/** * @private */Ext.define('Ext.chart.Util', { singleton: true, /** * @private * Given a `range` array of two (min/max) numbers and an arbitrary array of numbers * (`data`), updates the given `range`, if the range of `data` exceeds it. * Typically, one would start with the `[NaN, NaN]` range array instance, call the * method on multiple datasets with that range instance, then validate it with * {@link #validateRange}. * @param {Number[]} range * @param {Number[]} data */ expandRange: function (range, data) { var length = data.length, min = range[0], max = range[1], i, value; for (i = 0; i < length; i++) { value = data[i]; // `null` is a "finite" number in JavaScript // and greater than any negative number. if (value == null || !isFinite(value)) { continue; } if (value < min || !isFinite(min)) { min = value; } if (value > max || !isFinite(max)) { max = value; } } range[0] = min; range[1] = max; }, defaultRange: [0, 1], /** * @private * Makes sure the range exists, is not zero, and its min/max values are finite numbers. * If this is not the case, the values from the provided `defaultRange` * are used. * * The range to validate. Never modified. * @param {Number[]} range * The default range to use, if the given range is not a valid data structure, * if both values are infinities, or if both values are the same and dangerously * close to either infinity (which makes expansion of the range by the value of * `padding` impossible). * If only a single value is infinity, the other value will be derived * from the finite value by incrementing/decrementing it by the span * of the default range towards the infinity. * For example, if the `defaultRange` is `[0, 1]`, we have: * * [5, Infinity] --> [5, 6] * [3, -Infinity] --> [2, 3] * [-Infinity, -5] --> [-6, -5] * [-3, -Infinity] --> [-4, -3] * * @param {Number[]} [defaultRange=[0, 1]] * A non-negative padding to use in case of identical min/max. * Note that the range span is not guaranteed to be `padding * 2` in this case, * if min/max are close to MIN_SAFE_INTEGER/MAX_SAFE_INTEGER. * @param {Number} [padding=0.5] * @return {Number[]} */ validateRange: function (range, defaultRange, padding) { defaultRange = defaultRange || this.defaultRange.slice(); if (!(padding === 0 || padding > 0)) { padding = 0.5 } if (!range || range.length !== 2) { return defaultRange; } range = [range[0], range[1]]; if (!range[0]) { range[0] = 0; } if (!range[1]) { range[1] = 0; } if (padding && range[0] === range[1]) { range = [ range[0] - padding, range[0] + padding ]; // In case the range values are at Infinity, the expansion above by the value // of 'padding' won't do us much good, so we still have to fall back to the // 'defaultRange'. if (range[0] === range[1]) { return defaultRange; } } // Same sign infinities are ruled out at this point. var isFin0 = isFinite(range[0]); var isFin1 = isFinite(range[1]); if (!isFin0 && !isFin1) { return defaultRange; } // Different sign infinities are ruled out at this point. if (isFin0 && !isFin1) { range[1] = range[0] + Ext.Number.sign(range[1]) * (defaultRange[1] - defaultRange[0]); } else if (isFin1 && !isFin0) { range[0] = range[1] + Ext.Number.sign(range[0]) * (defaultRange[1] - defaultRange[0]); } // All infinities are ruled out at this point. return [ Math.min(range[0], range[1]), Math.max(range[0], range[1]) ]; }, applyAnimation: function (animation, oldAnimation) { if (!animation) { animation = { duration: 0 }; } else if (animation === true) { animation = { easing: 'easeInOut', duration: 500 }; } return oldAnimation ? Ext.apply({}, animation, oldAnimation) : animation; } });