public ILength Distance(IPosition p)
{
return(CircularArcGeometry.GetDistance(this, p));
}
internal void Draw()
{
ISpatialDisplay display = m_Cmd.ActiveDisplay;
// Draw the line we're extending in a special colour (any highlighting it
// originally had should have been removed during LineExtensionControl_Load)
if (m_ExtendLine!=null)
m_ExtendLine.Draw(display, Color.DarkBlue);
// If we're doing an update, draw the original extension in grey.
LineExtensionOperation pop = UpdateOp;
if (pop!=null)
{
LineFeature origLine = pop.NewLine;
if (origLine!=null)
origLine.Draw(display, Color.Gray);
PointFeature origPoint = pop.NewPoint;
if (origPoint!=null)
origPoint.Draw(display, Color.Gray);
}
// Calculate the start and end points of the extension, initially
// assuming that it's a straight line extension.
IPosition start, end;
if (LineExtensionUI.Calculate(m_ExtendLine, m_IsExtendFromEnd, m_Length, out start, out end))
{
// Draw the straight extension line
IDrawStyle style = (m_WantLine ? new DrawStyle(Color.Magenta) : new DottedStyle(Color.Magenta));
LineSegmentGeometry seg = new LineSegmentGeometry(start, end);
seg.Render(display, style);
}
else
{
// Perhaps it's a circular arc ...
IPosition center;
bool iscw;
if (LineExtensionUI.Calculate(m_ExtendLine, m_IsExtendFromEnd, m_Length,
out start, out end, out center, out iscw))
{
// And draw the curve.
IDrawStyle style = (m_WantLine ? new DrawStyle(Color.Magenta) : new DottedStyle(Color.Magenta));
IPointGeometry c = PointGeometry.Create(center);
CircularArcGeometry arc = new CircularArcGeometry(c, start, end, iscw);
arc.Render(display, style);
}
else if (m_ExtendLine!=null)
{
// Get the position we're extending from.
end = (m_IsExtendFromEnd ? m_ExtendLine.EndPoint : m_ExtendLine.StartPoint);
}
}
// If we actually got something, draw the end point.
if (end!=null)
{
IDrawStyle style = m_Cmd.Controller.DrawStyle;
style.FillColor = Color.Magenta;
style.Render(display, end);
}
}
public void Render(ISpatialDisplay display, IDrawStyle style)
{
CircularArcGeometry.Render(this, display, style);
}
public void Render(ISpatialDisplay display, IDrawStyle style)
{
if (this.category == CadastralLineCategory.Radial)
style = new DottedStyle(style.LineColor);
if (m_Center == null)
style.Render(display, this.PositionArray);
else
{
// radius less than zero may represent a counter-clockwise direction
bool isClockwise = (this.radius > 0.0);
// Define a circular arc that is assumed to run clockwise.
ICircleGeometry circle = new CircleGeometry(m_Center.Geometry, Math.Abs(this.radius));
ICircularArcGeometry arc = new CircularArcGeometry(circle, m_From.Geometry, m_To.Geometry, isClockwise);
// Assume clockwise, see what it looks like
style.Render(display, arc);
}
/*
else
{
if (!this.arcLengthSpecified)
throw new ApplicationException("Cannot determine arc direction");
// Define a circular arc that is assumed to run clockwise.
CircleGeometry circle = new CircleGeometry(m_Center.Geometry, this.radius);
CircularArcGeometry arc = new CircularArcGeometry(circle, m_From.Geometry, m_To.Geometry, true);
// Assume clockwise, see what it looks like
new DrawStyle(Color.Red).Render(display, arc);
//double arcLength = arc.Length.Meters;
//double othLength = circle.Length.Meters;
//// Get the arc length in meters (TODO: need to access file header to determine how to convert lengths)
//if (Math.Abs(othLength - this.arcLength) < Math.Abs(arcLength - this.arcLength))
// arc.IsClockwise = false;
}
*/
}
/// <summary>
/// Draws the current state of the edit
/// </summary>
internal void Draw()
{
Debug.Assert(m_Line!=null);
ISpatialDisplay view = ActiveDisplay;
// Figure out the positions for the ends of the parallel line (if any) ...
// Assume we already know both terminals.
IPosition start = m_Term1;
IPosition end = m_Term2;
// If either one is undefined, but a dialog for it is active,
// try to get the terminal from there instead.
if (m_TermDial1!=null && start==null)
start = m_TermDial1.TerminalPosition;
if (m_TermDial2!=null && end==null)
end = m_TermDial2.TerminalPosition;
// If they weren't actually defined, use the parallel points instead.
if (start==null)
start = m_Par1;
if (end==null)
end = m_Par2;
// If those weren't defined either, try to calculate them now.
if (end==null && Calculate())
{
start = m_Par1;
end = m_Par2;
}
// Any offset point
if (m_OffsetPoint!=null)
m_OffsetPoint.Draw(view, Color.Green);
// Everything else should draw in usual command-style colour.
IDrawStyle style = EditingController.Current.Style(Color.Magenta);
IDrawStyle dottedStyle = new DottedStyle();
// If the reference line is a curve, get the curve info.
ArcFeature arc = m_Line.GetArcBase();
if (arc != null)
{
bool iscw = arc.IsClockwise;
// Reverse the direction if necessary.
if (m_IsReversed)
iscw = !iscw;
// Draw the parallel line (the rest of the circle being dotted).
if (start!=null)
{
CircularArcGeometry parArc = new CircularArcGeometry(arc.Circle, start, end, iscw);
style.Render(view, parArc);
parArc.IsClockwise = !parArc.IsClockwise;
dottedStyle.Render(view, parArc);
}
}
else
{
// PARALLEL IS STRAIGHT
// If we've got something, figure out positions for dotted portion.
if (start!=null)
{
// What's the max length of a diagonal crossing the entire screen?
double maxdiag = this.MaxDiagonal;
// What's the bearing from the start to the end of the parallel?
double bearing = Geom.BearingInRadians(start, end);
// Project to a point before the start end of the parallel, as
// well as a point after the end.
IPosition before = Geom.Polar(start, bearing+Constants.PI, maxdiag);
IPosition after = Geom.Polar(end, bearing, maxdiag);
LineSegmentGeometry.Render(before, start, view, dottedStyle);
LineSegmentGeometry.Render(start, end, view, style);
LineSegmentGeometry.Render(end, after, view, dottedStyle);
}
}
// Draw terminal positions (if defined).
if (m_Term1!=null)
style.Render(view, m_Term1);
if (m_Term2!=null)
style.Render(view, m_Term2);
// The terminal lines.
if (m_TermLine1!=null)
m_TermLine1.Render(view, style);
if (m_TermLine2!=null)
m_TermLine2.Render(view, style);
// Do the active dialog last so their stuff draws on top.
if (m_ParDial!=null)
m_ParDial.Draw();
if (m_TermDial1!=null)
m_TermDial1.Draw();
if (m_TermDial2!=null)
m_TermDial2.Draw();
}
/// <summary>
/// Obtains the geometry for spans along an alternate face attached to this leg.
/// </summary>
/// <param name="legStart">The position for the start of the leg.
/// <param name="legEnd">The position for the end of the leg.</param>
/// <param name="spans">Information for the spans coinciding with this leg.</param>
/// <returns>The sections along this leg</returns>
internal override ILineGeometry[] GetSpanSections(IPosition legStart, IPosition legEnd, SpanInfo[] spans)
{
var result = new ILineGeometry[spans.Length];
Debug.Assert(AlternateFace != null);
// Define the arc that corresponds to the complete leg (the circle should have been
// already defined when we processed the primary face_.
Debug.Assert(Circle != null);
var arc = new CircularArcGeometry(Circle, legStart, legEnd, m_Metrics.IsClockwise);
// Handle case where the leg is a cul-de-sac with no observed spans on the alternate face
if (spans.Length == 1 && spans[0].ObservedDistance == null)
{
result[0] = arc;
return result;
}
// Get the required arc length (in meters on the ground)
double len = arc.Length.Meters;
// Get the observed arc length (in meters on the ground)
double obs = AlternateFace.GetTotal();
// Get the adjustment factor for stretching-compressing the observed distances.
double factor = len / obs;
// Define start of first arc.
IPosition sPos = legStart;
IPosition ePos = null;
// Haven't got anywhere yet.
double totobs = 0.0;
// Figure out the location of each span
for (int i = 0; i < result.Length; i++, sPos = ePos)
{
if (i == result.Length - 1)
{
ePos = legEnd;
}
else
{
// Add on the unscaled distance
totobs += spans[i].ObservedDistance.Meters;
// Scale to the required length for the overall leg
double elen = totobs * factor;
// Define the end position.
arc.GetPosition(new Length(elen), out ePos);
}
result[i] = new CircularArcGeometry(Circle, sPos, ePos, m_Metrics.IsClockwise);
}
return result;
}
/// <summary>
/// Obtains the geometry for spans along this leg.
/// </summary>
/// <param name="bc">The position for the start of the leg.
/// <param name="bcBearing">The bearing on entry into the leg.</param>
/// <param name="sfac">Scale factor to apply to distances.</param>
/// <param name="spans">Information for the spans coinciding with this leg.</param>
/// <returns>The sections along this leg</returns>
internal override ILineGeometry[] GetSpanSections(IPosition bc, double bcBearing, double sfac, SpanInfo[] spans)
{
// Can't do anything if the leg radius isn't defined
if (m_Metrics.ObservedRadius == null)
throw new InvalidOperationException("Cannot create sections for circular leg with undefined radius");
var result = new ILineGeometry[spans.Length];
// Use supplied stuff to derive info on the center and EC.
IPosition center;
IPosition ec;
double bearingToBC;
double ecBearing;
GetPositions(bc, bcBearing, sfac, out center, out bearingToBC, out ec, out ecBearing);
// Define the underlying circle
ICircleGeometry circle = new CircleGeometry(PointGeometry.Create(center), BasicGeom.Distance(center, bc));
// Handle case where the leg is a cul-de-sac with no observed spans
if (spans.Length == 1 && spans[0].ObservedDistance == null)
{
result[0] = new CircularArcGeometry(circle, bc, ec, m_Metrics.IsClockwise);
return result;
}
/// Initialize scaling factor for distances in cul-de-sacs (ratio of the length calculated from
/// the CA & Radius, versus the observed distances that were actually specified). For curves that
/// are not cul-de-sacs, this will be 1.0
double culFactor = 1.0;
if (m_Metrics.IsCulDeSac)
{
double obsv = PrimaryFace.GetTotal();
if (obsv > MathConstants.TINY)
culFactor = Length.Meters / obsv;
}
IPosition sPos = bc;
IPosition ePos = null;
bool isClockwise = m_Metrics.IsClockwise;
double radius = RadiusInMeters;
double edist = 0.0;
for (int i = 0; i < result.Length; i++, sPos = ePos)
{
// Add on the unscaled distance
edist += spans[i].ObservedDistance.Meters;
// Get the angle subtended at the center of the circle. We use
// unscaled values here, since the scale factors would cancel out.
// However, we DO apply any cul-de-sac scaling factor, to account
// for the fact that the distance may be inconsistent with the
// curve length derived from the CA and radius. For example, it
// is possible that the calculated curve length=200, although the
// total of the observed spans is somehow only 100. In that case,
// if the supplied distance is 50, we actually want to use a
// value of 50 * (200/100) = 100.
double angle = (edist * culFactor) / radius;
// Get the bearing of the point with respect to the center of the circle.
double bearing;
if (isClockwise)
bearing = bearingToBC + angle;
else
bearing = bearingToBC - angle;
// Calculate the position using the scaled radius.
ePos = Geom.Polar(center, bearing, radius * sfac);
result[i] = new CircularArcGeometry(circle, sPos, ePos, isClockwise);
}
return result;
}