/// <summary>
/// Add a <see cref="CurveItem"/> to the selection list.
/// </summary>
/// <param name="master">
/// The <see cref="MasterPane"/> that is the "owner" of the <see cref="CurveItem"/>'s.
/// </param>
/// <param name="ci">
/// The <see cref="CurveItem"/> to be added to the list.
/// </param>
public void AddToSelection(MasterPane master, CurveItem ci)
{
if (this.Contains(ci) == false)
{
this.Add(ci);
}
this.UpdateSelection(master);
}
/// <summary>
/// Find the data point that lies closest to the specified mouse (screen) point.
/// </summary>
/// <remarks>
/// This method will search through the specified list of curves to find which point is nearest. It will only consider points that are within
/// <see cref="Default.NearestTol"/> pixels of the screen point, and it will only consider <see cref="CurveItem"/>'s that are in
/// <paramref name="targetCurveList"/>.
/// </remarks>
/// <param name="mousePt">
/// The screen point, in pixel coordinates.
/// </param>
/// <param name="targetCurveList">
/// A <see cref="CurveList"/> object containing a subset of <see cref="CurveItem"/>'s to be searched.
/// </param>
/// <param name="nearestCurve">
/// A reference to the <see cref="CurveItem"/>
/// instance that contains the closest point. nearestCurve will be null if no data points are available.
/// </param>
/// <param name="iNearest">
/// The index number of the closest point. The actual data vpoint will then be <see cref="CurveItem.Points">CurveItem.Points[iNearest]</see>
/// . iNearest will be -1 if no data points are available.
/// </param>
/// <returns>
/// true if a point was found and that point lies within
/// <see cref="Default.NearestTol"/> pixels of the screen point, false otherwise.
/// </returns>
public bool FindNearestPoint(PointF mousePt, CurveList targetCurveList, out CurveItem nearestCurve, out int iNearest)
{
CurveItem nearestBar = null;
int iNearestBar = -1;
nearestCurve = null;
iNearest = -1;
// If the point is outside the ChartRect, always return false
if (!this._chart._rect.Contains(mousePt))
{
return false;
}
double x, x2;
double[] y;
double[] y2;
// ReverseTransform( mousePt, out x, out y, out y2 );
this.ReverseTransform(mousePt, out x, out x2, out y, out y2);
if (!this.AxisRangesValid())
{
return false;
}
ValueHandler valueHandler = new ValueHandler(this, false);
// double yPixPerUnit = chartRect.Height / ( yAxis.Max - yAxis.Min );
// double y2PixPerUnit; // = chartRect.Height / ( y2Axis.Max - y2Axis.Min );
double yPixPerUnitAct, yAct, yMinAct, yMaxAct, xAct;
double minDist = 1e20;
double xVal, yVal, dist = 99999, distX, distY;
double tolSquared = Default.NearestTol * Default.NearestTol;
int iBar = 0;
foreach (CurveItem curve in targetCurveList)
{
// test for pie first...if it's a pie rest of method superfluous
if (curve is PieItem && curve.IsVisible)
{
if (((PieItem)curve).SlicePath != null && ((PieItem)curve).SlicePath.IsVisible(mousePt))
{
nearestBar = curve;
iNearestBar = 0;
}
}
else if (curve.IsVisible)
{
int yIndex = curve.GetYAxisIndex(this);
Axis yAxis = curve.GetYAxis(this);
Axis xAxis = curve.GetXAxis(this);
if (curve.IsY2Axis)
{
yAct = y2[yIndex];
yMinAct = this._y2AxisList[yIndex]._scale._min;
yMaxAct = this._y2AxisList[yIndex]._scale._max;
}
else
{
yAct = y[yIndex];
yMinAct = this._yAxisList[yIndex]._scale._min;
yMaxAct = this._yAxisList[yIndex]._scale._max;
}
yPixPerUnitAct = this._chart._rect.Height / (yMaxAct - yMinAct);
double xPixPerUnit = this._chart._rect.Width / (xAxis._scale._max - xAxis._scale._min);
xAct = xAxis is XAxis ? x : x2;
IPointList points = curve.Points;
float barWidth = curve.GetBarWidth(this);
double barWidthUserHalf;
Axis baseAxis = curve.BaseAxis(this);
bool isXBaseAxis = baseAxis is XAxis || baseAxis is X2Axis;
if (isXBaseAxis)
{
barWidthUserHalf = barWidth / xPixPerUnit / 2.0;
}
else
{
barWidthUserHalf = barWidth / yPixPerUnitAct / 2.0;
}
if (points != null)
{
for (int iPt = 0; iPt < curve.NPts; iPt++)
{
// xVal is the user scale X value of the current point
if (xAxis._scale.IsAnyOrdinal && !curve.IsOverrideOrdinal)
{
xVal = iPt + 1.0;
}
else
{
xVal = points[iPt].X;
}
// yVal is the user scale Y value of the current point
if (yAxis._scale.IsAnyOrdinal && !curve.IsOverrideOrdinal)
{
yVal = iPt + 1.0;
}
else
{
yVal = points[iPt].Y;
}
if (xVal != PointPairBase.Missing && yVal != PointPairBase.Missing)
{
if (curve.IsBar || curve is ErrorBarItem || curve is HiLowBarItem || curve is OHLCBarItem
|| curve is JapaneseCandleStickItem)
{
double baseVal, lowVal, hiVal;
valueHandler.GetValues(curve, iPt, out baseVal, out lowVal, out hiVal);
if (lowVal > hiVal)
{
double tmpVal = lowVal;
lowVal = hiVal;
hiVal = tmpVal;
}
if (isXBaseAxis)
{
double centerVal = valueHandler.BarCenterValue(curve, barWidth, iPt, xVal, iBar);
if (xAct < centerVal - barWidthUserHalf || xAct > centerVal + barWidthUserHalf || yAct < lowVal
|| yAct > hiVal)
{
continue;
}
}
else
{
double centerVal = valueHandler.BarCenterValue(curve, barWidth, iPt, yVal, iBar);
if (yAct < centerVal - barWidthUserHalf || yAct > centerVal + barWidthUserHalf || xAct < lowVal
|| xAct > hiVal)
{
continue;
}
}
if (nearestBar == null)
{
iNearestBar = iPt;
nearestBar = curve;
}
}
else if (xVal >= xAxis._scale._min && xVal <= xAxis._scale._max && yVal >= yMinAct && yVal <= yMaxAct)
{
if (curve is LineItem && this._lineType == LineType.Stack)
{
double zVal;
valueHandler.GetValues(curve, iPt, out xVal, out zVal, out yVal);
}
distX = (xVal - xAct) * xPixPerUnit;
distY = (yVal - yAct) * yPixPerUnitAct;
dist = distX * distX + distY * distY;
if (dist >= minDist)
{
continue;
}
minDist = dist;
iNearest = iPt;
nearestCurve = curve;
}
}
}
if (curve.IsBar)
{
iBar++;
}
}
}
}
if (nearestCurve is LineItem)
{
float halfSymbol = ((LineItem)nearestCurve).Symbol.Size * this.CalcScaleFactor() / 2;
minDist -= halfSymbol * halfSymbol;
if (minDist < 0)
{
minDist = 0;
}
}
if (minDist >= tolSquared && nearestBar != null)
{
// if no point met the tolerance, but a bar was found, use it
nearestCurve = nearestBar;
iNearest = iNearestBar;
return true;
}
if (minDist < tolSquared)
{
// Did we find a close point, and is it within the tolerance?
// (minDist is the square of the distance in pixel units)
return true;
}
return false;
}
/// <summary>
/// Find the data point that lies closest to the specified mouse (screen) point.
/// </summary>
/// <remarks>
/// This method will search through all curves in
/// <see cref="GraphPane.CurveList"/> to find which point is nearest. It will only consider points that are within
/// <see cref="Default.NearestTol"/> pixels of the screen point.
/// </remarks>
/// <param name="mousePt">
/// The screen point, in pixel coordinates.
/// </param>
/// <param name="nearestCurve">
/// A reference to the <see cref="CurveItem"/>
/// instance that contains the closest point. nearestCurve will be null if no data points are available.
/// </param>
/// <param name="iNearest">
/// The index number of the closest point. The actual data vpoint will then be <see cref="CurveItem.Points">CurveItem.Points[iNearest]</see>
/// . iNearest will be -1 if no data points are available.
/// </param>
/// <returns>
/// true if a point was found and that point lies within
/// <see cref="Default.NearestTol"/> pixels of the screen point, false otherwise.
/// </returns>
public bool FindNearestPoint(PointF mousePt, out CurveItem nearestCurve, out int iNearest)
{
return this.FindNearestPoint(mousePt, this._curveList, out nearestCurve, out iNearest);
}
/// <summary>
/// Remove the specified <see cref="CurveItem"/> from the selection list.
/// </summary>
/// <param name="master">
/// The <see cref="MasterPane"/> that is the "owner" of the <see cref="CurveItem"/>'s.
/// </param>
/// <param name="ci">
/// The <see cref="CurveItem"/> to be removed from the list.
/// </param>
public void RemoveFromSelection(MasterPane master, CurveItem ci)
{
if (this.Contains(ci))
{
this.Remove(ci);
}
this.UpdateSelection(master);
}
/// <summary>
/// Do all rendering associated with this <see cref="Line"/> to the specified
/// <see cref="Graphics"/> device. This method is normally only called by the Draw method of the parent <see cref="LineItem"/> object.
/// </summary>
/// <param name="g">
/// A graphic device object to be drawn into. This is normally e.Graphics from the PaintEventArgs argument to the Paint() method.
/// </param>
/// <param name="pane">
/// A reference to the <see cref="GraphPane"/> object that is the parent or owner of this object.
/// </param>
/// <param name="curve">
/// A <see cref="LineItem"/> representing this curve.
/// </param>
/// <param name="scaleFactor">
/// The scaling factor to be used for rendering objects. This is calculated and passed down by the parent <see cref="GraphPane"/> object using the
/// <see cref="PaneBase.CalcScaleFactor"/> method, and is used to proportionally adjust font sizes, etc. according to the actual size of the graph.
/// </param>
public void Draw(Graphics g, GraphPane pane, CurveItem curve, float scaleFactor)
{
// If the line is being shown, draw it
if (this.IsVisible)
{
// How to handle fill vs nofill?
// if ( isSelected )
// GraphPane.Default.SelectedLine.
SmoothingMode sModeSave = g.SmoothingMode;
if (this._isAntiAlias)
{
g.SmoothingMode = SmoothingMode.HighQuality;
}
if (curve is StickItem)
{
this.DrawSticks(g, pane, curve, scaleFactor);
}
else if (this.IsSmooth || this.Fill.IsVisible)
{
this.DrawSmoothFilledCurve(g, pane, curve, scaleFactor);
}
else
{
this.DrawCurve(g, pane, curve, scaleFactor);
}
g.SmoothingMode = sModeSave;
}
}
/// <summary>
/// Build an array of <see cref="PointF"/> values (pixel coordinates) that represents the current curve. Note that this drawing routine ignores
/// <see cref="PointPairBase.Missing"/>
/// values, but it does not "break" the line to indicate values are missing.
/// </summary>
/// <param name="pane">
/// A reference to the <see cref="GraphPane"/> object that is the parent or owner of this object.
/// </param>
/// <param name="curve">
/// A <see cref="LineItem"/> representing this curve.
/// </param>
/// <param name="arrPoints">
/// An array of <see cref="PointF"/> values in pixel coordinates representing the current curve.
/// </param>
/// <param name="count">
/// The number of points contained in the "arrPoints" parameter.
/// </param>
/// <returns>
/// true for a successful points array build, false for data problems
/// </returns>
public bool BuildPointsArray(GraphPane pane, CurveItem curve, out PointF[] arrPoints, out int count)
{
arrPoints = null;
count = 0;
IPointList points = curve.Points;
if (this.IsVisible && !this.Color.IsEmpty && points != null)
{
int index = 0;
float curX, curY, lastX = 0, lastY = 0;
double x, y, lowVal;
ValueHandler valueHandler = new ValueHandler(pane, false);
// Step type plots get twice as many points. Always add three points so there is
// room to close out the curve for area fills.
arrPoints = new PointF[(this._stepType == StepType.NonStep ? 1 : 2) * points.Count + 1];
// Loop over all points in the curve
for (int i = 0; i < points.Count; i++)
{
// make sure that the current point is valid
if (!points[i].IsInvalid)
{
// Get the user scale values for the current point
// use the valueHandler only for stacked types
if (pane.LineType == LineType.Stack)
{
valueHandler.GetValues(curve, i, out x, out lowVal, out y);
}
// otherwise, just access the values directly. Avoiding the valueHandler for
// non-stacked types is an optimization to minimize overhead in case there are
// a large number of points.
else
{
x = points[i].X;
y = points[i].Y;
}
if (x == PointPairBase.Missing || y == PointPairBase.Missing)
{
continue;
}
// Transform the user scale values to pixel locations
Axis xAxis = curve.GetXAxis(pane);
curX = xAxis.Scale.Transform(curve.IsOverrideOrdinal, i, x);
Axis yAxis = curve.GetYAxis(pane);
curY = yAxis.Scale.Transform(curve.IsOverrideOrdinal, i, y);
if (curX < -1000000 || curY < -1000000 || curX > 1000000 || curY > 1000000)
{
continue;
}
// Add the pixel value pair into the points array
// Two points are added for step type curves
// ignore step-type setting for smooth curves
if (this._isSmooth || index == 0 || this.StepType == StepType.NonStep)
{
arrPoints[index].X = curX;
arrPoints[index].Y = curY;
}
else if (this.StepType == StepType.ForwardStep || this.StepType == StepType.ForwardSegment)
{
arrPoints[index].X = curX;
arrPoints[index].Y = lastY;
index++;
arrPoints[index].X = curX;
arrPoints[index].Y = curY;
}
else if (this.StepType == StepType.RearwardStep || this.StepType == StepType.RearwardSegment)
{
arrPoints[index].X = lastX;
arrPoints[index].Y = curY;
index++;
arrPoints[index].X = curX;
arrPoints[index].Y = curY;
}
lastX = curX;
lastY = curY;
index++;
}
}
// Make sure there is at least one valid point
if (index == 0)
{
return false;
}
// Add an extra point at the end, since the smoothing algorithm requires it
arrPoints[index] = arrPoints[index - 1];
index++;
count = index;
return true;
}
return false;
}
/// <summary>
/// The is first line.
/// </summary>
/// <param name="pane">
/// The pane.
/// </param>
/// <param name="curve">
/// The curve.
/// </param>
/// <returns>
/// The <see cref="bool"/>.
/// </returns>
private bool IsFirstLine(GraphPane pane, CurveItem curve)
{
CurveList curveList = pane.CurveList;
for (int j = 0; j < curveList.Count; j++)
{
CurveItem tCurve = curveList[j];
if (tCurve is LineItem && tCurve.IsY2Axis == curve.IsY2Axis && tCurve.YAxisIndex == curve.YAxisIndex)
{
return tCurve == curve;
}
}
return false;
}
/// <summary>
/// Render the <see cref="Line"/>'s as vertical sticks (from a <see cref="StickItem"/>) to the specified <see cref="Graphics"/> device.
/// </summary>
/// <param name="g">
/// A graphic device object to be drawn into. This is normally e.Graphics from the PaintEventArgs argument to the Paint() method.
/// </param>
/// <param name="pane">
/// A reference to the <see cref="GraphPane"/> object that is the parent or owner of this object.
/// </param>
/// <param name="curve">
/// A <see cref="CurveItem"/> representing this curve.
/// </param>
/// <param name="scaleFactor">
/// The scaling factor to be used for rendering objects. This is calculated and passed down by the parent <see cref="GraphPane"/> object using the
/// <see cref="PaneBase.CalcScaleFactor"/> method, and is used to proportionally adjust font sizes, etc. according to the actual size of the graph.
/// </param>
public void DrawSticks(Graphics g, GraphPane pane, CurveItem curve, float scaleFactor)
{
Line source = this;
if (curve.IsSelected)
{
source = Selection.Line;
}
Axis yAxis = curve.GetYAxis(pane);
Axis xAxis = curve.GetXAxis(pane);
float basePix = yAxis.Scale.Transform(0.0);
using (Pen pen = source.GetPen(pane, scaleFactor))
{
for (int i = 0; i < curve.Points.Count; i++)
{
PointPair pt = curve.Points[i];
if (pt.X != PointPairBase.Missing && pt.Y != PointPairBase.Missing && !double.IsNaN(pt.X) && !double.IsNaN(pt.Y)
&& !double.IsInfinity(pt.X) && !double.IsInfinity(pt.Y) && (!xAxis._scale.IsLog || pt.X > 0.0)
&& (!yAxis._scale.IsLog || pt.Y > 0.0))
{
float pixY = yAxis.Scale.Transform(curve.IsOverrideOrdinal, i, pt.Y);
float pixX = xAxis.Scale.Transform(curve.IsOverrideOrdinal, i, pt.X);
if (pixX >= pane.Chart._rect.Left && pixX <= pane.Chart._rect.Right)
{
if (pixY > pane.Chart._rect.Bottom)
{
pixY = pane.Chart._rect.Bottom;
}
if (pixY < pane.Chart._rect.Top)
{
pixY = pane.Chart._rect.Top;
}
if (!curve.IsSelected && this._gradientFill.IsGradientValueType)
{
using (Pen tPen = this.GetPen(pane, scaleFactor, pt)) g.DrawLine(tPen, pixX, pixY, pixX, basePix);
}
else
{
g.DrawLine(pen, pixX, pixY, pixX, basePix);
}
}
}
}
}
}
/// <summary>
/// Get the user scale values associate with a particular point of a particular curve.
/// </summary>
/// <remarks>
/// The main purpose of this method is to handle stacked bars and lines, in which case the stacked values are returned rather than the individual data
/// values. However, this method works generically for any curve type.
/// </remarks>
/// <param name="pane">
/// The parent <see cref="GraphPane"/> object.
/// </param>
/// <param name="curve">
/// A <see cref="CurveItem"/> object of interest.
/// </param>
/// <param name="iPt">
/// The zero-based point index for the point of interest.
/// </param>
/// <param name="baseVal">
/// A <see cref="double"/> value representing the value for the independent axis.
/// </param>
/// <param name="lowVal">
/// A <see cref="double"/> value representing the lower value for the dependent axis.
/// </param>
/// <param name="hiVal">
/// A <see cref="double"/> value representing the upper value for the dependent axis.
/// </param>
/// <returns>
/// true if the data point is value, false for
/// <see cref="PointPairBase.Missing"/>, invalid, etc. data.
/// </returns>
public static bool GetValues(GraphPane pane, CurveItem curve, int iPt, out double baseVal, out double lowVal, out double hiVal)
{
hiVal = PointPairBase.Missing;
lowVal = PointPairBase.Missing;
baseVal = PointPairBase.Missing;
if (curve == null || curve.Points.Count <= iPt || !curve.IsVisible)
{
return false;
}
Axis baseAxis = curve.BaseAxis(pane);
Axis valueAxis = curve.ValueAxis(pane);
if (baseAxis is XAxis || baseAxis is X2Axis)
{
baseVal = curve.Points[iPt].X;
}
else
{
baseVal = curve.Points[iPt].Y;
}
// is it a stacked bar type?
if (curve is BarItem && (pane._barSettings.Type == BarType.Stack || pane._barSettings.Type == BarType.PercentStack))
{
double positiveStack = 0;
double negativeStack = 0;
double curVal;
// loop through all the curves, summing up the values to get a total (only
// for the current ordinal position iPt)
foreach (CurveItem tmpCurve in pane.CurveList)
{
// Sum the value for the current curve only if it is a bar
if (tmpCurve.IsBar && tmpCurve.IsVisible)
{
curVal = PointPairBase.Missing;
// For non-ordinal curves, find a matching base value (must match exactly)
if (curve.IsOverrideOrdinal || !baseAxis._scale.IsAnyOrdinal)
{
IPointList points = tmpCurve.Points;
for (int i = 0; i < points.Count; i++)
{
if ((baseAxis is XAxis || baseAxis is X2Axis) && points[i].X == baseVal)
{
curVal = points[i].Y;
break;
}
if (!(baseAxis is XAxis || baseAxis is X2Axis) && points[i].Y == baseVal)
{
curVal = points[i].X;
break;
}
}
}
// otherwise, it's an ordinal type so use the value at the same ordinal position
else if (iPt < tmpCurve.Points.Count)
{
// Get the value for the appropriate value axis
if (baseAxis is XAxis || baseAxis is X2Axis)
{
curVal = tmpCurve.Points[iPt].Y;
}
else
{
curVal = tmpCurve.Points[iPt].X;
}
}
// If it's a missing value, skip it
if (curVal == PointPairBase.Missing)
{
positiveStack = PointPairBase.Missing;
negativeStack = PointPairBase.Missing;
}
// the current curve is the target curve, save the summed values for later
if (tmpCurve == curve)
{
// if the value is positive, use the positive stack
if (curVal >= 0)
{
lowVal = positiveStack;
hiVal = (curVal == PointPairBase.Missing || positiveStack == PointPairBase.Missing)
? PointPairBase.Missing
: positiveStack + curVal;
}
// otherwise, use the negative stack
else
{
hiVal = negativeStack;
lowVal = (curVal == PointPairBase.Missing || negativeStack == PointPairBase.Missing)
? PointPairBase.Missing
: negativeStack + curVal;
}
}
// Add all positive values to the positive stack, and negative values to the
// negative stack
if (curVal >= 0)
{
positiveStack = (curVal == PointPairBase.Missing || positiveStack == PointPairBase.Missing)
? PointPairBase.Missing
: positiveStack + curVal;
}
else
{
negativeStack = (curVal == PointPairBase.Missing || negativeStack == PointPairBase.Missing)
? PointPairBase.Missing
: negativeStack + curVal;
}
}
}
// if the curve is a PercentStack type, then calculate the percent for this bar
// based on the total height of the stack
if (pane._barSettings.Type == BarType.PercentStack && hiVal != PointPairBase.Missing && lowVal != PointPairBase.Missing)
{
// Use the total magnitude of the positive plus negative bar stacks to determine
// the percentage value
positiveStack += Math.Abs(negativeStack);
// just to avoid dividing by zero...
if (positiveStack != 0)
{
// calculate the percentage values
lowVal = lowVal / positiveStack * 100.0;
hiVal = hiVal / positiveStack * 100.0;
}
else
{
lowVal = 0;
hiVal = 0;
}
}
if (baseVal == PointPairBase.Missing || lowVal == PointPairBase.Missing || hiVal == PointPairBase.Missing)
{
return false;
}
return true;
}
// If the curve is a stacked line type, then sum up the values similar to the stacked bar type
if (curve is LineItem && pane.LineType == LineType.Stack)
{
double stack = 0;
double curVal;
// loop through all the curves, summing up the values to get a total (only
// for the current ordinal position iPt)
foreach (CurveItem tmpCurve in pane.CurveList)
{
// make sure the curve is a Line type
if (tmpCurve is LineItem && tmpCurve.IsVisible)
{
curVal = PointPairBase.Missing;
// For non-ordinal curves, find a matching base value (must match exactly)
if (curve.IsOverrideOrdinal || !baseAxis._scale.IsAnyOrdinal)
{
IPointList points = tmpCurve.Points;
for (int i = 0; i < points.Count; i++)
{
if (points[i].X == baseVal)
{
curVal = points[i].Y;
break;
}
}
}
// otherwise, it's an ordinal type so use the value at the same ordinal position
else if (iPt < tmpCurve.Points.Count)
{
// For line types, the Y axis is always the value axis
curVal = tmpCurve.Points[iPt].Y;
}
// if the current value is missing, then the rest of the stack is missing
if (curVal == PointPairBase.Missing)
{
stack = PointPairBase.Missing;
}
// if the current curve is the target curve, save the values
if (tmpCurve == curve)
{
lowVal = stack;
// if ( curVal < 0 && stack == 0 )
// {
// stack = curVal;
// lowVal = curVal;
// hiVal = curVal;
// }
// else
hiVal = (curVal == PointPairBase.Missing || stack == PointPairBase.Missing) ? PointPairBase.Missing : stack + curVal;
}
// sum all the curves to a single total. This includes both positive and
// negative values (unlike the bar stack type).
stack = (curVal == PointPairBase.Missing || stack == PointPairBase.Missing) ? PointPairBase.Missing : stack + curVal;
}
}
if (baseVal == PointPairBase.Missing || lowVal == PointPairBase.Missing || hiVal == PointPairBase.Missing)
{
return false;
}
return true;
}
// otherwise, the curve is not a stacked type (not a stacked bar or stacked line)
if ((!(curve is HiLowBarItem)) && (!(curve is ErrorBarItem)))
{
lowVal = 0;
}
else
{
lowVal = curve.Points[iPt].LowValue;
}
if (baseAxis is XAxis || baseAxis is X2Axis)
{
hiVal = curve.Points[iPt].Y;
}
else
{
hiVal = curve.Points[iPt].X;
}
// Special Exception: Bars on log scales should always plot from the Min value upwards,
// since they can never be zero
if (curve is BarItem && valueAxis._scale.IsLog && lowVal == 0)
{
lowVal = valueAxis._scale._min;
}
if (baseVal == PointPairBase.Missing || hiVal == PointPairBase.Missing
|| (lowVal == PointPairBase.Missing && (curve is ErrorBarItem || curve is HiLowBarItem)))
{
return false;
}
return true;
}
/// <summary>
/// Get the user scale values associate with a particular point of a particular curve.
/// </summary>
/// <remarks>
/// The main purpose of this method is to handle stacked bars, in which case the stacked values are returned rather than the individual data
/// values.
/// </remarks>
/// <param name="curve">
/// A <see cref="CurveItem"/> object of interest.
/// </param>
/// <param name="iPt">
/// The zero-based point index for the point of interest.
/// </param>
/// <param name="baseVal">
/// A <see cref="double"/> value representing the value for the independent axis.
/// </param>
/// <param name="lowVal">
/// A <see cref="double"/> value representing the lower value for the dependent axis.
/// </param>
/// <param name="hiVal">
/// A <see cref="double"/> value representing the upper value for the dependent axis.
/// </param>
/// <returns>
/// true if the data point is value, false for
/// <see cref="PointPairBase.Missing"/>, invalid, etc. data.
/// </returns>
public bool GetValues(CurveItem curve, int iPt, out double baseVal, out double lowVal, out double hiVal)
{
return GetValues(this._pane, curve, iPt, out baseVal, out lowVal, out hiVal);
}
/// <summary>
/// Calculate the user scale position of the center of the specified bar, using the
/// <see cref="Axis"/> as specified by <see cref="BarSettings.Base"/>. This method is used primarily by the
/// <see cref="GraphPane.FindNearestPoint(PointF,out CurveItem,out int)"/> method in order to determine the bar "location," which is defined as the
/// center of the top of the individual bar.
/// </summary>
/// <param name="curve">
/// The <see cref="CurveItem"/> representing the bar of interest.
/// </param>
/// <param name="barWidth">
/// The width of each individual bar. This can be calculated using the <see cref="CurveItem.GetBarWidth"/> method.
/// </param>
/// <param name="iCluster">
/// The cluster number for the bar of interest. This is the ordinal position of the current point. That is, if a particular <see cref="CurveItem"/>
/// has 10 points, then a value of 3 would indicate the 4th point in the data array.
/// </param>
/// <param name="val">
/// The actual independent axis value for the bar of interest.
/// </param>
/// <param name="iOrdinal">
/// The ordinal position of the <see cref="CurveItem"/> of interest. That is, the first bar series is 0, the second is 1, etc. Note that this applies
/// only to the bars. If a graph includes both bars and lines, then count only the bars.
/// </param>
/// <returns>
/// A user scale value position of the center of the bar of interest.
/// </returns>
public double BarCenterValue(CurveItem curve, float barWidth, int iCluster, double val, int iOrdinal)
{
Axis baseAxis = curve.BaseAxis(this._pane);
if (curve is ErrorBarItem || curve is HiLowBarItem || curve is OHLCBarItem || curve is JapaneseCandleStickItem)
{
if (baseAxis._scale.IsAnyOrdinal && iCluster >= 0 && !curve.IsOverrideOrdinal)
{
return iCluster + 1.0;
}
return val;
}
float clusterWidth = this._pane._barSettings.GetClusterWidth();
float clusterGap = this._pane._barSettings.MinClusterGap * barWidth;
float barGap = barWidth * this._pane._barSettings.MinBarGap;
if (curve.IsBar && this._pane._barSettings.Type != BarType.Cluster)
{
iOrdinal = 0;
}
float centerPix = baseAxis.Scale.Transform(curve.IsOverrideOrdinal, iCluster, val) - clusterWidth / 2.0F + clusterGap / 2.0F
+ iOrdinal * (barWidth + barGap) + 0.5F * barWidth;
return baseAxis.Scale.ReverseTransform(centerPix);
}
// public static Color SelectedSymbolColor = Color.Gray;
#endregion Other
#if ( DOTNET1 )
// Define a "Contains" method so that this class works with .Net 1.1 or 2.0
internal bool Contains( CurveItem item )
{
foreach ( CurveItem ci in this )
if ( item == ci )
return true;
return false;
}
/// <summary>
/// Place a <see cref="CurveItem"/> in the selection list, removing all other items.
/// </summary>
/// <param name="master">
/// The <see cref="MasterPane"/> that is the "owner" of the <see cref="CurveItem"/>'s.
/// </param>
/// <param name="ci">
/// The <see cref="CurveItem"/> to be added to the list.
/// </param>
public void Select(MasterPane master, CurveItem ci)
{
// Clear the selection, but don't send the event,
// the event will be sent in "AddToSelection" by calling "UpdateSelection"
this.ClearSelection(master, false);
this.AddToSelection(master, ci);
}
/// <summary>
/// Initializes a new instance of the <see cref="CurveItem"/> class.
/// The Copy Constructor
/// </summary>
/// <param name="rhs">
/// The CurveItem object from which to copy
/// </param>
public CurveItem(CurveItem rhs)
{
this._label = rhs._label.Clone();
this._isY2Axis = rhs.IsY2Axis;
this._isX2Axis = rhs.IsX2Axis;
this._isVisible = rhs.IsVisible;
this._isOverrideOrdinal = rhs._isOverrideOrdinal;
this._yAxisIndex = rhs._yAxisIndex;
if (rhs.Tag is ICloneable)
{
this.Tag = ((ICloneable)rhs.Tag).Clone();
}
else
{
this.Tag = rhs.Tag;
}
this._points = (IPointList)rhs.Points.Clone();
this._link = rhs._link.Clone();
}
/// <summary>
/// Draw the this <see cref="Bar"/> to the specified <see cref="Graphics"/>
/// device as a bar at each defined point. This method is normally only called by the <see cref="BarItem.Draw"/> method of the
/// <see cref="BarItem"/> object
/// </summary>
/// <param name="g">
/// A graphic device object to be drawn into. This is normally e.Graphics from the PaintEventArgs argument to the Paint() method.
/// </param>
/// <param name="pane">
/// A reference to the <see cref="GraphPane"/> object that is the parent or owner of this object.
/// </param>
/// <param name="curve">
/// A <see cref="CurveItem"/> object representing the
/// <see cref="Bar"/>'s to be drawn.
/// </param>
/// <param name="baseAxis">
/// The <see cref="Axis"/> class instance that defines the base (independent) axis for the <see cref="Bar"/>
/// </param>
/// <param name="valueAxis">
/// The <see cref="Axis"/> class instance that defines the value (dependent) axis for the <see cref="Bar"/>
/// </param>
/// <param name="barWidth">
/// The width of each bar, in pixels.
/// </param>
/// <param name="pos">
/// The ordinal position of the this bar series (0=first bar, 1=second bar, etc.) in the cluster of bars.
/// </param>
/// <param name="scaleFactor">
/// The scaling factor to be used for rendering objects. This is calculated and passed down by the parent <see cref="GraphPane"/> object using the
/// <see cref="PaneBase.CalcScaleFactor"/> method, and is used to proportionally adjust font sizes, etc. according to the actual size of the graph.
/// </param>
public void DrawBars(Graphics g, GraphPane pane, CurveItem curve, Axis baseAxis, Axis valueAxis, float barWidth, int pos, float scaleFactor)
{
// For non-cluster bar types, the position is always zero since the bars are on top
// of eachother
BarType barType = pane._barSettings.Type;
if (barType == BarType.Overlay || barType == BarType.Stack || barType == BarType.PercentStack || barType == BarType.SortedOverlay)
{
pos = 0;
}
// Loop over each defined point and draw the corresponding bar
for (int i = 0; i < curve.Points.Count; i++)
{
this.DrawSingleBar(g, pane, curve, i, pos, baseAxis, valueAxis, barWidth, scaleFactor);
}
}
/// <summary>
/// Draw the this <see cref="CurveItem"/> to the specified <see cref="Graphics"/>
/// device using the specified smoothing property (<see cref="Line.SmoothTension"/>). The routine draws the line segments and the area fill (if any, see
/// <see cref="FillType"/>; the symbols are drawn by the <see cref="Symbol.Draw"/> method. This method is normally only called by the Draw method of
/// the
/// <see cref="CurveItem"/> object. Note that the <see cref="StepType"/> property is ignored for smooth lines (e.g., when <see cref="Line.IsSmooth"/>
/// is true).
/// </summary>
/// <param name="g">
/// A graphic device object to be drawn into. This is normally e.Graphics from the PaintEventArgs argument to the Paint() method.
/// </param>
/// <param name="pane">
/// A reference to the <see cref="GraphPane"/> object that is the parent or owner of this object.
/// </param>
/// <param name="curve">
/// A <see cref="LineItem"/> representing this curve.
/// </param>
/// <param name="scaleFactor">
/// The scaling factor to be used for rendering objects. This is calculated and passed down by the parent <see cref="GraphPane"/> object using the
/// <see cref="PaneBase.CalcScaleFactor"/> method, and is used to proportionally adjust font sizes, etc. according to the actual size of the graph.
/// </param>
public void DrawSmoothFilledCurve(Graphics g, GraphPane pane, CurveItem curve, float scaleFactor)
{
Line source = this;
if (curve.IsSelected)
{
source = Selection.Line;
}
PointF[] arrPoints;
int count;
IPointList points = curve.Points;
if (this.IsVisible && !this.Color.IsEmpty && points != null && this.BuildPointsArray(pane, curve, out arrPoints, out count) && count > 2)
{
float tension = this._isSmooth ? this._smoothTension : 0f;
// Fill the curve if needed
if (this.Fill.IsVisible)
{
Axis yAxis = curve.GetYAxis(pane);
using (GraphicsPath path = new GraphicsPath(FillMode.Winding))
{
path.AddCurve(arrPoints, 0, count - 2, tension);
double yMin = yAxis._scale._min < 0 ? 0.0 : yAxis._scale._min;
this.CloseCurve(pane, curve, arrPoints, count, yMin, path);
RectangleF rect = path.GetBounds();
using (Brush brush = source._fill.MakeBrush(rect))
{
if (pane.LineType == LineType.Stack && yAxis.Scale._min < 0 && this.IsFirstLine(pane, curve))
{
float zeroPix = yAxis.Scale.Transform(0);
RectangleF tRect = pane.Chart._rect;
tRect.Height = zeroPix - tRect.Top;
if (tRect.Height > 0)
{
Region reg = g.Clip;
g.SetClip(tRect);
g.FillPath(brush, path);
g.SetClip(pane.Chart._rect);
}
}
else
{
g.FillPath(brush, path);
}
// brush.Dispose();
}
// restore the zero line if needed (since the fill tends to cover it up)
yAxis.FixZeroLine(g, pane, scaleFactor, rect.Left, rect.Right);
}
}
// If it's a smooth curve, go ahead and render the path. Otherwise, use the
// standard drawcurve method just in case there are missing values.
if (this._isSmooth)
{
using (Pen pen = this.GetPen(pane, scaleFactor))
{
// Stroke the curve
g.DrawCurve(pen, arrPoints, 0, count - 2, tension);
// pen.Dispose();
}
}
else
{
this.DrawCurve(g, pane, curve, scaleFactor);
}
}
}
/// <summary>
/// Draw the specified single bar (an individual "point") of this series to the specified
/// <see cref="Graphics"/> device. This method is not as efficient as
/// <see cref="DrawBars"/>, which draws the bars for all points. It is intended to be used only for <see cref="BarType.SortedOverlay"/>, which
/// requires special handling of each bar.
/// </summary>
/// <param name="g">
/// A graphic device object to be drawn into. This is normally e.Graphics from the PaintEventArgs argument to the Paint() method.
/// </param>
/// <param name="pane">
/// A reference to the <see cref="GraphPane"/> object that is the parent or owner of this object.
/// </param>
/// <param name="curve">
/// A <see cref="CurveItem"/> object representing the
/// <see cref="Bar"/>'s to be drawn.
/// </param>
/// <param name="baseAxis">
/// The <see cref="Axis"/> class instance that defines the base (independent) axis for the <see cref="Bar"/>
/// </param>
/// <param name="valueAxis">
/// The <see cref="Axis"/> class instance that defines the value (dependent) axis for the <see cref="Bar"/>
/// </param>
/// <param name="pos">
/// The ordinal position of the this bar series (0=first bar, 1=second bar, etc.) in the cluster of bars.
/// </param>
/// <param name="index">
/// The zero-based index number for the single bar to be drawn.
/// </param>
/// <param name="barWidth">
/// The width of each bar, in pixels.
/// </param>
/// <param name="scaleFactor">
/// The scaling factor to be used for rendering objects. This is calculated and passed down by the parent <see cref="GraphPane"/> object using the
/// <see cref="PaneBase.CalcScaleFactor"/> method, and is used to proportionally adjust font sizes, etc. according to the actual size of the graph.
/// </param>
public void DrawSingleBar(
Graphics g,
GraphPane pane,
CurveItem curve,
Axis baseAxis,
Axis valueAxis,
int pos,
int index,
float barWidth,
float scaleFactor)
{
// Make sure that a bar value exists for the current curve and current ordinal position
if (index >= curve.Points.Count)
{
return;
}
// For Overlay and Stack bars, the position is always zero since the bars are on top
// of eachother
if (pane._barSettings.Type == BarType.Overlay || pane._barSettings.Type == BarType.Stack || pane._barSettings.Type == BarType.PercentStack)
{
pos = 0;
}
// Draw the specified bar
this.DrawSingleBar(g, pane, curve, index, pos, baseAxis, valueAxis, barWidth, scaleFactor);
}
/// <summary>
/// This method just handles the case where one or more of the coordinates are outrageous, or GDI+ threw an exception. This method attempts to correct
/// the outrageous coordinates by interpolating them to a point (along the original line) that lies at the edge of the ChartRect so that GDI+ will handle
/// it properly. GDI+ will throw an exception, or just plot the data incorrectly if the coordinates are too large (empirically, this appears to be when
/// the coordinate value is greater than 5,000,000 or less than -5,000,000). Although you typically would not see coordinates like this, if you
/// repeatedly zoom in on a ZedGraphControl, eventually all your points will be way outside the bounds of the plot.
/// </summary>
/// <param name="g">
/// The g.
/// </param>
/// <param name="pane">
/// The pane.
/// </param>
/// <param name="curve">
/// The curve.
/// </param>
/// <param name="lastPt">
/// The last Pt.
/// </param>
/// <param name="scaleFactor">
/// The scale Factor.
/// </param>
/// <param name="pen">
/// The pen.
/// </param>
/// <param name="lastX">
/// The last X.
/// </param>
/// <param name="lastY">
/// The last Y.
/// </param>
/// <param name="tmpX">
/// The tmp X.
/// </param>
/// <param name="tmpY">
/// The tmp Y.
/// </param>
private void InterpolatePoint(
Graphics g,
GraphPane pane,
CurveItem curve,
PointPair lastPt,
float scaleFactor,
Pen pen,
float lastX,
float lastY,
float tmpX,
float tmpY)
{
try
{
RectangleF chartRect = pane.Chart._rect;
// try to interpolate values
bool lastIn = chartRect.Contains(lastX, lastY);
bool curIn = chartRect.Contains(tmpX, tmpY);
// If both points are outside the ChartRect, make a new point that is on the LastX/Y
// side of the ChartRect, and fall through to the code that handles lastIn == true
if (!lastIn)
{
float newX, newY;
if (Math.Abs(lastX) > Math.Abs(lastY))
{
newX = lastX < 0 ? chartRect.Left : chartRect.Right;
newY = lastY + (tmpY - lastY) * (newX - lastX) / (tmpX - lastX);
}
else
{
newY = lastY < 0 ? chartRect.Top : chartRect.Bottom;
newX = lastX + (tmpX - lastX) * (newY - lastY) / (tmpY - lastY);
}
lastX = newX;
lastY = newY;
}
if (!curIn)
{
float newX, newY;
if (Math.Abs(tmpX) > Math.Abs(tmpY))
{
newX = tmpX < 0 ? chartRect.Left : chartRect.Right;
newY = tmpY + (lastY - tmpY) * (newX - tmpX) / (lastX - tmpX);
}
else
{
newY = tmpY < 0 ? chartRect.Top : chartRect.Bottom;
newX = tmpX + (lastX - tmpX) * (newY - tmpY) / (lastY - tmpY);
}
tmpX = newX;
tmpY = newY;
}
/*
if ( this.StepType == StepType.ForwardStep )
{
g.DrawLine( pen, lastX, lastY, tmpX, lastY );
g.DrawLine( pen, tmpX, lastY, tmpX, tmpY );
}
else if ( this.StepType == StepType.RearwardStep )
{
g.DrawLine( pen, lastX, lastY, lastX, tmpY );
g.DrawLine( pen, lastX, tmpY, tmpX, tmpY );
}
else // non-step
g.DrawLine( pen, lastX, lastY, tmpX, tmpY );
*/
if (!curve.IsSelected && this._gradientFill.IsGradientValueType)
{
using (Pen tPen = this.GetPen(pane, scaleFactor, lastPt))
{
if (this.StepType == StepType.NonStep)
{
g.DrawLine(tPen, lastX, lastY, tmpX, tmpY);
}
else if (this.StepType == StepType.ForwardStep)
{
g.DrawLine(tPen, lastX, lastY, tmpX, lastY);
g.DrawLine(tPen, tmpX, lastY, tmpX, tmpY);
}
else if (this.StepType == StepType.RearwardStep)
{
g.DrawLine(tPen, lastX, lastY, lastX, tmpY);
g.DrawLine(tPen, lastX, tmpY, tmpX, tmpY);
}
else if (this.StepType == StepType.ForwardSegment)
{
g.DrawLine(tPen, lastX, lastY, tmpX, lastY);
}
else
{
g.DrawLine(tPen, lastX, tmpY, tmpX, tmpY);
}
}
}
else
{
if (this.StepType == StepType.NonStep)
{
g.DrawLine(pen, lastX, lastY, tmpX, tmpY);
}
else if (this.StepType == StepType.ForwardStep)
{
g.DrawLine(pen, lastX, lastY, tmpX, lastY);
g.DrawLine(pen, tmpX, lastY, tmpX, tmpY);
}
else if (this.StepType == StepType.RearwardStep)
{
g.DrawLine(pen, lastX, lastY, lastX, tmpY);
g.DrawLine(pen, lastX, tmpY, tmpX, tmpY);
}
else if (this.StepType == StepType.ForwardSegment)
{
g.DrawLine(pen, lastX, lastY, tmpX, lastY);
}
else if (this.StepType == StepType.RearwardSegment)
{
g.DrawLine(pen, lastX, tmpY, tmpX, tmpY);
}
}
}
catch
{
}
}
/// <summary>
/// Protected internal routine that draws the specified single bar (an individual "point") of this series to the specified <see cref="Graphics"/>
/// device.
/// </summary>
/// <param name="g">
/// A graphic device object to be drawn into. This is normally e.Graphics from the PaintEventArgs argument to the Paint() method.
/// </param>
/// <param name="pane">
/// A reference to the <see cref="GraphPane"/> object that is the parent or owner of this object.
/// </param>
/// <param name="curve">
/// A <see cref="CurveItem"/> object representing the
/// <see cref="Bar"/>'s to be drawn.
/// </param>
/// <param name="index">
/// The zero-based index number for the single bar to be drawn.
/// </param>
/// <param name="pos">
/// The ordinal position of the this bar series (0=first bar, 1=second bar, etc.) in the cluster of bars.
/// </param>
/// <param name="baseAxis">
/// The <see cref="Axis"/> class instance that defines the base (independent) axis for the <see cref="Bar"/>
/// </param>
/// <param name="valueAxis">
/// The <see cref="Axis"/> class instance that defines the value (dependent) axis for the <see cref="Bar"/>
/// </param>
/// <param name="barWidth">
/// The width of each bar, in pixels.
/// </param>
/// <param name="scaleFactor">
/// The scaling factor to be used for rendering objects. This is calculated and passed down by the parent <see cref="GraphPane"/> object using the
/// <see cref="PaneBase.CalcScaleFactor"/> method, and is used to proportionally adjust font sizes, etc. according to the actual size of the graph.
/// </param>
protected virtual void DrawSingleBar(
Graphics g,
GraphPane pane,
CurveItem curve,
int index,
int pos,
Axis baseAxis,
Axis valueAxis,
float barWidth,
float scaleFactor)
{
// pixBase = pixel value for the bar center on the base axis
// pixHiVal = pixel value for the bar top on the value axis
// pixLowVal = pixel value for the bar bottom on the value axis
float pixBase, pixHiVal, pixLowVal;
float clusterWidth = pane.BarSettings.GetClusterWidth();
// float barWidth = curve.GetBarWidth( pane );
float clusterGap = pane._barSettings.MinClusterGap * barWidth;
float barGap = barWidth * pane._barSettings.MinBarGap;
// curBase = the scale value on the base axis of the current bar
// curHiVal = the scale value on the value axis of the current bar
// curLowVal = the scale value of the bottom of the bar
double curBase, curLowVal, curHiVal;
ValueHandler valueHandler = new ValueHandler(pane, false);
valueHandler.GetValues(curve, index, out curBase, out curLowVal, out curHiVal);
// Any value set to double max is invalid and should be skipped
// This is used for calculated values that are out of range, divide
// by zero, etc.
// Also, any value <= zero on a log scale is invalid
if (!curve.Points[index].IsInvalid)
{
// calculate a pixel value for the top of the bar on value axis
pixLowVal = valueAxis.Scale.Transform(curve.IsOverrideOrdinal, index, curLowVal);
pixHiVal = valueAxis.Scale.Transform(curve.IsOverrideOrdinal, index, curHiVal);
// calculate a pixel value for the center of the bar on the base axis
pixBase = baseAxis.Scale.Transform(curve.IsOverrideOrdinal, index, curBase);
// Calculate the pixel location for the side of the bar (on the base axis)
float pixSide = pixBase - clusterWidth / 2.0F + clusterGap / 2.0F + pos * (barWidth + barGap);
// Draw the bar
if (pane._barSettings.Base == BarBase.X)
{
this.Draw(g, pane, pixSide, pixSide + barWidth, pixLowVal, pixHiVal, scaleFactor, true, curve.IsSelected, curve.Points[index]);
}
else
{
this.Draw(g, pane, pixLowVal, pixHiVal, pixSide, pixSide + barWidth, scaleFactor, true, curve.IsSelected, curve.Points[index]);
}
}
}
/// <summary>
/// Build an array of <see cref="PointF"/> values (pixel coordinates) that represents the low values for the current curve.
/// </summary>
/// <remarks>
/// Note that this drawing routine ignores <see cref="PointPairBase.Missing"/>
/// values, but it does not "break" the line to indicate values are missing.
/// </remarks>
/// <param name="pane">
/// A reference to the <see cref="GraphPane"/> object that is the parent or owner of this object.
/// </param>
/// <param name="curve">
/// A <see cref="LineItem"/> representing this curve.
/// </param>
/// <param name="arrPoints">
/// An array of <see cref="PointF"/> values in pixel coordinates representing the current curve.
/// </param>
/// <param name="count">
/// The number of points contained in the "arrPoints" parameter.
/// </param>
/// <returns>
/// true for a successful points array build, false for data problems
/// </returns>
public bool BuildLowPointsArray(GraphPane pane, CurveItem curve, out PointF[] arrPoints, out int count)
{
arrPoints = null;
count = 0;
IPointList points = curve.Points;
if (this.IsVisible && !this.Color.IsEmpty && points != null)
{
int index = 0;
float curX, curY, lastX = 0, lastY = 0;
double x, y, hiVal;
ValueHandler valueHandler = new ValueHandler(pane, false);
// Step type plots get twice as many points. Always add three points so there is
// room to close out the curve for area fills.
arrPoints = new PointF[(this._stepType == StepType.NonStep ? 1 : 2) * (pane.LineType == LineType.Stack ? 2 : 1) * points.Count + 1];
// Loop backwards over all points in the curve
// In this case an array of points was already built forward by BuildPointsArray().
// This time we build backwards to complete a loop around the area between two curves.
for (int i = points.Count - 1; i >= 0; i--)
{
// Make sure the current point is valid
if (!points[i].IsInvalid)
{
// Get the user scale values for the current point
valueHandler.GetValues(curve, i, out x, out y, out hiVal);
if (x == PointPairBase.Missing || y == PointPairBase.Missing)
{
continue;
}
// Transform the user scale values to pixel locations
Axis xAxis = curve.GetXAxis(pane);
curX = xAxis.Scale.Transform(curve.IsOverrideOrdinal, i, x);
Axis yAxis = curve.GetYAxis(pane);
curY = yAxis.Scale.Transform(curve.IsOverrideOrdinal, i, y);
// Add the pixel value pair into the points array
// Two points are added for step type curves
// ignore step-type setting for smooth curves
if (this._isSmooth || index == 0 || this.StepType == StepType.NonStep)
{
arrPoints[index].X = curX;
arrPoints[index].Y = curY;
}
else if (this.StepType == StepType.ForwardStep)
{
arrPoints[index].X = curX;
arrPoints[index].Y = lastY;
index++;
arrPoints[index].X = curX;
arrPoints[index].Y = curY;
}
else if (this.StepType == StepType.RearwardStep)
{
arrPoints[index].X = lastX;
arrPoints[index].Y = curY;
index++;
arrPoints[index].X = curX;
arrPoints[index].Y = curY;
}
lastX = curX;
lastY = curY;
index++;
}
}
// Make sure there is at least one valid point
if (index == 0)
{
return false;
}
// Add an extra point at the end, since the smoothing algorithm requires it
arrPoints[index] = arrPoints[index - 1];
index++;
count = index;
return true;
}
return false;
}
/// <summary>
/// Create a URL for a <see cref="CurveItem"/> that includes the index of the point that was selected.
/// </summary>
/// <remarks>
/// An "index" parameter is added to the <see cref="Url"/> property for this link to indicate which point was selected. Further, if the X or Y axes
/// that correspond to this <see cref="CurveItem"/> are of
/// <see cref="AxisType.Text"/>, then an additional parameter will be added containing the text value that corresponds to the <paramref name="index"/>
/// of the selected point. The <see cref="XAxis"/> text parameter will be labeled "xtext", and the <see cref="YAxis"/> text parameter will be labeled
/// "ytext".
/// </remarks>
/// <param name="pane">
/// The <see cref="GraphPane"/> of interest
/// </param>
/// <param name="curve">
/// The <see cref="CurveItem"/> for which to make the url string.
/// </param>
/// <param name="index">
/// The zero-based index of the selected point
/// </param>
/// <returns>
/// A string containing the url with an index parameter added.
/// </returns>
public virtual string MakeCurveItemUrl(GraphPane pane, CurveItem curve, int index)
{
string url = this._url;
if (url.IndexOf('?') >= 0)
{
url += "&index=" + index;
}
else
{
url += "?index=" + index;
}
Axis xAxis = curve.GetXAxis(pane);
if (xAxis.Type == AxisType.Text && index >= 0 && xAxis.Scale.TextLabels != null && index <= xAxis.Scale.TextLabels.Length)
{
url += "&xtext=" + xAxis.Scale.TextLabels[index];
}
Axis yAxis = curve.GetYAxis(pane);
if (yAxis != null && yAxis.Type == AxisType.Text && index >= 0 && yAxis.Scale.TextLabels != null && index <= yAxis.Scale.TextLabels.Length)
{
url += "&ytext=" + yAxis.Scale.TextLabels[index];
}
return url;
}
/// <summary>
/// Close off a <see cref="GraphicsPath"/> that defines a curve
/// </summary>
/// <param name="pane">
/// A reference to the <see cref="GraphPane"/> object that is the parent or owner of this object.
/// </param>
/// <param name="curve">
/// A <see cref="LineItem"/> representing this curve.
/// </param>
/// <param name="arrPoints">
/// An array of <see cref="PointF"/> values in screen pixel coordinates representing the current curve.
/// </param>
/// <param name="count">
/// The number of points contained in the "arrPoints" parameter.
/// </param>
/// <param name="yMin">
/// The Y axis value location where the X axis crosses.
/// </param>
/// <param name="path">
/// The <see cref="GraphicsPath"/> class that represents the curve.
/// </param>
public void CloseCurve(GraphPane pane, CurveItem curve, PointF[] arrPoints, int count, double yMin, GraphicsPath path)
{
// For non-stacked lines, the fill area is just the area between the curve and the X axis
if (pane.LineType != LineType.Stack)
{
// Determine the current value for the bottom of the curve (usually the Y value where
// the X axis crosses)
float yBase;
Axis yAxis = curve.GetYAxis(pane);
yBase = yAxis.Scale.Transform(yMin);
// Add three points to the path to move from the end of the curve (as defined by
// arrPoints) to the X axis, from there to the start of the curve at the X axis,
// and from there back up to the beginning of the curve.
path.AddLine(arrPoints[count - 1].X, arrPoints[count - 1].Y, arrPoints[count - 1].X, yBase);
path.AddLine(arrPoints[count - 1].X, yBase, arrPoints[0].X, yBase);
path.AddLine(arrPoints[0].X, yBase, arrPoints[0].X, arrPoints[0].Y);
}
// For stacked line types, the fill area is the area between this curve and the curve below it
else
{
PointF[] arrPoints2;
int count2;
float tension = this._isSmooth ? this._smoothTension : 0f;
// Find the next lower curve in the curveList that is also a LineItem type, and use
// its smoothing properties for the lower side of the filled area.
int index = pane.CurveList.IndexOf(curve);
if (index > 0)
{
CurveItem tmpCurve;
for (int i = index - 1; i >= 0; i--)
{
tmpCurve = pane.CurveList[i];
if (tmpCurve is LineItem)
{
tension = ((LineItem)tmpCurve).Line.IsSmooth ? ((LineItem)tmpCurve).Line.SmoothTension : 0f;
break;
}
}
}
// Build another points array consisting of the low points (which are actually the points for
// the curve below the current curve)
this.BuildLowPointsArray(pane, curve, out arrPoints2, out count2);
// Add the new points to the GraphicsPath
path.AddCurve(arrPoints2, 0, count2 - 2, tension);
}
}
/// <summary>
/// Find the data point that lies closest to the specified mouse (screen) point for the specified curve.
/// </summary>
/// <remarks>
/// This method will search only through the points for the specified curve to determine which point is nearest the mouse point. It will only consider
/// points that are within
/// <see cref="Default.NearestTol"/> pixels of the screen point.
/// </remarks>
/// <param name="mousePt">
/// The screen point, in pixel coordinates.
/// </param>
/// <param name="targetCurve">
/// A <see cref="CurveItem"/> object containing the data points to be searched.
/// </param>
/// <param name="nearestCurve">
/// A reference to the <see cref="CurveItem"/>
/// instance that contains the closest point. nearestCurve will be null if no data points are available.
/// </param>
/// <param name="iNearest">
/// The index number of the closest point. The actual data vpoint will then be <see cref="CurveItem.Points">CurveItem.Points[iNearest]</see>
/// . iNearest will be -1 if no data points are available.
/// </param>
/// <returns>
/// true if a point was found and that point lies within
/// <see cref="Default.NearestTol"/> pixels of the screen point, false otherwise.
/// </returns>
public bool FindNearestPoint(PointF mousePt, CurveItem targetCurve, out CurveItem nearestCurve, out int iNearest)
{
CurveList targetCurveList = new CurveList();
targetCurveList.Add(targetCurve);
return this.FindNearestPoint(mousePt, targetCurveList, out nearestCurve, out iNearest);
}
/// <summary>
/// Draw the this <see cref="CurveItem"/> to the specified <see cref="Graphics"/>
/// device. The format (stair-step or line) of the curve is defined by the <see cref="StepType"/> property. The routine only draws the line segments;
/// the symbols are drawn by the
/// <see cref="Symbol.Draw"/> method. This method is normally only called by the Draw method of the
/// <see cref="CurveItem"/> object
/// </summary>
/// <param name="g">
/// A graphic device object to be drawn into. This is normally e.Graphics from the PaintEventArgs argument to the Paint() method.
/// </param>
/// <param name="pane">
/// A reference to the <see cref="GraphPane"/> object that is the parent or owner of this object.
/// </param>
/// <param name="curve">
/// A <see cref="LineItem"/> representing this curve.
/// </param>
/// <param name="scaleFactor">
/// The scaling factor to be used for rendering objects. This is calculated and passed down by the parent <see cref="GraphPane"/> object using the
/// <see cref="PaneBase.CalcScaleFactor"/> method, and is used to proportionally adjust font sizes, etc. according to the actual size of the graph.
/// </param>
public void DrawCurveOriginal(Graphics g, GraphPane pane, CurveItem curve, float scaleFactor)
{
Line source = this;
if (curve.IsSelected)
{
source = Selection.Line;
}
float tmpX, tmpY, lastX = float.MaxValue, lastY = float.MaxValue;
double curX, curY, lowVal;
PointPair curPt, lastPt = new PointPair();
bool lastBad = true;
IPointList points = curve.Points;
ValueHandler valueHandler = new ValueHandler(pane, false);
Axis yAxis = curve.GetYAxis(pane);
Axis xAxis = curve.GetXAxis(pane);
bool xIsLog = xAxis._scale.IsLog;
bool yIsLog = yAxis._scale.IsLog;
float minX = pane.Chart.Rect.Left;
float maxX = pane.Chart.Rect.Right;
float minY = pane.Chart.Rect.Top;
float maxY = pane.Chart.Rect.Bottom;
using (Pen pen = source.GetPen(pane, scaleFactor))
{
if (points != null && !this._color.IsEmpty && this.IsVisible)
{
// bool lastOut = false;
bool isOut;
// Loop over each point in the curve
for (int i = 0; i < points.Count; i++)
{
curPt = points[i];
if (pane.LineType == LineType.Stack)
{
if (!valueHandler.GetValues(curve, i, out curX, out lowVal, out curY))
{
curX = PointPairBase.Missing;
curY = PointPairBase.Missing;
}
}
else
{
curX = curPt.X;
curY = curPt.Y;
}
// Any value set to double max is invalid and should be skipped
// This is used for calculated values that are out of range, divide
// by zero, etc.
// Also, any value <= zero on a log scale is invalid
if (curX == PointPairBase.Missing || curY == PointPairBase.Missing || double.IsNaN(curX) || double.IsNaN(curY)
|| double.IsInfinity(curX) || double.IsInfinity(curY) || (xIsLog && curX <= 0.0) || (yIsLog && curY <= 0.0))
{
// If the point is invalid, then make a linebreak only if IsIgnoreMissing is false
// LastX and LastY are always the last valid point, so this works out
lastBad = lastBad || !pane.IsIgnoreMissing;
isOut = true;
}
else
{
// Transform the current point from user scale units to
// screen coordinates
tmpX = xAxis.Scale.Transform(curve.IsOverrideOrdinal, i, curX);
tmpY = yAxis.Scale.Transform(curve.IsOverrideOrdinal, i, curY);
isOut = (tmpX < minX && lastX < minX) || (tmpX > maxX && lastX > maxX) || (tmpY < minY && lastY < minY)
|| (tmpY > maxY && lastY > maxY);
if (!lastBad)
{
try
{
// GDI+ plots the data wrong and/or throws an exception for
// outrageous coordinates, so we do a sanity check here
if (lastX > 5000000 || lastX < -5000000 || lastY > 5000000 || lastY < -5000000 || tmpX > 5000000
|| tmpX < -5000000 || tmpY > 5000000 || tmpY < -5000000)
{
this.InterpolatePoint(g, pane, curve, lastPt, scaleFactor, pen, lastX, lastY, tmpX, tmpY);
}
else if (!isOut)
{
if (!curve.IsSelected && this._gradientFill.IsGradientValueType)
{
using (Pen tPen = this.GetPen(pane, scaleFactor, lastPt))
{
if (this.StepType == StepType.NonStep)
{
g.DrawLine(tPen, lastX, lastY, tmpX, tmpY);
}
else if (this.StepType == StepType.ForwardStep)
{
g.DrawLine(tPen, lastX, lastY, tmpX, lastY);
g.DrawLine(tPen, tmpX, lastY, tmpX, tmpY);
}
else if (this.StepType == StepType.RearwardStep)
{
g.DrawLine(tPen, lastX, lastY, lastX, tmpY);
g.DrawLine(tPen, lastX, tmpY, tmpX, tmpY);
}
else if (this.StepType == StepType.ForwardSegment)
{
g.DrawLine(tPen, lastX, lastY, tmpX, lastY);
}
else
{
g.DrawLine(tPen, lastX, tmpY, tmpX, tmpY);
}
}
}
else
{
if (this.StepType == StepType.NonStep)
{
g.DrawLine(pen, lastX, lastY, tmpX, tmpY);
}
else if (this.StepType == StepType.ForwardStep)
{
g.DrawLine(pen, lastX, lastY, tmpX, lastY);
g.DrawLine(pen, tmpX, lastY, tmpX, tmpY);
}
else if (this.StepType == StepType.RearwardStep)
{
g.DrawLine(pen, lastX, lastY, lastX, tmpY);
g.DrawLine(pen, lastX, tmpY, tmpX, tmpY);
}
else if (this.StepType == StepType.ForwardSegment)
{
g.DrawLine(pen, lastX, lastY, tmpX, lastY);
}
else if (this.StepType == StepType.RearwardSegment)
{
g.DrawLine(pen, lastX, tmpY, tmpX, tmpY);
}
}
}
}
catch
{
this.InterpolatePoint(g, pane, curve, lastPt, scaleFactor, pen, lastX, lastY, tmpX, tmpY);
}
}
lastPt = curPt;
lastX = tmpX;
lastY = tmpY;
lastBad = false;
// lastOut = isOut;
}
}
}
}
}
/// <summary>
/// The graph_ point value event.
/// </summary>
/// <param name="sender">
/// The sender.
/// </param>
/// <param name="pane">
/// The pane.
/// </param>
/// <param name="curve">
/// The curve.
/// </param>
/// <param name="iPt">
/// The i pt.
/// </param>
/// <returns>
/// The <see cref="string"/>.
/// </returns>
private string graph_PointValueEvent(ZedGraphControl sender, GraphPane pane, CurveItem curve, int iPt)
{
PointPair point = curve[iPt];
var flight = point.Tag as Flight;
if (flight != null)
{
return flight.SummaryString;
}
return string.Empty;
}
