Commit 0647ee94 authored by SOLIMAN Sylvain's avatar SOLIMAN Sylvain

better images with jqplot and local JS/CSS

parent aa049705
# very much inspired form the example bash_kernel
# https://raw.githubusercontent.com/takluyver/bash_kernel/
import base64
import os
# TODO: add logo-64x64.png
def display_data_for_image(filename):
with open(filename, 'rb') as f:
......@@ -13,60 +13,58 @@ def display_data_for_image(filename):
if image_type == 'svg':
image_type = 'image/svg+xml'
image_data = image.decode('utf-8')
elif image_type == 'js':
elif image_type == 'csv':
image_type = 'text/html'
image = image.decode('utf-8')
# FIXME use local URLs and use mouse CSS
jsurl = 'http://www.gnuplot.info/demo_canvas'
jsid = filename[:-3]
lines = [line.split(',') for line in image.splitlines()]
labels = ', '.join(['"' + label + '"' for label in lines.pop(0)[1:]])
series = '[' + ', '.join([
'[' +
', '.join(['[' + lines[i][0] + ', ' + lines[i][j] + ']'
for i in range(len(lines))]) +
']' for j in range(1, len(lines[0]))]) + ']'
plotid = filename.split('.')[-2]
image_data = '''
<script src="{jsurl}/canvastext.js"></script>
<script src="{jsurl}/gnuplot_common.js"></script>
<script src="{jsurl}/gnuplot_dashedlines.js"></script>
<script src="{jsurl}/gnuplot_mouse.js"></script>
<script>'''.format(jsurl=jsurl) + image + '</script>'
image_data = image_data + '''
<canvas id="{jsid}" width=600 height=400
oncontextmenu="return false;"
onkeypress=gnuplot.do_hotkey()></canvas>
<table id="gnuplot_mousebox" class="mbunder">
<tr>
<td class="icon" style="padding: 0px;"
onclick="gnuplot.toggle_grid();"><img
src="{jsurl}/grid.png" id="gnuplot_grid_icon" alt="#"
title="toggle grid"></td>
<td class="icon" style="padding: 0px;"
onclick="gnuplot.unzoom();"><img
src="{jsurl}/previouszoom.png" id="gnuplot_unzoom_icon"
alt="unzoom" title="unzoom"></td>
<td class="icon" style="padding: 0px;"
onclick="gnuplot.rezoom();"><img
src="{jsurl}/nextzoom.png" id="gnuplot_rezoom_icon"
alt="rezoom" title="rezoom"></td>
<td class="icon" style="padding: 0px;"><a
href="{jsurl}/canvas_help.html"><img
src="{jsurl}/help.png" align=right alt="help"
title="help"></a></td>
'''.format(jsid=jsid, jsurl=jsurl)
for i in range(image.count('End {}_plot_'.format(jsid))):
image_data = image_data + '''
<td class="icon" style="padding: 0px;"
onclick='gnuplot.toggle_plot("{jsid}_plot_{nb}")'>{nb}</td>
'''.format(jsid=jsid, nb=i+1)
image_data = image_data + '''
<td class="mb0">x</td>
<td class="mb1"><span id="{jsid}_x">&nbsp;</span></td>
<td class="mb0">y</td>
<td class="mb1"><span id="{jsid}_y">&nbsp;</span></td>
</table>
<script>var cssNode = document.createElement('link');
cssNode.type = 'text/css';
cssNode.rel = 'stylesheet';
cssNode.href = '{jsurl}/gnuplot_mouse.css';
document.head.appendChild(cssNode);</script>
<script>var gnuplot_canvas = {jsid};
{jsid}();</script>
'''.format(jsid=jsid, jsurl=jsurl)
<div id="{plotid}" style="height: 400px; width: 600px;"></div>
<script>
function waitForJQplot() {{
if (typeof $.jqplot !== 'undefined') {{
$.jqplot.config.enablePlugins = true;
$.jqplot('{plotid}', {data}, {{
seriesDefaults: {{
showMarker: false
}},
legend: {{
show: true,
placement: "outside",
labels: [{labels}],
renderer: $.jqplot.EnhancedLegendRenderer,
rendererOptions: {{
seriesToggle: true,
showLineStyle: true
}}
}},
cursor: {{
show: true,
zoom: true,
tooltipFormatString: "%.2e, %.2e",
cursorLegendFormatString: "%.2e, %.2e"
}},
highlighter: {{
formatString: "%.2e"
}}
}});
$('#{plotid}').contextmenu(function() {{
$('#{plotid}').jqplotSaveImage();
return false;
}});
}} else {{ window.setTimeout(waitForJQplot, 250); }}
}}
$(document).ready(function(){{
waitForJQplot();
}});
</script>
'''.format(plotid=plotid, data=series, labels=labels)
else:
image_type = 'image/' + image_type
image_data = base64.b64encode(image).decode('ascii')
......
/**
* jqPlot
* Pure JavaScript plotting plugin using jQuery
*
* Version: 1.0.9
* Revision: d96a669
*
* Copyright (c) 2009-2016 Chris Leonello
* jqPlot is currently available for use in all personal or commercial projects
* under both the MIT (http://www.opensource.org/licenses/mit-license.php) and GPL
* version 2.0 (http://www.gnu.org/licenses/gpl-2.0.html) licenses. This means that you can
* choose the license that best suits your project and use it accordingly.
*
* Although not required, the author would appreciate an email letting him
* know of any substantial use of jqPlot. You can reach the author at:
* chris at jqplot dot com or see http://www.jqplot.com/info.php .
*
* If you are feeling kind and generous, consider supporting the project by
* making a donation at: http://www.jqplot.com/donate.php .
*
* sprintf functions contained in jqplot.sprintf.js by Ash Searle:
*
* version 2007.04.27
* author Ash Searle
* http://hexmen.com/blog/2007/03/printf-sprintf/
* http://hexmen.com/js/sprintf.js
* The author (Ash Searle) has placed this code in the public domain:
* "This code is unrestricted: you are free to use it however you like."
*
*/
(function($) {
/**
* Class: $.jqplot.Cursor
* Plugin class representing the cursor as displayed on the plot.
*/
$.jqplot.Cursor = function(options) {
// Group: Properties
//
// prop: style
// CSS spec for cursor style
this.style = 'crosshair';
this.previousCursor = 'auto';
// prop: show
// whether to show the cursor or not.
this.show = $.jqplot.config.enablePlugins;
// prop: showTooltip
// show a cursor position tooltip. Location of the tooltip
// will be controlled by followMouse and tooltipLocation.
this.showTooltip = true;
// prop: followMouse
// Tooltip follows the mouse, it is not at a fixed location.
// Tooltip will show on the grid at the location given by
// tooltipLocation, offset from the grid edge by tooltipOffset.
this.followMouse = false;
// prop: tooltipLocation
// Where to position tooltip. If followMouse is true, this is
// relative to the cursor, otherwise, it is relative to the grid.
// One of 'n', 'ne', 'e', 'se', 's', 'sw', 'w', 'nw'
this.tooltipLocation = 'se';
// prop: tooltipOffset
// Pixel offset of tooltip from the grid boudaries or cursor center.
this.tooltipOffset = 6;
// prop: showTooltipGridPosition
// show the grid pixel coordinates of the mouse.
this.showTooltipGridPosition = false;
// prop: showTooltipUnitPosition
// show the unit (data) coordinates of the mouse.
this.showTooltipUnitPosition = true;
// prop: showTooltipDataPosition
// Used with showVerticalLine to show intersecting data points in the tooltip.
this.showTooltipDataPosition = false;
// prop: tooltipFormatString
// sprintf format string for the tooltip.
// Uses Ash Searle's javascript sprintf implementation
// found here: http://hexmen.com/blog/2007/03/printf-sprintf/
// See http://perldoc.perl.org/functions/sprintf.html for reference
// Note, if showTooltipDataPosition is true, the default tooltipFormatString
// will be set to the cursorLegendFormatString, not the default given here.
this.tooltipFormatString = '%.4P, %.4P';
// prop: useAxesFormatters
// Use the x and y axes formatters to format the text in the tooltip.
this.useAxesFormatters = true;
// prop: tooltipAxisGroups
// Show position for the specified axes.
// This is an array like [['xaxis', 'yaxis'], ['xaxis', 'y2axis']]
// Default is to compute automatically for all visible axes.
this.tooltipAxisGroups = [];
// prop: zoom
// Enable plot zooming.
this.zoom = false;
// zoomProxy and zoomTarget properties are not directly set by user.
// They Will be set through call to zoomProxy method.
this.zoomProxy = false;
this.zoomTarget = false;
// prop: looseZoom
// Will expand zoom range to provide more rounded tick values.
// Works only with linear, log and date axes.
this.looseZoom = true;
// prop: clickReset
// Will reset plot zoom if single click on plot without drag.
this.clickReset = false;
// prop: dblClickReset
// Will reset plot zoom if double click on plot without drag.
this.dblClickReset = true;
// prop: showVerticalLine
// draw a vertical line across the plot which follows the cursor.
// When the line is near a data point, a special legend and/or tooltip can
// be updated with the data values.
this.showVerticalLine = false;
// prop: showHorizontalLine
// draw a horizontal line across the plot which follows the cursor.
this.showHorizontalLine = false;
// prop: constrainZoomTo
// 'none', 'x' or 'y'
this.constrainZoomTo = 'none';
// // prop: autoscaleConstraint
// // when a constrained axis is specified, true will
// // auatoscale the adjacent axis.
// this.autoscaleConstraint = true;
this.shapeRenderer = new $.jqplot.ShapeRenderer();
this._zoom = {start:[], end:[], started: false, zooming:false, isZoomed:false, axes:{start:{}, end:{}}, gridpos:{}, datapos:{}};
this._tooltipElem;
this.zoomCanvas;
this.cursorCanvas;
// prop: intersectionThreshold
// pixel distance from data point or marker to consider cursor lines intersecting with point.
// If data point markers are not shown, this should be >= 1 or will often miss point intersections.
this.intersectionThreshold = 2;
// prop: showCursorLegend
// Replace the plot legend with an enhanced legend displaying intersection information.
this.showCursorLegend = false;
// prop: cursorLegendFormatString
// Format string used in the cursor legend. If showTooltipDataPosition is true,
// this will also be the default format string used by tooltipFormatString.
this.cursorLegendFormatString = $.jqplot.Cursor.cursorLegendFormatString;
// whether the cursor is over the grid or not.
this._oldHandlers = {onselectstart: null, ondrag: null, onmousedown: null};
// prop: constrainOutsideZoom
// True to limit actual zoom area to edges of grid, even when zooming
// outside of plot area. That is, can't zoom out by mousing outside plot.
this.constrainOutsideZoom = true;
// prop: showTooltipOutsideZoom
// True will keep updating the tooltip when zooming of the grid.
this.showTooltipOutsideZoom = false;
// true if mouse is over grid, false if not.
this.onGrid = false;
$.extend(true, this, options);
};
$.jqplot.Cursor.cursorLegendFormatString = '%s x:%s, y:%s';
// called with scope of plot
$.jqplot.Cursor.init = function (target, data, opts){
// add a cursor attribute to the plot
var options = opts || {};
this.plugins.cursor = new $.jqplot.Cursor(options.cursor);
var c = this.plugins.cursor;
if (c.show) {
$.jqplot.eventListenerHooks.push(['jqplotMouseEnter', handleMouseEnter]);
$.jqplot.eventListenerHooks.push(['jqplotMouseLeave', handleMouseLeave]);
$.jqplot.eventListenerHooks.push(['jqplotMouseMove', handleMouseMove]);
if (c.showCursorLegend) {
opts.legend = opts.legend || {};
opts.legend.renderer = $.jqplot.CursorLegendRenderer;
opts.legend.formatString = this.plugins.cursor.cursorLegendFormatString;
opts.legend.show = true;
}
if (c.zoom) {
$.jqplot.eventListenerHooks.push(['jqplotMouseDown', handleMouseDown]);
if (c.clickReset) {
$.jqplot.eventListenerHooks.push(['jqplotClick', handleClick]);
}
if (c.dblClickReset) {
$.jqplot.eventListenerHooks.push(['jqplotDblClick', handleDblClick]);
}
}
this.resetZoom = function() {
var axes = this.axes;
if (!c.zoomProxy) {
for (var ax in axes) {
axes[ax].reset();
axes[ax]._ticks = [];
// fake out tick creation algorithm to make sure original auto
// computed format string is used if _overrideFormatString is true
if (c._zoom.axes[ax] !== undefined) {
axes[ax]._autoFormatString = c._zoom.axes[ax].tickFormatString;
}
}
this.redraw();
}
else {
var ctx = this.plugins.cursor.zoomCanvas._ctx;
ctx.clearRect(0,0,ctx.canvas.width, ctx.canvas.height);
ctx = null;
}
this.plugins.cursor._zoom.isZoomed = false;
this.target.trigger('jqplotResetZoom', [this, this.plugins.cursor]);
};
if (c.showTooltipDataPosition) {
c.showTooltipUnitPosition = false;
c.showTooltipGridPosition = false;
if (options.cursor.tooltipFormatString == undefined) {
c.tooltipFormatString = $.jqplot.Cursor.cursorLegendFormatString;
}
}
}
};
// called with context of plot
$.jqplot.Cursor.postDraw = function() {
var c = this.plugins.cursor;
// Memory Leaks patch
if (c.zoomCanvas) {
c.zoomCanvas.resetCanvas();
c.zoomCanvas = null;
}
if (c.cursorCanvas) {
c.cursorCanvas.resetCanvas();
c.cursorCanvas = null;
}
if (c._tooltipElem) {
c._tooltipElem.emptyForce();
c._tooltipElem = null;
}
if (c.zoom) {
c.zoomCanvas = new $.jqplot.GenericCanvas();
this.eventCanvas._elem.before(c.zoomCanvas.createElement(this._gridPadding, 'jqplot-zoom-canvas', this._plotDimensions, this));
c.zoomCanvas.setContext();
}
var elem = document.createElement('div');
c._tooltipElem = $(elem);
elem = null;
c._tooltipElem.addClass('jqplot-cursor-tooltip');
c._tooltipElem.css({position:'absolute', display:'none'});
if (c.zoomCanvas) {
c.zoomCanvas._elem.before(c._tooltipElem);
}
else {
this.eventCanvas._elem.before(c._tooltipElem);
}
if (c.showVerticalLine || c.showHorizontalLine) {
c.cursorCanvas = new $.jqplot.GenericCanvas();
this.eventCanvas._elem.before(c.cursorCanvas.createElement(this._gridPadding, 'jqplot-cursor-canvas', this._plotDimensions, this));
c.cursorCanvas.setContext();
}
// if we are showing the positions in unit coordinates, and no axes groups
// were specified, create a default set.
if (c.showTooltipUnitPosition){
if (c.tooltipAxisGroups.length === 0) {
var series = this.series;
var s;
var temp = [];
for (var i=0; i<series.length; i++) {
s = series[i];
var ax = s.xaxis+','+s.yaxis;
if ($.inArray(ax, temp) == -1) {
temp.push(ax);
}
}
for (var i=0; i<temp.length; i++) {
c.tooltipAxisGroups.push(temp[i].split(','));
}
}
}
};
// Group: methods
//
// method: $.jqplot.Cursor.zoomProxy
// links targetPlot to controllerPlot so that plot zooming of
// targetPlot will be controlled by zooming on the controllerPlot.
// controllerPlot will not actually zoom, but acts as an
// overview plot. Note, the zoom options must be set to true for
// zoomProxy to work.
$.jqplot.Cursor.zoomProxy = function(targetPlot, controllerPlot) {
var tc = targetPlot.plugins.cursor;
var cc = controllerPlot.plugins.cursor;
tc.zoomTarget = true;
tc.zoom = true;
tc.style = 'auto';
tc.dblClickReset = false;
cc.zoom = true;
cc.zoomProxy = true;
controllerPlot.target.bind('jqplotZoom', plotZoom);
controllerPlot.target.bind('jqplotResetZoom', plotReset);
function plotZoom(ev, gridpos, datapos, plot, cursor) {
tc.doZoom(gridpos, datapos, targetPlot, cursor);
}
function plotReset(ev, plot, cursor) {
targetPlot.resetZoom();
}
};
$.jqplot.Cursor.prototype.resetZoom = function(plot, cursor) {
var axes = plot.axes;
var cax = cursor._zoom.axes;
if (!plot.plugins.cursor.zoomProxy && cursor._zoom.isZoomed) {
for (var ax in axes) {
// axes[ax]._ticks = [];
// axes[ax].min = cax[ax].min;
// axes[ax].max = cax[ax].max;
// axes[ax].numberTicks = cax[ax].numberTicks;
// axes[ax].tickInterval = cax[ax].tickInterval;
// // for date axes
// axes[ax].daTickInterval = cax[ax].daTickInterval;
axes[ax].reset();
axes[ax]._ticks = [];
// fake out tick creation algorithm to make sure original auto
// computed format string is used if _overrideFormatString is true
axes[ax]._autoFormatString = cax[ax].tickFormatString;
}
plot.redraw();
cursor._zoom.isZoomed = false;
}
else {
var ctx = cursor.zoomCanvas._ctx;
ctx.clearRect(0,0,ctx.canvas.width, ctx.canvas.height);
ctx = null;
}
plot.target.trigger('jqplotResetZoom', [plot, cursor]);
};
$.jqplot.Cursor.resetZoom = function(plot) {
plot.resetZoom();
};
$.jqplot.Cursor.prototype.doZoom = function (gridpos, datapos, plot, cursor) {
var c = cursor;
var axes = plot.axes;
var zaxes = c._zoom.axes;
var start = zaxes.start;
var end = zaxes.end;
var min, max, dp, span,
newmin, newmax, curax, _numberTicks, ret;
var ctx = plot.plugins.cursor.zoomCanvas._ctx;
// don't zoom if zoom area is too small (in pixels)
if ((c.constrainZoomTo == 'none' && Math.abs(gridpos.x - c._zoom.start[0]) > 6 && Math.abs(gridpos.y - c._zoom.start[1]) > 6) || (c.constrainZoomTo == 'x' && Math.abs(gridpos.x - c._zoom.start[0]) > 6) || (c.constrainZoomTo == 'y' && Math.abs(gridpos.y - c._zoom.start[1]) > 6)) {
if (!plot.plugins.cursor.zoomProxy) {
for (var ax in datapos) {
// make a copy of the original axes to revert back.
if (c._zoom.axes[ax] == undefined) {
c._zoom.axes[ax] = {};
c._zoom.axes[ax].numberTicks = axes[ax].numberTicks;
c._zoom.axes[ax].tickInterval = axes[ax].tickInterval;
// for date axes...
c._zoom.axes[ax].daTickInterval = axes[ax].daTickInterval;
c._zoom.axes[ax].min = axes[ax].min;
c._zoom.axes[ax].max = axes[ax].max;
c._zoom.axes[ax].tickFormatString = (axes[ax].tickOptions != null) ? axes[ax].tickOptions.formatString : '';
}
if ((c.constrainZoomTo == 'none') || (c.constrainZoomTo == 'x' && ax.charAt(0) == 'x') || (c.constrainZoomTo == 'y' && ax.charAt(0) == 'y')) {
dp = datapos[ax];
if (dp != null) {
if (dp > start[ax]) {
newmin = start[ax];
newmax = dp;
}
else {
span = start[ax] - dp;
newmin = dp;
newmax = start[ax];
}
curax = axes[ax];
_numberTicks = null;
// if aligning this axis, use number of ticks from previous axis.
// Do I need to reset somehow if alignTicks is changed and then graph is replotted??
if (curax.alignTicks) {
if (curax.name === 'x2axis' && plot.axes.xaxis.show) {
_numberTicks = plot.axes.xaxis.numberTicks;
}
else if (curax.name.charAt(0) === 'y' && curax.name !== 'yaxis' && curax.name !== 'yMidAxis' && plot.axes.yaxis.show) {
_numberTicks = plot.axes.yaxis.numberTicks;
}
}
if (this.looseZoom && (axes[ax].renderer.constructor === $.jqplot.LinearAxisRenderer || axes[ax].renderer.constructor === $.jqplot.LogAxisRenderer )) { //} || axes[ax].renderer.constructor === $.jqplot.DateAxisRenderer)) {
ret = $.jqplot.LinearTickGenerator(newmin, newmax, curax._scalefact, _numberTicks);
// if new minimum is less than "true" minimum of axis display, adjust it
if (axes[ax].tickInset && ret[0] < axes[ax].min + axes[ax].tickInset * axes[ax].tickInterval) {
ret[0] += ret[4];
ret[2] -= 1;
}
// if new maximum is greater than "true" max of axis display, adjust it
if (axes[ax].tickInset && ret[1] > axes[ax].max - axes[ax].tickInset * axes[ax].tickInterval) {
ret[1] -= ret[4];
ret[2] -= 1;
}
// for log axes, don't fall below current minimum, this will look bad and can't have 0 in range anyway.
if (axes[ax].renderer.constructor === $.jqplot.LogAxisRenderer && ret[0] < axes[ax].min) {
// remove a tick and shift min up
ret[0] += ret[4];
ret[2] -= 1;
}
axes[ax].min = ret[0];
axes[ax].max = ret[1];
axes[ax]._autoFormatString = ret[3];
axes[ax].numberTicks = ret[2];
axes[ax].tickInterval = ret[4];
// for date axes...
axes[ax].daTickInterval = [ret[4]/1000, 'seconds'];
}
else {
axes[ax].min = newmin;
axes[ax].max = newmax;
axes[ax].tickInterval = null;
axes[ax].numberTicks = null;
// for date axes...
axes[ax].daTickInterval = null;
}
axes[ax]._ticks = [];
}
}
// if ((c.constrainZoomTo == 'x' && ax.charAt(0) == 'y' && c.autoscaleConstraint) || (c.constrainZoomTo == 'y' && ax.charAt(0) == 'x' && c.autoscaleConstraint)) {
// dp = datapos[ax];
// if (dp != null) {
// axes[ax].max == null;
// axes[ax].min = null;
// }
// }
}
ctx.clearRect(0,0,ctx.canvas.width, ctx.canvas.height);
plot.redraw();
c._zoom.isZoomed = true;
ctx = null;
}
plot.target.trigger('jqplotZoom', [gridpos, datapos, plot, cursor]);
}
};
$.jqplot.preInitHooks.push($.jqplot.Cursor.init);
$.jqplot.postDrawHooks.push($.jqplot.Cursor.postDraw);
function updateTooltip(gridpos, datapos, plot) {
var c = plot.plugins.cursor;
var s = '';
var addbr = false;
if (c.showTooltipGridPosition) {
s = gridpos.x+', '+gridpos.y;
addbr = true;
}
if (c.showTooltipUnitPosition) {
var g;
for (var i=0; i<c.tooltipAxisGroups.length; i++) {
g = c.tooltipAxisGroups[i];
if (addbr) {
s += '<br />';
}
if (c.useAxesFormatters) {
for (var j=0; j<g.length; j++) {
if (j) {
s += ', ';
}
var af = plot.axes[g[j]]._ticks[0].formatter;
var afstr = plot.axes[g[j]]._ticks[0].formatString;
s += af(afstr, datapos[g[j]]);
}
}
else {
s += $.jqplot.sprintf(c.tooltipFormatString, datapos[g[0]], datapos[g[1]]);
}
addbr = true;
}
}
if (c.showTooltipDataPosition) {
var series = plot.series;
var ret = getIntersectingPoints(plot, gridpos.x, gridpos.y);
var addbr = false;
for (var i = 0; i< series.length; i++) {
if (series[i].show) {
var idx = series[i].index;
var label = series[i].label.toString();
var cellid = $.inArray(idx, ret.indices);
var sx = undefined;
var sy = undefined;
if (cellid != -1) {
var data = ret.data[cellid].data;
if (c.useAxesFormatters) {
var xf = series[i]._xaxis._ticks[0].formatter;
var yf = series[i]._yaxis._ticks[0].formatter;
var xfstr = series[i]._xaxis._ticks[0].formatString;
var yfstr = series[i]._yaxis._ticks[0].formatString;
sx = xf(xfstr, data[0]);
sy = yf(yfstr, data[1]);
}
else {
sx = data[0];
sy = data[1];
}
if (addbr) {
s += '<br />';
}
s += $.jqplot.sprintf(c.tooltipFormatString, label, sx, sy);
addbr = true;
}
}
}
}
c._tooltipElem.html(s);
}
function moveLine(gridpos, plot) {
var c = plot.plugins.cursor;
var ctx = c.cursorCanvas._ctx;
ctx.clearRect(0,0,ctx.canvas.width, ctx.canvas.height);
if (c.showVerticalLine) {
c.shapeRenderer.draw(ctx, [[gridpos.x, 0], [gridpos.x, ctx.canvas.height]]);
}
if (c.showHorizontalLine) {
c.shapeRenderer.draw(ctx, [[0, gridpos.y], [ctx.canvas.width, gridpos.y]]);
}
var ret = getIntersectingPoints(plot, gridpos.x, gridpos.y);
if (c.showCursorLegend) {
var cells = $(plot.targetId + ' td.jqplot-cursor-legend-label');
for (var i=0; i<cells.length; i++) {
var idx = $(cells[i]).data('seriesIndex');
var series = plot.series[idx];
var label = series.label.toString();
var cellid = $.inArray(idx, ret.indices);
var sx = undefined;
var sy = undefined;
if (cellid != -1) {
var data = ret.data[cellid].data;
if (c.useAxesFormatters) {
var xf = series._xaxis._ticks[0].formatter;
var yf = series._yaxis._ticks[0].formatter;
var xfstr = series._xaxis._ticks[0].formatString;
var yfstr = series._yaxis._ticks[0].formatString;
sx = xf(xfstr, data[0]);
sy = yf(yfstr, data[1]);
}
else {
sx = data[0];
sy = data[1];
}
}
if (plot.legend.escapeHtml) {
$(cells[i]).text($.jqplot.sprintf(c.cursorLegendFormatString, label, sx, sy));
}
else {
$(cells[i]).html($.jqplot.sprintf(c.cursorLegendFormatString, label, sx, sy));
}
}