/* Javascript plotting library for jQuery, version 3.0.0. Copyright (c) 2007-2014 IOLA and Ole Laursen. Licensed under the MIT license. */ // the actual Flot code (function($) { "use strict"; var Canvas = window.Flot.Canvas; function defaultTickGenerator(axis) { var ticks = [], start = $.plot.saturated.saturate($.plot.saturated.floorInBase(axis.min, axis.tickSize)), i = 0, v = Number.NaN, prev; if (start === -Number.MAX_VALUE) { ticks.push(start); start = $.plot.saturated.floorInBase(axis.min + axis.tickSize, axis.tickSize); } do { prev = v; //v = start + i * axis.tickSize; v = $.plot.saturated.multiplyAdd(axis.tickSize, i, start); ticks.push(v); ++i; } while (v < axis.max && v !== prev); return ticks; } function defaultTickFormatter(value, axis, precision) { var oldTickDecimals = axis.tickDecimals, expPosition = ("" + value).indexOf("e"); if (expPosition !== -1) { return expRepTickFormatter(value, axis, precision); } if (precision > 0) { axis.tickDecimals = precision; } var factor = axis.tickDecimals ? parseFloat('1e' + axis.tickDecimals) : 1, formatted = "" + Math.round(value * factor) / factor; // If tickDecimals was specified, ensure that we have exactly that // much precision; otherwise default to the value's own precision. if (axis.tickDecimals != null) { var decimal = formatted.indexOf("."), decimalPrecision = decimal === -1 ? 0 : formatted.length - decimal - 1; if (decimalPrecision < axis.tickDecimals) { var decimals = ("" + factor).substr(1, axis.tickDecimals - decimalPrecision); formatted = (decimalPrecision ? formatted : formatted + ".") + decimals; } } axis.tickDecimals = oldTickDecimals; return formatted; }; function expRepTickFormatter(value, axis, precision) { var expPosition = ("" + value).indexOf("e"), exponentValue = parseInt(("" + value).substr(expPosition + 1)), tenExponent = expPosition !== -1 ? exponentValue : (value > 0 ? Math.floor(Math.log(value) / Math.LN10) : 0), roundWith = parseFloat('1e' + tenExponent), x = value / roundWith; if (precision) { var updatedPrecision = recomputePrecision(value, precision); return (value / roundWith).toFixed(updatedPrecision) + 'e' + tenExponent; } if (axis.tickDecimals > 0) { return x.toFixed(recomputePrecision(value, axis.tickDecimals)) + 'e' + tenExponent; } return x.toFixed() + 'e' + tenExponent; } function recomputePrecision(num, precision) { //for numbers close to zero, the precision from flot will be a big number //while for big numbers, the precision will be negative var log10Value = Math.log(Math.abs(num)) * Math.LOG10E, newPrecision = Math.abs(log10Value + precision); return newPrecision <= 20 ? Math.floor(newPrecision) : 20; } /////////////////////////////////////////////////////////////////////////// // The top-level container for the entire plot. function Plot(placeholder, data_, options_, plugins) { // data is on the form: // [ series1, series2 ... ] // where series is either just the data as [ [x1, y1], [x2, y2], ... ] // or { data: [ [x1, y1], [x2, y2], ... ], label: "some label", ... } var series = [], options = { // the color theme used for graphs colors: ["#edc240", "#afd8f8", "#cb4b4b", "#4da74d", "#9440ed"], xaxis: { show: null, // null = auto-detect, true = always, false = never position: "bottom", // or "top" mode: null, // null or "time" font: null, // null (derived from CSS in placeholder) or object like { size: 11, lineHeight: 13, style: "italic", weight: "bold", family: "sans-serif", variant: "small-caps" } color: null, // base color, labels, ticks tickColor: null, // possibly different color of ticks, e.g. "rgba(0,0,0,0.15)" transform: null, // null or f: number -> number to transform axis inverseTransform: null, // if transform is set, this should be the inverse function min: null, // min. value to show, null means set automatically max: null, // max. value to show, null means set automatically autoScaleMargin: null, // margin in % to add if autoScale option is on "loose" mode, autoScale: "exact", // Available modes: "none", "loose", "exact", "sliding-window" windowSize: null, // null or number. This is the size of sliding-window. growOnly: null, // grow only, useful for smoother auto-scale, the scales will grow to accomodate data but won't shrink back. ticks: null, // either [1, 3] or [[1, "a"], 3] or (fn: axis info -> ticks) or app. number of ticks for auto-ticks tickFormatter: null, // fn: number -> string showTickLabels: "major", // "none", "endpoints", "major", "all" labelWidth: null, // size of tick labels in pixels labelHeight: null, reserveSpace: null, // whether to reserve space even if axis isn't shown tickLength: null, // size in pixels of major tick marks showMinorTicks: null, // true = show minor tick marks, false = hide minor tick marks showTicks: null, // true = show tick marks, false = hide all tick marks gridLines: null, // true = show grid lines, false = hide grid lines alignTicksWithAxis: null, // axis number or null for no sync tickDecimals: null, // no. of decimals, null means auto tickSize: null, // number or [number, "unit"] minTickSize: null, // number or [number, "unit"] offset: { below: 0, above: 0 }, // the plot drawing offset. this is calculated by the flot.navigate for each axis boxPosition: { centerX: 0, centerY: 0 } //position of the axis on the corresponding axis box }, yaxis: { autoScaleMargin: 0.02, // margin in % to add if autoScale option is on "loose" mode autoScale: "loose", // Available modes: "none", "loose", "exact" growOnly: null, // grow only, useful for smoother auto-scale, the scales will grow to accomodate data but won't shrink back. position: "left", // or "right" showTickLabels: "major", // "none", "endpoints", "major", "all" offset: { below: 0, above: 0 }, // the plot drawing offset. this is calculated by the flot.navigate for each axis boxPosition: { centerX: 0, centerY: 0 } //position of the axis on the corresponding axis box }, xaxes: [], yaxes: [], series: { points: { show: false, radius: 3, lineWidth: 2, // in pixels fill: true, fillColor: "#ffffff", symbol: 'circle' // or callback }, lines: { // we don't put in show: false so we can see // whether lines were actively disabled lineWidth: 1, // in pixels fill: false, fillColor: null, steps: false // Omit 'zero', so we can later default its value to // match that of the 'fill' option. }, bars: { show: false, lineWidth: 2, // in pixels // barWidth: number or [number, absolute] // when 'absolute' is false, 'number' is relative to the minimum distance between points for the series // when 'absolute' is true, 'number' is considered to be in units of the x-axis horizontal: false, barWidth: 0.8, fill: true, fillColor: null, align: "left", // "left", "right", or "center" zero: true }, shadowSize: 3, highlightColor: null }, grid: { show: true, aboveData: false, color: "#545454", // primary color used for outline and labels backgroundColor: null, // null for transparent, else color borderColor: null, // set if different from the grid color tickColor: null, // color for the ticks, e.g. "rgba(0,0,0,0.15)" margin: 0, // distance from the canvas edge to the grid labelMargin: 5, // in pixels axisMargin: 8, // in pixels borderWidth: 1, // in pixels minBorderMargin: null, // in pixels, null means taken from points radius markings: null, // array of ranges or fn: axes -> array of ranges markingsColor: "#f4f4f4", markingsLineWidth: 2, // interactive stuff clickable: false, hoverable: false, autoHighlight: true, // highlight in case mouse is near mouseActiveRadius: 15 // how far the mouse can be away to activate an item }, interaction: { redrawOverlayInterval: 1000 / 60 // time between updates, -1 means in same flow }, hooks: {} }, surface = null, // the canvas for the plot itself overlay = null, // canvas for interactive stuff on top of plot eventHolder = null, // jQuery object that events should be bound to ctx = null, octx = null, xaxes = [], yaxes = [], plotOffset = { left: 0, right: 0, top: 0, bottom: 0 }, plotWidth = 0, plotHeight = 0, hooks = { processOptions: [], processRawData: [], processDatapoints: [], processOffset: [], setupGrid: [], adjustSeriesDataRange: [], setRange: [], drawBackground: [], drawSeries: [], drawAxis: [], draw: [], findNearbyItems: [], axisReserveSpace: [], bindEvents: [], drawOverlay: [], resize: [], shutdown: [] }, plot = this; var eventManager = {}; // interactive features var redrawTimeout = null; // public functions plot.setData = setData; plot.setupGrid = setupGrid; plot.draw = draw; plot.getPlaceholder = function() { return placeholder; }; plot.getCanvas = function() { return surface.element; }; plot.getSurface = function() { return surface; }; plot.getEventHolder = function() { return eventHolder[0]; }; plot.getPlotOffset = function() { return plotOffset; }; plot.width = function() { return plotWidth; }; plot.height = function() { return plotHeight; }; plot.offset = function() { var o = eventHolder.offset(); o.left += plotOffset.left; o.top += plotOffset.top; return o; }; plot.getData = function() { return series; }; plot.getAxes = function() { var res = {}; $.each(xaxes.concat(yaxes), function(_, axis) { if (axis) { res[axis.direction + (axis.n !== 1 ? axis.n : "") + "axis"] = axis; } }); return res; }; plot.getXAxes = function() { return xaxes; }; plot.getYAxes = function() { return yaxes; }; plot.c2p = canvasToCartesianAxisCoords; plot.p2c = cartesianAxisToCanvasCoords; plot.getOptions = function() { return options; }; plot.triggerRedrawOverlay = triggerRedrawOverlay; plot.pointOffset = function(point) { return { left: parseInt(xaxes[axisNumber(point, "x") - 1].p2c(+point.x) + plotOffset.left, 10), top: parseInt(yaxes[axisNumber(point, "y") - 1].p2c(+point.y) + plotOffset.top, 10) }; }; plot.shutdown = shutdown; plot.destroy = function() { shutdown(); placeholder.removeData("plot").empty(); series = []; options = null; surface = null; overlay = null; eventHolder = null; ctx = null; octx = null; xaxes = []; yaxes = []; hooks = null; plot = null; }; plot.resize = function() { var width = placeholder.width(), height = placeholder.height(); surface.resize(width, height); overlay.resize(width, height); executeHooks(hooks.resize, [width, height]); }; plot.clearTextCache = function () { surface.clearCache(); overlay.clearCache(); }; plot.autoScaleAxis = autoScaleAxis; plot.computeRangeForDataSeries = computeRangeForDataSeries; plot.adjustSeriesDataRange = adjustSeriesDataRange; plot.findNearbyItem = findNearbyItem; plot.findNearbyItems = findNearbyItems; plot.findNearbyInterpolationPoint = findNearbyInterpolationPoint; plot.computeValuePrecision = computeValuePrecision; plot.computeTickSize = computeTickSize; plot.addEventHandler = addEventHandler; // public attributes plot.hooks = hooks; // initialize var MINOR_TICKS_COUNT_CONSTANT = $.plot.uiConstants.MINOR_TICKS_COUNT_CONSTANT; var TICK_LENGTH_CONSTANT = $.plot.uiConstants.TICK_LENGTH_CONSTANT; initPlugins(plot); setupCanvases(); parseOptions(options_); setData(data_); setupGrid(true); draw(); bindEvents(); function executeHooks(hook, args) { args = [plot].concat(args); for (var i = 0; i < hook.length; ++i) { hook[i].apply(this, args); } } function initPlugins() { // References to key classes, allowing plugins to modify them var classes = { Canvas: Canvas }; for (var i = 0; i < plugins.length; ++i) { var p = plugins[i]; p.init(plot, classes); if (p.options) { $.extend(true, options, p.options); } } } function parseOptions(opts) { $.extend(true, options, opts); // $.extend merges arrays, rather than replacing them. When less // colors are provided than the size of the default palette, we // end up with those colors plus the remaining defaults, which is // not expected behavior; avoid it by replacing them here. if (opts && opts.colors) { options.colors = opts.colors; } if (options.xaxis.color == null) { options.xaxis.color = $.color.parse(options.grid.color).scale('a', 0.22).toString(); } if (options.yaxis.color == null) { options.yaxis.color = $.color.parse(options.grid.color).scale('a', 0.22).toString(); } if (options.xaxis.tickColor == null) { // grid.tickColor for back-compatibility options.xaxis.tickColor = options.grid.tickColor || options.xaxis.color; } if (options.yaxis.tickColor == null) { // grid.tickColor for back-compatibility options.yaxis.tickColor = options.grid.tickColor || options.yaxis.color; } if (options.grid.borderColor == null) { options.grid.borderColor = options.grid.color; } if (options.grid.tickColor == null) { options.grid.tickColor = $.color.parse(options.grid.color).scale('a', 0.22).toString(); } // Fill in defaults for axis options, including any unspecified // font-spec fields, if a font-spec was provided. // If no x/y axis options were provided, create one of each anyway, // since the rest of the code assumes that they exist. var i, axisOptions, axisCount, fontSize = placeholder.css("font-size"), fontSizeDefault = fontSize ? +fontSize.replace("px", "") : 13, fontDefaults = { style: placeholder.css("font-style"), size: Math.round(0.8 * fontSizeDefault), variant: placeholder.css("font-variant"), weight: placeholder.css("font-weight"), family: placeholder.css("font-family") }; axisCount = options.xaxes.length || 1; for (i = 0; i < axisCount; ++i) { axisOptions = options.xaxes[i]; if (axisOptions && !axisOptions.tickColor) { axisOptions.tickColor = axisOptions.color; } axisOptions = $.extend(true, {}, options.xaxis, axisOptions); options.xaxes[i] = axisOptions; if (axisOptions.font) { axisOptions.font = $.extend({}, fontDefaults, axisOptions.font); if (!axisOptions.font.color) { axisOptions.font.color = axisOptions.color; } if (!axisOptions.font.lineHeight) { axisOptions.font.lineHeight = Math.round(axisOptions.font.size * 1.15); } } } axisCount = options.yaxes.length || 1; for (i = 0; i < axisCount; ++i) { axisOptions = options.yaxes[i]; if (axisOptions && !axisOptions.tickColor) { axisOptions.tickColor = axisOptions.color; } axisOptions = $.extend(true, {}, options.yaxis, axisOptions); options.yaxes[i] = axisOptions; if (axisOptions.font) { axisOptions.font = $.extend({}, fontDefaults, axisOptions.font); if (!axisOptions.font.color) { axisOptions.font.color = axisOptions.color; } if (!axisOptions.font.lineHeight) { axisOptions.font.lineHeight = Math.round(axisOptions.font.size * 1.15); } } } // save options on axes for future reference for (i = 0; i < options.xaxes.length; ++i) { getOrCreateAxis(xaxes, i + 1).options = options.xaxes[i]; } for (i = 0; i < options.yaxes.length; ++i) { getOrCreateAxis(yaxes, i + 1).options = options.yaxes[i]; } //process boxPosition options used for axis.box size $.each(allAxes(), function(_, axis) { axis.boxPosition = axis.options.boxPosition || {centerX: 0, centerY: 0}; }); // add hooks from options for (var n in hooks) { if (options.hooks[n] && options.hooks[n].length) { hooks[n] = hooks[n].concat(options.hooks[n]); } } executeHooks(hooks.processOptions, [options]); } function setData(d) { var oldseries = series; series = parseData(d); fillInSeriesOptions(); processData(oldseries); } function parseData(d) { var res = []; for (var i = 0; i < d.length; ++i) { var s = $.extend(true, {}, options.series); if (d[i].data != null) { s.data = d[i].data; // move the data instead of deep-copy delete d[i].data; $.extend(true, s, d[i]); d[i].data = s.data; } else { s.data = d[i]; } res.push(s); } return res; } function axisNumber(obj, coord) { var a = obj[coord + "axis"]; if (typeof a === "object") { // if we got a real axis, extract number a = a.n; } if (typeof a !== "number") { a = 1; // default to first axis } return a; } function allAxes() { // return flat array without annoying null entries return xaxes.concat(yaxes).filter(function(a) { return a; }); } // canvas to axis for cartesian axes function canvasToCartesianAxisCoords(pos) { // return an object with x/y corresponding to all used axes var res = {}, i, axis; for (i = 0; i < xaxes.length; ++i) { axis = xaxes[i]; if (axis && axis.used) { res["x" + axis.n] = axis.c2p(pos.left); } } for (i = 0; i < yaxes.length; ++i) { axis = yaxes[i]; if (axis && axis.used) { res["y" + axis.n] = axis.c2p(pos.top); } } if (res.x1 !== undefined) { res.x = res.x1; } if (res.y1 !== undefined) { res.y = res.y1; } return res; } // axis to canvas for cartesian axes function cartesianAxisToCanvasCoords(pos) { // get canvas coords from the first pair of x/y found in pos var res = {}, i, axis, key; for (i = 0; i < xaxes.length; ++i) { axis = xaxes[i]; if (axis && axis.used) { key = "x" + axis.n; if (pos[key] == null && axis.n === 1) { key = "x"; } if (pos[key] != null) { res.left = axis.p2c(pos[key]); break; } } } for (i = 0; i < yaxes.length; ++i) { axis = yaxes[i]; if (axis && axis.used) { key = "y" + axis.n; if (pos[key] == null && axis.n === 1) { key = "y"; } if (pos[key] != null) { res.top = axis.p2c(pos[key]); break; } } } return res; } function getOrCreateAxis(axes, number) { if (!axes[number - 1]) { axes[number - 1] = { n: number, // save the number for future reference direction: axes === xaxes ? "x" : "y", options: $.extend(true, {}, axes === xaxes ? options.xaxis : options.yaxis) }; } return axes[number - 1]; } function fillInSeriesOptions() { var neededColors = series.length, maxIndex = -1, i; // Subtract the number of series that already have fixed colors or // color indexes from the number that we still need to generate. for (i = 0; i < series.length; ++i) { var sc = series[i].color; if (sc != null) { neededColors--; if (typeof sc === "number" && sc > maxIndex) { maxIndex = sc; } } } // If any of the series have fixed color indexes, then we need to // generate at least as many colors as the highest index. if (neededColors <= maxIndex) { neededColors = maxIndex + 1; } // Generate all the colors, using first the option colors and then // variations on those colors once they're exhausted. var c, colors = [], colorPool = options.colors, colorPoolSize = colorPool.length, variation = 0, definedColors = Math.max(0, series.length - neededColors); for (i = 0; i < neededColors; i++) { c = $.color.parse(colorPool[(definedColors + i) % colorPoolSize] || "#666"); // Each time we exhaust the colors in the pool we adjust // a scaling factor used to produce more variations on // those colors. The factor alternates negative/positive // to produce lighter/darker colors. // Reset the variation after every few cycles, or else // it will end up producing only white or black colors. if (i % colorPoolSize === 0 && i) { if (variation >= 0) { if (variation < 0.5) { variation = -variation - 0.2; } else variation = 0; } else variation = -variation; } colors[i] = c.scale('rgb', 1 + variation); } // Finalize the series options, filling in their colors var colori = 0, s; for (i = 0; i < series.length; ++i) { s = series[i]; // assign colors if (s.color == null) { s.color = colors[colori].toString(); ++colori; } else if (typeof s.color === "number") { s.color = colors[s.color].toString(); } // turn on lines automatically in case nothing is set if (s.lines.show == null) { var v, show = true; for (v in s) { if (s[v] && s[v].show) { show = false; break; } } if (show) { s.lines.show = true; } } // If nothing was provided for lines.zero, default it to match // lines.fill, since areas by default should extend to zero. if (s.lines.zero == null) { s.lines.zero = !!s.lines.fill; } // setup axes s.xaxis = getOrCreateAxis(xaxes, axisNumber(s, "x")); s.yaxis = getOrCreateAxis(yaxes, axisNumber(s, "y")); } } function processData(prevSeries) { var topSentry = Number.POSITIVE_INFINITY, bottomSentry = Number.NEGATIVE_INFINITY, i, j, k, m, s, points, ps, val, f, p, data, format; function updateAxis(axis, min, max) { if (min < axis.datamin && min !== -Infinity) { axis.datamin = min; } if (max > axis.datamax && max !== Infinity) { axis.datamax = max; } } function reusePoints(prevSeries, i) { if (prevSeries && prevSeries[i] && prevSeries[i].datapoints && prevSeries[i].datapoints.points) { return prevSeries[i].datapoints.points; } return []; } $.each(allAxes(), function(_, axis) { // init axis if (axis.options.growOnly !== true) { axis.datamin = topSentry; axis.datamax = bottomSentry; } else { if (axis.datamin === undefined) { axis.datamin = topSentry; } if (axis.datamax === undefined) { axis.datamax = bottomSentry; } } axis.used = false; }); for (i = 0; i < series.length; ++i) { s = series[i]; s.datapoints = { points: [] }; if (s.datapoints.points.length === 0) { s.datapoints.points = reusePoints(prevSeries, i); } executeHooks(hooks.processRawData, [s, s.data, s.datapoints]); } // first pass: clean and copy data for (i = 0; i < series.length; ++i) { s = series[i]; data = s.data; format = s.datapoints.format; if (!format) { format = []; // find out how to copy format.push({ x: true, y: false, number: true, required: true, computeRange: s.xaxis.options.autoScale !== 'none', defaultValue: null }); format.push({ x: false, y: true, number: true, required: true, computeRange: s.yaxis.options.autoScale !== 'none', defaultValue: null }); if (s.stack || s.bars.show || (s.lines.show && s.lines.fill)) { var expectedPs = s.datapoints.pointsize != null ? s.datapoints.pointsize : (s.data && s.data[0] && s.data[0].length ? s.data[0].length : 3); if (expectedPs > 2) { format.push({ x: false, y: true, number: true, required: false, computeRange: s.yaxis.options.autoScale !== 'none', defaultValue: 0 }); } } s.datapoints.format = format; } s.xaxis.used = s.yaxis.used = true; if (s.datapoints.pointsize != null) continue; // already filled in s.datapoints.pointsize = format.length; ps = s.datapoints.pointsize; points = s.datapoints.points; for (j = k = 0; j < data.length; ++j, k += ps) { p = data[j]; var nullify = p == null; if (!nullify) { for (m = 0; m < ps; ++m) { val = p[m]; f = format[m]; if (f) { if (f.number && val != null) { val = +val; // convert to number if (isNaN(val)) { val = null; } } if (val == null) { if (f.required) nullify = true; if (f.defaultValue != null) val = f.defaultValue; } } points[k + m] = val; } } if (nullify) { for (m = 0; m < ps; ++m) { val = points[k + m]; if (val != null) { f = format[m]; // extract min/max info if (f.computeRange) { if (f.x) { updateAxis(s.xaxis, val, val); } if (f.y) { updateAxis(s.yaxis, val, val); } } } points[k + m] = null; } } } points.length = k; //trims the internal buffer to the correct length } // give the hooks a chance to run for (i = 0; i < series.length; ++i) { s = series[i]; executeHooks(hooks.processDatapoints, [s, s.datapoints]); } // second pass: find datamax/datamin for auto-scaling for (i = 0; i < series.length; ++i) { s = series[i]; format = s.datapoints.format; if (format.every(function (f) { return !f.computeRange; })) { continue; } var range = plot.adjustSeriesDataRange(s, plot.computeRangeForDataSeries(s)); executeHooks(hooks.adjustSeriesDataRange, [s, range]); updateAxis(s.xaxis, range.xmin, range.xmax); updateAxis(s.yaxis, range.ymin, range.ymax); } $.each(allAxes(), function(_, axis) { if (axis.datamin === topSentry) { axis.datamin = null; } if (axis.datamax === bottomSentry) { axis.datamax = null; } }); } function setupCanvases() { // Make sure the placeholder is clear of everything except canvases // from a previous plot in this container that we'll try to re-use. placeholder.css("padding", 0) // padding messes up the positioning .children().filter(function() { return !$(this).hasClass("flot-overlay") && !$(this).hasClass('flot-base'); }).remove(); if (placeholder.css("position") === 'static') { placeholder.css("position", "relative"); // for positioning labels and overlay } surface = new Canvas("flot-base", placeholder[0]); overlay = new Canvas("flot-overlay", placeholder[0]); // overlay canvas for interactive features ctx = surface.context; octx = overlay.context; // define which element we're listening for events on eventHolder = $(overlay.element).unbind(); // If we're re-using a plot object, shut down the old one var existing = placeholder.data("plot"); if (existing) { existing.shutdown(); overlay.clear(); } // save in case we get replotted placeholder.data("plot", plot); } function bindEvents() { executeHooks(hooks.bindEvents, [eventHolder]); } function addEventHandler(event, handler, eventHolder, priority) { var key = eventHolder + event; var eventList = eventManager[key] || []; eventList.push({"event": event, "handler": handler, "eventHolder": eventHolder, "priority": priority}); eventList.sort((a, b) => b.priority - a.priority); eventList.forEach(eventData => { eventData.eventHolder.unbind(eventData.event, eventData.handler); eventData.eventHolder.bind(eventData.event, eventData.handler); }); eventManager[key] = eventList; } function shutdown() { if (redrawTimeout) { clearTimeout(redrawTimeout); } executeHooks(hooks.shutdown, [eventHolder]); } function setTransformationHelpers(axis) { // set helper functions on the axis, assumes plot area // has been computed already function identity(x) { return x; } var s, m, t = axis.options.transform || identity, it = axis.options.inverseTransform; // precompute how much the axis is scaling a point // in canvas space if (axis.direction === "x") { if (isFinite(t(axis.max) - t(axis.min))) { s = axis.scale = plotWidth / Math.abs(t(axis.max) - t(axis.min)); } else { s = axis.scale = 1 / Math.abs($.plot.saturated.delta(t(axis.min), t(axis.max), plotWidth)); } m = Math.min(t(axis.max), t(axis.min)); } else { if (isFinite(t(axis.max) - t(axis.min))) { s = axis.scale = plotHeight / Math.abs(t(axis.max) - t(axis.min)); } else { s = axis.scale = 1 / Math.abs($.plot.saturated.delta(t(axis.min), t(axis.max), plotHeight)); } s = -s; m = Math.max(t(axis.max), t(axis.min)); } // data point to canvas coordinate if (t === identity) { // slight optimization axis.p2c = function(p) { if (isFinite(p - m)) { return (p - m) * s; } else { return (p / 4 - m / 4) * s * 4; } }; } else { axis.p2c = function(p) { var tp = t(p); if (isFinite(tp - m)) { return (tp - m) * s; } else { return (tp / 4 - m / 4) * s * 4; } }; } // canvas coordinate to data point if (!it) { axis.c2p = function(c) { return m + c / s; }; } else { axis.c2p = function(c) { return it(m + c / s); }; } } function measureTickLabels(axis) { var opts = axis.options, ticks = opts.showTickLabels !== 'none' && axis.ticks ? axis.ticks : [], showMajorTickLabels = opts.showTickLabels === 'major' || opts.showTickLabels === 'all', showEndpointsTickLabels = opts.showTickLabels === 'endpoints' || opts.showTickLabels === 'all', labelWidth = opts.labelWidth || 0, labelHeight = opts.labelHeight || 0, legacyStyles = axis.direction + "Axis " + axis.direction + axis.n + "Axis", layer = "flot-" + axis.direction + "-axis flot-" + axis.direction + axis.n + "-axis " + legacyStyles, font = opts.font || "flot-tick-label tickLabel"; for (var i = 0; i < ticks.length; ++i) { var t = ticks[i]; var label = t.label; if (!t.label || (showMajorTickLabels === false && i > 0 && i < ticks.length - 1) || (showEndpointsTickLabels === false && (i === 0 || i === ticks.length - 1))) { continue; } if (typeof t.label === 'object') { label = t.label.name; } var info = surface.getTextInfo(layer, label, font); labelWidth = Math.max(labelWidth, info.width); labelHeight = Math.max(labelHeight, info.height); } axis.labelWidth = opts.labelWidth || labelWidth; axis.labelHeight = opts.labelHeight || labelHeight; } function allocateAxisBoxFirstPhase(axis) { // find the bounding box of the axis by looking at label // widths/heights and ticks, make room by diminishing the // plotOffset; this first phase only looks at one // dimension per axis, the other dimension depends on the // other axes so will have to wait // here reserve additional space executeHooks(hooks.axisReserveSpace, [axis]); var lw = axis.labelWidth, lh = axis.labelHeight, pos = axis.options.position, isXAxis = axis.direction === "x", tickLength = axis.options.tickLength, showTicks = axis.options.showTicks, showMinorTicks = axis.options.showMinorTicks, gridLines = axis.options.gridLines, axisMargin = options.grid.axisMargin, padding = options.grid.labelMargin, innermost = true, outermost = true, found = false; // Determine the axis's position in its direction and on its side $.each(isXAxis ? xaxes : yaxes, function(i, a) { if (a && (a.show || a.reserveSpace)) { if (a === axis) { found = true; } else if (a.options.position === pos) { if (found) { outermost = false; } else { innermost = false; } } } }); // The outermost axis on each side has no margin if (outermost) { axisMargin = 0; } // Set the default tickLength if necessary if (tickLength == null) { tickLength = TICK_LENGTH_CONSTANT; } // By default, major tick marks are visible if (showTicks == null) { showTicks = true; } // By default, minor tick marks are visible if (showMinorTicks == null) { showMinorTicks = true; } // By default, grid lines are visible if (gridLines == null) { if (innermost) { gridLines = true; } else { gridLines = false; } } if (!isNaN(+tickLength)) { padding += showTicks ? +tickLength : 0; } if (isXAxis) { lh += padding; if (pos === "bottom") { plotOffset.bottom += lh + axisMargin; axis.box = { top: surface.height - plotOffset.bottom, height: lh }; } else { axis.box = { top: plotOffset.top + axisMargin, height: lh }; plotOffset.top += lh + axisMargin; } } else { lw += padding; if (pos === "left") { axis.box = { left: plotOffset.left + axisMargin, width: lw }; plotOffset.left += lw + axisMargin; } else { plotOffset.right += lw + axisMargin; axis.box = { left: surface.width - plotOffset.right, width: lw }; } } // save for future reference axis.position = pos; axis.tickLength = tickLength; axis.showMinorTicks = showMinorTicks; axis.showTicks = showTicks; axis.gridLines = gridLines; axis.box.padding = padding; axis.innermost = innermost; } function allocateAxisBoxSecondPhase(axis) { // now that all axis boxes have been placed in one // dimension, we can set the remaining dimension coordinates if (axis.direction === "x") { axis.box.left = plotOffset.left - axis.labelWidth / 2; axis.box.width = surface.width - plotOffset.left - plotOffset.right + axis.labelWidth; } else { axis.box.top = plotOffset.top - axis.labelHeight / 2; axis.box.height = surface.height - plotOffset.bottom - plotOffset.top + axis.labelHeight; } } function adjustLayoutForThingsStickingOut() { // possibly adjust plot offset to ensure everything stays // inside the canvas and isn't clipped off var minMargin = options.grid.minBorderMargin, i; // check stuff from the plot (FIXME: this should just read // a value from the series, otherwise it's impossible to // customize) if (minMargin == null) { minMargin = 0; for (i = 0; i < series.length; ++i) { minMargin = Math.max(minMargin, 2 * (series[i].points.radius + series[i].points.lineWidth / 2)); } } var a, offset = {}, margins = { left: minMargin, right: minMargin, top: minMargin, bottom: minMargin }; // check axis labels, note we don't check the actual // labels but instead use the overall width/height to not // jump as much around with replots $.each(allAxes(), function(_, axis) { if (axis.reserveSpace && axis.ticks && axis.ticks.length) { if (axis.direction === "x") { margins.left = Math.max(margins.left, axis.labelWidth / 2); margins.right = Math.max(margins.right, axis.labelWidth / 2); } else { margins.bottom = Math.max(margins.bottom, axis.labelHeight / 2); margins.top = Math.max(margins.top, axis.labelHeight / 2); } } }); for (a in margins) { offset[a] = margins[a] - plotOffset[a]; } $.each(xaxes.concat(yaxes), function(_, axis) { alignAxisWithGrid(axis, offset, function (offset) { return offset > 0; }); }); plotOffset.left = Math.ceil(Math.max(margins.left, plotOffset.left)); plotOffset.right = Math.ceil(Math.max(margins.right, plotOffset.right)); plotOffset.top = Math.ceil(Math.max(margins.top, plotOffset.top)); plotOffset.bottom = Math.ceil(Math.max(margins.bottom, plotOffset.bottom)); } function alignAxisWithGrid(axis, offset, isValid) { if (axis.direction === "x") { if (axis.position === "bottom" && isValid(offset.bottom)) { axis.box.top -= Math.ceil(offset.bottom); } if (axis.position === "top" && isValid(offset.top)) { axis.box.top += Math.ceil(offset.top); } } else { if (axis.position === "left" && isValid(offset.left)) { axis.box.left += Math.ceil(offset.left); } if (axis.position === "right" && isValid(offset.right)) { axis.box.left -= Math.ceil(offset.right); } } } function setupGrid(autoScale) { var i, a, axes = allAxes(), showGrid = options.grid.show; // Initialize the plot's offset from the edge of the canvas for (a in plotOffset) { plotOffset[a] = 0; } executeHooks(hooks.processOffset, [plotOffset]); // If the grid is visible, add its border width to the offset for (a in plotOffset) { if (typeof (options.grid.borderWidth) === "object") { plotOffset[a] += showGrid ? options.grid.borderWidth[a] : 0; } else { plotOffset[a] += showGrid ? options.grid.borderWidth : 0; } } $.each(axes, function(_, axis) { var axisOpts = axis.options; axis.show = axisOpts.show == null ? axis.used : axisOpts.show; axis.reserveSpace = axisOpts.reserveSpace == null ? axis.show : axisOpts.reserveSpace; setupTickFormatter(axis); executeHooks(hooks.setRange, [axis, autoScale]); setRange(axis, autoScale); }); if (showGrid) { plotWidth = surface.width - plotOffset.left - plotOffset.right; plotHeight = surface.height - plotOffset.bottom - plotOffset.top; var allocatedAxes = $.grep(axes, function(axis) { return axis.show || axis.reserveSpace; }); $.each(allocatedAxes, function(_, axis) { // make the ticks setupTickGeneration(axis); setMajorTicks(axis); snapRangeToTicks(axis, axis.ticks, series); //for computing the endpoints precision, transformationHelpers are needed setTransformationHelpers(axis); setEndpointTicks(axis, series); // find labelWidth/Height for axis measureTickLabels(axis); }); // with all dimensions calculated, we can compute the // axis bounding boxes, start from the outside // (reverse order) for (i = allocatedAxes.length - 1; i >= 0; --i) { allocateAxisBoxFirstPhase(allocatedAxes[i]); } // make sure we've got enough space for things that // might stick out adjustLayoutForThingsStickingOut(); $.each(allocatedAxes, function(_, axis) { allocateAxisBoxSecondPhase(axis); }); } //adjust axis and plotOffset according to grid.margins if (options.grid.margin) { for (a in plotOffset) { var margin = options.grid.margin || 0; plotOffset[a] += typeof margin === "number" ? margin : (margin[a] || 0); } $.each(xaxes.concat(yaxes), function(_, axis) { alignAxisWithGrid(axis, options.grid.margin, function(offset) { return offset !== undefined && offset !== null; }); }); } //after adjusting the axis, plot width and height will be modified plotWidth = surface.width - plotOffset.left - plotOffset.right; plotHeight = surface.height - plotOffset.bottom - plotOffset.top; // now we got the proper plot dimensions, we can compute the scaling $.each(axes, function(_, axis) { setTransformationHelpers(axis); }); if (showGrid) { drawAxisLabels(); } executeHooks(hooks.setupGrid, []); } function widenMinMax(minimum, maximum) { var min = (minimum === undefined ? null : minimum); var max = (maximum === undefined ? null : maximum); var delta = max - min; if (delta === 0.0) { // degenerate case var widen = max === 0 ? 1 : 0.01; var wmin = null; if (min == null) { wmin -= widen; } // always widen max if we couldn't widen min to ensure we // don't fall into min == max which doesn't work if (max == null || min != null) { max += widen; } if (wmin != null) { min = wmin; } } return { min: min, max: max }; } function autoScaleAxis(axis) { var opts = axis.options, min = opts.min, max = opts.max, datamin = axis.datamin, datamax = axis.datamax, delta; switch (opts.autoScale) { case "none": min = +(opts.min != null ? opts.min : datamin); max = +(opts.max != null ? opts.max : datamax); break; case "loose": if (datamin != null && datamax != null) { min = datamin; max = datamax; delta = $.plot.saturated.saturate(max - min); var margin = ((typeof opts.autoScaleMargin === 'number') ? opts.autoScaleMargin : 0.02); min = $.plot.saturated.saturate(min - delta * margin); max = $.plot.saturated.saturate(max + delta * margin); // make sure we don't go below zero if all values are positive if (min < 0 && datamin >= 0) { min = 0; } } else { min = opts.min; max = opts.max; } break; case "exact": min = (datamin != null ? datamin : opts.min); max = (datamax != null ? datamax : opts.max); break; case "sliding-window": if (datamax > max) { // move the window to fit the new data, // keeping the axis range constant max = datamax; min = Math.max(datamax - (opts.windowSize || 100), min); } break; } var widenedMinMax = widenMinMax(min, max); min = widenedMinMax.min; max = widenedMinMax.max; // grow loose or grow exact supported if (opts.growOnly === true && opts.autoScale !== "none" && opts.autoScale !== "sliding-window") { min = (min < datamin) ? min : (datamin !== null ? datamin : min); max = (max > datamax) ? max : (datamax !== null ? datamax : max); } axis.autoScaledMin = min; axis.autoScaledMax = max; } function setRange(axis, autoScale) { var min = typeof axis.options.min === 'number' ? axis.options.min : axis.min, max = typeof axis.options.max === 'number' ? axis.options.max : axis.max, plotOffset = axis.options.offset; if (autoScale) { autoScaleAxis(axis); min = axis.autoScaledMin; max = axis.autoScaledMax; } min = (min != null ? min : -1) + (plotOffset.below || 0); max = (max != null ? max : 1) + (plotOffset.above || 0); if (min > max) { var tmp = min; min = max; max = tmp; axis.options.offset = { above: 0, below: 0 }; } axis.min = $.plot.saturated.saturate(min); axis.max = $.plot.saturated.saturate(max); } function computeValuePrecision (min, max, direction, ticks, tickDecimals) { var noTicks = fixupNumberOfTicks(direction, surface, ticks); var delta = $.plot.saturated.delta(min, max, noTicks), dec = -Math.floor(Math.log(delta) / Math.LN10); //if it is called with tickDecimals, then the precision should not be greather then that if (tickDecimals && dec > tickDecimals) { dec = tickDecimals; } var magn = parseFloat('1e' + (-dec)), norm = delta / magn; if (norm > 2.25 && norm < 3 && (dec + 1) <= tickDecimals) { //we need an extra decimals when tickSize is 2.5 ++dec; } return isFinite(dec) ? dec : 0; }; function computeTickSize (min, max, noTicks, tickDecimals) { var delta = $.plot.saturated.delta(min, max, noTicks), dec = -Math.floor(Math.log(delta) / Math.LN10); //if it is called with tickDecimals, then the precision should not be greather then that if (tickDecimals && dec > tickDecimals) { dec = tickDecimals; } var magn = parseFloat('1e' + (-dec)), norm = delta / magn, // norm is between 1.0 and 10.0 size; if (norm < 1.5) { size = 1; } else if (norm < 3) { size = 2; if (norm > 2.25 && (tickDecimals == null || (dec + 1) <= tickDecimals)) { size = 2.5; } } else if (norm < 7.5) { size = 5; } else { size = 10; } size *= magn; return size; } function getAxisTickSize(min, max, direction, options, tickDecimals) { var noTicks; if (typeof options.ticks === "number" && options.ticks > 0) { noTicks = options.ticks; } else { // heuristic based on the model a*sqrt(x) fitted to // some data points that seemed reasonable noTicks = 0.3 * Math.sqrt(direction === "x" ? surface.width : surface.height); } var size = computeTickSize(min, max, noTicks, tickDecimals); if (options.minTickSize != null && size < options.minTickSize) { size = options.minTickSize; } return options.tickSize || size; }; function fixupNumberOfTicks(direction, surface, ticksOption) { var noTicks; if (typeof ticksOption === "number" && ticksOption > 0) { noTicks = ticksOption; } else { noTicks = 0.3 * Math.sqrt(direction === "x" ? surface.width : surface.height); } return noTicks; } function setupTickFormatter(axis) { var opts = axis.options; if (!axis.tickFormatter) { if (typeof opts.tickFormatter === 'function') { axis.tickFormatter = function() { var args = Array.prototype.slice.call(arguments); return "" + opts.tickFormatter.apply(null, args); }; } else { axis.tickFormatter = defaultTickFormatter; } } } function setupTickGeneration(axis) { var opts = axis.options; var noTicks; noTicks = fixupNumberOfTicks(axis.direction, surface, opts.ticks); axis.delta = $.plot.saturated.delta(axis.min, axis.max, noTicks); var precision = plot.computeValuePrecision(axis.min, axis.max, axis.direction, noTicks, opts.tickDecimals); axis.tickDecimals = Math.max(0, opts.tickDecimals != null ? opts.tickDecimals : precision); axis.tickSize = getAxisTickSize(axis.min, axis.max, axis.direction, opts, opts.tickDecimals); // Flot supports base-10 axes; any other mode else is handled by a plug-in, // like flot.time.js. if (!axis.tickGenerator) { if (typeof opts.tickGenerator === 'function') { axis.tickGenerator = opts.tickGenerator; } else { axis.tickGenerator = defaultTickGenerator; } } if (opts.alignTicksWithAxis != null) { var otherAxis = (axis.direction === "x" ? xaxes : yaxes)[opts.alignTicksWithAxis - 1]; if (otherAxis && otherAxis.used && otherAxis !== axis) { // consider snapping min/max to outermost nice ticks var niceTicks = axis.tickGenerator(axis, plot); if (niceTicks.length > 0) { if (opts.min == null) { axis.min = Math.min(axis.min, niceTicks[0]); } if (opts.max == null && niceTicks.length > 1) { axis.max = Math.max(axis.max, niceTicks[niceTicks.length - 1]); } } axis.tickGenerator = function(axis) { // copy ticks, scaled to this axis var ticks = [], v, i; for (i = 0; i < otherAxis.ticks.length; ++i) { v = (otherAxis.ticks[i].v - otherAxis.min) / (otherAxis.max - otherAxis.min); v = axis.min + v * (axis.max - axis.min); ticks.push(v); } return ticks; }; // we might need an extra decimal since forced // ticks don't necessarily fit naturally if (!axis.mode && opts.tickDecimals == null) { var extraDec = Math.max(0, -Math.floor(Math.log(axis.delta) / Math.LN10) + 1), ts = axis.tickGenerator(axis, plot); // only proceed if the tick interval rounded // with an extra decimal doesn't give us a // zero at end if (!(ts.length > 1 && /\..*0$/.test((ts[1] - ts[0]).toFixed(extraDec)))) { axis.tickDecimals = extraDec; } } } } } function setMajorTicks(axis) { var oticks = axis.options.ticks, ticks = []; if (oticks == null || (typeof oticks === "number" && oticks > 0)) { ticks = axis.tickGenerator(axis, plot); } else if (oticks) { if ($.isFunction(oticks)) { // generate the ticks ticks = oticks(axis); } else { ticks = oticks; } } // clean up/labelify the supplied ticks, copy them over var i, v; axis.ticks = []; for (i = 0; i < ticks.length; ++i) { var label = null; var t = ticks[i]; if (typeof t === "object") { v = +t[0]; if (t.length > 1) { label = t[1]; } } else { v = +t; } if (!isNaN(v)) { axis.ticks.push( newTick(v, label, axis, 'major')); } } } function newTick(v, label, axis, type) { if (label === null) { switch (type) { case 'min': case 'max': //improving the precision of endpoints var precision = getEndpointPrecision(v, axis); label = isFinite(precision) ? axis.tickFormatter(v, axis, precision, plot) : axis.tickFormatter(v, axis, precision, plot); break; case 'major': label = axis.tickFormatter(v, axis, undefined, plot); } } return { v: v, label: label }; } function snapRangeToTicks(axis, ticks, series) { var anyDataInSeries = function(series) { return series.some(e => e.datapoints.points.length > 0); } if (axis.options.autoScale === "loose" && ticks.length > 0 && anyDataInSeries(series)) { // snap to ticks axis.min = Math.min(axis.min, ticks[0].v); axis.max = Math.max(axis.max, ticks[ticks.length - 1].v); } } function getEndpointPrecision(value, axis) { var canvas1 = Math.floor(axis.p2c(value)), canvas2 = axis.direction === "x" ? canvas1 + 1 : canvas1 - 1, point1 = axis.c2p(canvas1), point2 = axis.c2p(canvas2), precision = computeValuePrecision(point1, point2, axis.direction, 1); return precision; } function setEndpointTicks(axis, series) { if (isValidEndpointTick(axis, series)) { axis.ticks.unshift(newTick(axis.min, null, axis, 'min')); axis.ticks.push(newTick(axis.max, null, axis, 'max')); } } function isValidEndpointTick(axis, series) { if (axis.options.showTickLabels === 'endpoints') { return true; } if (axis.options.showTickLabels === 'all') { var associatedSeries = series.filter(function(s) { return s.xaxis === axis; }), notAllBarSeries = associatedSeries.some(function(s) { return !s.bars.show; }); return associatedSeries.length === 0 || notAllBarSeries; } if (axis.options.showTickLabels === 'major' || axis.options.showTickLabels === 'none') { return false; } } function draw() { surface.clear(); executeHooks(hooks.drawBackground, [ctx]); var grid = options.grid; // draw background, if any if (grid.show && grid.backgroundColor) { drawBackground(); } if (grid.show && !grid.aboveData) { drawGrid(); } for (var i = 0; i < series.length; ++i) { executeHooks(hooks.drawSeries, [ctx, series[i], i, getColorOrGradient]); drawSeries(series[i]); } executeHooks(hooks.draw, [ctx]); if (grid.show && grid.aboveData) { drawGrid(); } surface.render(); // A draw implies that either the axes or data have changed, so we // should probably update the overlay highlights as well. triggerRedrawOverlay(); } function extractRange(ranges, coord) { var axis, from, to, key, axes = allAxes(); for (var i = 0; i < axes.length; ++i) { axis = axes[i]; if (axis.direction === coord) { key = coord + axis.n + "axis"; if (!ranges[key] && axis.n === 1) { // support x1axis as xaxis key = coord + "axis"; } if (ranges[key]) { from = ranges[key].from; to = ranges[key].to; break; } } } // backwards-compat stuff - to be removed in future if (!ranges[key]) { axis = coord === "x" ? xaxes[0] : yaxes[0]; from = ranges[coord + "1"]; to = ranges[coord + "2"]; } // auto-reverse as an added bonus if (from != null && to != null && from > to) { var tmp = from; from = to; to = tmp; } return { from: from, to: to, axis: axis }; } function drawBackground() { ctx.save(); ctx.translate(plotOffset.left, plotOffset.top); ctx.fillStyle = getColorOrGradient(options.grid.backgroundColor, plotHeight, 0, "rgba(255, 255, 255, 0)"); ctx.fillRect(0, 0, plotWidth, plotHeight); ctx.restore(); } function drawMarkings() { // draw markings var markings = options.grid.markings, axes; if (markings) { if ($.isFunction(markings)) { axes = plot.getAxes(); // xmin etc. is backwards compatibility, to be // removed in the future axes.xmin = axes.xaxis.min; axes.xmax = axes.xaxis.max; axes.ymin = axes.yaxis.min; axes.ymax = axes.yaxis.max; markings = markings(axes); } var i; for (i = 0; i < markings.length; ++i) { var m = markings[i], xrange = extractRange(m, "x"), yrange = extractRange(m, "y"); // fill in missing if (xrange.from == null) { xrange.from = xrange.axis.min; } if (xrange.to == null) { xrange.to = xrange.axis.max; } if (yrange.from == null) { yrange.from = yrange.axis.min; } if (yrange.to == null) { yrange.to = yrange.axis.max; } // clip if (xrange.to < xrange.axis.min || xrange.from > xrange.axis.max || yrange.to < yrange.axis.min || yrange.from > yrange.axis.max) { continue; } xrange.from = Math.max(xrange.from, xrange.axis.min); xrange.to = Math.min(xrange.to, xrange.axis.max); yrange.from = Math.max(yrange.from, yrange.axis.min); yrange.to = Math.min(yrange.to, yrange.axis.max); var xequal = xrange.from === xrange.to, yequal = yrange.from === yrange.to; if (xequal && yequal) { continue; } // then draw xrange.from = Math.floor(xrange.axis.p2c(xrange.from)); xrange.to = Math.floor(xrange.axis.p2c(xrange.to)); yrange.from = Math.floor(yrange.axis.p2c(yrange.from)); yrange.to = Math.floor(yrange.axis.p2c(yrange.to)); if (xequal || yequal) { var lineWidth = m.lineWidth || options.grid.markingsLineWidth, subPixel = lineWidth % 2 ? 0.5 : 0; ctx.beginPath(); ctx.strokeStyle = m.color || options.grid.markingsColor; ctx.lineWidth = lineWidth; if (xequal) { ctx.moveTo(xrange.to + subPixel, yrange.from); ctx.lineTo(xrange.to + subPixel, yrange.to); } else { ctx.moveTo(xrange.from, yrange.to + subPixel); ctx.lineTo(xrange.to, yrange.to + subPixel); } ctx.stroke(); } else { ctx.fillStyle = m.color || options.grid.markingsColor; ctx.fillRect(xrange.from, yrange.to, xrange.to - xrange.from, yrange.from - yrange.to); } } } } function findEdges(axis) { var box = axis.box, x = 0, y = 0; // find the edges if (axis.direction === "x") { x = 0; y = box.top - plotOffset.top + (axis.position === "top" ? box.height : 0); } else { y = 0; x = box.left - plotOffset.left + (axis.position === "left" ? box.width : 0) + axis.boxPosition.centerX; } return { x: x, y: y }; }; function alignPosition(lineWidth, pos) { return ((lineWidth % 2) !== 0) ? Math.floor(pos) + 0.5 : pos; }; function drawTickBar(axis) { ctx.lineWidth = 1; var edges = findEdges(axis), x = edges.x, y = edges.y; // draw tick bar if (axis.show) { var xoff = 0, yoff = 0; ctx.strokeStyle = axis.options.color; ctx.beginPath(); if (axis.direction === "x") { xoff = plotWidth + 1; } else { yoff = plotHeight + 1; } if (axis.direction === "x") { y = alignPosition(ctx.lineWidth, y); } else { x = alignPosition(ctx.lineWidth, x); } ctx.moveTo(x, y); ctx.lineTo(x + xoff, y + yoff); ctx.stroke(); } }; function drawTickMarks(axis) { var t = axis.tickLength, minorTicks = axis.showMinorTicks, minorTicksNr = MINOR_TICKS_COUNT_CONSTANT, edges = findEdges(axis), x = edges.x, y = edges.y, i = 0; // draw major tick marks ctx.strokeStyle = axis.options.color; ctx.beginPath(); for (i = 0; i < axis.ticks.length; ++i) { var v = axis.ticks[i].v, xoff = 0, yoff = 0, xminor = 0, yminor = 0, j; if (!isNaN(v) && v >= axis.min && v <= axis.max) { if (axis.direction === "x") { x = axis.p2c(v); yoff = t; if (axis.position === "top") { yoff = -yoff; } } else { y = axis.p2c(v); xoff = t; if (axis.position === "left") { xoff = -xoff; } } if (axis.direction === "x") { x = alignPosition(ctx.lineWidth, x); } else { y = alignPosition(ctx.lineWidth, y); } ctx.moveTo(x, y); ctx.lineTo(x + xoff, y + yoff); } //draw minor tick marks if (minorTicks === true && i < axis.ticks.length - 1) { var v1 = axis.ticks[i].v, v2 = axis.ticks[i + 1].v, step = (v2 - v1) / (minorTicksNr + 1); for (j = 1; j <= minorTicksNr; j++) { // compute minor tick position if (axis.direction === "x") { yminor = t / 2; // minor ticks are half length x = alignPosition(ctx.lineWidth, axis.p2c(v1 + j * step)) if (axis.position === "top") { yminor = -yminor; } // don't go over the plot borders if ((x < 0) || (x > plotWidth)) { continue; } } else { xminor = t / 2; // minor ticks are half length y = alignPosition(ctx.lineWidth, axis.p2c(v1 + j * step)); if (axis.position === "left") { xminor = -xminor; } // don't go over the plot borders if ((y < 0) || (y > plotHeight)) { continue; } } ctx.moveTo(x, y); ctx.lineTo(x + xminor, y + yminor); } } } ctx.stroke(); }; function drawGridLines(axis) { // check if the line will be overlapped with a border var overlappedWithBorder = function (value) { var bw = options.grid.borderWidth; return (((typeof bw === "object" && bw[axis.position] > 0) || bw > 0) && (value === axis.min || value === axis.max)); }; ctx.strokeStyle = options.grid.tickColor; ctx.beginPath(); var i; for (i = 0; i < axis.ticks.length; ++i) { var v = axis.ticks[i].v, xoff = 0, yoff = 0, x = 0, y = 0; if (isNaN(v) || v < axis.min || v > axis.max) continue; // skip those lying on the axes if we got a border if (overlappedWithBorder(v)) continue; if (axis.direction === "x") { x = axis.p2c(v); y = plotHeight; yoff = -plotHeight; } else { x = 0; y = axis.p2c(v); xoff = plotWidth; } if (axis.direction === "x") { x = alignPosition(ctx.lineWidth, x); } else { y = alignPosition(ctx.lineWidth, y); } ctx.moveTo(x, y); ctx.lineTo(x + xoff, y + yoff); } ctx.stroke(); }; function drawBorder() { // If either borderWidth or borderColor is an object, then draw the border // line by line instead of as one rectangle var bw = options.grid.borderWidth, bc = options.grid.borderColor; if (typeof bw === "object" || typeof bc === "object") { if (typeof bw !== "object") { bw = { top: bw, right: bw, bottom: bw, left: bw }; } if (typeof bc !== "object") { bc = { top: bc, right: bc, bottom: bc, left: bc }; } if (bw.top > 0) { ctx.strokeStyle = bc.top; ctx.lineWidth = bw.top; ctx.beginPath(); ctx.moveTo(0 - bw.left, 0 - bw.top / 2); ctx.lineTo(plotWidth, 0 - bw.top / 2); ctx.stroke(); } if (bw.right > 0) { ctx.strokeStyle = bc.right; ctx.lineWidth = bw.right; ctx.beginPath(); ctx.moveTo(plotWidth + bw.right / 2, 0 - bw.top); ctx.lineTo(plotWidth + bw.right / 2, plotHeight); ctx.stroke(); } if (bw.bottom > 0) { ctx.strokeStyle = bc.bottom; ctx.lineWidth = bw.bottom; ctx.beginPath(); ctx.moveTo(plotWidth + bw.right, plotHeight + bw.bottom / 2); ctx.lineTo(0, plotHeight + bw.bottom / 2); ctx.stroke(); } if (bw.left > 0) { ctx.strokeStyle = bc.left; ctx.lineWidth = bw.left; ctx.beginPath(); ctx.moveTo(0 - bw.left / 2, plotHeight + bw.bottom); ctx.lineTo(0 - bw.left / 2, 0); ctx.stroke(); } } else { ctx.lineWidth = bw; ctx.strokeStyle = options.grid.borderColor; ctx.strokeRect(-bw / 2, -bw / 2, plotWidth + bw, plotHeight + bw); } }; function drawGrid() { var axes, bw; ctx.save(); ctx.translate(plotOffset.left, plotOffset.top); drawMarkings(); axes = allAxes(); bw = options.grid.borderWidth; for (var j = 0; j < axes.length; ++j) { var axis = axes[j]; if (!axis.show) { continue; } drawTickBar(axis); if (axis.showTicks === true) { drawTickMarks(axis); } if (axis.gridLines === true) { drawGridLines(axis, bw); } } // draw border if (bw) { drawBorder(); } ctx.restore(); } function drawAxisLabels() { $.each(allAxes(), function(_, axis) { var box = axis.box, legacyStyles = axis.direction + "Axis " + axis.direction + axis.n + "Axis", layer = "flot-" + axis.direction + "-axis flot-" + axis.direction + axis.n + "-axis " + legacyStyles, font = axis.options.font || "flot-tick-label tickLabel", i, x, y, halign, valign, info, margin = 3, nullBox = {x: NaN, y: NaN, width: NaN, height: NaN}, newLabelBox, labelBoxes = [], overlapping = function(x11, y11, x12, y12, x21, y21, x22, y22) { return ((x11 <= x21 && x21 <= x12) || (x21 <= x11 && x11 <= x22)) && ((y11 <= y21 && y21 <= y12) || (y21 <= y11 && y11 <= y22)); }, overlapsOtherLabels = function(newLabelBox, previousLabelBoxes) { return previousLabelBoxes.some(function(labelBox) { return overlapping( newLabelBox.x, newLabelBox.y, newLabelBox.x + newLabelBox.width, newLabelBox.y + newLabelBox.height, labelBox.x, labelBox.y, labelBox.x + labelBox.width, labelBox.y + labelBox.height); }); }, drawAxisLabel = function (tick, labelBoxes) { if (!tick || !tick.label || tick.v < axis.min || tick.v > axis.max) { return nullBox; } info = surface.getTextInfo(layer, tick.label, font); if (axis.direction === "x") { halign = "center"; x = plotOffset.left + axis.p2c(tick.v); if (axis.position === "bottom") { y = box.top + box.padding - axis.boxPosition.centerY; } else { y = box.top + box.height - box.padding + axis.boxPosition.centerY; valign = "bottom"; } newLabelBox = {x: x - info.width / 2 - margin, y: y - margin, width: info.width + 2 * margin, height: info.height + 2 * margin}; } else { valign = "middle"; y = plotOffset.top + axis.p2c(tick.v); if (axis.position === "left") { x = box.left + box.width - box.padding - axis.boxPosition.centerX; halign = "right"; } else { x = box.left + box.padding + axis.boxPosition.centerX; } newLabelBox = {x: x - info.width / 2 - margin, y: y - margin, width: info.width + 2 * margin, height: info.height + 2 * margin}; } if (overlapsOtherLabels(newLabelBox, labelBoxes)) { return nullBox; } surface.addText(layer, x, y, tick.label, font, null, null, halign, valign); return newLabelBox; }; // Remove text before checking for axis.show and ticks.length; // otherwise plugins, like flot-tickrotor, that draw their own // tick labels will end up with both theirs and the defaults. surface.removeText(layer); executeHooks(hooks.drawAxis, [axis, surface]); if (!axis.show) { return; } switch (axis.options.showTickLabels) { case 'none': break; case 'endpoints': labelBoxes.push(drawAxisLabel(axis.ticks[0], labelBoxes)); labelBoxes.push(drawAxisLabel(axis.ticks[axis.ticks.length - 1], labelBoxes)); break; case 'major': labelBoxes.push(drawAxisLabel(axis.ticks[0], labelBoxes)); labelBoxes.push(drawAxisLabel(axis.ticks[axis.ticks.length - 1], labelBoxes)); for (i = 1; i < axis.ticks.length - 1; ++i) { labelBoxes.push(drawAxisLabel(axis.ticks[i], labelBoxes)); } break; case 'all': labelBoxes.push(drawAxisLabel(axis.ticks[0], [])); labelBoxes.push(drawAxisLabel(axis.ticks[axis.ticks.length - 1], labelBoxes)); for (i = 1; i < axis.ticks.length - 1; ++i) { labelBoxes.push(drawAxisLabel(axis.ticks[i], labelBoxes)); } break; } }); } function drawSeries(series) { if (series.lines.show) { $.plot.drawSeries.drawSeriesLines(series, ctx, plotOffset, plotWidth, plotHeight, plot.drawSymbol, getColorOrGradient); } if (series.bars.show) { $.plot.drawSeries.drawSeriesBars(series, ctx, plotOffset, plotWidth, plotHeight, plot.drawSymbol, getColorOrGradient); } if (series.points.show) { $.plot.drawSeries.drawSeriesPoints(series, ctx, plotOffset, plotWidth, plotHeight, plot.drawSymbol, getColorOrGradient); } } function computeRangeForDataSeries(series, force, isValid) { var points = series.datapoints.points, ps = series.datapoints.pointsize, format = series.datapoints.format, topSentry = Number.POSITIVE_INFINITY, bottomSentry = Number.NEGATIVE_INFINITY, range = { xmin: topSentry, ymin: topSentry, xmax: bottomSentry, ymax: bottomSentry }; for (var j = 0; j < points.length; j += ps) { if (points[j] === null) { continue; } if (typeof (isValid) === 'function' && !isValid(points[j])) { continue; } for (var m = 0; m < ps; ++m) { var val = points[j + m], f = format[m]; if (f === null || f === undefined) { continue; } if (typeof (isValid) === 'function' && !isValid(val)) { continue; } if ((!force && !f.computeRange) || val === Infinity || val === -Infinity) { continue; } if (f.x === true) { if (val < range.xmin) { range.xmin = val; } if (val > range.xmax) { range.xmax = val; } } if (f.y === true) { if (val < range.ymin) { range.ymin = val; } if (val > range.ymax) { range.ymax = val; } } } } return range; }; function adjustSeriesDataRange(series, range) { if (series.bars.show) { // make sure we got room for the bar on the dancing floor var delta; // update bar width if needed var useAbsoluteBarWidth = series.bars.barWidth[1]; if (series.datapoints && series.datapoints.points && !useAbsoluteBarWidth) { computeBarWidth(series); } var barWidth = series.bars.barWidth[0] || series.bars.barWidth; switch (series.bars.align) { case "left": delta = 0; break; case "right": delta = -barWidth; break; default: delta = -barWidth / 2; } if (series.bars.horizontal) { range.ymin += delta; range.ymax += delta + barWidth; } else { range.xmin += delta; range.xmax += delta + barWidth; } } if ((series.bars.show && series.bars.zero) || (series.lines.show && series.lines.zero)) { var ps = series.datapoints.pointsize; // make sure the 0 point is included in the computed y range when requested if (ps <= 2) { /*if ps > 0 the points were already taken into account for autoScale */ range.ymin = Math.min(0, range.ymin); range.ymax = Math.max(0, range.ymax); } } return range; }; function computeBarWidth(series) { var xValues = []; var pointsize = series.datapoints.pointsize, minDistance = Number.MAX_VALUE; if (series.datapoints.points.length <= pointsize) { minDistance = 1; } var start = series.bars.horizontal ? 1 : 0; for (let j = start; j < series.datapoints.points.length; j += pointsize) { if (isFinite(series.datapoints.points[j]) && series.datapoints.points[j] !== null) { xValues.push(series.datapoints.points[j]); } } function onlyUnique(value, index, self) { return self.indexOf(value) === index; } xValues = xValues.filter(onlyUnique); xValues.sort(function(a, b) { return a - b }); for (let j = 1; j < xValues.length; j++) { var distance = Math.abs(xValues[j] - xValues[j - 1]); if (distance < minDistance && isFinite(distance)) { minDistance = distance; } } if (typeof series.bars.barWidth === "number") { series.bars.barWidth = series.bars.barWidth * minDistance; } else { series.bars.barWidth[0] = series.bars.barWidth[0] * minDistance; } } function findNearbyItems(mouseX, mouseY, seriesFilter, radius, computeDistance) { var items = findItems(mouseX, mouseY, seriesFilter, radius, computeDistance); for (var i = 0; i < series.length; ++i) { if (seriesFilter(i)) { executeHooks(hooks.findNearbyItems, [mouseX, mouseY, series, i, radius, computeDistance, items]); } } return items.sort((a, b) => { if (b.distance === undefined) { return -1; } else if (a.distance === undefined && b.distance !== undefined) { return 1; } return a.distance - b.distance; }); } function findNearbyItem(mouseX, mouseY, seriesFilter, radius, computeDistance) { var items = findNearbyItems(mouseX, mouseY, seriesFilter, radius, computeDistance); return items[0] !== undefined ? items[0] : null; } // returns the data item the mouse is over/ the cursor is closest to, or null if none is found function findItems(mouseX, mouseY, seriesFilter, radius, computeDistance) { var i, foundItems = [], items = [], smallestDistance = radius * radius + 1; for (i = series.length - 1; i >= 0; --i) { if (!seriesFilter(i)) continue; var s = series[i]; if (!s.datapoints) return; var foundPoint = false; if (s.lines.show || s.points.show) { var found = findNearbyPoint(s, mouseX, mouseY, radius, computeDistance); if (found) { items.push({ seriesIndex: i, dataIndex: found.dataIndex, distance: found.distance }); foundPoint = true; } } if (s.bars.show && !foundPoint) { // no other point can be nearby var foundIndex = findNearbyBar(s, mouseX, mouseY); if (foundIndex >= 0) { items.push({ seriesIndex: i, dataIndex: foundIndex, distance: smallestDistance }); } } } for (i = 0; i < items.length; i++) { var seriesIndex = items[i].seriesIndex; var dataIndex = items[i].dataIndex; var itemDistance = items[i].distance; var ps = series[seriesIndex].datapoints.pointsize; foundItems.push({ datapoint: series[seriesIndex].datapoints.points.slice(dataIndex * ps, (dataIndex + 1) * ps), dataIndex: dataIndex, series: series[seriesIndex], seriesIndex: seriesIndex, distance: Math.sqrt(itemDistance) }); } return foundItems; } function findNearbyPoint (series, mouseX, mouseY, maxDistance, computeDistance) { var mx = series.xaxis.c2p(mouseX), my = series.yaxis.c2p(mouseY), maxx = maxDistance / series.xaxis.scale, maxy = maxDistance / series.yaxis.scale, points = series.datapoints.points, ps = series.datapoints.pointsize, smallestDistance = Number.POSITIVE_INFINITY; // with inverse transforms, we can't use the maxx/maxy // optimization, sadly if (series.xaxis.options.inverseTransform) { maxx = Number.MAX_VALUE; } if (series.yaxis.options.inverseTransform) { maxy = Number.MAX_VALUE; } var found = null; for (var j = 0; j < points.length; j += ps) { var x = points[j]; var y = points[j + 1]; if (x == null) { continue; } if (x - mx > maxx || x - mx < -maxx || y - my > maxy || y - my < -maxy) { continue; } // We have to calculate distances in pixels, not in // data units, because the scales of the axes may be different var dx = Math.abs(series.xaxis.p2c(x) - mouseX); var dy = Math.abs(series.yaxis.p2c(y) - mouseY); var dist = computeDistance ? computeDistance(dx, dy) : dx * dx + dy * dy; // use <= to ensure last point takes precedence // (last generally means on top of) if (dist < smallestDistance) { smallestDistance = dist; found = { dataIndex: j / ps, distance: dist }; } } return found; } function findNearbyBar (series, mouseX, mouseY) { var barLeft, barRight, barWidth = series.bars.barWidth[0] || series.bars.barWidth, mx = series.xaxis.c2p(mouseX), my = series.yaxis.c2p(mouseY), points = series.datapoints.points, ps = series.datapoints.pointsize; switch (series.bars.align) { case "left": barLeft = 0; break; case "right": barLeft = -barWidth; break; default: barLeft = -barWidth / 2; } barRight = barLeft + barWidth; var fillTowards = series.bars.fillTowards || 0; var defaultBottom = fillTowards > series.yaxis.min ? Math.min(series.yaxis.max, fillTowards) : series.yaxis.min; var foundIndex = -1; for (var j = 0; j < points.length; j += ps) { var x = points[j], y = points[j + 1]; if (x == null) { continue; } var bottom = ps === 3 ? points[j + 2] : defaultBottom; // for a bar graph, the cursor must be inside the bar if (series.bars.horizontal ? (mx <= Math.max(bottom, x) && mx >= Math.min(bottom, x) && my >= y + barLeft && my <= y + barRight) : (mx >= x + barLeft && mx <= x + barRight && my >= Math.min(bottom, y) && my <= Math.max(bottom, y))) { foundIndex = j / ps; } } return foundIndex; } function findNearbyInterpolationPoint(posX, posY, seriesFilter) { var i, j, dist, dx, dy, ps, item, smallestDistance = Number.MAX_VALUE; for (i = 0; i < series.length; ++i) { if (!seriesFilter(i)) { continue; } var points = series[i].datapoints.points; ps = series[i].datapoints.pointsize; // if the data is coming from positive -> negative, reverse the comparison const comparer = points[points.length - ps] < points[0] ? function (x1, x2) { return x1 > x2 } : function (x1, x2) { return x2 > x1 }; // do not interpolate outside the bounds of the data. if (comparer(posX, points[0])) { continue; } // Find the nearest points, x-wise for (j = ps; j < points.length; j += ps) { if (comparer(posX, points[j])) { break; } } // Now Interpolate var y, p1x = points[j - ps], p1y = points[j - ps + 1], p2x = points[j], p2y = points[j + 1]; if ((p1x === undefined) || (p2x === undefined) || (p1y === undefined) || (p2y === undefined)) { continue; } if (p1x === p2x) { y = p2y } else { y = p1y + (p2y - p1y) * (posX - p1x) / (p2x - p1x); } posY = y; dx = Math.abs(series[i].xaxis.p2c(p2x) - posX); dy = Math.abs(series[i].yaxis.p2c(p2y) - posY); dist = dx * dx + dy * dy; if (dist < smallestDistance) { smallestDistance = dist; item = [posX, posY, i, j]; } } if (item) { i = item[2]; j = item[3]; ps = series[i].datapoints.pointsize; points = series[i].datapoints.points; p1x = points[j - ps]; p1y = points[j - ps + 1]; p2x = points[j]; p2y = points[j + 1]; return { datapoint: [item[0], item[1]], leftPoint: [p1x, p1y], rightPoint: [p2x, p2y], seriesIndex: i }; } return null; } function triggerRedrawOverlay() { var t = options.interaction.redrawOverlayInterval; if (t === -1) { // skip event queue drawOverlay(); return; } if (!redrawTimeout) { redrawTimeout = setTimeout(function() { drawOverlay(plot); }, t); } } function drawOverlay(plot) { redrawTimeout = null; if (!octx) { return; } overlay.clear(); executeHooks(hooks.drawOverlay, [octx, overlay]); var event = new CustomEvent('onDrawingDone'); plot.getEventHolder().dispatchEvent(event); plot.getPlaceholder().trigger('drawingdone'); } function getColorOrGradient(spec, bottom, top, defaultColor) { if (typeof spec === "string") { return spec; } else { // assume this is a gradient spec; IE currently only // supports a simple vertical gradient properly, so that's // what we support too var gradient = ctx.createLinearGradient(0, top, 0, bottom); for (var i = 0, l = spec.colors.length; i < l; ++i) { var c = spec.colors[i]; if (typeof c !== "string") { var co = $.color.parse(defaultColor); if (c.brightness != null) { co = co.scale('rgb', c.brightness); } if (c.opacity != null) { co.a *= c.opacity; } c = co.toString(); } gradient.addColorStop(i / (l - 1), c); } return gradient; } } } // Add the plot function to the top level of the jQuery object $.plot = function(placeholder, data, options) { var plot = new Plot($(placeholder), data, options, $.plot.plugins); return plot; }; $.plot.version = "3.0.0"; $.plot.plugins = []; // Also add the plot function as a chainable property $.fn.plot = function(data, options) { return this.each(function() { $.plot(this, data, options); }); }; $.plot.linearTickGenerator = defaultTickGenerator; $.plot.defaultTickFormatter = defaultTickFormatter; $.plot.expRepTickFormatter = expRepTickFormatter; })(jQuery);