(arguments[0].toString()); }; Number.prototype.minus = function() { if ((arguments.length == 0) || (arguments.length > 1) || isNaN(arguments[0]))return; return Number(this.toString()) - Number(arguments[0].toString()); }; console.log(2); ...
function calcfibonacciNumbers() { var i, nm = []; nm[0] = 0; for(i=1; i<10; i++) { if(i==1) { nm[i] = nm[i-1] + 1; console.log (nm[i]); } else { ...
Number.prototype.plus = function(num) { return this + num }; Number.prototype.minus = function(num) { return this - num }; Number.prototype.multi = function(num) { return this * num debug((5).plus(3).minus(6)) debug((5).multi((3).plus(2))) debug(6..multi(2..plus(2))) function add(x) { return function(y) { return function(z) { return x + y + z debug(add(2) + '\n\n') debug(add(2)(3) + '\n\n') debug(add(2)(3)(5) + '\n\n')
Number.prototype.times = function () { return _.times(this, function (i) { return i; }); };
Number.prototype.timesPlusOne = function () { return _.map(this.times(), function (i) { return i + 1; }); };
Number.prototype.timesRepeat = function(f){ for(var i=0; i<this; i++){ f();
var x = new Number(2); console.log(x); Number.prototype.timesTwo = function(x){ return x * 2; }; console.log(x.timesTwo(x)); console.log(Number.isNaN(x)); Number.isInteger = Number.isInteger || function(x){ return typeof x === "number" && ...
Number.prototype.clone = function(handler) { return new this.constructor(this); };