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2 Commits

Author SHA1 Message Date
Johannes Schmelz
748226f4ed added Move Camera based on player position 2024-11-23 19:27:04 +01:00
Johannes Schmelz
f658f53ba9 refactor 2024-11-23 19:26:36 +01:00
3 changed files with 27 additions and 53 deletions

View File

@ -5,47 +5,13 @@
## (c) Mark Minas (mark.minas@unibw.de)
########################################
#
# Battleship client configuration
#
# Specifies the map used by the opponent in single mode.
# Single mode is activated if this property is set.
#map.opponent=maps/map2.json
#
# Specifies the map used by the player in single mode.
# The player must define their own map if this property is not set.
map.own=maps/map1.json
#
# Coordinates of the shots fired by the RobotClient in the order listed.
# Example:
# 2, 0,\
# 2, 1,\
# 2, 2,\
# 2, 3
# defines four shots, namely at the coordinates
# (x=2, y=0), (x=2, y=1), (x=2, y=2), and (x=2, y=3)
robot.targets=2, 0,\
2, 1,\
2, 2,\
2, 3
#
# Delay in milliseconds between each shot fired by the RobotClient.
robot.delay=500
# Monopoly client configuration
#
# The dimensions of the game map used in single mode.
# 'map.width' defines the number of columns, and 'map.height' defines the number of rows.
map.width=10
map.height=10
#
# The number of ships of each length available in single mode.
# The value is a comma-separated list where each element corresponds to the number of ships
# with a specific length. For example:
# ship.nums=4, 3, 2, 1
# This configuration means:
# - 4 ships of length 1
# - 3 ships of length 2
# - 2 ships of length 3
# - 1 ship of length 4
ship.nums=4, 3, 2, 1
#
# Screen settings
#

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@ -39,21 +39,22 @@ public class CameraController {
* @param tpf Zeit pro Frame
*/
public void update(float tpf) {
// Aktualisiere den Winkel basierend auf der Geschwindigkeit
angle += speed * tpf;
if (angle >= FastMath.TWO_PI) {
angle -= FastMath.TWO_PI; // Winkel zurücksetzen, um Überläufe zu vermeiden
}
// Berechne die neue Position der Kamera
float x = center.x + radius * FastMath.cos(angle);
float z = center.z + radius * FastMath.sin(angle);
float y = center.y + height;
// Setze die Kameraposition
camera.setLocation(new Vector3f(x, y, z));
// Lasse die Kamera auf den Fokuspunkt blicken
camera.lookAt(center, Vector3f.UNIT_Y);
}
public void setPosition(int fieldID) {
camera.setLocation(fieldIdToVector(fieldID));
}
public void setPosition(float x, float y) {
camera.setLocation(new Vector3f(x,height,y));
}
private Vector3f fieldIdToVector(int fieldID) {
if (fieldID <= 10) return new Vector3f(4,height,0);
if (fieldID <= 20) return new Vector3f(0, height, 4);
if (fieldID <= 30) return new Vector3f(-4, height, 0);
if (fieldID <= 40) return new Vector3f(0, height, -4);
else throw new IllegalArgumentException();
}
}

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@ -1,5 +1,9 @@
package pp.monopoly.client.gui;
import java.util.concurrent.Executors;
import java.util.concurrent.ScheduledExecutorService;
import java.util.concurrent.TimeUnit;
import com.jme3.material.Material;
import com.jme3.math.ColorRGBA;
import com.jme3.math.Vector3f;
@ -43,15 +47,18 @@ public class TestWorld {
cameraController = new CameraController(
app.getCamera(), // Die Kamera der App
Vector3f.ZERO, // Fokus auf die Mitte des Spielfelds
5, // Radius des Kreises
3, // Höhe der Kamera
0.5f // Geschwindigkeit der Bewegung
4, // Radius des Kreises
2, // Höhe der Kamera
0 // Geschwindigkeit der Bewegung
);
// Füge die Toolbar hinzu
new Toolbar(app, cube);
cameraController.setPosition(0);
}
/**
* Aktualisiert die Kameraposition.
*