if (!this.attributes_.getForAxis("logscale", 'x')) {
return xRange[0] + (x - area.x) / area.w * (xRange[1] - xRange[0]);
} else {
- // TODO: remove duplicate code?
- // Computing the inverse of toDomCoord.
var pct = (x - area.x) / area.w;
-
- // Computing the inverse of toPercentXCoord. The function was arrived at with
- // the following steps:
- //
- // Original calcuation:
- // pct = (log(x) - log(xRange[0])) / (log(xRange[1]) - log(xRange[0])));
- //
- // Multiply both sides by the right-side demoninator.
- // pct * (log(xRange[1] - log(xRange[0]))) = log(x) - log(xRange[0])
- //
- // add log(xRange[0]) to both sides
- // log(xRange[0]) + (pct * (log(xRange[1]) - log(xRange[0])) = log(x);
- //
- // Swap both sides of the equation,
- // log(x) = log(xRange[0]) + (pct * (log(xRange[1]) - log(xRange[0]))
- //
- // Use both sides as the exponent in 10^exp and we're done.
- // x = 10 ^ (log(xRange[0]) + (pct * (log(xRange[1]) - log(xRange[0])))
- var logr0 = utils.log10(xRange[0]);
- var logr1 = utils.log10(xRange[1]);
- var exponent = logr0 + (pct * (logr1 - logr0));
- var value = Math.pow(utils.LOG_SCALE, exponent);
- return value;
+ return utils.logRangeFraction(xRange[0], xRange[1], pct);
}
};
} else {
// Computing the inverse of toDomCoord.
var pct = (y - area.y) / area.h;
-
- // Computing the inverse of toPercentYCoord. The function was arrived at with
- // the following steps:
- //
- // Original calcuation:
- // pct = (log(yRange[1]) - log(y)) / (log(yRange[1]) - log(yRange[0]));
- //
- // Multiply both sides by the right-side demoninator.
- // pct * (log(yRange[1]) - log(yRange[0])) = log(yRange[1]) - log(y);
- //
- // subtract log(yRange[1]) from both sides.
- // (pct * (log(yRange[1]) - log(yRange[0]))) - log(yRange[1]) = -log(y);
- //
- // and multiply both sides by -1.
- // log(yRange[1]) - (pct * (logr1 - log(yRange[0])) = log(y);
- //
- // Swap both sides of the equation,
- // log(y) = log(yRange[1]) - (pct * (log(yRange[1]) - log(yRange[0])));
- //
- // Use both sides as the exponent in 10^exp and we're done.
- // y = 10 ^ (log(yRange[1]) - (pct * (log(yRange[1]) - log(yRange[0]))));
- var logr0 = utils.log10(yRange[0]);
- var logr1 = utils.log10(yRange[1]);
- var exponent = logr1 - (pct * (logr1 - logr0));
- var value = Math.pow(utils.LOG_SCALE, exponent);
- return value;
+ // Note reversed yRange, y1 is on top with pct==0.
+ return utils.logRangeFraction(yRange[1], yRange[0], pct);
}
};
ctx.save();
for (i = 0; i < this.selPoints_.length; i++) {
var pt = this.selPoints_[i];
- if (!utils.isOK(pt.canvasy)) continue;
+ if (isNaN(pt.canvasy)) continue;
var circleSize = this.getNumericOption('highlightCircleSize', pt.name);
var callback = this.getFunctionOption("drawHighlightPointCallback", pt.name);
// for. If it is, just use it, otherwise search the array for a point
// in the proper place.
var setRow = row - this.getLeftBoundary_(setIdx);
- if (setRow < points.length && points[setRow].idx == row) {
+ if (setRow >= 0 && setRow < points.length && points[setRow].idx == row) {
var point = points[setRow];
if (point.yval !== null) this.selPoints_.push(point);
} else {
this.setIndexByName_ = {};
var labels = this.attr_("labels");
- if (labels.length > 0) {
- this.setIndexByName_[labels[0]] = 0;
- }
var dataIdx = 0;
for (var i = 1; i < points.length; i++) {
- this.setIndexByName_[labels[i]] = i;
if (!this.visibility()[i - 1]) continue;
this.layout_.addDataset(labels[i], points[i]);
this.datasetIndex_[i] = dataIdx++;
}
+ for (var i = 0; i < labels.length; i++) {
+ this.setIndexByName_[labels[i]] = i;
+ }
this.computeYAxisRanges_(extremes);
this.layout_.setYAxes(this.axes_);
}
}
- var maxAxisY, minAxisY;
- if (logscale) {
- if (ypadCompat) {
+ var maxAxisY = maxY, minAxisY = minY;
+ if (ypadCompat) {
+ if (logscale) {
maxAxisY = maxY + ypad * span;
minAxisY = minY;
} else {
- var logpad = Math.exp(Math.log(span) * ypad);
- maxAxisY = maxY * logpad;
- minAxisY = minY / logpad;
- }
- } else {
- maxAxisY = maxY + ypad * span;
- minAxisY = minY - ypad * span;
-
- // Backwards-compatible behavior: Move the span to start or end at zero if it's
- // close to zero, but not if avoidMinZero is set.
- if (ypadCompat && !this.getBooleanOption("avoidMinZero")) {
- if (minAxisY < 0 && minY >= 0) minAxisY = 0;
- if (maxAxisY > 0 && maxY <= 0) maxAxisY = 0;
+ maxAxisY = maxY + ypad * span;
+ minAxisY = minY - ypad * span;
+
+ // Backwards-compatible behavior: Move the span to start or end at zero if it's
+ // close to zero, but not if avoidMinZero is set.
+ if (!this.getBooleanOption("avoidMinZero")) {
+ if (minAxisY < 0 && minY >= 0) minAxisY = 0;
+ if (maxAxisY > 0 && maxY <= 0) maxAxisY = 0;
+ }
}
}
axis.extremeRange = [minAxisY, maxAxisY];
// This is a user-set value range for this axis.
var y0 = isNullUndefinedOrNaN(axis.valueRange[0]) ? axis.extremeRange[0] : axis.valueRange[0];
var y1 = isNullUndefinedOrNaN(axis.valueRange[1]) ? axis.extremeRange[1] : axis.valueRange[1];
- if (!ypadCompat) {
- if (axis.logscale) {
- var logpad = Math.exp(Math.log(span) * ypad);
- y0 *= logpad;
- y1 /= logpad;
- } else {
- span = y1 - y0;
- y0 -= span * ypad;
- y1 += span * ypad;
- }
- }
axis.computedValueRange = [y0, y1];
} else {
axis.computedValueRange = axis.extremeRange;
}
+ if (!axis.valueWindow && !ypadCompat) {
+ // When using yRangePad, adjust the upper/lower bounds to add
+ // padding unless the user has zoomed/panned the Y axis range.
+ if (logscale) {
+ y0 = axis.computedValueRange[0];
+ y1 = axis.computedValueRange[1];
+ var y0pct = ypad / (2 * ypad - 1);
+ var y1pct = (ypad - 1) / (2 * ypad - 1);
+ axis.computedValueRange[0] = utils.logRangeFraction(y0, y1, y0pct);
+ axis.computedValueRange[1] = utils.logRangeFraction(y0, y1, y1pct);
+ } else {
+ y0 = axis.computedValueRange[0];
+ y1 = axis.computedValueRange[1];
+ span = y1 - y0;
+ axis.computedValueRange[0] = y0 - span * ypad;
+ axis.computedValueRange[1] = y1 + span * ypad;
+ }
+ }
if (independentTicks) {