Difference between revisions of "Wall Smoothing/Exact"
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private final double MAX_Y; | private final double MAX_Y; | ||
− | public | + | public ExactWallSmooth(double fieldWidth, double fieldHeight) { |
MIN_X = WALL_PADDING; | MIN_X = WALL_PADDING; | ||
MIN_Y = WALL_PADDING; | MIN_Y = WALL_PADDING; |
Revision as of 16:25, 24 September 2017
Unlike any other wall smoothing method, all using some kind of imaginary stick — this approach simulates exact robocode physics without using iterations.
public final class ExactWallSmooth {
private static final double DELTA_SIN = Math.sin(Rules.getTurnRateRadians(Rules.MAX_VELOCITY) / 2);
private static final double DELTA_COS = Math.sqrt(1 - DELTA_SIN * DELTA_SIN);
private static final double INNER_R = Rules.MAX_VELOCITY / 2 / Math.tan(Rules.getTurnRateRadians(Rules.MAX_VELOCITY) / 2);
private static final double OUTER_R = Rules.MAX_VELOCITY / 2 / DELTA_SIN;
private static final double WALL_PADDING = 18.5;
private final double MIN_X;
private final double MIN_Y;
private final double MAX_X;
private final double MAX_Y;
public ExactWallSmooth(double fieldWidth, double fieldHeight) {
MIN_X = WALL_PADDING;
MIN_Y = WALL_PADDING;
MAX_X = fieldWidth - WALL_PADDING;
MAX_Y = fieldHeight - WALL_PADDING;
}
public double smoothHeading(double absoluteHeading, @Output Trig headingTrig, double x, double y, int latDir) {
double stickBearingSin = +headingTrig.cos * latDir;
double stickBearingCos = -headingTrig.sin * latDir;
double stickX = x + INNER_R * stickBearingSin + 4 * headingTrig.sin;
double stickY = y + INNER_R * stickBearingCos + 4 * headingTrig.cos;
double stickDistW = stickX - MIN_X;
double stickDistE = MAX_X - stickX;
double stickDistN = MAX_Y - stickY;
double stickDistS = stickY - MIN_Y;
double distW = x - MIN_X;
double distE = MAX_X - x;
double distN = MAX_Y - y;
double distS = y - MIN_Y;
double stickDistH;
WALL wallH = null;
if (stickDistW < stickDistE) {
stickDistH = stickDistW;
if (stickDistH < OUTER_R - 0.1) {
wallH = WALL.W;
}
} else {
stickDistH = stickDistE;
if (stickDistH < OUTER_R - 0.1) {
wallH = WALL.E;
}
}
double stickDistV;
WALL wallV = null;
if (stickDistS < stickDistN) {
stickDistV = stickDistS;
if (stickDistV < OUTER_R - 0.1) {
wallV = WALL.S;
}
} else {
stickDistV = stickDistN;
if (stickDistV < OUTER_R - 0.1) {
wallV = WALL.N;
}
}
WALL forwardHWall;
if (headingTrig.sin < 0) {
forwardHWall = WALL.W;
} else {
forwardHWall = WALL.E;
}
WALL forwardVWall;
if (headingTrig.cos < 0) {
forwardVWall = WALL.S;
} else {
forwardVWall = WALL.N;
}
WALL firstWall = null;
WALL secondWall = null;
double firstDist = Double.NaN;
double secondDist = Double.NaN;
if (forwardHWall == wallH && forwardVWall == wallV) {
if (latDir > 0) {
if (forwardHWall == WALL.W) {
if (forwardVWall == WALL.N) {
firstWall = WALL.W;
firstDist = distW;
secondWall = WALL.N;
secondDist = distN;
} else {
firstWall = WALL.S;
firstDist = distS;
secondWall = WALL.W;
secondDist = distW;
}
} else {
if (forwardVWall == WALL.N) {
firstWall = WALL.N;
firstDist = distN;
secondWall = WALL.E;
secondDist = distE;
} else {
firstWall = WALL.E;
firstDist = distE;
secondWall = WALL.S;
secondDist = distS;
}
}
} else {
if (forwardHWall == WALL.W) {
if (forwardVWall == WALL.N) {
firstWall = WALL.N;
firstDist = distN;
secondWall = WALL.W;
secondDist = distW;
} else {
firstWall = WALL.W;
firstDist = distW;
secondWall = WALL.S;
secondDist = distS;
}
} else {
if (forwardVWall == WALL.N) {
firstWall = WALL.E;
firstDist = distE;
secondWall = WALL.N;
secondDist = distN;
} else {
firstWall = WALL.S;
firstDist = distS;
secondWall = WALL.E;
secondDist = distE;
}
}
}
} else if (forwardHWall == wallH) {
firstWall = wallH;
firstDist = wallH == WALL.W ? distW : distE;
} else if (forwardVWall == wallV) {
firstWall = wallV;
firstDist = wallV == WALL.S ? distS : distN;
}
WALL smoothWall = firstWall;
double smoothDist = firstDist;
while (smoothWall != null) {
double wallSin = (OUTER_R - smoothDist) / OUTER_R;
if (wallSin > 1) {
wallSin = 1;
}
wallSin *= latDir;
double wallCos = Math.sqrt(1 - wallSin * wallSin);
double newWallSin = wallSin * DELTA_COS + wallCos * DELTA_SIN * latDir;
double newWallCos = wallCos * DELTA_COS - wallSin * DELTA_SIN * latDir;
if (newWallCos > 0) {
wallSin = newWallSin;
wallCos = newWallCos;
}
double newSin;
double newCos;
if (smoothWall == WALL.N) {
newSin = +wallSin;
newCos = +wallCos * +1;
} else if (smoothWall == WALL.E) {
newSin = +wallCos * +1;
newCos = -wallSin;
} else if (smoothWall == WALL.S) {
newSin = -wallSin;
newCos = -wallCos * +1;
} else {
newSin = -wallCos * +1;
newCos = +wallSin;
}
double newHeading = Math.atan2(newSin, newCos);
if (Math.signum(Utils.normalRelativeAngle(newHeading - absoluteHeading)) == latDir) {
headingTrig.sin = newSin;
headingTrig.cos = newCos;
absoluteHeading = newHeading;
if (debugSticks != null || debugHeadings != null) {
stickBearingSin = +newCos * latDir;
stickBearingCos = -newSin * latDir;
double imagineStickX = x + INNER_R * stickBearingSin + 4 * newSin;
double imagineStickY = y + INNER_R * stickBearingCos + 4 * newCos;
}
}
if (smoothWall == firstWall) {
smoothWall = secondWall;
smoothDist = secondDist;
} else {
break;
}
}
return absoluteHeading;
}
enum WALL {
W, N, E, S,
}
}