/*! * Chart.js v4.4.4 * https://www.chartjs.org * (c) 2024 Chart.js Contributors * Released under the MIT License */ 'use strict'; var color$1 = require('@kurkle/color'); /** * @namespace Chart.helpers */ /** * An empty function that can be used, for example, for optional callback. */ function noop() { /* noop */ } /** * Returns a unique id, sequentially generated from a global variable. */ const uid = (()=>{ let id = 0; return ()=>id++; })(); /** * Returns true if `value` is neither null nor undefined, else returns false. * @param value - The value to test. * @since 2.7.0 */ function isNullOrUndef(value) { return value === null || typeof value === 'undefined'; } /** * Returns true if `value` is an array (including typed arrays), else returns false. * @param value - The value to test. * @function */ function isArray(value) { if (Array.isArray && Array.isArray(value)) { return true; } const type = Object.prototype.toString.call(value); if (type.slice(0, 7) === '[object' && type.slice(-6) === 'Array]') { return true; } return false; } /** * Returns true if `value` is an object (excluding null), else returns false. * @param value - The value to test. * @since 2.7.0 */ function isObject(value) { return value !== null && Object.prototype.toString.call(value) === '[object Object]'; } /** * Returns true if `value` is a finite number, else returns false * @param value - The value to test. */ function isNumberFinite(value) { return (typeof value === 'number' || value instanceof Number) && isFinite(+value); } /** * Returns `value` if finite, else returns `defaultValue`. * @param value - The value to return if defined. * @param defaultValue - The value to return if `value` is not finite. */ function finiteOrDefault(value, defaultValue) { return isNumberFinite(value) ? value : defaultValue; } /** * Returns `value` if defined, else returns `defaultValue`. * @param value - The value to return if defined. * @param defaultValue - The value to return if `value` is undefined. */ function valueOrDefault(value, defaultValue) { return typeof value === 'undefined' ? defaultValue : value; } const toPercentage = (value, dimension)=>typeof value === 'string' && value.endsWith('%') ? parseFloat(value) / 100 : +value / dimension; const toDimension = (value, dimension)=>typeof value === 'string' && value.endsWith('%') ? parseFloat(value) / 100 * dimension : +value; /** * Calls `fn` with the given `args` in the scope defined by `thisArg` and returns the * value returned by `fn`. If `fn` is not a function, this method returns undefined. * @param fn - The function to call. * @param args - The arguments with which `fn` should be called. * @param [thisArg] - The value of `this` provided for the call to `fn`. */ function callback(fn, args, thisArg) { if (fn && typeof fn.call === 'function') { return fn.apply(thisArg, args); } } function each(loopable, fn, thisArg, reverse) { let i, len, keys; if (isArray(loopable)) { len = loopable.length; if (reverse) { for(i = len - 1; i >= 0; i--){ fn.call(thisArg, loopable[i], i); } } else { for(i = 0; i < len; i++){ fn.call(thisArg, loopable[i], i); } } } else if (isObject(loopable)) { keys = Object.keys(loopable); len = keys.length; for(i = 0; i < len; i++){ fn.call(thisArg, loopable[keys[i]], keys[i]); } } } /** * Returns true if the `a0` and `a1` arrays have the same content, else returns false. * @param a0 - The array to compare * @param a1 - The array to compare * @private */ function _elementsEqual(a0, a1) { let i, ilen, v0, v1; if (!a0 || !a1 || a0.length !== a1.length) { return false; } for(i = 0, ilen = a0.length; i < ilen; ++i){ v0 = a0[i]; v1 = a1[i]; if (v0.datasetIndex !== v1.datasetIndex || v0.index !== v1.index) { return false; } } return true; } /** * Returns a deep copy of `source` without keeping references on objects and arrays. * @param source - The value to clone. */ function clone(source) { if (isArray(source)) { return source.map(clone); } if (isObject(source)) { const target = Object.create(null); const keys = Object.keys(source); const klen = keys.length; let k = 0; for(; k < klen; ++k){ target[keys[k]] = clone(source[keys[k]]); } return target; } return source; } function isValidKey(key) { return [ '__proto__', 'prototype', 'constructor' ].indexOf(key) === -1; } /** * The default merger when Chart.helpers.merge is called without merger option. * Note(SB): also used by mergeConfig and mergeScaleConfig as fallback. * @private */ function _merger(key, target, source, options) { if (!isValidKey(key)) { return; } const tval = target[key]; const sval = source[key]; if (isObject(tval) && isObject(sval)) { // eslint-disable-next-line @typescript-eslint/no-use-before-define merge(tval, sval, options); } else { target[key] = clone(sval); } } function merge(target, source, options) { const sources = isArray(source) ? source : [ source ]; const ilen = sources.length; if (!isObject(target)) { return target; } options = options || {}; const merger = options.merger || _merger; let current; for(let i = 0; i < ilen; ++i){ current = sources[i]; if (!isObject(current)) { continue; } const keys = Object.keys(current); for(let k = 0, klen = keys.length; k < klen; ++k){ merger(keys[k], target, current, options); } } return target; } function mergeIf(target, source) { // eslint-disable-next-line @typescript-eslint/no-use-before-define return merge(target, source, { merger: _mergerIf }); } /** * Merges source[key] in target[key] only if target[key] is undefined. * @private */ function _mergerIf(key, target, source) { if (!isValidKey(key)) { return; } const tval = target[key]; const sval = source[key]; if (isObject(tval) && isObject(sval)) { mergeIf(tval, sval); } else if (!Object.prototype.hasOwnProperty.call(target, key)) { target[key] = clone(sval); } } /** * @private */ function _deprecated(scope, value, previous, current) { if (value !== undefined) { console.warn(scope + ': "' + previous + '" is deprecated. Please use "' + current + '" instead'); } } // resolveObjectKey resolver cache const keyResolvers = { // Chart.helpers.core resolveObjectKey should resolve empty key to root object '': (v)=>v, // default resolvers x: (o)=>o.x, y: (o)=>o.y }; /** * @private */ function _splitKey(key) { const parts = key.split('.'); const keys = []; let tmp = ''; for (const part of parts){ tmp += part; if (tmp.endsWith('\\')) { tmp = tmp.slice(0, -1) + '.'; } else { keys.push(tmp); tmp = ''; } } return keys; } function _getKeyResolver(key) { const keys = _splitKey(key); return (obj)=>{ for (const k of keys){ if (k === '') { break; } obj = obj && obj[k]; } return obj; }; } function resolveObjectKey(obj, key) { const resolver = keyResolvers[key] || (keyResolvers[key] = _getKeyResolver(key)); return resolver(obj); } /** * @private */ function _capitalize(str) { return str.charAt(0).toUpperCase() + str.slice(1); } const defined = (value)=>typeof value !== 'undefined'; const isFunction = (value)=>typeof value === 'function'; // Adapted from https://stackoverflow.com/questions/31128855/comparing-ecma6-sets-for-equality#31129384 const setsEqual = (a, b)=>{ if (a.size !== b.size) { return false; } for (const item of a){ if (!b.has(item)) { return false; } } return true; }; /** * @param e - The event * @private */ function _isClickEvent(e) { return e.type === 'mouseup' || e.type === 'click' || e.type === 'contextmenu'; } /** * @alias Chart.helpers.math * @namespace */ const PI = Math.PI; const TAU = 2 * PI; const PITAU = TAU + PI; const INFINITY = Number.POSITIVE_INFINITY; const RAD_PER_DEG = PI / 180; const HALF_PI = PI / 2; const QUARTER_PI = PI / 4; const TWO_THIRDS_PI = PI * 2 / 3; const log10 = Math.log10; const sign = Math.sign; function almostEquals(x, y, epsilon) { return Math.abs(x - y) < epsilon; } /** * Implementation of the nice number algorithm used in determining where axis labels will go */ function niceNum(range) { const roundedRange = Math.round(range); range = almostEquals(range, roundedRange, range / 1000) ? roundedRange : range; const niceRange = Math.pow(10, Math.floor(log10(range))); const fraction = range / niceRange; const niceFraction = fraction <= 1 ? 1 : fraction <= 2 ? 2 : fraction <= 5 ? 5 : 10; return niceFraction * niceRange; } /** * Returns an array of factors sorted from 1 to sqrt(value) * @private */ function _factorize(value) { const result = []; const sqrt = Math.sqrt(value); let i; for(i = 1; i < sqrt; i++){ if (value % i === 0) { result.push(i); result.push(value / i); } } if (sqrt === (sqrt | 0)) { result.push(sqrt); } result.sort((a, b)=>a - b).pop(); return result; } function isNumber(n) { return !isNaN(parseFloat(n)) && isFinite(n); } function almostWhole(x, epsilon) { const rounded = Math.round(x); return rounded - epsilon <= x && rounded + epsilon >= x; } /** * @private */ function _setMinAndMaxByKey(array, target, property) { let i, ilen, value; for(i = 0, ilen = array.length; i < ilen; i++){ value = array[i][property]; if (!isNaN(value)) { target.min = Math.min(target.min, value); target.max = Math.max(target.max, value); } } } function toRadians(degrees) { return degrees * (PI / 180); } function toDegrees(radians) { return radians * (180 / PI); } /** * Returns the number of decimal places * i.e. the number of digits after the decimal point, of the value of this Number. * @param x - A number. * @returns The number of decimal places. * @private */ function _decimalPlaces(x) { if (!isNumberFinite(x)) { return; } let e = 1; let p = 0; while(Math.round(x * e) / e !== x){ e *= 10; p++; } return p; } // Gets the angle from vertical upright to the point about a centre. function getAngleFromPoint(centrePoint, anglePoint) { const distanceFromXCenter = anglePoint.x - centrePoint.x; const distanceFromYCenter = anglePoint.y - centrePoint.y; const radialDistanceFromCenter = Math.sqrt(distanceFromXCenter * distanceFromXCenter + distanceFromYCenter * distanceFromYCenter); let angle = Math.atan2(distanceFromYCenter, distanceFromXCenter); if (angle < -0.5 * PI) { angle += TAU; // make sure the returned angle is in the range of (-PI/2, 3PI/2] } return { angle, distance: radialDistanceFromCenter }; } function distanceBetweenPoints(pt1, pt2) { return Math.sqrt(Math.pow(pt2.x - pt1.x, 2) + Math.pow(pt2.y - pt1.y, 2)); } /** * Shortest distance between angles, in either direction. * @private */ function _angleDiff(a, b) { return (a - b + PITAU) % TAU - PI; } /** * Normalize angle to be between 0 and 2*PI * @private */ function _normalizeAngle(a) { return (a % TAU + TAU) % TAU; } /** * @private */ function _angleBetween(angle, start, end, sameAngleIsFullCircle) { const a = _normalizeAngle(angle); const s = _normalizeAngle(start); const e = _normalizeAngle(end); const angleToStart = _normalizeAngle(s - a); const angleToEnd = _normalizeAngle(e - a); const startToAngle = _normalizeAngle(a - s); const endToAngle = _normalizeAngle(a - e); return a === s || a === e || sameAngleIsFullCircle && s === e || angleToStart > angleToEnd && startToAngle < endToAngle; } /** * Limit `value` between `min` and `max` * @param value * @param min * @param max * @private */ function _limitValue(value, min, max) { return Math.max(min, Math.min(max, value)); } /** * @param {number} value * @private */ function _int16Range(value) { return _limitValue(value, -32768, 32767); } /** * @param value * @param start * @param end * @param [epsilon] * @private */ function _isBetween(value, start, end, epsilon = 1e-6) { return value >= Math.min(start, end) - epsilon && value <= Math.max(start, end) + epsilon; } function _lookup(table, value, cmp) { cmp = cmp || ((index)=>table[index] < value); let hi = table.length - 1; let lo = 0; let mid; while(hi - lo > 1){ mid = lo + hi >> 1; if (cmp(mid)) { lo = mid; } else { hi = mid; } } return { lo, hi }; } /** * Binary search * @param table - the table search. must be sorted! * @param key - property name for the value in each entry * @param value - value to find * @param last - lookup last index * @private */ const _lookupByKey = (table, key, value, last)=>_lookup(table, value, last ? (index)=>{ const ti = table[index][key]; return ti < value || ti === value && table[index + 1][key] === value; } : (index)=>table[index][key] < value); /** * Reverse binary search * @param table - the table search. must be sorted! * @param key - property name for the value in each entry * @param value - value to find * @private */ const _rlookupByKey = (table, key, value)=>_lookup(table, value, (index)=>table[index][key] >= value); /** * Return subset of `values` between `min` and `max` inclusive. * Values are assumed to be in sorted order. * @param values - sorted array of values * @param min - min value * @param max - max value */ function _filterBetween(values, min, max) { let start = 0; let end = values.length; while(start < end && values[start] < min){ start++; } while(end > start && values[end - 1] > max){ end--; } return start > 0 || end < values.length ? values.slice(start, end) : values; } const arrayEvents = [ 'push', 'pop', 'shift', 'splice', 'unshift' ]; function listenArrayEvents(array, listener) { if (array._chartjs) { array._chartjs.listeners.push(listener); return; } Object.defineProperty(array, '_chartjs', { configurable: true, enumerable: false, value: { listeners: [ listener ] } }); arrayEvents.forEach((key)=>{ const method = '_onData' + _capitalize(key); const base = array[key]; Object.defineProperty(array, key, { configurable: true, enumerable: false, value (...args) { const res = base.apply(this, args); array._chartjs.listeners.forEach((object)=>{ if (typeof object[method] === 'function') { object[method](...args); } }); return res; } }); }); } function unlistenArrayEvents(array, listener) { const stub = array._chartjs; if (!stub) { return; } const listeners = stub.listeners; const index = listeners.indexOf(listener); if (index !== -1) { listeners.splice(index, 1); } if (listeners.length > 0) { return; } arrayEvents.forEach((key)=>{ delete array[key]; }); delete array._chartjs; } /** * @param items */ function _arrayUnique(items) { const set = new Set(items); if (set.size === items.length) { return items; } return Array.from(set); } function fontString(pixelSize, fontStyle, fontFamily) { return fontStyle + ' ' + pixelSize + 'px ' + fontFamily; } /** * Request animation polyfill */ const requestAnimFrame = function() { if (typeof window === 'undefined') { return function(callback) { return callback(); }; } return window.requestAnimationFrame; }(); /** * Throttles calling `fn` once per animation frame * Latest arguments are used on the actual call */ function throttled(fn, thisArg) { let argsToUse = []; let ticking = false; return function(...args) { // Save the args for use later argsToUse = args; if (!ticking) { ticking = true; requestAnimFrame.call(window, ()=>{ ticking = false; fn.apply(thisArg, argsToUse); }); } }; } /** * Debounces calling `fn` for `delay` ms */ function debounce(fn, delay) { let timeout; return function(...args) { if (delay) { clearTimeout(timeout); timeout = setTimeout(fn, delay, args); } else { fn.apply(this, args); } return delay; }; } /** * Converts 'start' to 'left', 'end' to 'right' and others to 'center' * @private */ const _toLeftRightCenter = (align)=>align === 'start' ? 'left' : align === 'end' ? 'right' : 'center'; /** * Returns `start`, `end` or `(start + end) / 2` depending on `align`. Defaults to `center` * @private */ const _alignStartEnd = (align, start, end)=>align === 'start' ? start : align === 'end' ? end : (start + end) / 2; /** * Returns `left`, `right` or `(left + right) / 2` depending on `align`. Defaults to `left` * @private */ const _textX = (align, left, right, rtl)=>{ const check = rtl ? 'left' : 'right'; return align === check ? right : align === 'center' ? (left + right) / 2 : left; }; /** * Return start and count of visible points. * @private */ function _getStartAndCountOfVisiblePoints(meta, points, animationsDisabled) { const pointCount = points.length; let start = 0; let count = pointCount; if (meta._sorted) { const { iScale , _parsed } = meta; const axis = iScale.axis; const { min , max , minDefined , maxDefined } = iScale.getUserBounds(); if (minDefined) { start = _limitValue(Math.min(// @ts-expect-error Need to type _parsed _lookupByKey(_parsed, axis, min).lo, // @ts-expect-error Need to fix types on _lookupByKey animationsDisabled ? pointCount : _lookupByKey(points, axis, iScale.getPixelForValue(min)).lo), 0, pointCount - 1); } if (maxDefined) { count = _limitValue(Math.max(// @ts-expect-error Need to type _parsed _lookupByKey(_parsed, iScale.axis, max, true).hi + 1, // @ts-expect-error Need to fix types on _lookupByKey animationsDisabled ? 0 : _lookupByKey(points, axis, iScale.getPixelForValue(max), true).hi + 1), start, pointCount) - start; } else { count = pointCount - start; } } return { start, count }; } /** * Checks if the scale ranges have changed. * @param {object} meta - dataset meta. * @returns {boolean} * @private */ function _scaleRangesChanged(meta) { const { xScale , yScale , _scaleRanges } = meta; const newRanges = { xmin: xScale.min, xmax: xScale.max, ymin: yScale.min, ymax: yScale.max }; if (!_scaleRanges) { meta._scaleRanges = newRanges; return true; } const changed = _scaleRanges.xmin !== xScale.min || _scaleRanges.xmax !== xScale.max || _scaleRanges.ymin !== yScale.min || _scaleRanges.ymax !== yScale.max; Object.assign(_scaleRanges, newRanges); return changed; } const atEdge = (t)=>t === 0 || t === 1; const elasticIn = (t, s, p)=>-(Math.pow(2, 10 * (t -= 1)) * Math.sin((t - s) * TAU / p)); const elasticOut = (t, s, p)=>Math.pow(2, -10 * t) * Math.sin((t - s) * TAU / p) + 1; /** * Easing functions adapted from Robert Penner's easing equations. * @namespace Chart.helpers.easing.effects * @see http://www.robertpenner.com/easing/ */ const effects = { linear: (t)=>t, easeInQuad: (t)=>t * t, easeOutQuad: (t)=>-t * (t - 2), easeInOutQuad: (t)=>(t /= 0.5) < 1 ? 0.5 * t * t : -0.5 * (--t * (t - 2) - 1), easeInCubic: (t)=>t * t * t, easeOutCubic: (t)=>(t -= 1) * t * t + 1, easeInOutCubic: (t)=>(t /= 0.5) < 1 ? 0.5 * t * t * t : 0.5 * ((t -= 2) * t * t + 2), easeInQuart: (t)=>t * t * t * t, easeOutQuart: (t)=>-((t -= 1) * t * t * t - 1), easeInOutQuart: (t)=>(t /= 0.5) < 1 ? 0.5 * t * t * t * t : -0.5 * ((t -= 2) * t * t * t - 2), easeInQuint: (t)=>t * t * t * t * t, easeOutQuint: (t)=>(t -= 1) * t * t * t * t + 1, easeInOutQuint: (t)=>(t /= 0.5) < 1 ? 0.5 * t * t * t * t * t : 0.5 * ((t -= 2) * t * t * t * t + 2), easeInSine: (t)=>-Math.cos(t * HALF_PI) + 1, easeOutSine: (t)=>Math.sin(t * HALF_PI), easeInOutSine: (t)=>-0.5 * (Math.cos(PI * t) - 1), easeInExpo: (t)=>t === 0 ? 0 : Math.pow(2, 10 * (t - 1)), easeOutExpo: (t)=>t === 1 ? 1 : -Math.pow(2, -10 * t) + 1, easeInOutExpo: (t)=>atEdge(t) ? t : t < 0.5 ? 0.5 * Math.pow(2, 10 * (t * 2 - 1)) : 0.5 * (-Math.pow(2, -10 * (t * 2 - 1)) + 2), easeInCirc: (t)=>t >= 1 ? t : -(Math.sqrt(1 - t * t) - 1), easeOutCirc: (t)=>Math.sqrt(1 - (t -= 1) * t), easeInOutCirc: (t)=>(t /= 0.5) < 1 ? -0.5 * (Math.sqrt(1 - t * t) - 1) : 0.5 * (Math.sqrt(1 - (t -= 2) * t) + 1), easeInElastic: (t)=>atEdge(t) ? t : elasticIn(t, 0.075, 0.3), easeOutElastic: (t)=>atEdge(t) ? t : elasticOut(t, 0.075, 0.3), easeInOutElastic (t) { const s = 0.1125; const p = 0.45; return atEdge(t) ? t : t < 0.5 ? 0.5 * elasticIn(t * 2, s, p) : 0.5 + 0.5 * elasticOut(t * 2 - 1, s, p); }, easeInBack (t) { const s = 1.70158; return t * t * ((s + 1) * t - s); }, easeOutBack (t) { const s = 1.70158; return (t -= 1) * t * ((s + 1) * t + s) + 1; }, easeInOutBack (t) { let s = 1.70158; if ((t /= 0.5) < 1) { return 0.5 * (t * t * (((s *= 1.525) + 1) * t - s)); } return 0.5 * ((t -= 2) * t * (((s *= 1.525) + 1) * t + s) + 2); }, easeInBounce: (t)=>1 - effects.easeOutBounce(1 - t), easeOutBounce (t) { const m = 7.5625; const d = 2.75; if (t < 1 / d) { return m * t * t; } if (t < 2 / d) { return m * (t -= 1.5 / d) * t + 0.75; } if (t < 2.5 / d) { return m * (t -= 2.25 / d) * t + 0.9375; } return m * (t -= 2.625 / d) * t + 0.984375; }, easeInOutBounce: (t)=>t < 0.5 ? effects.easeInBounce(t * 2) * 0.5 : effects.easeOutBounce(t * 2 - 1) * 0.5 + 0.5 }; function isPatternOrGradient(value) { if (value && typeof value === 'object') { const type = value.toString(); return type === '[object CanvasPattern]' || type === '[object CanvasGradient]'; } return false; } function color(value) { return isPatternOrGradient(value) ? value : new color$1.Color(value); } function getHoverColor(value) { return isPatternOrGradient(value) ? value : new color$1.Color(value).saturate(0.5).darken(0.1).hexString(); } const numbers = [ 'x', 'y', 'borderWidth', 'radius', 'tension' ]; const colors = [ 'color', 'borderColor', 'backgroundColor' ]; function applyAnimationsDefaults(defaults) { defaults.set('animation', { delay: undefined, duration: 1000, easing: 'easeOutQuart', fn: undefined, from: undefined, loop: undefined, to: undefined, type: undefined }); defaults.describe('animation', { _fallback: false, _indexable: false, _scriptable: (name)=>name !== 'onProgress' && name !== 'onComplete' && name !== 'fn' }); defaults.set('animations', { colors: { type: 'color', properties: colors }, numbers: { type: 'number', properties: numbers } }); defaults.describe('animations', { _fallback: 'animation' }); defaults.set('transitions', { active: { animation: { duration: 400 } }, resize: { animation: { duration: 0 } }, show: { animations: { colors: { from: 'transparent' }, visible: { type: 'boolean', duration: 0 } } }, hide: { animations: { colors: { to: 'transparent' }, visible: { type: 'boolean', easing: 'linear', fn: (v)=>v | 0 } } } }); } function applyLayoutsDefaults(defaults) { defaults.set('layout', { autoPadding: true, padding: { top: 0, right: 0, bottom: 0, left: 0 } }); } const intlCache = new Map(); function getNumberFormat(locale, options) { options = options || {}; const cacheKey = locale + JSON.stringify(options); let formatter = intlCache.get(cacheKey); if (!formatter) { formatter = new Intl.NumberFormat(locale, options); intlCache.set(cacheKey, formatter); } return formatter; } function formatNumber(num, locale, options) { return getNumberFormat(locale, options).format(num); } const formatters = { values (value) { return isArray(value) ? value : '' + value; }, numeric (tickValue, index, ticks) { if (tickValue === 0) { return '0'; } const locale = this.chart.options.locale; let notation; let delta = tickValue; if (ticks.length > 1) { const maxTick = Math.max(Math.abs(ticks[0].value), Math.abs(ticks[ticks.length - 1].value)); if (maxTick < 1e-4 || maxTick > 1e+15) { notation = 'scientific'; } delta = calculateDelta(tickValue, ticks); } const logDelta = log10(Math.abs(delta)); const numDecimal = isNaN(logDelta) ? 1 : Math.max(Math.min(-1 * Math.floor(logDelta), 20), 0); const options = { notation, minimumFractionDigits: numDecimal, maximumFractionDigits: numDecimal }; Object.assign(options, this.options.ticks.format); return formatNumber(tickValue, locale, options); }, logarithmic (tickValue, index, ticks) { if (tickValue === 0) { return '0'; } const remain = ticks[index].significand || tickValue / Math.pow(10, Math.floor(log10(tickValue))); if ([ 1, 2, 3, 5, 10, 15 ].includes(remain) || index > 0.8 * ticks.length) { return formatters.numeric.call(this, tickValue, index, ticks); } return ''; } }; function calculateDelta(tickValue, ticks) { let delta = ticks.length > 3 ? ticks[2].value - ticks[1].value : ticks[1].value - ticks[0].value; if (Math.abs(delta) >= 1 && tickValue !== Math.floor(tickValue)) { delta = tickValue - Math.floor(tickValue); } return delta; } var Ticks = { formatters }; function applyScaleDefaults(defaults) { defaults.set('scale', { display: true, offset: false, reverse: false, beginAtZero: false, bounds: 'ticks', clip: true, grace: 0, grid: { display: true, lineWidth: 1, drawOnChartArea: true, drawTicks: true, tickLength: 8, tickWidth: (_ctx, options)=>options.lineWidth, tickColor: (_ctx, options)=>options.color, offset: false }, border: { display: true, dash: [], dashOffset: 0.0, width: 1 }, title: { display: false, text: '', padding: { top: 4, bottom: 4 } }, ticks: { minRotation: 0, maxRotation: 50, mirror: false, textStrokeWidth: 0, textStrokeColor: '', padding: 3, display: true, autoSkip: true, autoSkipPadding: 3, labelOffset: 0, callback: Ticks.formatters.values, minor: {}, major: {}, align: 'center', crossAlign: 'near', showLabelBackdrop: false, backdropColor: 'rgba(255, 255, 255, 0.75)', backdropPadding: 2 } }); defaults.route('scale.ticks', 'color', '', 'color'); defaults.route('scale.grid', 'color', '', 'borderColor'); defaults.route('scale.border', 'color', '', 'borderColor'); defaults.route('scale.title', 'color', '', 'color'); defaults.describe('scale', { _fallback: false, _scriptable: (name)=>!name.startsWith('before') && !name.startsWith('after') && name !== 'callback' && name !== 'parser', _indexable: (name)=>name !== 'borderDash' && name !== 'tickBorderDash' && name !== 'dash' }); defaults.describe('scales', { _fallback: 'scale' }); defaults.describe('scale.ticks', { _scriptable: (name)=>name !== 'backdropPadding' && name !== 'callback', _indexable: (name)=>name !== 'backdropPadding' }); } const overrides = Object.create(null); const descriptors = Object.create(null); function getScope$1(node, key) { if (!key) { return node; } const keys = key.split('.'); for(let i = 0, n = keys.length; i < n; ++i){ const k = keys[i]; node = node[k] || (node[k] = Object.create(null)); } return node; } function set(root, scope, values) { if (typeof scope === 'string') { return merge(getScope$1(root, scope), values); } return merge(getScope$1(root, ''), scope); } class Defaults { constructor(_descriptors, _appliers){ this.animation = undefined; this.backgroundColor = 'rgba(0,0,0,0.1)'; this.borderColor = 'rgba(0,0,0,0.1)'; this.color = '#666'; this.datasets = {}; this.devicePixelRatio = (context)=>context.chart.platform.getDevicePixelRatio(); this.elements = {}; this.events = [ 'mousemove', 'mouseout', 'click', 'touchstart', 'touchmove' ]; this.font = { family: "'Helvetica Neue', 'Helvetica', 'Arial', sans-serif", size: 12, style: 'normal', lineHeight: 1.2, weight: null }; this.hover = {}; this.hoverBackgroundColor = (ctx, options)=>getHoverColor(options.backgroundColor); this.hoverBorderColor = (ctx, options)=>getHoverColor(options.borderColor); this.hoverColor = (ctx, options)=>getHoverColor(options.color); this.indexAxis = 'x'; this.interaction = { mode: 'nearest', intersect: true, includeInvisible: false }; this.maintainAspectRatio = true; this.onHover = null; this.onClick = null; this.parsing = true; this.plugins = {}; this.responsive = true; this.scale = undefined; this.scales = {}; this.showLine = true; this.drawActiveElementsOnTop = true; this.describe(_descriptors); this.apply(_appliers); } set(scope, values) { return set(this, scope, values); } get(scope) { return getScope$1(this, scope); } describe(scope, values) { return set(descriptors, scope, values); } override(scope, values) { return set(overrides, scope, values); } route(scope, name, targetScope, targetName) { const scopeObject = getScope$1(this, scope); const targetScopeObject = getScope$1(this, targetScope); const privateName = '_' + name; Object.defineProperties(scopeObject, { [privateName]: { value: scopeObject[name], writable: true }, [name]: { enumerable: true, get () { const local = this[privateName]; const target = targetScopeObject[targetName]; if (isObject(local)) { return Object.assign({}, target, local); } return valueOrDefault(local, target); }, set (value) { this[privateName] = value; } } }); } apply(appliers) { appliers.forEach((apply)=>apply(this)); } } var defaults = /* #__PURE__ */ new Defaults({ _scriptable: (name)=>!name.startsWith('on'), _indexable: (name)=>name !== 'events', hover: { _fallback: 'interaction' }, interaction: { _scriptable: false, _indexable: false } }, [ applyAnimationsDefaults, applyLayoutsDefaults, applyScaleDefaults ]); /** * Converts the given font object into a CSS font string. * @param font - A font object. * @return The CSS font string. See https://developer.mozilla.org/en-US/docs/Web/CSS/font * @private */ function toFontString(font) { if (!font || isNullOrUndef(font.size) || isNullOrUndef(font.family)) { return null; } return (font.style ? font.style + ' ' : '') + (font.weight ? font.weight + ' ' : '') + font.size + 'px ' + font.family; } /** * @private */ function _measureText(ctx, data, gc, longest, string) { let textWidth = data[string]; if (!textWidth) { textWidth = data[string] = ctx.measureText(string).width; gc.push(string); } if (textWidth > longest) { longest = textWidth; } return longest; } /** * @private */ // eslint-disable-next-line complexity function _longestText(ctx, font, arrayOfThings, cache) { cache = cache || {}; let data = cache.data = cache.data || {}; let gc = cache.garbageCollect = cache.garbageCollect || []; if (cache.font !== font) { data = cache.data = {}; gc = cache.garbageCollect = []; cache.font = font; } ctx.save(); ctx.font = font; let longest = 0; const ilen = arrayOfThings.length; let i, j, jlen, thing, nestedThing; for(i = 0; i < ilen; i++){ thing = arrayOfThings[i]; // Undefined strings and arrays should not be measured if (thing !== undefined && thing !== null && !isArray(thing)) { longest = _measureText(ctx, data, gc, longest, thing); } else if (isArray(thing)) { // if it is an array lets measure each element // to do maybe simplify this function a bit so we can do this more recursively? for(j = 0, jlen = thing.length; j < jlen; j++){ nestedThing = thing[j]; // Undefined strings and arrays should not be measured if (nestedThing !== undefined && nestedThing !== null && !isArray(nestedThing)) { longest = _measureText(ctx, data, gc, longest, nestedThing); } } } } ctx.restore(); const gcLen = gc.length / 2; if (gcLen > arrayOfThings.length) { for(i = 0; i < gcLen; i++){ delete data[gc[i]]; } gc.splice(0, gcLen); } return longest; } /** * Returns the aligned pixel value to avoid anti-aliasing blur * @param chart - The chart instance. * @param pixel - A pixel value. * @param width - The width of the element. * @returns The aligned pixel value. * @private */ function _alignPixel(chart, pixel, width) { const devicePixelRatio = chart.currentDevicePixelRatio; const halfWidth = width !== 0 ? Math.max(width / 2, 0.5) : 0; return Math.round((pixel - halfWidth) * devicePixelRatio) / devicePixelRatio + halfWidth; } /** * Clears the entire canvas. */ function clearCanvas(canvas, ctx) { if (!ctx && !canvas) { return; } ctx = ctx || canvas.getContext('2d'); ctx.save(); // canvas.width and canvas.height do not consider the canvas transform, // while clearRect does ctx.resetTransform(); ctx.clearRect(0, 0, canvas.width, canvas.height); ctx.restore(); } function drawPoint(ctx, options, x, y) { // eslint-disable-next-line @typescript-eslint/no-use-before-define drawPointLegend(ctx, options, x, y, null); } // eslint-disable-next-line complexity function drawPointLegend(ctx, options, x, y, w) { let type, xOffset, yOffset, size, cornerRadius, width, xOffsetW, yOffsetW; const style = options.pointStyle; const rotation = options.rotation; const radius = options.radius; let rad = (rotation || 0) * RAD_PER_DEG; if (style && typeof style === 'object') { type = style.toString(); if (type === '[object HTMLImageElement]' || type === '[object HTMLCanvasElement]') { ctx.save(); ctx.translate(x, y); ctx.rotate(rad); ctx.drawImage(style, -style.width / 2, -style.height / 2, style.width, style.height); ctx.restore(); return; } } if (isNaN(radius) || radius <= 0) { return; } ctx.beginPath(); switch(style){ // Default includes circle default: if (w) { ctx.ellipse(x, y, w / 2, radius, 0, 0, TAU); } else { ctx.arc(x, y, radius, 0, TAU); } ctx.closePath(); break; case 'triangle': width = w ? w / 2 : radius; ctx.moveTo(x + Math.sin(rad) * width, y - Math.cos(rad) * radius); rad += TWO_THIRDS_PI; ctx.lineTo(x + Math.sin(rad) * width, y - Math.cos(rad) * radius); rad += TWO_THIRDS_PI; ctx.lineTo(x + Math.sin(rad) * width, y - Math.cos(rad) * radius); ctx.closePath(); break; case 'rectRounded': // NOTE: the rounded rect implementation changed to use `arc` instead of // `quadraticCurveTo` since it generates better results when rect is // almost a circle. 0.516 (instead of 0.5) produces results with visually // closer proportion to the previous impl and it is inscribed in the // circle with `radius`. For more details, see the following PRs: // https://github.com/chartjs/Chart.js/issues/5597 // https://github.com/chartjs/Chart.js/issues/5858 cornerRadius = radius * 0.516; size = radius - cornerRadius; xOffset = Math.cos(rad + QUARTER_PI) * size; xOffsetW = Math.cos(rad + QUARTER_PI) * (w ? w / 2 - cornerRadius : size); yOffset = Math.sin(rad + QUARTER_PI) * size; yOffsetW = Math.sin(rad + QUARTER_PI) * (w ? w / 2 - cornerRadius : size); ctx.arc(x - xOffsetW, y - yOffset, cornerRadius, rad - PI, rad - HALF_PI); ctx.arc(x + yOffsetW, y - xOffset, cornerRadius, rad - HALF_PI, rad); ctx.arc(x + xOffsetW, y + yOffset, cornerRadius, rad, rad + HALF_PI); ctx.arc(x - yOffsetW, y + xOffset, cornerRadius, rad + HALF_PI, rad + PI); ctx.closePath(); break; case 'rect': if (!rotation) { size = Math.SQRT1_2 * radius; width = w ? w / 2 : size; ctx.rect(x - width, y - size, 2 * width, 2 * size); break; } rad += QUARTER_PI; /* falls through */ case 'rectRot': xOffsetW = Math.cos(rad) * (w ? w / 2 : radius); xOffset = Math.cos(rad) * radius; yOffset = Math.sin(rad) * radius; yOffsetW = Math.sin(rad) * (w ? w / 2 : radius); ctx.moveTo(x - xOffsetW, y - yOffset); ctx.lineTo(x + yOffsetW, y - xOffset); ctx.lineTo(x + xOffsetW, y + yOffset); ctx.lineTo(x - yOffsetW, y + xOffset); ctx.closePath(); break; case 'crossRot': rad += QUARTER_PI; /* falls through */ case 'cross': xOffsetW = Math.cos(rad) * (w ? w / 2 : radius); xOffset = Math.cos(rad) * radius; yOffset = Math.sin(rad) * radius; yOffsetW = Math.sin(rad) * (w ? w / 2 : radius); ctx.moveTo(x - xOffsetW, y - yOffset); ctx.lineTo(x + xOffsetW, y + yOffset); ctx.moveTo(x + yOffsetW, y - xOffset); ctx.lineTo(x - yOffsetW, y + xOffset); break; case 'star': xOffsetW = Math.cos(rad) * (w ? w / 2 : radius); xOffset = Math.cos(rad) * radius; yOffset = Math.sin(rad) * radius; yOffsetW = Math.sin(rad) * (w ? w / 2 : radius); ctx.moveTo(x - xOffsetW, y - yOffset); ctx.lineTo(x + xOffsetW, y + yOffset); ctx.moveTo(x + yOffsetW, y - xOffset); ctx.lineTo(x - yOffsetW, y + xOffset); rad += QUARTER_PI; xOffsetW = Math.cos(rad) * (w ? w / 2 : radius); xOffset = Math.cos(rad) * radius; yOffset = Math.sin(rad) * radius; yOffsetW = Math.sin(rad) * (w ? w / 2 : radius); ctx.moveTo(x - xOffsetW, y - yOffset); ctx.lineTo(x + xOffsetW, y + yOffset); ctx.moveTo(x + yOffsetW, y - xOffset); ctx.lineTo(x - yOffsetW, y + xOffset); break; case 'line': xOffset = w ? w / 2 : Math.cos(rad) * radius; yOffset = Math.sin(rad) * radius; ctx.moveTo(x - xOffset, y - yOffset); ctx.lineTo(x + xOffset, y + yOffset); break; case 'dash': ctx.moveTo(x, y); ctx.lineTo(x + Math.cos(rad) * (w ? w / 2 : radius), y + Math.sin(rad) * radius); break; case false: ctx.closePath(); break; } ctx.fill(); if (options.borderWidth > 0) { ctx.stroke(); } } /** * Returns true if the point is inside the rectangle * @param point - The point to test * @param area - The rectangle * @param margin - allowed margin * @private */ function _isPointInArea(point, area, margin) { margin = margin || 0.5; // margin - default is to match rounded decimals return !area || point && point.x > area.left - margin && point.x < area.right + margin && point.y > area.top - margin && point.y < area.bottom + margin; } function clipArea(ctx, area) { ctx.save(); ctx.beginPath(); ctx.rect(area.left, area.top, area.right - area.left, area.bottom - area.top); ctx.clip(); } function unclipArea(ctx) { ctx.restore(); } /** * @private */ function _steppedLineTo(ctx, previous, target, flip, mode) { if (!previous) { return ctx.lineTo(target.x, target.y); } if (mode === 'middle') { const midpoint = (previous.x + target.x) / 2.0; ctx.lineTo(midpoint, previous.y); ctx.lineTo(midpoint, target.y); } else if (mode === 'after' !== !!flip) { ctx.lineTo(previous.x, target.y); } else { ctx.lineTo(target.x, previous.y); } ctx.lineTo(target.x, target.y); } /** * @private */ function _bezierCurveTo(ctx, previous, target, flip) { if (!previous) { return ctx.lineTo(target.x, target.y); } ctx.bezierCurveTo(flip ? previous.cp1x : previous.cp2x, flip ? previous.cp1y : previous.cp2y, flip ? target.cp2x : target.cp1x, flip ? target.cp2y : target.cp1y, target.x, target.y); } function setRenderOpts(ctx, opts) { if (opts.translation) { ctx.translate(opts.translation[0], opts.translation[1]); } if (!isNullOrUndef(opts.rotation)) { ctx.rotate(opts.rotation); } if (opts.color) { ctx.fillStyle = opts.color; } if (opts.textAlign) { ctx.textAlign = opts.textAlign; } if (opts.textBaseline) { ctx.textBaseline = opts.textBaseline; } } function decorateText(ctx, x, y, line, opts) { if (opts.strikethrough || opts.underline) { /** * Now that IE11 support has been dropped, we can use more * of the TextMetrics object. The actual bounding boxes * are unflagged in Chrome, Firefox, Edge, and Safari so they * can be safely used. * See https://developer.mozilla.org/en-US/docs/Web/API/TextMetrics#Browser_compatibility */ const metrics = ctx.measureText(line); const left = x - metrics.actualBoundingBoxLeft; const right = x + metrics.actualBoundingBoxRight; const top = y - metrics.actualBoundingBoxAscent; const bottom = y + metrics.actualBoundingBoxDescent; const yDecoration = opts.strikethrough ? (top + bottom) / 2 : bottom; ctx.strokeStyle = ctx.fillStyle; ctx.beginPath(); ctx.lineWidth = opts.decorationWidth || 2; ctx.moveTo(left, yDecoration); ctx.lineTo(right, yDecoration); ctx.stroke(); } } function drawBackdrop(ctx, opts) { const oldColor = ctx.fillStyle; ctx.fillStyle = opts.color; ctx.fillRect(opts.left, opts.top, opts.width, opts.height); ctx.fillStyle = oldColor; } /** * Render text onto the canvas */ function renderText(ctx, text, x, y, font, opts = {}) { const lines = isArray(text) ? text : [ text ]; const stroke = opts.strokeWidth > 0 && opts.strokeColor !== ''; let i, line; ctx.save(); ctx.font = font.string; setRenderOpts(ctx, opts); for(i = 0; i < lines.length; ++i){ line = lines[i]; if (opts.backdrop) { drawBackdrop(ctx, opts.backdrop); } if (stroke) { if (opts.strokeColor) { ctx.strokeStyle = opts.strokeColor; } if (!isNullOrUndef(opts.strokeWidth)) { ctx.lineWidth = opts.strokeWidth; } ctx.strokeText(line, x, y, opts.maxWidth); } ctx.fillText(line, x, y, opts.maxWidth); decorateText(ctx, x, y, line, opts); y += Number(font.lineHeight); } ctx.restore(); } /** * Add a path of a rectangle with rounded corners to the current sub-path * @param ctx - Context * @param rect - Bounding rect */ function addRoundedRectPath(ctx, rect) { const { x , y , w , h , radius } = rect; // top left arc ctx.arc(x + radius.topLeft, y + radius.topLeft, radius.topLeft, 1.5 * PI, PI, true); // line from top left to bottom left ctx.lineTo(x, y + h - radius.bottomLeft); // bottom left arc ctx.arc(x + radius.bottomLeft, y + h - radius.bottomLeft, radius.bottomLeft, PI, HALF_PI, true); // line from bottom left to bottom right ctx.lineTo(x + w - radius.bottomRight, y + h); // bottom right arc ctx.arc(x + w - radius.bottomRight, y + h - radius.bottomRight, radius.bottomRight, HALF_PI, 0, true); // line from bottom right to top right ctx.lineTo(x + w, y + radius.topRight); // top right arc ctx.arc(x + w - radius.topRight, y + radius.topRight, radius.topRight, 0, -HALF_PI, true); // line from top right to top left ctx.lineTo(x + radius.topLeft, y); } const LINE_HEIGHT = /^(normal|(\d+(?:\.\d+)?)(px|em|%)?)$/; const FONT_STYLE = /^(normal|italic|initial|inherit|unset|(oblique( -?[0-9]?[0-9]deg)?))$/; /** * @alias Chart.helpers.options * @namespace */ /** * Converts the given line height `value` in pixels for a specific font `size`. * @param value - The lineHeight to parse (eg. 1.6, '14px', '75%', '1.6em'). * @param size - The font size (in pixels) used to resolve relative `value`. * @returns The effective line height in pixels (size * 1.2 if value is invalid). * @see https://developer.mozilla.org/en-US/docs/Web/CSS/line-height * @since 2.7.0 */ function toLineHeight(value, size) { const matches = ('' + value).match(LINE_HEIGHT); if (!matches || matches[1] === 'normal') { return size * 1.2; } value = +matches[2]; switch(matches[3]){ case 'px': return value; case '%': value /= 100; break; } return size * value; } const numberOrZero = (v)=>+v || 0; function _readValueToProps(value, props) { const ret = {}; const objProps = isObject(props); const keys = objProps ? Object.keys(props) : props; const read = isObject(value) ? objProps ? (prop)=>valueOrDefault(value[prop], value[props[prop]]) : (prop)=>value[prop] : ()=>value; for (const prop of keys){ ret[prop] = numberOrZero(read(prop)); } return ret; } /** * Converts the given value into a TRBL object. * @param value - If a number, set the value to all TRBL component, * else, if an object, use defined properties and sets undefined ones to 0. * x / y are shorthands for same value for left/right and top/bottom. * @returns The padding values (top, right, bottom, left) * @since 3.0.0 */ function toTRBL(value) { return _readValueToProps(value, { top: 'y', right: 'x', bottom: 'y', left: 'x' }); } /** * Converts the given value into a TRBL corners object (similar with css border-radius). * @param value - If a number, set the value to all TRBL corner components, * else, if an object, use defined properties and sets undefined ones to 0. * @returns The TRBL corner values (topLeft, topRight, bottomLeft, bottomRight) * @since 3.0.0 */ function toTRBLCorners(value) { return _readValueToProps(value, [ 'topLeft', 'topRight', 'bottomLeft', 'bottomRight' ]); } /** * Converts the given value into a padding object with pre-computed width/height. * @param value - If a number, set the value to all TRBL component, * else, if an object, use defined properties and sets undefined ones to 0. * x / y are shorthands for same value for left/right and top/bottom. * @returns The padding values (top, right, bottom, left, width, height) * @since 2.7.0 */ function toPadding(value) { const obj = toTRBL(value); obj.width = obj.left + obj.right; obj.height = obj.top + obj.bottom; return obj; } /** * Parses font options and returns the font object. * @param options - A object that contains font options to be parsed. * @param fallback - A object that contains fallback font options. * @return The font object. * @private */ function toFont(options, fallback) { options = options || {}; fallback = fallback || defaults.font; let size = valueOrDefault(options.size, fallback.size); if (typeof size === 'string') { size = parseInt(size, 10); } let style = valueOrDefault(options.style, fallback.style); if (style && !('' + style).match(FONT_STYLE)) { console.warn('Invalid font style specified: "' + style + '"'); style = undefined; } const font = { family: valueOrDefault(options.family, fallback.family), lineHeight: toLineHeight(valueOrDefault(options.lineHeight, fallback.lineHeight), size), size, style, weight: valueOrDefault(options.weight, fallback.weight), string: '' }; font.string = toFontString(font); return font; } /** * Evaluates the given `inputs` sequentially and returns the first defined value. * @param inputs - An array of values, falling back to the last value. * @param context - If defined and the current value is a function, the value * is called with `context` as first argument and the result becomes the new input. * @param index - If defined and the current value is an array, the value * at `index` become the new input. * @param info - object to return information about resolution in * @param info.cacheable - Will be set to `false` if option is not cacheable. * @since 2.7.0 */ function resolve(inputs, context, index, info) { let cacheable = true; let i, ilen, value; for(i = 0, ilen = inputs.length; i < ilen; ++i){ value = inputs[i]; if (value === undefined) { continue; } if (context !== undefined && typeof value === 'function') { value = value(context); cacheable = false; } if (index !== undefined && isArray(value)) { value = value[index % value.length]; cacheable = false; } if (value !== undefined) { if (info && !cacheable) { info.cacheable = false; } return value; } } } /** * @param minmax * @param grace * @param beginAtZero * @private */ function _addGrace(minmax, grace, beginAtZero) { const { min , max } = minmax; const change = toDimension(grace, (max - min) / 2); const keepZero = (value, add)=>beginAtZero && value === 0 ? 0 : value + add; return { min: keepZero(min, -Math.abs(change)), max: keepZero(max, change) }; } function createContext(parentContext, context) { return Object.assign(Object.create(parentContext), context); } /** * Creates a Proxy for resolving raw values for options. * @param scopes - The option scopes to look for values, in resolution order * @param prefixes - The prefixes for values, in resolution order. * @param rootScopes - The root option scopes * @param fallback - Parent scopes fallback * @param getTarget - callback for getting the target for changed values * @returns Proxy * @private */ function _createResolver(scopes, prefixes = [ '' ], rootScopes, fallback, getTarget = ()=>scopes[0]) { const finalRootScopes = rootScopes || scopes; if (typeof fallback === 'undefined') { fallback = _resolve('_fallback', scopes); } const cache = { [Symbol.toStringTag]: 'Object', _cacheable: true, _scopes: scopes, _rootScopes: finalRootScopes, _fallback: fallback, _getTarget: getTarget, override: (scope)=>_createResolver([ scope, ...scopes ], prefixes, finalRootScopes, fallback) }; return new Proxy(cache, { /** * A trap for the delete operator. */ deleteProperty (target, prop) { delete target[prop]; // remove from cache delete target._keys; // remove cached keys delete scopes[0][prop]; // remove from top level scope return true; }, /** * A trap for getting property values. */ get (target, prop) { return _cached(target, prop, ()=>_resolveWithPrefixes(prop, prefixes, scopes, target)); }, /** * A trap for Object.getOwnPropertyDescriptor. * Also used by Object.hasOwnProperty. */ getOwnPropertyDescriptor (target, prop) { return Reflect.getOwnPropertyDescriptor(target._scopes[0], prop); }, /** * A trap for Object.getPrototypeOf. */ getPrototypeOf () { return Reflect.getPrototypeOf(scopes[0]); }, /** * A trap for the in operator. */ has (target, prop) { return getKeysFromAllScopes(target).includes(prop); }, /** * A trap for Object.getOwnPropertyNames and Object.getOwnPropertySymbols. */ ownKeys (target) { return getKeysFromAllScopes(target); }, /** * A trap for setting property values. */ set (target, prop, value) { const storage = target._storage || (target._storage = getTarget()); target[prop] = storage[prop] = value; // set to top level scope + cache delete target._keys; // remove cached keys return true; } }); } /** * Returns an Proxy for resolving option values with context. * @param proxy - The Proxy returned by `_createResolver` * @param context - Context object for scriptable/indexable options * @param subProxy - The proxy provided for scriptable options * @param descriptorDefaults - Defaults for descriptors * @private */ function _attachContext(proxy, context, subProxy, descriptorDefaults) { const cache = { _cacheable: false, _proxy: proxy, _context: context, _subProxy: subProxy, _stack: new Set(), _descriptors: _descriptors(proxy, descriptorDefaults), setContext: (ctx)=>_attachContext(proxy, ctx, subProxy, descriptorDefaults), override: (scope)=>_attachContext(proxy.override(scope), context, subProxy, descriptorDefaults) }; return new Proxy(cache, { /** * A trap for the delete operator. */ deleteProperty (target, prop) { delete target[prop]; // remove from cache delete proxy[prop]; // remove from proxy return true; }, /** * A trap for getting property values. */ get (target, prop, receiver) { return _cached(target, prop, ()=>_resolveWithContext(target, prop, receiver)); }, /** * A trap for Object.getOwnPropertyDescriptor. * Also used by Object.hasOwnProperty. */ getOwnPropertyDescriptor (target, prop) { return target._descriptors.allKeys ? Reflect.has(proxy, prop) ? { enumerable: true, configurable: true } : undefined : Reflect.getOwnPropertyDescriptor(proxy, prop); }, /** * A trap for Object.getPrototypeOf. */ getPrototypeOf () { return Reflect.getPrototypeOf(proxy); }, /** * A trap for the in operator. */ has (target, prop) { return Reflect.has(proxy, prop); }, /** * A trap for Object.getOwnPropertyNames and Object.getOwnPropertySymbols. */ ownKeys () { return Reflect.ownKeys(proxy); }, /** * A trap for setting property values. */ set (target, prop, value) { proxy[prop] = value; // set to proxy delete target[prop]; // remove from cache return true; } }); } /** * @private */ function _descriptors(proxy, defaults = { scriptable: true, indexable: true }) { const { _scriptable =defaults.scriptable , _indexable =defaults.indexable , _allKeys =defaults.allKeys } = proxy; return { allKeys: _allKeys, scriptable: _scriptable, indexable: _indexable, isScriptable: isFunction(_scriptable) ? _scriptable : ()=>_scriptable, isIndexable: isFunction(_indexable) ? _indexable : ()=>_indexable }; } const readKey = (prefix, name)=>prefix ? prefix + _capitalize(name) : name; const needsSubResolver = (prop, value)=>isObject(value) && prop !== 'adapters' && (Object.getPrototypeOf(value) === null || value.constructor === Object); function _cached(target, prop, resolve) { if (Object.prototype.hasOwnProperty.call(target, prop) || prop === 'constructor') { return target[prop]; } const value = resolve(); // cache the resolved value target[prop] = value; return value; } function _resolveWithContext(target, prop, receiver) { const { _proxy , _context , _subProxy , _descriptors: descriptors } = target; let value = _proxy[prop]; // resolve from proxy // resolve with context if (isFunction(value) && descriptors.isScriptable(prop)) { value = _resolveScriptable(prop, value, target, receiver); } if (isArray(value) && value.length) { value = _resolveArray(prop, value, target, descriptors.isIndexable); } if (needsSubResolver(prop, value)) { // if the resolved value is an object, create a sub resolver for it value = _attachContext(value, _context, _subProxy && _subProxy[prop], descriptors); } return value; } function _resolveScriptable(prop, getValue, target, receiver) { const { _proxy , _context , _subProxy , _stack } = target; if (_stack.has(prop)) { throw new Error('Recursion detected: ' + Array.from(_stack).join('->') + '->' + prop); } _stack.add(prop); let value = getValue(_context, _subProxy || receiver); _stack.delete(prop); if (needsSubResolver(prop, value)) { // When scriptable option returns an object, create a resolver on that. value = createSubResolver(_proxy._scopes, _proxy, prop, value); } return value; } function _resolveArray(prop, value, target, isIndexable) { const { _proxy , _context , _subProxy , _descriptors: descriptors } = target; if (typeof _context.index !== 'undefined' && isIndexable(prop)) { return value[_context.index % value.length]; } else if (isObject(value[0])) { // Array of objects, return array or resolvers const arr = value; const scopes = _proxy._scopes.filter((s)=>s !== arr); value = []; for (const item of arr){ const resolver = createSubResolver(scopes, _proxy, prop, item); value.push(_attachContext(resolver, _context, _subProxy && _subProxy[prop], descriptors)); } } return value; } function resolveFallback(fallback, prop, value) { return isFunction(fallback) ? fallback(prop, value) : fallback; } const getScope = (key, parent)=>key === true ? parent : typeof key === 'string' ? resolveObjectKey(parent, key) : undefined; function addScopes(set, parentScopes, key, parentFallback, value) { for (const parent of parentScopes){ const scope = getScope(key, parent); if (scope) { set.add(scope); const fallback = resolveFallback(scope._fallback, key, value); if (typeof fallback !== 'undefined' && fallback !== key && fallback !== parentFallback) { // When we reach the descriptor that defines a new _fallback, return that. // The fallback will resume to that new scope. return fallback; } } else if (scope === false && typeof parentFallback !== 'undefined' && key !== parentFallback) { // Fallback to `false` results to `false`, when falling back to different key. // For example `interaction` from `hover` or `plugins.tooltip` and `animation` from `animations` return null; } } return false; } function createSubResolver(parentScopes, resolver, prop, value) { const rootScopes = resolver._rootScopes; const fallback = resolveFallback(resolver._fallback, prop, value); const allScopes = [ ...parentScopes, ...rootScopes ]; const set = new Set(); set.add(value); let key = addScopesFromKey(set, allScopes, prop, fallback || prop, value); if (key === null) { return false; } if (typeof fallback !== 'undefined' && fallback !== prop) { key = addScopesFromKey(set, allScopes, fallback, key, value); if (key === null) { return false; } } return _createResolver(Array.from(set), [ '' ], rootScopes, fallback, ()=>subGetTarget(resolver, prop, value)); } function addScopesFromKey(set, allScopes, key, fallback, item) { while(key){ key = addScopes(set, allScopes, key, fallback, item); } return key; } function subGetTarget(resolver, prop, value) { const parent = resolver._getTarget(); if (!(prop in parent)) { parent[prop] = {}; } const target = parent[prop]; if (isArray(target) && isObject(value)) { // For array of objects, the object is used to store updated values return value; } return target || {}; } function _resolveWithPrefixes(prop, prefixes, scopes, proxy) { let value; for (const prefix of prefixes){ value = _resolve(readKey(prefix, prop), scopes); if (typeof value !== 'undefined') { return needsSubResolver(prop, value) ? createSubResolver(scopes, proxy, prop, value) : value; } } } function _resolve(key, scopes) { for (const scope of scopes){ if (!scope) { continue; } const value = scope[key]; if (typeof value !== 'undefined') { return value; } } } function getKeysFromAllScopes(target) { let keys = target._keys; if (!keys) { keys = target._keys = resolveKeysFromAllScopes(target._scopes); } return keys; } function resolveKeysFromAllScopes(scopes) { const set = new Set(); for (const scope of scopes){ for (const key of Object.keys(scope).filter((k)=>!k.startsWith('_'))){ set.add(key); } } return Array.from(set); } function _parseObjectDataRadialScale(meta, data, start, count) { const { iScale } = meta; const { key ='r' } = this._parsing; const parsed = new Array(count); let i, ilen, index, item; for(i = 0, ilen = count; i < ilen; ++i){ index = i + start; item = data[index]; parsed[i] = { r: iScale.parse(resolveObjectKey(item, key), index) }; } return parsed; } const EPSILON = Number.EPSILON || 1e-14; const getPoint = (points, i)=>i < points.length && !points[i].skip && points[i]; const getValueAxis = (indexAxis)=>indexAxis === 'x' ? 'y' : 'x'; function splineCurve(firstPoint, middlePoint, afterPoint, t) { // Props to Rob Spencer at scaled innovation for his post on splining between points // http://scaledinnovation.com/analytics/splines/aboutSplines.html // This function must also respect "skipped" points const previous = firstPoint.skip ? middlePoint : firstPoint; const current = middlePoint; const next = afterPoint.skip ? middlePoint : afterPoint; const d01 = distanceBetweenPoints(current, previous); const d12 = distanceBetweenPoints(next, current); let s01 = d01 / (d01 + d12); let s12 = d12 / (d01 + d12); // If all points are the same, s01 & s02 will be inf s01 = isNaN(s01) ? 0 : s01; s12 = isNaN(s12) ? 0 : s12; const fa = t * s01; // scaling factor for triangle Ta const fb = t * s12; return { previous: { x: current.x - fa * (next.x - previous.x), y: current.y - fa * (next.y - previous.y) }, next: { x: current.x + fb * (next.x - previous.x), y: current.y + fb * (next.y - previous.y) } }; } /** * Adjust tangents to ensure monotonic properties */ function monotoneAdjust(points, deltaK, mK) { const pointsLen = points.length; let alphaK, betaK, tauK, squaredMagnitude, pointCurrent; let pointAfter = getPoint(points, 0); for(let i = 0; i < pointsLen - 1; ++i){ pointCurrent = pointAfter; pointAfter = getPoint(points, i + 1); if (!pointCurrent || !pointAfter) { continue; } if (almostEquals(deltaK[i], 0, EPSILON)) { mK[i] = mK[i + 1] = 0; continue; } alphaK = mK[i] / deltaK[i]; betaK = mK[i + 1] / deltaK[i]; squaredMagnitude = Math.pow(alphaK, 2) + Math.pow(betaK, 2); if (squaredMagnitude <= 9) { continue; } tauK = 3 / Math.sqrt(squaredMagnitude); mK[i] = alphaK * tauK * deltaK[i]; mK[i + 1] = betaK * tauK * deltaK[i]; } } function monotoneCompute(points, mK, indexAxis = 'x') { const valueAxis = getValueAxis(indexAxis); const pointsLen = points.length; let delta, pointBefore, pointCurrent; let pointAfter = getPoint(points, 0); for(let i = 0; i < pointsLen; ++i){ pointBefore = pointCurrent; pointCurrent = pointAfter; pointAfter = getPoint(points, i + 1); if (!pointCurrent) { continue; } const iPixel = pointCurrent[indexAxis]; const vPixel = pointCurrent[valueAxis]; if (pointBefore) { delta = (iPixel - pointBefore[indexAxis]) / 3; pointCurrent[`cp1${indexAxis}`] = iPixel - delta; pointCurrent[`cp1${valueAxis}`] = vPixel - delta * mK[i]; } if (pointAfter) { delta = (pointAfter[indexAxis] - iPixel) / 3; pointCurrent[`cp2${indexAxis}`] = iPixel + delta; pointCurrent[`cp2${valueAxis}`] = vPixel + delta * mK[i]; } } } /** * This function calculates Bézier control points in a similar way than |splineCurve|, * but preserves monotonicity of the provided data and ensures no local extremums are added * between the dataset discrete points due to the interpolation. * See : https://en.wikipedia.org/wiki/Monotone_cubic_interpolation */ function splineCurveMonotone(points, indexAxis = 'x') { const valueAxis = getValueAxis(indexAxis); const pointsLen = points.length; const deltaK = Array(pointsLen).fill(0); const mK = Array(pointsLen); // Calculate slopes (deltaK) and initialize tangents (mK) let i, pointBefore, pointCurrent; let pointAfter = getPoint(points, 0); for(i = 0; i < pointsLen; ++i){ pointBefore = pointCurrent; pointCurrent = pointAfter; pointAfter = getPoint(points, i + 1); if (!pointCurrent) { continue; } if (pointAfter) { const slopeDelta = pointAfter[indexAxis] - pointCurrent[indexAxis]; // In the case of two points that appear at the same x pixel, slopeDeltaX is 0 deltaK[i] = slopeDelta !== 0 ? (pointAfter[valueAxis] - pointCurrent[valueAxis]) / slopeDelta : 0; } mK[i] = !pointBefore ? deltaK[i] : !pointAfter ? deltaK[i - 1] : sign(deltaK[i - 1]) !== sign(deltaK[i]) ? 0 : (deltaK[i - 1] + deltaK[i]) / 2; } monotoneAdjust(points, deltaK, mK); monotoneCompute(points, mK, indexAxis); } function capControlPoint(pt, min, max) { return Math.max(Math.min(pt, max), min); } function capBezierPoints(points, area) { let i, ilen, point, inArea, inAreaPrev; let inAreaNext = _isPointInArea(points[0], area); for(i = 0, ilen = points.length; i < ilen; ++i){ inAreaPrev = inArea; inArea = inAreaNext; inAreaNext = i < ilen - 1 && _isPointInArea(points[i + 1], area); if (!inArea) { continue; } point = points[i]; if (inAreaPrev) { point.cp1x = capControlPoint(point.cp1x, area.left, area.right); point.cp1y = capControlPoint(point.cp1y, area.top, area.bottom); } if (inAreaNext) { point.cp2x = capControlPoint(point.cp2x, area.left, area.right); point.cp2y = capControlPoint(point.cp2y, area.top, area.bottom); } } } /** * @private */ function _updateBezierControlPoints(points, options, area, loop, indexAxis) { let i, ilen, point, controlPoints; // Only consider points that are drawn in case the spanGaps option is used if (options.spanGaps) { points = points.filter((pt)=>!pt.skip); } if (options.cubicInterpolationMode === 'monotone') { splineCurveMonotone(points, indexAxis); } else { let prev = loop ? points[points.length - 1] : points[0]; for(i = 0, ilen = points.length; i < ilen; ++i){ point = points[i]; controlPoints = splineCurve(prev, point, points[Math.min(i + 1, ilen - (loop ? 0 : 1)) % ilen], options.tension); point.cp1x = controlPoints.previous.x; point.cp1y = controlPoints.previous.y; point.cp2x = controlPoints.next.x; point.cp2y = controlPoints.next.y; prev = point; } } if (options.capBezierPoints) { capBezierPoints(points, area); } } /** * Note: typedefs are auto-exported, so use a made-up `dom` namespace where * necessary to avoid duplicates with `export * from './helpers`; see * https://github.com/microsoft/TypeScript/issues/46011 * @typedef { import('../core/core.controller.js').default } dom.Chart * @typedef { import('../../types').ChartEvent } ChartEvent */ /** * @private */ function _isDomSupported() { return typeof window !== 'undefined' && typeof document !== 'undefined'; } /** * @private */ function _getParentNode(domNode) { let parent = domNode.parentNode; if (parent && parent.toString() === '[object ShadowRoot]') { parent = parent.host; } return parent; } /** * convert max-width/max-height values that may be percentages into a number * @private */ function parseMaxStyle(styleValue, node, parentProperty) { let valueInPixels; if (typeof styleValue === 'string') { valueInPixels = parseInt(styleValue, 10); if (styleValue.indexOf('%') !== -1) { // percentage * size in dimension valueInPixels = valueInPixels / 100 * node.parentNode[parentProperty]; } } else { valueInPixels = styleValue; } return valueInPixels; } const getComputedStyle = (element)=>element.ownerDocument.defaultView.getComputedStyle(element, null); function getStyle(el, property) { return getComputedStyle(el).getPropertyValue(property); } const positions = [ 'top', 'right', 'bottom', 'left' ]; function getPositionedStyle(styles, style, suffix) { const result = {}; suffix = suffix ? '-' + suffix : ''; for(let i = 0; i < 4; i++){ const pos = positions[i]; result[pos] = parseFloat(styles[style + '-' + pos + suffix]) || 0; } result.width = result.left + result.right; result.height = result.top + result.bottom; return result; } const useOffsetPos = (x, y, target)=>(x > 0 || y > 0) && (!target || !target.shadowRoot); /** * @param e * @param canvas * @returns Canvas position */ function getCanvasPosition(e, canvas) { const touches = e.touches; const source = touches && touches.length ? touches[0] : e; const { offsetX , offsetY } = source; let box = false; let x, y; if (useOffsetPos(offsetX, offsetY, e.target)) { x = offsetX; y = offsetY; } else { const rect = canvas.getBoundingClientRect(); x = source.clientX - rect.left; y = source.clientY - rect.top; box = true; } return { x, y, box }; } /** * Gets an event's x, y coordinates, relative to the chart area * @param event * @param chart * @returns x and y coordinates of the event */ function getRelativePosition(event, chart) { if ('native' in event) { return event; } const { canvas , currentDevicePixelRatio } = chart; const style = getComputedStyle(canvas); const borderBox = style.boxSizing === 'border-box'; const paddings = getPositionedStyle(style, 'padding'); const borders = getPositionedStyle(style, 'border', 'width'); const { x , y , box } = getCanvasPosition(event, canvas); const xOffset = paddings.left + (box && borders.left); const yOffset = paddings.top + (box && borders.top); let { width , height } = chart; if (borderBox) { width -= paddings.width + borders.width; height -= paddings.height + borders.height; } return { x: Math.round((x - xOffset) / width * canvas.width / currentDevicePixelRatio), y: Math.round((y - yOffset) / height * canvas.height / currentDevicePixelRatio) }; } function getContainerSize(canvas, width, height) { let maxWidth, maxHeight; if (width === undefined || height === undefined) { const container = canvas && _getParentNode(canvas); if (!container) { width = canvas.clientWidth; height = canvas.clientHeight; } else { const rect = container.getBoundingClientRect(); // this is the border box of the container const containerStyle = getComputedStyle(container); const containerBorder = getPositionedStyle(containerStyle, 'border', 'width'); const containerPadding = getPositionedStyle(containerStyle, 'padding'); width = rect.width - containerPadding.width - containerBorder.width; height = rect.height - containerPadding.height - containerBorder.height; maxWidth = parseMaxStyle(containerStyle.maxWidth, container, 'clientWidth'); maxHeight = parseMaxStyle(containerStyle.maxHeight, container, 'clientHeight'); } } return { width, height, maxWidth: maxWidth || INFINITY, maxHeight: maxHeight || INFINITY }; } const round1 = (v)=>Math.round(v * 10) / 10; // eslint-disable-next-line complexity function getMaximumSize(canvas, bbWidth, bbHeight, aspectRatio) { const style = getComputedStyle(canvas); const margins = getPositionedStyle(style, 'margin'); const maxWidth = parseMaxStyle(style.maxWidth, canvas, 'clientWidth') || INFINITY; const maxHeight = parseMaxStyle(style.maxHeight, canvas, 'clientHeight') || INFINITY; const containerSize = getContainerSize(canvas, bbWidth, bbHeight); let { width , height } = containerSize; if (style.boxSizing === 'content-box') { const borders = getPositionedStyle(style, 'border', 'width'); const paddings = getPositionedStyle(style, 'padding'); width -= paddings.width + borders.width; height -= paddings.height + borders.height; } width = Math.max(0, width - margins.width); height = Math.max(0, aspectRatio ? width / aspectRatio : height - margins.height); width = round1(Math.min(width, maxWidth, containerSize.maxWidth)); height = round1(Math.min(height, maxHeight, containerSize.maxHeight)); if (width && !height) { // https://github.com/chartjs/Chart.js/issues/4659 // If the canvas has width, but no height, default to aspectRatio of 2 (canvas default) height = round1(width / 2); } const maintainHeight = bbWidth !== undefined || bbHeight !== undefined; if (maintainHeight && aspectRatio && containerSize.height && height > containerSize.height) { height = containerSize.height; width = round1(Math.floor(height * aspectRatio)); } return { width, height }; } /** * @param chart * @param forceRatio * @param forceStyle * @returns True if the canvas context size or transformation has changed. */ function retinaScale(chart, forceRatio, forceStyle) { const pixelRatio = forceRatio || 1; const deviceHeight = Math.floor(chart.height * pixelRatio); const deviceWidth = Math.floor(chart.width * pixelRatio); chart.height = Math.floor(chart.height); chart.width = Math.floor(chart.width); const canvas = chart.canvas; // If no style has been set on the canvas, the render size is used as display size, // making the chart visually bigger, so let's enforce it to the "correct" values. // See https://github.com/chartjs/Chart.js/issues/3575 if (canvas.style && (forceStyle || !canvas.style.height && !canvas.style.width)) { canvas.style.height = `${chart.height}px`; canvas.style.width = `${chart.width}px`; } if (chart.currentDevicePixelRatio !== pixelRatio || canvas.height !== deviceHeight || canvas.width !== deviceWidth) { chart.currentDevicePixelRatio = pixelRatio; canvas.height = deviceHeight; canvas.width = deviceWidth; chart.ctx.setTransform(pixelRatio, 0, 0, pixelRatio, 0, 0); return true; } return false; } /** * Detects support for options object argument in addEventListener. * https://developer.mozilla.org/en-US/docs/Web/API/EventTarget/addEventListener#Safely_detecting_option_support * @private */ const supportsEventListenerOptions = function() { let passiveSupported = false; try { const options = { get passive () { passiveSupported = true; return false; } }; if (_isDomSupported()) { window.addEventListener('test', null, options); window.removeEventListener('test', null, options); } } catch (e) { // continue regardless of error } return passiveSupported; }(); /** * The "used" size is the final value of a dimension property after all calculations have * been performed. This method uses the computed style of `element` but returns undefined * if the computed style is not expressed in pixels. That can happen in some cases where * `element` has a size relative to its parent and this last one is not yet displayed, * for example because of `display: none` on a parent node. * @see https://developer.mozilla.org/en-US/docs/Web/CSS/used_value * @returns Size in pixels or undefined if unknown. */ function readUsedSize(element, property) { const value = getStyle(element, property); const matches = value && value.match(/^(\d+)(\.\d+)?px$/); return matches ? +matches[1] : undefined; } /** * @private */ function _pointInLine(p1, p2, t, mode) { return { x: p1.x + t * (p2.x - p1.x), y: p1.y + t * (p2.y - p1.y) }; } /** * @private */ function _steppedInterpolation(p1, p2, t, mode) { return { x: p1.x + t * (p2.x - p1.x), y: mode === 'middle' ? t < 0.5 ? p1.y : p2.y : mode === 'after' ? t < 1 ? p1.y : p2.y : t > 0 ? p2.y : p1.y }; } /** * @private */ function _bezierInterpolation(p1, p2, t, mode) { const cp1 = { x: p1.cp2x, y: p1.cp2y }; const cp2 = { x: p2.cp1x, y: p2.cp1y }; const a = _pointInLine(p1, cp1, t); const b = _pointInLine(cp1, cp2, t); const c = _pointInLine(cp2, p2, t); const d = _pointInLine(a, b, t); const e = _pointInLine(b, c, t); return _pointInLine(d, e, t); } const getRightToLeftAdapter = function(rectX, width) { return { x (x) { return rectX + rectX + width - x; }, setWidth (w) { width = w; }, textAlign (align) { if (align === 'center') { return align; } return align === 'right' ? 'left' : 'right'; }, xPlus (x, value) { return x - value; }, leftForLtr (x, itemWidth) { return x - itemWidth; } }; }; const getLeftToRightAdapter = function() { return { x (x) { return x; }, setWidth (w) {}, textAlign (align) { return align; }, xPlus (x, value) { return x + value; }, leftForLtr (x, _itemWidth) { return x; } }; }; function getRtlAdapter(rtl, rectX, width) { return rtl ? getRightToLeftAdapter(rectX, width) : getLeftToRightAdapter(); } function overrideTextDirection(ctx, direction) { let style, original; if (direction === 'ltr' || direction === 'rtl') { style = ctx.canvas.style; original = [ style.getPropertyValue('direction'), style.getPropertyPriority('direction') ]; style.setProperty('direction', direction, 'important'); ctx.prevTextDirection = original; } } function restoreTextDirection(ctx, original) { if (original !== undefined) { delete ctx.prevTextDirection; ctx.canvas.style.setProperty('direction', original[0], original[1]); } } function propertyFn(property) { if (property === 'angle') { return { between: _angleBetween, compare: _angleDiff, normalize: _normalizeAngle }; } return { between: _isBetween, compare: (a, b)=>a - b, normalize: (x)=>x }; } function normalizeSegment({ start , end , count , loop , style }) { return { start: start % count, end: end % count, loop: loop && (end - start + 1) % count === 0, style }; } function getSegment(segment, points, bounds) { const { property , start: startBound , end: endBound } = bounds; const { between , normalize } = propertyFn(property); const count = points.length; let { start , end , loop } = segment; let i, ilen; if (loop) { start += count; end += count; for(i = 0, ilen = count; i < ilen; ++i){ if (!between(normalize(points[start % count][property]), startBound, endBound)) { break; } start--; end--; } start %= count; end %= count; } if (end < start) { end += count; } return { start, end, loop, style: segment.style }; } function _boundSegment(segment, points, bounds) { if (!bounds) { return [ segment ]; } const { property , start: startBound , end: endBound } = bounds; const count = points.length; const { compare , between , normalize } = propertyFn(property); const { start , end , loop , style } = getSegment(segment, points, bounds); const result = []; let inside = false; let subStart = null; let value, point, prevValue; const startIsBefore = ()=>between(startBound, prevValue, value) && compare(startBound, prevValue) !== 0; const endIsBefore = ()=>compare(endBound, value) === 0 || between(endBound, prevValue, value); const shouldStart = ()=>inside || startIsBefore(); const shouldStop = ()=>!inside || endIsBefore(); for(let i = start, prev = start; i <= end; ++i){ point = points[i % count]; if (point.skip) { continue; } value = normalize(point[property]); if (value === prevValue) { continue; } inside = between(value, startBound, endBound); if (subStart === null && shouldStart()) { subStart = compare(value, startBound) === 0 ? i : prev; } if (subStart !== null && shouldStop()) { result.push(normalizeSegment({ start: subStart, end: i, loop, count, style })); subStart = null; } prev = i; prevValue = value; } if (subStart !== null) { result.push(normalizeSegment({ start: subStart, end, loop, count, style })); } return result; } function _boundSegments(line, bounds) { const result = []; const segments = line.segments; for(let i = 0; i < segments.length; i++){ const sub = _boundSegment(segments[i], line.points, bounds); if (sub.length) { result.push(...sub); } } return result; } function findStartAndEnd(points, count, loop, spanGaps) { let start = 0; let end = count - 1; if (loop && !spanGaps) { while(start < count && !points[start].skip){ start++; } } while(start < count && points[start].skip){ start++; } start %= count; if (loop) { end += start; } while(end > start && points[end % count].skip){ end--; } end %= count; return { start, end }; } function solidSegments(points, start, max, loop) { const count = points.length; const result = []; let last = start; let prev = points[start]; let end; for(end = start + 1; end <= max; ++end){ const cur = points[end % count]; if (cur.skip || cur.stop) { if (!prev.skip) { loop = false; result.push({ start: start % count, end: (end - 1) % count, loop }); start = last = cur.stop ? end : null; } } else { last = end; if (prev.skip) { start = end; } } prev = cur; } if (last !== null) { result.push({ start: start % count, end: last % count, loop }); } return result; } function _computeSegments(line, segmentOptions) { const points = line.points; const spanGaps = line.options.spanGaps; const count = points.length; if (!count) { return []; } const loop = !!line._loop; const { start , end } = findStartAndEnd(points, count, loop, spanGaps); if (spanGaps === true) { return splitByStyles(line, [ { start, end, loop } ], points, segmentOptions); } const max = end < start ? end + count : end; const completeLoop = !!line._fullLoop && start === 0 && end === count - 1; return splitByStyles(line, solidSegments(points, start, max, completeLoop), points, segmentOptions); } function splitByStyles(line, segments, points, segmentOptions) { if (!segmentOptions || !segmentOptions.setContext || !points) { return segments; } return doSplitByStyles(line, segments, points, segmentOptions); } function doSplitByStyles(line, segments, points, segmentOptions) { const chartContext = line._chart.getContext(); const baseStyle = readStyle(line.options); const { _datasetIndex: datasetIndex , options: { spanGaps } } = line; const count = points.length; const result = []; let prevStyle = baseStyle; let start = segments[0].start; let i = start; function addStyle(s, e, l, st) { const dir = spanGaps ? -1 : 1; if (s === e) { return; } s += count; while(points[s % count].skip){ s -= dir; } while(points[e % count].skip){ e += dir; } if (s % count !== e % count) { result.push({ start: s % count, end: e % count, loop: l, style: st }); prevStyle = st; start = e % count; } } for (const segment of segments){ start = spanGaps ? start : segment.start; let prev = points[start % count]; let style; for(i = start + 1; i <= segment.end; i++){ const pt = points[i % count]; style = readStyle(segmentOptions.setContext(createContext(chartContext, { type: 'segment', p0: prev, p1: pt, p0DataIndex: (i - 1) % count, p1DataIndex: i % count, datasetIndex }))); if (styleChanged(style, prevStyle)) { addStyle(start, i - 1, segment.loop, prevStyle); } prev = pt; prevStyle = style; } if (start < i - 1) { addStyle(start, i - 1, segment.loop, prevStyle); } } return result; } function readStyle(options) { return { backgroundColor: options.backgroundColor, borderCapStyle: options.borderCapStyle, borderDash: options.borderDash, borderDashOffset: options.borderDashOffset, borderJoinStyle: options.borderJoinStyle, borderWidth: options.borderWidth, borderColor: options.borderColor }; } function styleChanged(style, prevStyle) { if (!prevStyle) { return false; } const cache = []; const replacer = function(key, value) { if (!isPatternOrGradient(value)) { return value; } if (!cache.includes(value)) { cache.push(value); } return cache.indexOf(value); }; return JSON.stringify(style, replacer) !== JSON.stringify(prevStyle, replacer); } exports.HALF_PI = HALF_PI; exports.INFINITY = INFINITY; exports.PI = PI; exports.PITAU = PITAU; exports.QUARTER_PI = QUARTER_PI; exports.RAD_PER_DEG = RAD_PER_DEG; exports.TAU = TAU; exports.TWO_THIRDS_PI = TWO_THIRDS_PI; exports.Ticks = Ticks; exports._addGrace = _addGrace; exports._alignPixel = _alignPixel; exports._alignStartEnd = _alignStartEnd; exports._angleBetween = _angleBetween; exports._angleDiff = _angleDiff; exports._arrayUnique = _arrayUnique; exports._attachContext = _attachContext; exports._bezierCurveTo = _bezierCurveTo; exports._bezierInterpolation = _bezierInterpolation; exports._boundSegment = _boundSegment; exports._boundSegments = _boundSegments; exports._capitalize = _capitalize; exports._computeSegments = _computeSegments; exports._createResolver = _createResolver; exports._decimalPlaces = _decimalPlaces; exports._deprecated = _deprecated; exports._descriptors = _descriptors; exports._elementsEqual = _elementsEqual; exports._factorize = _factorize; exports._filterBetween = _filterBetween; exports._getParentNode = _getParentNode; exports._getStartAndCountOfVisiblePoints = _getStartAndCountOfVisiblePoints; exports._int16Range = _int16Range; exports._isBetween = _isBetween; exports._isClickEvent = _isClickEvent; exports._isDomSupported = _isDomSupported; exports._isPointInArea = _isPointInArea; exports._limitValue = _limitValue; exports._longestText = _longestText; exports._lookup = _lookup; exports._lookupByKey = _lookupByKey; exports._measureText = _measureText; exports._merger = _merger; exports._mergerIf = _mergerIf; exports._normalizeAngle = _normalizeAngle; exports._parseObjectDataRadialScale = _parseObjectDataRadialScale; exports._pointInLine = _pointInLine; exports._readValueToProps = _readValueToProps; exports._rlookupByKey = _rlookupByKey; exports._scaleRangesChanged = _scaleRangesChanged; exports._setMinAndMaxByKey = _setMinAndMaxByKey; exports._splitKey = _splitKey; exports._steppedInterpolation = _steppedInterpolation; exports._steppedLineTo = _steppedLineTo; exports._textX = _textX; exports._toLeftRightCenter = _toLeftRightCenter; exports._updateBezierControlPoints = _updateBezierControlPoints; exports.addRoundedRectPath = addRoundedRectPath; exports.almostEquals = almostEquals; exports.almostWhole = almostWhole; exports.callback = callback; exports.clearCanvas = clearCanvas; exports.clipArea = clipArea; exports.clone = clone; exports.color = color; exports.createContext = createContext; exports.debounce = debounce; exports.defaults = defaults; exports.defined = defined; exports.descriptors = descriptors; exports.distanceBetweenPoints = distanceBetweenPoints; exports.drawPoint = drawPoint; exports.drawPointLegend = drawPointLegend; exports.each = each; exports.effects = effects; exports.finiteOrDefault = finiteOrDefault; exports.fontString = fontString; exports.formatNumber = formatNumber; exports.getAngleFromPoint = getAngleFromPoint; exports.getHoverColor = getHoverColor; exports.getMaximumSize = getMaximumSize; exports.getRelativePosition = getRelativePosition; exports.getRtlAdapter = getRtlAdapter; exports.getStyle = getStyle; exports.isArray = isArray; exports.isFunction = isFunction; exports.isNullOrUndef = isNullOrUndef; exports.isNumber = isNumber; exports.isNumberFinite = isNumberFinite; exports.isObject = isObject; exports.isPatternOrGradient = isPatternOrGradient; exports.listenArrayEvents = listenArrayEvents; exports.log10 = log10; exports.merge = merge; exports.mergeIf = mergeIf; exports.niceNum = niceNum; exports.noop = noop; exports.overrideTextDirection = overrideTextDirection; exports.overrides = overrides; exports.readUsedSize = readUsedSize; exports.renderText = renderText; exports.requestAnimFrame = requestAnimFrame; exports.resolve = resolve; exports.resolveObjectKey = resolveObjectKey; exports.restoreTextDirection = restoreTextDirection; exports.retinaScale = retinaScale; exports.setsEqual = setsEqual; exports.sign = sign; exports.splineCurve = splineCurve; exports.splineCurveMonotone = splineCurveMonotone; exports.supportsEventListenerOptions = supportsEventListenerOptions; exports.throttled = throttled; exports.toDegrees = toDegrees; exports.toDimension = toDimension; exports.toFont = toFont; exports.toFontString = toFontString; exports.toLineHeight = toLineHeight; exports.toPadding = toPadding; exports.toPercentage = toPercentage; exports.toRadians = toRadians; exports.toTRBL = toTRBL; exports.toTRBLCorners = toTRBLCorners; exports.uid = uid; exports.unclipArea = unclipArea; exports.unlistenArrayEvents = unlistenArrayEvents; exports.valueOrDefault = valueOrDefault; //# sourceMappingURL=helpers.segment.cjs.map