Ejemplo n.º 1
0
  public static void main(String[] args) {
    try {
      PlanStackData planData = new PlanStackData(10);

      TrackModel model = TrackModel.load("wheel2.saved_model");

      Point2D.Double point = new Point2D.Double(0.5, 90.0);
      OpponentObserver obs = new de.janquadflieg.mrracer.opponents.DebugObserver(point);

      double dist = 5.0;

      planData.addSegment(0, model.getSegment(0).getLength() - dist, 25.0);

      String msg =
          "(angle 0)(curLapTime 10.21)(damage 0)(distFromStart "
              + String.valueOf(dist)
              + ")(distRaced 10.0)(fuel 94)(gear 5)(lastLapTime 0)(opponents 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200 200)(racePos 1)(rpm 942.478)(speedX 170.0)(speedY 0)(speedZ 0.0196266)(track 4.00001 4.06171 4.25672 4.61881 5.22164 6.22291 8.00001 11.6952 23.0351 200 46.0701 23.3904 16 12.4458 10.4433 9.2376 8.51342 8.12341 7.99999)(trackPos 0.333332)(wheelSpinVel 0 0 0 0)(z 0.339955)(focus -1 -1 -1 -1 -1)";

      PlanStraight planner =
          new PlanStraight(new Plan2011(new de.janquadflieg.mrracer.controller.MrRacer2012()));

      planner.plan(planData, new SensorData(new scr.MessageBasedSensorModel(msg)), model, obs);

    } catch (Exception e) {
      e.printStackTrace(System.out);
    }
  }
Ejemplo n.º 2
0
  private PlanElement2011 plan(
      PlanStackData planData,
      SensorData data,
      TrackModel trackModel,
      OpponentObserver observer,
      boolean planning) {
    int index = planData.currentSegment();
    TrackSegment current = trackModel.getSegment(index);
    TrackSegment next = trackModel.getSegment(trackModel.incrementIndex(index));
    TrackSegment prev = trackModel.getSegment(trackModel.decrementIndex(index));

    double end = planData.end();
    double start = planData.start();

    if (Plan.TEXT_DEBUG && planning) {
      plan.println("");
      plan.println("------------ PlanStraight------------");
      plan.println(
          "Start/End: "
              + Utils.dTS(start)
              + ", "
              + Utils.dTS(end)
              + " ["
              + Utils.dTS(end - start)
              + "m]"
              + " - ");
      planData.print();
      plan.println("");
    }

    // plan like the last element?
    boolean planLikeLast = current.contains(data.getDistanceFromStartLine());

    if (planLikeLast) {
      start = data.getDistanceRaced();

      if (Plan.TEXT_DEBUG && planning) {
        plan.println("This is the last segment to plan for...");
      }
    }

    // check if we can combine the planning of this segment and the previous
    if (!planLikeLast && prev.isStraight()) {
      if (Plan.TEXT_DEBUG && planning) {
        plan.println("Previous is also straight, checking further...");
      }
      if (start - prev.getLength() <= data.getDistanceRaced()) {
        if (Plan.TEXT_DEBUG && planning) {
          plan.println("Prev is the last segment to plan for");
        }
        start = data.getDistanceRaced();
        planLikeLast = true;

      } else {
        if (Plan.TEXT_DEBUG && planning) {
          plan.println("Prev is also a middle segment");
        }
        start -= prev.getLength();
        int prevIndex = trackModel.decrementIndex(index);
        int prevPrevIndex = trackModel.decrementIndex(prevIndex);
        if (Plan.TEXT_DEBUG && planning) {
          plan.println("Switching prev from " + prevIndex + " to " + prevPrevIndex);
        }
        prev = trackModel.getSegment(prevPrevIndex);
      }

      if (Plan.TEXT_DEBUG && planning) {
        plan.println(
            "Moving start to " + Utils.dTS(start) + ", new length " + Utils.dTS(end - start) + "m");
      }
      planData.popSegment();
    }

    double brakeDistance = 0.0;

    if (planData.approachSpeed != Plan2013.MAX_SPEED) {
      if (planData.first()) {
        brakeDistance =
            plan.calcBrakingZoneStraight(data.getSpeed(), end - start, planData.approachSpeed);
      } else {
        brakeDistance =
            plan.calcBrakingZoneStraight(planData.speed(), end - start, planData.approachSpeed);
      }
    }

    if (Plan.TEXT_DEBUG && planning) {
      plan.println("Brake distance: " + Utils.dTS(brakeDistance) + "m");
    }

    Point2D targetPosition = OpponentObserver.NO_RECOMMENDED_POINT;

    if (observer.otherCars()
        && observer.getRecommendedPosition() != OpponentObserver.NO_RECOMMENDED_POINT) {
      Point2D recommendation = new Point2D.Double();
      recommendation.setLocation(observer.getRecommendedPosition());

      if (start <= recommendation.getY() && recommendation.getY() < end) {
        targetPosition = new Point2D.Double();
        targetPosition.setLocation(recommendation);
      }
    }

    // track positions
    ArrayList<Interpolator> positions = new ArrayList<>();

    double currStart = start;
    double remainingLength = end - start;
    double currPosition = plan.getAnchorPoint(prev, current);
    if (planLikeLast) {
      currPosition = data.getTrackPosition();
    }

    if (Plan.TEXT_DEBUG && planning) {
      plan.println(Utils.dTS(remainingLength) + "m remain...");
    }

    if (targetPosition != OpponentObserver.NO_RECOMMENDED_POINT) {
      if (Plan.TEXT_DEBUG && planning) {
        plan.println("I need to take care of other cars, point is " + targetPosition.toString());
        plan.println("Right now, i'm planning with currStart: " + Utils.dTS(currStart));
      }
      if (targetPosition.getY() < currStart) {
        if (Plan.TEXT_DEBUG && planning) {
          plan.println("Point is before currStart, moving it to +1m");
        }
        targetPosition.setLocation(targetPosition.getX(), targetPosition.getY() + 1.0);
      }

      if (Plan.TEXT_DEBUG && planning) {
        plan.println("Checking, if there is enough room...");
      }

      double lengthNeeded = targetPosition.getY() - currStart;

      if (Plan.TEXT_DEBUG && planning) {
        plan.println(
            "I need at least "
                + Utils.dTS(lengthNeeded)
                + "m, "
                + Utils.dTS(remainingLength)
                + "m remain");
      }

      if (remainingLength < lengthNeeded) {
        targetPosition = OpponentObserver.NO_RECOMMENDED_POINT;
        if (Plan.TEXT_DEBUG && planning) {
          plan.println("Cannot overtake, not enough room");
        }
      }
    }

    if (targetPosition != OpponentObserver.NO_RECOMMENDED_POINT) {
      if (Plan.TEXT_DEBUG && planning) {
        plan.println("Trying to overtake");
      }

      // switch Position 1
      double[] xP = new double[3];
      double[] yP = new double[3];

      xP[0] = currStart;
      xP[2] = targetPosition.getY();
      xP[1] = (xP[0] + xP[2]) / 2.0;

      yP[0] = currPosition;
      yP[2] = targetPosition.getX();
      yP[1] = (yP[0] + yP[2]) / 2.0;

      if (Plan.TEXT_DEBUG && planning) {
        plan.println("Switch Position 1:");
        for (int k = 0; k < xP.length; ++k) {
          plan.println(xP[k] + " , " + yP[k]);
        }
      }

      CubicSpline spline = new CubicSpline(xP, yP);
      spline.setDerivLimits(0.0, 0.0);
      positions.add(new FlanaganCubicWrapper(spline));

      currStart = xP[2];
      remainingLength = end - currStart;
      currPosition = targetPosition.getX();

      // overtaking
      if (Plan.TEXT_DEBUG && planning) {
        plan.println("Overtaking line");
      }

      xP = new double[3];

      xP[0] = currStart;
      xP[2] = end - 150.0;

      if (Plan.TEXT_DEBUG && planning) {
        plan.println(
            "Overtaking line: "
                + Utils.dTS(currStart)
                + " "
                + Utils.dTS(end - 150.0)
                + " "
                + targetPosition.getX());
      }

      positions.add(new ConstantValue(xP[0], xP[2], targetPosition.getX()));

      currStart = xP[2];
      remainingLength = end - currStart;
      currPosition = targetPosition.getX();
    }

    // simply drive towards the target position for the next corner
    if (Plan.TEXT_DEBUG && planning) {
      plan.println("Planning towards the next corner...");
    }

    double[] xP = new double[3];
    double[] yP = new double[3];

    xP[0] = currStart;
    xP[2] = end;
    xP[1] = (xP[0] + xP[2]) / 2.0;

    yP[0] = currPosition;

    double absCurrPosition =
        SensorData.calcAbsoluteTrackPosition(currPosition, trackModel.getWidth());
    double possibleDelta = Plan2013.calcPossibleSwitchDelta(data, end - currStart);
    double anchor = plan.getAnchorPoint(current, next);
    double absDesiredPosition = SensorData.calcAbsoluteTrackPosition(anchor, trackModel.getWidth());

    if (Plan.TEXT_DEBUG && planning) {
      plan.println("absCurrPosition: " + Utils.dTS(absCurrPosition));
      plan.println("PossibleDelta: " + Utils.dTS(possibleDelta));
      plan.println("absDesiredPosition: " + Utils.dTS(absDesiredPosition));
    }

    if (Math.abs(absDesiredPosition - absCurrPosition) <= possibleDelta) {
      if (Plan.TEXT_DEBUG && planning) {
        plan.println("Positioning ok");
      }
      yP[2] = plan.getAnchorPoint(current, next);

    } else {
      // move to the right
      if (anchor < 0) {
        yP[2] =
            SensorData.calcRelativeTrackPosition(
                absCurrPosition + possibleDelta, trackModel.getWidth());

      } else {
        // move to the left
        yP[2] =
            SensorData.calcRelativeTrackPosition(
                absCurrPosition - possibleDelta, trackModel.getWidth());
      }
    }

    yP[1] = (yP[0] + yP[2]) / 2.0;

    if (Plan.TEXT_DEBUG && planning) {
      plan.println("Position towards the next corner:");
      for (int k = 0; k < xP.length; ++k) {
        plan.println(xP[k] + " , " + yP[k]);
      }
    }

    CubicSpline spline = new CubicSpline(xP, yP);
    spline.setDerivLimits(0.0, 0.0);
    positions.add(new FlanaganCubicWrapper(spline));

    // target speed
    double[] xS;
    double[] yS;

    if (brakeDistance >= end - start || brakeDistance == 0.0) {
      xS = new double[3];
      yS = new double[3];

      xS[0] = start;
      xS[2] = end;
      xS[1] = (xS[0] + xS[2]) / 2.0;

      if (brakeDistance == 0.0) {
        yS[0] = Plan2013.MAX_SPEED;
        yS[1] = Plan2013.MAX_SPEED;
        yS[2] = Plan2013.MAX_SPEED;
        planData.approachSpeed = Plan2013.MAX_SPEED;

      } else {
        yS[0] = planData.approachSpeed;
        yS[1] = planData.approachSpeed;
        yS[2] = planData.approachSpeed;
        planData.approachSpeed =
            plan.calcApproachSpeedStraight(planData.approachSpeed, end - start);
      }

    } else {
      xS = new double[4];
      yS = new double[4];

      xS[0] = start;
      xS[1] = end - brakeDistance;
      xS[2] = end - (brakeDistance * 0.99);
      xS[3] = end;

      yS[0] = Plan2013.MAX_SPEED;
      yS[1] = Plan2013.MAX_SPEED;
      yS[2] = planData.approachSpeed;
      yS[3] = planData.approachSpeed;

      planData.approachSpeed = Plan2013.MAX_SPEED;
    }

    if (Plan.TEXT_DEBUG && planning) {
      plan.println("Speed:");
      for (int i = 0; i < xS.length; ++i) {
        plan.println(xS[i] + " , " + yS[i]);
      }
    }

    LinearInterpolator speed;

    try {
      speed = new LinearInterpolator(xS, yS);

    } catch (RuntimeException e) {
      System.out.println("*****************EXCEPTION**************");
      System.out.println(
          "Start/End: "
              + Utils.dTS(start)
              + ", "
              + Utils.dTS(end)
              + " ["
              + Utils.dTS(end - start)
              + "m]"
              + " - ");
      System.out.println("Segment: " + current.toString());
      System.out.println("Start: " + start);
      System.out.println("End: " + end);
      System.out.println("BrakeDistance: " + brakeDistance);
      System.out.println("Data:");
      try {
        java.io.OutputStreamWriter osw = new java.io.OutputStreamWriter(System.out);
        SensorData.writeHeader(osw);
        osw.append('\n');
        data.write(osw);
        osw.flush();

      } catch (Exception schwupp) {

      }
      System.out.println("");
      System.out.println("Speed:");
      for (int i = 0; i < xS.length; ++i) {
        System.out.println(xS[i] + " , " + yS[i]);
      }
      System.out.println("Complete Model:");
      trackModel.print();

      throw e;
    }

    PlanElement2011 element = new PlanElement2011(xS[0], xS[xS.length - 1], "Accelerate");

    for (Interpolator cs : positions) {
      element.attachPosition(cs);
    }

    element.setSpeed(speed);

    return element;
  }