private static void DrawnTrajectory(Rect r, DefaultAscentPath path, MechJebModuleFlightRecorder recorder)
{
if (recorder.history.Length <= 2 || recorder.historyIdx == 0)
{
return;
}
float scale = (float)((path.autoPath ? path.autoTurnEndAltitude : path.turnEndAltitude) / r.height); //meters per pixel
int t = 1;
Vector2 p1 = new Vector2(r.xMin + (float)(recorder.history[0].downRange / scale), r.yMax - (float)(recorder.history[0].altitudeASL / scale));
Vector2 p2 = new Vector2();
while (t <= recorder.historyIdx && t < recorder.history.Length)
{
var rec = recorder.history[t];
p2.x = r.xMin + (float)(rec.downRange / scale);
p2.y = r.yMax - (float)(rec.altitudeASL / scale);
if (r.Contains(p2) && (p1 - p2).sqrMagnitude >= 1.0 || t < 2)
{
Drawing.DrawLine(p1, p2, Color.white, 2, true);
p1.x = p2.x;
p1.y = p2.y;
}
t++;
}
}
public static void DrawnPath(Rect r, float scaleX, float scaleY, DefaultAscentPath path, Color color)
{
float alt = 0;
float downrange = 0;
Vector2 p1 = new Vector2(r.xMin, r.yMax);
Vector2 p2 = new Vector2();
while (alt < (path.autoPath ? path.autoTurnEndAltitude : path.turnEndAltitude) && downrange < r.width * scaleX)
{
float desiredAngle = (float)(alt < path.VerticalAscentEnd() ? 90 : path.FlightPathAngle(alt, 0));
alt += scaleY * Mathf.Sin(desiredAngle * Mathf.Deg2Rad);
downrange += scaleX * Mathf.Cos(desiredAngle * Mathf.Deg2Rad);
p2.x = r.xMin + downrange / scaleX;
p2.y = r.yMax - alt / scaleY;
if ((p1 - p2).sqrMagnitude >= 1.0)
{
Drawing.DrawLine(p1, p2, color, 2, true);
p1.x = p2.x;
p1.y = p2.y;
}
}
}
public override void OnStart(PartModule.StartState state)
{
path = (DefaultAscentPath)core.GetComputerModule <MechJebModuleAscentAutopilot>().ascentPath;
}
public override void OnStart(PartModule.StartState state)
{
path = (DefaultAscentPath)core.GetComputerModule<MechJebModuleAscentAutopilot>().ascentPath;
}
private static void DrawnTrajectory(Rect r, DefaultAscentPath path, MechJebModuleFlightRecorder recorder)
{
if (recorder.history.Length <= 2 || recorder.historyIdx == 0)
return;
float scale = (float)((path.autoPath ? path.autoTurnEndAltitude : path.turnEndAltitude) / r.height); //meters per pixel
int t = 1;
Vector2 p1 = new Vector2(r.xMin + (float)(recorder.history[0].downRange / scale), r.yMax - (float)(recorder.history[0].altitudeASL / scale));
Vector2 p2 = new Vector2();
while (t <= recorder.historyIdx && t < recorder.history.Length)
{
var rec = recorder.history[t];
p2.x = r.xMin + (float)(rec.downRange / scale);
p2.y = r.yMax - (float)(rec.altitudeASL / scale);
if (r.Contains(p2) && (p1 - p2).sqrMagnitude >= 1.0 || t < 2)
{
Drawing.DrawLine(p1, p2, Color.white, 2, true);
p1.x = p2.x;
p1.y = p2.y;
}
t++;
}
}
public static void DrawnPath(Rect r, float scaleX, float scaleY, DefaultAscentPath path, Color color)
{
float alt = 0;
float downrange = 0;
Vector2 p1 = new Vector2(r.xMin, r.yMax);
Vector2 p2 = new Vector2();
while (alt < (path.autoPath ? path.autoTurnEndAltitude : path.turnEndAltitude) && downrange < r.width * scaleX)
{
float desiredAngle = (float)(alt < path.VerticalAscentEnd() ? 90 : path.FlightPathAngle(alt, 0));
alt += scaleY * Mathf.Sin(desiredAngle * Mathf.Deg2Rad);
downrange += scaleX * Mathf.Cos(desiredAngle * Mathf.Deg2Rad);
p2.x = r.xMin + downrange / scaleX;
p2.y = r.yMax - alt / scaleY;
if ((p1 - p2).sqrMagnitude >= 1.0)
{
Drawing.DrawLine(p1, p2, color, 2, true);
p1.x = p2.x;
p1.y = p2.y;
}
}
}
