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/**
* Chartist path interpolation functions.
*
* @module Chartist.Interpolation
*/
/* global Chartist */
(function(window, document, Chartist) {
'use strict';
Chartist.Interpolation = {};
/**
* This interpolation function does not smooth the path and the result is only containing lines and no curves.
*
* @example
* var chart = new Chartist.Line('.ct-chart', {
* labels: [1, 2, 3, 4, 5],
* series: [[1, 2, 8, 1, 7]]
* }, {
* lineSmooth: Chartist.Interpolation.none({
* fillHoles: false
* })
* });
*
*
* @memberof Chartist.Interpolation
* @return {Function}
*/
Chartist.Interpolation.none = function(options) {
var defaultOptions = {
fillHoles: false
};
options = Chartist.extend({}, defaultOptions, options);
return function none(pathCoordinates, valueData) {
var path = new Chartist.Svg.Path();
var hole = true;
for(var i = 0; i < pathCoordinates.length; i += 2) {
var currX = pathCoordinates[i];
var currY = pathCoordinates[i + 1];
var currData = valueData[i / 2];
if(Chartist.getMultiValue(currData.value) !== undefined) {
if(hole) {
path.move(currX, currY, false, currData);
} else {
path.line(currX, currY, false, currData);
}
hole = false;
} else if(!options.fillHoles) {
hole = true;
}
}
return path;
};
};
/**
* Simple smoothing creates horizontal handles that are positioned with a fraction of the length between two data points. You can use the divisor option to specify the amount of smoothing.
*
* Simple smoothing can be used instead of `Chartist.Smoothing.cardinal` if you'd like to get rid of the artifacts it produces sometimes. Simple smoothing produces less flowing lines but is accurate by hitting the points and it also doesn't swing below or above the given data point.
*
* All smoothing functions within Chartist are factory functions that accept an options parameter. The simple interpolation function accepts one configuration parameter `divisor`, between 1 and ∞, which controls the smoothing characteristics.
*
* @example
* var chart = new Chartist.Line('.ct-chart', {
* labels: [1, 2, 3, 4, 5],
* series: [[1, 2, 8, 1, 7]]
* }, {
* lineSmooth: Chartist.Interpolation.simple({
* divisor: 2,
* fillHoles: false
* })
* });
*
*
* @memberof Chartist.Interpolation
* @param {Object} options The options of the simple interpolation factory function.
* @return {Function}
*/
Chartist.Interpolation.simple = function(options) {
var defaultOptions = {
divisor: 2,
fillHoles: false
};
options = Chartist.extend({}, defaultOptions, options);
var d = 1 / Math.max(1, options.divisor);
return function simple(pathCoordinates, valueData) {
var path = new Chartist.Svg.Path();
var prevX, prevY, prevData;
for(var i = 0; i < pathCoordinates.length; i += 2) {
var currX = pathCoordinates[i];
var currY = pathCoordinates[i + 1];
var length = (currX - prevX) * d;
var currData = valueData[i / 2];
if(currData.value !== undefined) {
if(prevData === undefined) {
path.move(currX, currY, false, currData);
} else {
path.curve(
prevX + length,
prevY,
currX - length,
currY,
currX,
currY,
false,
currData
);
}
prevX = currX;
prevY = currY;
prevData = currData;
} else if(!options.fillHoles) {
prevX = currX = prevData = undefined;
}
}
return path;
};
};
/**
* Cardinal / Catmull-Rome spline interpolation is the default smoothing function in Chartist. It produces nice results where the splines will always meet the points. It produces some artifacts though when data values are increased or decreased rapidly. The line may not follow a very accurate path and if the line should be accurate this smoothing function does not produce the best results.
*
* Cardinal splines can only be created if there are more than two data points. If this is not the case this smoothing will fallback to `Chartist.Smoothing.none`.
*
* All smoothing functions within Chartist are factory functions that accept an options parameter. The cardinal interpolation function accepts one configuration parameter `tension`, between 0 and 1, which controls the smoothing intensity.
*
* @example
* var chart = new Chartist.Line('.ct-chart', {
* labels: [1, 2, 3, 4, 5],
* series: [[1, 2, 8, 1, 7]]
* }, {
* lineSmooth: Chartist.Interpolation.cardinal({
* tension: 1,
* fillHoles: false
* })
* });
*
* @memberof Chartist.Interpolation
* @param {Object} options The options of the cardinal factory function.
* @return {Function}
*/
Chartist.Interpolation.cardinal = function(options) {
var defaultOptions = {
tension: 1,
fillHoles: false
};
options = Chartist.extend({}, defaultOptions, options);
var t = Math.min(1, Math.max(0, options.tension)),
c = 1 - t;
return function cardinal(pathCoordinates, valueData) {
// First we try to split the coordinates into segments
// This is necessary to treat "holes" in line charts
var segments = Chartist.splitIntoSegments(pathCoordinates, valueData, {
fillHoles: options.fillHoles
});
if(!segments.length) {
// If there were no segments return 'Chartist.Interpolation.none'
return Chartist.Interpolation.none()([]);
} else if(segments.length > 1) {
// If the split resulted in more that one segment we need to interpolate each segment individually and join them
// afterwards together into a single path.
var paths = [];
// For each segment we will recurse the cardinal function
segments.forEach(function(segment) {
paths.push(cardinal(segment.pathCoordinates, segment.valueData));
});
// Join the segment path data into a single path and return
return Chartist.Svg.Path.join(paths);
} else {
// If there was only one segment we can proceed regularly by using pathCoordinates and valueData from the first
// segment
pathCoordinates = segments[0].pathCoordinates;
valueData = segments[0].valueData;
// If less than two points we need to fallback to no smoothing
if(pathCoordinates.length <= 4) {
return Chartist.Interpolation.none()(pathCoordinates, valueData);
}
var path = new Chartist.Svg.Path().move(pathCoordinates[0], pathCoordinates[1], false, valueData[0]),
z;
for (var i = 0, iLen = pathCoordinates.length; iLen - 2 * !z > i; i += 2) {
var p = [
{x: +pathCoordinates[i - 2], y: +pathCoordinates[i - 1]},
{x: +pathCoordinates[i], y: +pathCoordinates[i + 1]},
{x: +pathCoordinates[i + 2], y: +pathCoordinates[i + 3]},
{x: +pathCoordinates[i + 4], y: +pathCoordinates[i + 5]}
];
if (z) {
if (!i) {
p[0] = {x: +pathCoordinates[iLen - 2], y: +pathCoordinates[iLen - 1]};
} else if (iLen - 4 === i) {
p[3] = {x: +pathCoordinates[0], y: +pathCoordinates[1]};
} else if (iLen - 2 === i) {
p[2] = {x: +pathCoordinates[0], y: +pathCoordinates[1]};
p[3] = {x: +pathCoordinates[2], y: +pathCoordinates[3]};
}
} else {
if (iLen - 4 === i) {
p[3] = p[2];
} else if (!i) {
p[0] = {x: +pathCoordinates[i], y: +pathCoordinates[i + 1]};
}
}
path.curve(
(t * (-p[0].x + 6 * p[1].x + p[2].x) / 6) + (c * p[2].x),
(t * (-p[0].y + 6 * p[1].y + p[2].y) / 6) + (c * p[2].y),
(t * (p[1].x + 6 * p[2].x - p[3].x) / 6) + (c * p[2].x),
(t * (p[1].y + 6 * p[2].y - p[3].y) / 6) + (c * p[2].y),
p[2].x,
p[2].y,
false,
valueData[(i + 2) / 2]
);
}
return path;
}
};
};
/**
* Monotone Cubic spline interpolation produces a smooth curve which preserves monotonicity. Unlike cardinal splines, the curve will not extend beyond the range of y-values of the original data points.
*
* Monotone Cubic splines can only be created if there are more than two data points. If this is not the case this smoothing will fallback to `Chartist.Smoothing.none`.
*
* The x-values of subsequent points must be increasing to fit a Monotone Cubic spline. If this condition is not met for a pair of adjacent points, then there will be a break in the curve between those data points.
*
* All smoothing functions within Chartist are factory functions that accept an options parameter.
*
* @example
* var chart = new Chartist.Line('.ct-chart', {
* labels: [1, 2, 3, 4, 5],
* series: [[1, 2, 8, 1, 7]]
* }, {
* lineSmooth: Chartist.Interpolation.monotoneCubic({
* fillHoles: false
* })
* });
*
* @memberof Chartist.Interpolation
* @param {Object} options The options of the monotoneCubic factory function.
* @return {Function}
*/
Chartist.Interpolation.monotoneCubic = function(options) {
var defaultOptions = {
fillHoles: false
};
options = Chartist.extend({}, defaultOptions, options);
return function monotoneCubic(pathCoordinates, valueData) {
// First we try to split the coordinates into segments
// This is necessary to treat "holes" in line charts
var segments = Chartist.splitIntoSegments(pathCoordinates, valueData, {
fillHoles: options.fillHoles,
increasingX: true
});
if(!segments.length) {
// If there were no segments return 'Chartist.Interpolation.none'
return Chartist.Interpolation.none()([]);
} else if(segments.length > 1) {
// If the split resulted in more that one segment we need to interpolate each segment individually and join them
// afterwards together into a single path.
var paths = [];
// For each segment we will recurse the monotoneCubic fn function
segments.forEach(function(segment) {
paths.push(monotoneCubic(segment.pathCoordinates, segment.valueData));
});
// Join the segment path data into a single path and return
return Chartist.Svg.Path.join(paths);
} else {
// If there was only one segment we can proceed regularly by using pathCoordinates and valueData from the first
// segment
pathCoordinates = segments[0].pathCoordinates;
valueData = segments[0].valueData;
// If less than three points we need to fallback to no smoothing
if(pathCoordinates.length <= 4) {
return Chartist.Interpolation.none()(pathCoordinates, valueData);
}
var xs = [],
ys = [],
i,
n = pathCoordinates.length / 2,
ms = [],
ds = [], dys = [], dxs = [],
path;
// Populate x and y coordinates into separate arrays, for readability
for(i = 0; i < n; i++) {
xs[i] = pathCoordinates[i * 2];
ys[i] = pathCoordinates[i * 2 + 1];
}
// Calculate deltas and derivative
for(i = 0; i < n - 1; i++) {
dys[i] = ys[i + 1] - ys[i];
dxs[i] = xs[i + 1] - xs[i];
ds[i] = dys[i] / dxs[i];
}
// Determine desired slope (m) at each point using Fritsch-Carlson method
// See: http://math.stackexchange.com/questions/45218/implementation-of-monotone-cubic-interpolation
ms[0] = ds[0];
ms[n - 1] = ds[n - 2];
for(i = 1; i < n - 1; i++) {
if(ds[i] === 0 || ds[i - 1] === 0 || (ds[i - 1] > 0) !== (ds[i] > 0)) {
ms[i] = 0;
} else {
ms[i] = 3 * (dxs[i - 1] + dxs[i]) / (
(2 * dxs[i] + dxs[i - 1]) / ds[i - 1] +
(dxs[i] + 2 * dxs[i - 1]) / ds[i]);
if(!isFinite(ms[i])) {
ms[i] = 0;
}
}
}
// Now build a path from the slopes
path = new Chartist.Svg.Path().move(xs[0], ys[0], false, valueData[0]);
for(i = 0; i < n - 1; i++) {
path.curve(
// First control point
xs[i] + dxs[i] / 3,
ys[i] + ms[i] * dxs[i] / 3,
// Second control point
xs[i + 1] - dxs[i] / 3,
ys[i + 1] - ms[i + 1] * dxs[i] / 3,
// End point
xs[i + 1],
ys[i + 1],
false,
valueData[i + 1]
);
}
return path;
}
};
};
/**
* Step interpolation will cause the line chart to move in steps rather than diagonal or smoothed lines. This interpolation will create additional points that will also be drawn when the `showPoint` option is enabled.
*
* All smoothing functions within Chartist are factory functions that accept an options parameter. The step interpolation function accepts one configuration parameter `postpone`, that can be `true` or `false`. The default value is `true` and will cause the step to occur where the value actually changes. If a different behaviour is needed where the step is shifted to the left and happens before the actual value, this option can be set to `false`.
*
* @example
* var chart = new Chartist.Line('.ct-chart', {
* labels: [1, 2, 3, 4, 5],
* series: [[1, 2, 8, 1, 7]]
* }, {
* lineSmooth: Chartist.Interpolation.step({
* postpone: true,
* fillHoles: false
* })
* });
*
* @memberof Chartist.Interpolation
* @param options
* @returns {Function}
*/
Chartist.Interpolation.step = function(options) {
var defaultOptions = {
postpone: true,
fillHoles: false
};
options = Chartist.extend({}, defaultOptions, options);
return function step(pathCoordinates, valueData) {
var path = new Chartist.Svg.Path();
var prevX, prevY, prevData;
for (var i = 0; i < pathCoordinates.length; i += 2) {
var currX = pathCoordinates[i];
var currY = pathCoordinates[i + 1];
var currData = valueData[i / 2];
// If the current point is also not a hole we can draw the step lines
if(currData.value !== undefined) {
if(prevData === undefined) {
path.move(currX, currY, false, currData);
} else {
if(options.postpone) {
// If postponed we should draw the step line with the value of the previous value
path.line(currX, prevY, false, prevData);
} else {
// If not postponed we should draw the step line with the value of the current value
path.line(prevX, currY, false, currData);
}
// Line to the actual point (this should only be a Y-Axis movement
path.line(currX, currY, false, currData);
}
prevX = currX;
prevY = currY;
prevData = currData;
} else if(!options.fillHoles) {
prevX = prevY = prevData = undefined;
}
}
return path;
};
};
}(window, document, Chartist));
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