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/*
 * Copyright (c) 2009-2012 jMonkeyEngine
 * All rights reserved.
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 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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package com.jme3.renderer;

import com.jme3.bounding.BoundingBox;
import com.jme3.bounding.BoundingVolume;
import com.jme3.export.*;
import com.jme3.math.*;
import com.jme3.util.TempVars;
import java.io.IOException;
import java.util.logging.Level;
import java.util.logging.Logger;

/**
 * Camera is a standalone, purely mathematical class for doing
 * camera-related computations.
 *
 * 

* Given input data such as location, orientation (direction, left, up), * and viewport settings, it can compute data necessary to render objects * with the graphics library. Two matrices are generated, the view matrix * transforms objects from world space into eye space, while the projection * matrix transforms objects from eye space into clip space. *

*

Another purpose of the camera class is to do frustum culling operations, * defined by six planes which define a 3D frustum shape, it is possible to * test if an object bounded by a mathematically defined volume is inside * the camera frustum, and thus to avoid rendering objects that are outside * the frustum *

* * @author Mark Powell * @author Joshua Slack */ public class Camera implements Savable, Cloneable { private static final Logger logger = Logger.getLogger(Camera.class.getName()); /** * The FrustumIntersect enum is returned as a result * of a culling check operation, * see {@link #contains(com.jme3.bounding.BoundingVolume) } */ public enum FrustumIntersect { /** * defines a constant assigned to spatials that are completely outside * of this camera's view frustum. */ Outside, /** * defines a constant assigned to spatials that are completely inside * the camera's view frustum. */ Inside, /** * defines a constant assigned to spatials that are intersecting one of * the six planes that define the view frustum. */ Intersects; } /** * LEFT_PLANE represents the left plane of the camera frustum. */ private static final int LEFT_PLANE = 0; /** * RIGHT_PLANE represents the right plane of the camera frustum. */ private static final int RIGHT_PLANE = 1; /** * BOTTOM_PLANE represents the bottom plane of the camera frustum. */ private static final int BOTTOM_PLANE = 2; /** * TOP_PLANE represents the top plane of the camera frustum. */ private static final int TOP_PLANE = 3; /** * FAR_PLANE represents the far plane of the camera frustum. */ private static final int FAR_PLANE = 4; /** * NEAR_PLANE represents the near plane of the camera frustum. */ private static final int NEAR_PLANE = 5; /** * FRUSTUM_PLANES represents the number of planes of the camera frustum. */ private static final int FRUSTUM_PLANES = 6; /** * MAX_WORLD_PLANES holds the maximum planes allowed by the system. */ private static final int MAX_WORLD_PLANES = 6; /** * Camera's location */ protected Vector3f location; /** * The orientation of the camera. */ protected Quaternion rotation; /** * Distance from camera to near frustum plane. */ protected float frustumNear; /** * Distance from camera to far frustum plane. */ protected float frustumFar; /** * Distance from camera to left frustum plane. */ protected float frustumLeft; /** * Distance from camera to right frustum plane. */ protected float frustumRight; /** * Distance from camera to top frustum plane. */ protected float frustumTop; /** * Distance from camera to bottom frustum plane. */ protected float frustumBottom; //Temporary values computed in onFrustumChange that are needed if a //call is made to onFrameChange. protected float[] coeffLeft; protected float[] coeffRight; protected float[] coeffBottom; protected float[] coeffTop; //view port coordinates /** * Percent value on display where horizontal viewing starts for this camera. * Default is 0. */ protected float viewPortLeft; /** * Percent value on display where horizontal viewing ends for this camera. * Default is 1. */ protected float viewPortRight; /** * Percent value on display where vertical viewing ends for this camera. * Default is 1. */ protected float viewPortTop; /** * Percent value on display where vertical viewing begins for this camera. * Default is 0. */ protected float viewPortBottom; /** * Array holding the planes that this camera will check for culling. */ protected Plane[] worldPlane; /** * A mask value set during contains() that allows fast culling of a Node's * children. */ private int planeState; protected int width; protected int height; protected boolean viewportChanged = true; /** * store the value for field parallelProjection */ private boolean parallelProjection = true; protected Matrix4f projectionMatrixOverride = new Matrix4f(); private boolean overrideProjection; protected Matrix4f viewMatrix = new Matrix4f(); protected Matrix4f projectionMatrix = new Matrix4f(); protected Matrix4f viewProjectionMatrix = new Matrix4f(); private BoundingBox guiBounding = new BoundingBox(); /** The camera's name. */ protected String name; /** * Serialization only. Do not use. */ public Camera() { worldPlane = new Plane[MAX_WORLD_PLANES]; for (int i = 0; i < MAX_WORLD_PLANES; i++) { worldPlane[i] = new Plane(); } } /** * Constructor instantiates a new Camera object. All * values of the camera are set to default. */ public Camera(int width, int height) { this(); location = new Vector3f(); rotation = new Quaternion(); frustumNear = 1.0f; frustumFar = 2.0f; frustumLeft = -0.5f; frustumRight = 0.5f; frustumTop = 0.5f; frustumBottom = -0.5f; coeffLeft = new float[2]; coeffRight = new float[2]; coeffBottom = new float[2]; coeffTop = new float[2]; viewPortLeft = 0.0f; viewPortRight = 1.0f; viewPortTop = 1.0f; viewPortBottom = 0.0f; this.width = width; this.height = height; onFrustumChange(); onViewPortChange(); onFrameChange(); logger.log(Level.FINE, "Camera created (W: {0}, H: {1})", new Object[]{width, height}); } @Override public Camera clone() { try { Camera cam = (Camera) super.clone(); cam.viewportChanged = true; cam.planeState = 0; cam.worldPlane = new Plane[MAX_WORLD_PLANES]; for (int i = 0; i < worldPlane.length; i++) { cam.worldPlane[i] = worldPlane[i].clone(); } cam.coeffLeft = new float[2]; cam.coeffRight = new float[2]; cam.coeffBottom = new float[2]; cam.coeffTop = new float[2]; cam.location = location.clone(); cam.rotation = rotation.clone(); if (projectionMatrixOverride != null) { cam.projectionMatrixOverride = projectionMatrixOverride.clone(); } cam.viewMatrix = viewMatrix.clone(); cam.projectionMatrix = projectionMatrix.clone(); cam.viewProjectionMatrix = viewProjectionMatrix.clone(); cam.guiBounding = (BoundingBox) guiBounding.clone(); cam.update(); return cam; } catch (CloneNotSupportedException ex) { throw new AssertionError(); } } /** * This method copies the settings of the given camera. * * @param cam * the camera we copy the settings from */ public void copyFrom(Camera cam) { location.set(cam.location); rotation.set(cam.rotation); frustumNear = cam.frustumNear; frustumFar = cam.frustumFar; frustumLeft = cam.frustumLeft; frustumRight = cam.frustumRight; frustumTop = cam.frustumTop; frustumBottom = cam.frustumBottom; coeffLeft[0] = cam.coeffLeft[0]; coeffLeft[1] = cam.coeffLeft[1]; coeffRight[0] = cam.coeffRight[0]; coeffRight[1] = cam.coeffRight[1]; coeffBottom[0] = cam.coeffBottom[0]; coeffBottom[1] = cam.coeffBottom[1]; coeffTop[0] = cam.coeffTop[0]; coeffTop[1] = cam.coeffTop[1]; viewPortLeft = cam.viewPortLeft; viewPortRight = cam.viewPortRight; viewPortTop = cam.viewPortTop; viewPortBottom = cam.viewPortBottom; this.width = cam.width; this.height = cam.height; this.planeState = 0; this.viewportChanged = true; for (int i = 0; i < MAX_WORLD_PLANES; ++i) { worldPlane[i].setNormal(cam.worldPlane[i].getNormal()); worldPlane[i].setConstant(cam.worldPlane[i].getConstant()); } this.parallelProjection = cam.parallelProjection; this.overrideProjection = cam.overrideProjection; this.projectionMatrixOverride.set(cam.projectionMatrixOverride); this.viewMatrix.set(cam.viewMatrix); this.projectionMatrix.set(cam.projectionMatrix); this.viewProjectionMatrix.set(cam.viewProjectionMatrix); this.guiBounding.setXExtent(cam.guiBounding.getXExtent()); this.guiBounding.setYExtent(cam.guiBounding.getYExtent()); this.guiBounding.setZExtent(cam.guiBounding.getZExtent()); this.guiBounding.setCenter(cam.guiBounding.getCenter()); this.guiBounding.setCheckPlane(cam.guiBounding.getCheckPlane()); this.name = cam.name; } /** * This method sets the cameras name. * @param name the cameras name */ public void setName(String name) { this.name = name; } /** * This method returns the cameras name. * @return the cameras name */ public String getName() { return name; } /** * Sets a clipPlane for this camera. * The clipPlane is used to recompute the * projectionMatrix using the plane as the near plane * This technique is known as the oblique near-plane clipping method introduced by Eric Lengyel * more info here * * * Note that this will work properly only if it's called on each update, and be aware that it won't work properly with the sky bucket. * if you want to handle the sky bucket, look at how it's done in SimpleWaterProcessor.java * @param clipPlane the plane * @param side the side the camera stands from the plane */ public void setClipPlane(Plane clipPlane, Plane.Side side) { float sideFactor = 1; if (side == Plane.Side.Negative) { sideFactor = -1; } //we are on the other side of the plane no need to clip anymore. if (clipPlane.whichSide(location) == side) { return; } TempVars vars = TempVars.get(); try { Matrix4f p = projectionMatrixOverride.set(projectionMatrix); Matrix4f ivm = viewMatrix; Vector3f point = clipPlane.getNormal().mult(clipPlane.getConstant(), vars.vect1); Vector3f pp = ivm.mult(point, vars.vect2); Vector3f pn = ivm.multNormal(clipPlane.getNormal(), vars.vect3); Vector4f clipPlaneV = vars.vect4f1.set(pn.x * sideFactor, pn.y * sideFactor, pn.z * sideFactor, -(pp.dot(pn)) * sideFactor); Vector4f v = vars.vect4f2.set(0, 0, 0, 0); v.x = (Math.signum(clipPlaneV.x) + p.m02) / p.m00; v.y = (Math.signum(clipPlaneV.y) + p.m12) / p.m11; v.z = -1.0f; v.w = (1.0f + p.m22) / p.m23; float dot = clipPlaneV.dot(v);//clipPlaneV.x * v.x + clipPlaneV.y * v.y + clipPlaneV.z * v.z + clipPlaneV.w * v.w; Vector4f c = clipPlaneV.multLocal(2.0f / dot); p.m20 = c.x - p.m30; p.m21 = c.y - p.m31; p.m22 = c.z - p.m32; p.m23 = c.w - p.m33; setProjectionMatrix(p); } finally { vars.release(); } } /** * Sets a clipPlane for this camera. * The cliPlane is used to recompute the projectionMatrix using the plane as the near plane * This technique is known as the oblique near-plane clipping method introduced by Eric Lengyel * more info here * * * Note that this will work properly only if it's called on each update, and be aware that it won't work properly with the sky bucket. * if you want to handle the sky bucket, look at how it's done in SimpleWaterProcessor.java * @param clipPlane the plane */ public void setClipPlane(Plane clipPlane) { setClipPlane(clipPlane, clipPlane.whichSide(location)); } /** * Resizes this camera's view with the given width and height. This is * similar to constructing a new camera, but reusing the same Object. This * method is called by an associated {@link RenderManager} to notify the camera of * changes in the display dimensions. * * @param width the view width * @param height the view height * @param fixAspect If true, the camera's aspect ratio will be recomputed. * Recomputing the aspect ratio requires changing the frustum values. */ public void resize(int width, int height, boolean fixAspect) { this.width = width; this.height = height; onViewPortChange(); if (fixAspect /*&& !parallelProjection*/) { frustumRight = frustumTop * ((float) width / height); frustumLeft = -frustumRight; onFrustumChange(); } } /** * getFrustumBottom returns the value of the bottom frustum * plane. * * @return the value of the bottom frustum plane. */ public float getFrustumBottom() { return frustumBottom; } /** * setFrustumBottom sets the value of the bottom frustum * plane. * * @param frustumBottom the value of the bottom frustum plane. */ public void setFrustumBottom(float frustumBottom) { this.frustumBottom = frustumBottom; onFrustumChange(); } /** * getFrustumFar gets the value of the far frustum plane. * * @return the value of the far frustum plane. */ public float getFrustumFar() { return frustumFar; } /** * setFrustumFar sets the value of the far frustum plane. * * @param frustumFar the value of the far frustum plane. */ public void setFrustumFar(float frustumFar) { this.frustumFar = frustumFar; onFrustumChange(); } /** * getFrustumLeft gets the value of the left frustum plane. * * @return the value of the left frustum plane. */ public float getFrustumLeft() { return frustumLeft; } /** * setFrustumLeft sets the value of the left frustum plane. * * @param frustumLeft the value of the left frustum plane. */ public void setFrustumLeft(float frustumLeft) { this.frustumLeft = frustumLeft; onFrustumChange(); } /** * getFrustumNear gets the value of the near frustum plane. * * @return the value of the near frustum plane. */ public float getFrustumNear() { return frustumNear; } /** * setFrustumNear sets the value of the near frustum plane. * * @param frustumNear the value of the near frustum plane. */ public void setFrustumNear(float frustumNear) { this.frustumNear = frustumNear; onFrustumChange(); } /** * getFrustumRight gets the value of the right frustum plane. * * @return frustumRight the value of the right frustum plane. */ public float getFrustumRight() { return frustumRight; } /** * setFrustumRight sets the value of the right frustum plane. * * @param frustumRight the value of the right frustum plane. */ public void setFrustumRight(float frustumRight) { this.frustumRight = frustumRight; onFrustumChange(); } /** * getFrustumTop gets the value of the top frustum plane. * * @return the value of the top frustum plane. */ public float getFrustumTop() { return frustumTop; } /** * setFrustumTop sets the value of the top frustum plane. * * @param frustumTop the value of the top frustum plane. */ public void setFrustumTop(float frustumTop) { this.frustumTop = frustumTop; onFrustumChange(); } /** * getLocation retrieves the location vector of the camera. * * @return the position of the camera. * @see Camera#getLocation() */ public Vector3f getLocation() { return location; } /** * getRotation retrieves the rotation quaternion of the camera. * * @return the rotation of the camera. */ public Quaternion getRotation() { return rotation; } /** * getDirection retrieves the direction vector the camera is * facing. * * @return the direction the camera is facing. * @see Camera#getDirection() */ public Vector3f getDirection() { return rotation.getRotationColumn(2); } /** * getLeft retrieves the left axis of the camera. * * @return the left axis of the camera. * @see Camera#getLeft() */ public Vector3f getLeft() { return rotation.getRotationColumn(0); } /** * getUp retrieves the up axis of the camera. * * @return the up axis of the camera. * @see Camera#getUp() */ public Vector3f getUp() { return rotation.getRotationColumn(1); } /** * getDirection retrieves the direction vector the camera is * facing. * * @return the direction the camera is facing. * @see Camera#getDirection() */ public Vector3f getDirection(Vector3f store) { return rotation.getRotationColumn(2, store); } /** * getLeft retrieves the left axis of the camera. * * @return the left axis of the camera. * @see Camera#getLeft() */ public Vector3f getLeft(Vector3f store) { return rotation.getRotationColumn(0, store); } /** * getUp retrieves the up axis of the camera. * * @return the up axis of the camera. * @see Camera#getUp() */ public Vector3f getUp(Vector3f store) { return rotation.getRotationColumn(1, store); } /** * setLocation sets the position of the camera. * * @param location the position of the camera. */ public void setLocation(Vector3f location) { this.location.set(location); onFrameChange(); } /** * setRotation sets the orientation of this camera. This will * be equivalent to setting each of the axes: *
* cam.setLeft(rotation.getRotationColumn(0));
* cam.setUp(rotation.getRotationColumn(1));
* cam.setDirection(rotation.getRotationColumn(2));
*
* * @param rotation the rotation of this camera */ public void setRotation(Quaternion rotation) { this.rotation.set(rotation); onFrameChange(); } /** * lookAtDirection sets the direction the camera is facing * given a direction and an up vector. * * @param direction the direction this camera is facing. */ public void lookAtDirection(Vector3f direction, Vector3f up) { this.rotation.lookAt(direction, up); onFrameChange(); } /** * setAxes sets the axes (left, up and direction) for this * camera. * * @param left the left axis of the camera. * @param up the up axis of the camera. * @param direction the direction the camera is facing. * * @see Camera#setAxes(com.jme3.math.Quaternion) */ public void setAxes(Vector3f left, Vector3f up, Vector3f direction) { this.rotation.fromAxes(left, up, direction); onFrameChange(); } /** * setAxes uses a rotational matrix to set the axes of the * camera. * * @param axes the matrix that defines the orientation of the camera. */ public void setAxes(Quaternion axes) { this.rotation.set(axes); onFrameChange(); } /** * normalize normalizes the camera vectors. */ public void normalize() { this.rotation.normalizeLocal(); onFrameChange(); } /** * setFrustum sets the frustum of this camera object. * * @param near the near plane. * @param far the far plane. * @param left the left plane. * @param right the right plane. * @param top the top plane. * @param bottom the bottom plane. * @see Camera#setFrustum(float, float, float, float, * float, float) */ public void setFrustum(float near, float far, float left, float right, float top, float bottom) { frustumNear = near; frustumFar = far; frustumLeft = left; frustumRight = right; frustumTop = top; frustumBottom = bottom; onFrustumChange(); } /** * setFrustumPerspective defines the frustum for the camera. This * frustum is defined by a viewing angle, aspect ratio, and near/far planes * * @param fovY Frame of view angle along the Y in degrees. * @param aspect Width:Height ratio * @param near Near view plane distance * @param far Far view plane distance */ public void setFrustumPerspective(float fovY, float aspect, float near, float far) { if (Float.isNaN(aspect) || Float.isInfinite(aspect)) { // ignore. logger.log(Level.WARNING, "Invalid aspect given to setFrustumPerspective: {0}", aspect); return; } float h = FastMath.tan(fovY * FastMath.DEG_TO_RAD * .5f) * near; float w = h * aspect; frustumLeft = -w; frustumRight = w; frustumBottom = -h; frustumTop = h; frustumNear = near; frustumFar = far; // Camera is no longer parallel projection even if it was before parallelProjection = false; onFrustumChange(); } /** * setFrame sets the orientation and location of the camera. * * @param location the point position of the camera. * @param left the left axis of the camera. * @param up the up axis of the camera. * @param direction the facing of the camera. * @see Camera#setFrame(com.jme3.math.Vector3f, * com.jme3.math.Vector3f, com.jme3.math.Vector3f, com.jme3.math.Vector3f) */ public void setFrame(Vector3f location, Vector3f left, Vector3f up, Vector3f direction) { this.location = location; this.rotation.fromAxes(left, up, direction); onFrameChange(); } /** * lookAt is a convenience method for auto-setting the frame * based on a world position the user desires the camera to look at. It * repoints the camera towards the given position using the difference * between the position and the current camera location as a direction * vector and the worldUpVector to compute up and left camera vectors. * * @param pos where to look at in terms of world coordinates * @param worldUpVector a normalized vector indicating the up direction of the world. * (typically {0, 1, 0} in jME.) */ public void lookAt(Vector3f pos, Vector3f worldUpVector) { TempVars vars = TempVars.get(); Vector3f newDirection = vars.vect1; Vector3f newUp = vars.vect2; Vector3f newLeft = vars.vect3; newDirection.set(pos).subtractLocal(location).normalizeLocal(); newUp.set(worldUpVector).normalizeLocal(); if (newUp.equals(Vector3f.ZERO)) { newUp.set(Vector3f.UNIT_Y); } newLeft.set(newUp).crossLocal(newDirection).normalizeLocal(); if (newLeft.equals(Vector3f.ZERO)) { if (newDirection.x != 0) { newLeft.set(newDirection.y, -newDirection.x, 0f); } else { newLeft.set(0f, newDirection.z, -newDirection.y); } } newUp.set(newDirection).crossLocal(newLeft).normalizeLocal(); this.rotation.fromAxes(newLeft, newUp, newDirection); this.rotation.normalizeLocal(); vars.release(); onFrameChange(); } /** * setFrame sets the orientation and location of the camera. * * @param location * the point position of the camera. * @param axes * the orientation of the camera. */ public void setFrame(Vector3f location, Quaternion axes) { this.location = location; this.rotation.set(axes); onFrameChange(); } /** * update updates the camera parameters by calling * onFrustumChange,onViewPortChange and * onFrameChange. * * @see Camera#update() */ public void update() { onFrustumChange(); onViewPortChange(); //...this is always called by onFrustumChange() //onFrameChange(); } /** * getPlaneState returns the state of the frustum planes. So * checks can be made as to which frustum plane has been examined for * culling thus far. * * @return the current plane state int. */ public int getPlaneState() { return planeState; } /** * setPlaneState sets the state to keep track of tested * planes for culling. * * @param planeState the updated state. */ public void setPlaneState(int planeState) { this.planeState = planeState; } /** * getViewPortLeft gets the left boundary of the viewport * * @return the left boundary of the viewport */ public float getViewPortLeft() { return viewPortLeft; } /** * setViewPortLeft sets the left boundary of the viewport * * @param left the left boundary of the viewport */ public void setViewPortLeft(float left) { viewPortLeft = left; onViewPortChange(); } /** * getViewPortRight gets the right boundary of the viewport * * @return the right boundary of the viewport */ public float getViewPortRight() { return viewPortRight; } /** * setViewPortRight sets the right boundary of the viewport * * @param right the right boundary of the viewport */ public void setViewPortRight(float right) { viewPortRight = right; onViewPortChange(); } /** * getViewPortTop gets the top boundary of the viewport * * @return the top boundary of the viewport */ public float getViewPortTop() { return viewPortTop; } /** * setViewPortTop sets the top boundary of the viewport * * @param top the top boundary of the viewport */ public void setViewPortTop(float top) { viewPortTop = top; onViewPortChange(); } /** * getViewPortBottom gets the bottom boundary of the viewport * * @return the bottom boundary of the viewport */ public float getViewPortBottom() { return viewPortBottom; } /** * setViewPortBottom sets the bottom boundary of the viewport * * @param bottom the bottom boundary of the viewport */ public void setViewPortBottom(float bottom) { viewPortBottom = bottom; onViewPortChange(); } /** * setViewPort sets the boundaries of the viewport * * @param left the left boundary of the viewport (default: 0) * @param right the right boundary of the viewport (default: 1) * @param bottom the bottom boundary of the viewport (default: 0) * @param top the top boundary of the viewport (default: 1) */ public void setViewPort(float left, float right, float bottom, float top) { this.viewPortLeft = left; this.viewPortRight = right; this.viewPortBottom = bottom; this.viewPortTop = top; onViewPortChange(); } /** * Returns the pseudo distance from the given position to the near * plane of the camera. This is used for render queue sorting. * @param pos The position to compute a distance to. * @return Distance from the far plane to the point. */ public float distanceToNearPlane(Vector3f pos) { return worldPlane[NEAR_PLANE].pseudoDistance(pos); } /** * contains tests a bounding volume against the planes of the * camera's frustum. The frustum's planes are set such that the normals all * face in towards the viewable scene. Therefore, if the bounding volume is * on the negative side of the plane is can be culled out. * * NOTE: This method is used internally for culling, for public usage, * the plane state of the bounding volume must be saved and restored, e.g: * BoundingVolume bv;
* Camera c;
* int planeState = bv.getPlaneState();
* bv.setPlaneState(0);
* c.contains(bv);
* bv.setPlaneState(plateState);
*
* * @param bound the bound to check for culling * @return See enums in FrustumIntersect */ public FrustumIntersect contains(BoundingVolume bound) { if (bound == null) { return FrustumIntersect.Inside; } int mask; FrustumIntersect rVal = FrustumIntersect.Inside; for (int planeCounter = FRUSTUM_PLANES; planeCounter >= 0; planeCounter--) { if (planeCounter == bound.getCheckPlane()) { continue; // we have already checked this plane at first iteration } int planeId = (planeCounter == FRUSTUM_PLANES) ? bound.getCheckPlane() : planeCounter; // int planeId = planeCounter; mask = 1 << (planeId); if ((planeState & mask) == 0) { Plane.Side side = bound.whichSide(worldPlane[planeId]); if (side == Plane.Side.Negative) { //object is outside of frustum bound.setCheckPlane(planeId); return FrustumIntersect.Outside; } else if (side == Plane.Side.Positive) { //object is visible on *this* plane, so mark this plane //so that we don't check it for sub nodes. planeState |= mask; } else { rVal = FrustumIntersect.Intersects; } } } return rVal; } public Plane getWorldPlane(int planeId) { return worldPlane[planeId]; } /** * containsGui tests a bounding volume against the ortho * bounding box of the camera. A bounding box spanning from * 0, 0 to Width, Height. Constrained by the viewport settings on the * camera. * * @param bound the bound to check for culling * @return True if the camera contains the gui element bounding volume. */ public boolean containsGui(BoundingVolume bound) { if (bound == null) { return true; } return guiBounding.intersects(bound); } /** * @return the view matrix of the camera. * The view matrix transforms world space into eye space. * This matrix is usually defined by the position and * orientation of the camera. */ public Matrix4f getViewMatrix() { return viewMatrix; } /** * Overrides the projection matrix used by the camera. Will * use the matrix for computing the view projection matrix as well. * Use null argument to return to normal functionality. * * @param projMatrix */ public void setProjectionMatrix(Matrix4f projMatrix) { if (projMatrix == null) { overrideProjection = false; projectionMatrixOverride.loadIdentity(); } else { overrideProjection = true; projectionMatrixOverride.set(projMatrix); } updateViewProjection(); } /** * @return the projection matrix of the camera. * The view projection matrix transforms eye space into clip space. * This matrix is usually defined by the viewport and perspective settings * of the camera. */ public Matrix4f getProjectionMatrix() { if (overrideProjection) { return projectionMatrixOverride; } return projectionMatrix; } /** * Updates the view projection matrix. */ public void updateViewProjection() { if (overrideProjection) { viewProjectionMatrix.set(projectionMatrixOverride).multLocal(viewMatrix); } else { //viewProjectionMatrix.set(viewMatrix).multLocal(projectionMatrix); viewProjectionMatrix.set(projectionMatrix).multLocal(viewMatrix); } } /** * @return The result of multiplying the projection matrix by the view * matrix. This matrix is required for rendering an object. It is * precomputed so as to not compute it every time an object is rendered. */ public Matrix4f getViewProjectionMatrix() { return viewProjectionMatrix; } /** * @return True if the viewport (width, height, left, right, bottom, up) * has been changed. This is needed in the renderer so that the proper * viewport can be set-up. */ public boolean isViewportChanged() { return viewportChanged; } /** * Clears the viewport changed flag once it has been updated inside * the renderer. */ public void clearViewportChanged() { viewportChanged = false; } /** * Called when the viewport has been changed. */ public void onViewPortChange() { viewportChanged = true; setGuiBounding(); } private void setGuiBounding() { float sx = width * viewPortLeft; float ex = width * viewPortRight; float sy = height * viewPortBottom; float ey = height * viewPortTop; float xExtent = Math.max(0f, (ex - sx) / 2f); float yExtent = Math.max(0f, (ey - sy) / 2f); guiBounding.setCenter(sx + xExtent, sy + yExtent, 0); guiBounding.setXExtent(xExtent); guiBounding.setYExtent(yExtent); guiBounding.setZExtent(Float.MAX_VALUE); } /** * onFrustumChange updates the frustum to reflect any changes * made to the planes. The new frustum values are kept in a temporary * location for use when calculating the new frame. The projection * matrix is updated to reflect the current values of the frustum. */ public void onFrustumChange() { if (!isParallelProjection()) { float nearSquared = frustumNear * frustumNear; float leftSquared = frustumLeft * frustumLeft; float rightSquared = frustumRight * frustumRight; float bottomSquared = frustumBottom * frustumBottom; float topSquared = frustumTop * frustumTop; float inverseLength = FastMath.invSqrt(nearSquared + leftSquared); coeffLeft[0] = -frustumNear * inverseLength; coeffLeft[1] = -frustumLeft * inverseLength; inverseLength = FastMath.invSqrt(nearSquared + rightSquared); coeffRight[0] = frustumNear * inverseLength; coeffRight[1] = frustumRight * inverseLength; inverseLength = FastMath.invSqrt(nearSquared + bottomSquared); coeffBottom[0] = frustumNear * inverseLength; coeffBottom[1] = -frustumBottom * inverseLength; inverseLength = FastMath.invSqrt(nearSquared + topSquared); coeffTop[0] = -frustumNear * inverseLength; coeffTop[1] = frustumTop * inverseLength; } else { coeffLeft[0] = 1; coeffLeft[1] = 0; coeffRight[0] = -1; coeffRight[1] = 0; coeffBottom[0] = 1; coeffBottom[1] = 0; coeffTop[0] = -1; coeffTop[1] = 0; } projectionMatrix.fromFrustum(frustumNear, frustumFar, frustumLeft, frustumRight, frustumTop, frustumBottom, parallelProjection); // projectionMatrix.transposeLocal(); // The frame is effected by the frustum values // update it as well onFrameChange(); } /** * onFrameChange updates the view frame of the camera. */ public void onFrameChange() { TempVars vars = TempVars.get(); Vector3f left = getLeft(vars.vect1); Vector3f direction = getDirection(vars.vect2); Vector3f up = getUp(vars.vect3); float dirDotLocation = direction.dot(location); // left plane Vector3f leftPlaneNormal = worldPlane[LEFT_PLANE].getNormal(); leftPlaneNormal.x = left.x * coeffLeft[0]; leftPlaneNormal.y = left.y * coeffLeft[0]; leftPlaneNormal.z = left.z * coeffLeft[0]; leftPlaneNormal.addLocal(direction.x * coeffLeft[1], direction.y * coeffLeft[1], direction.z * coeffLeft[1]); worldPlane[LEFT_PLANE].setConstant(location.dot(leftPlaneNormal)); // right plane Vector3f rightPlaneNormal = worldPlane[RIGHT_PLANE].getNormal(); rightPlaneNormal.x = left.x * coeffRight[0]; rightPlaneNormal.y = left.y * coeffRight[0]; rightPlaneNormal.z = left.z * coeffRight[0]; rightPlaneNormal.addLocal(direction.x * coeffRight[1], direction.y * coeffRight[1], direction.z * coeffRight[1]); worldPlane[RIGHT_PLANE].setConstant(location.dot(rightPlaneNormal)); // bottom plane Vector3f bottomPlaneNormal = worldPlane[BOTTOM_PLANE].getNormal(); bottomPlaneNormal.x = up.x * coeffBottom[0]; bottomPlaneNormal.y = up.y * coeffBottom[0]; bottomPlaneNormal.z = up.z * coeffBottom[0]; bottomPlaneNormal.addLocal(direction.x * coeffBottom[1], direction.y * coeffBottom[1], direction.z * coeffBottom[1]); worldPlane[BOTTOM_PLANE].setConstant(location.dot(bottomPlaneNormal)); // top plane Vector3f topPlaneNormal = worldPlane[TOP_PLANE].getNormal(); topPlaneNormal.x = up.x * coeffTop[0]; topPlaneNormal.y = up.y * coeffTop[0]; topPlaneNormal.z = up.z * coeffTop[0]; topPlaneNormal.addLocal(direction.x * coeffTop[1], direction.y * coeffTop[1], direction.z * coeffTop[1]); worldPlane[TOP_PLANE].setConstant(location.dot(topPlaneNormal)); if (isParallelProjection()) { worldPlane[LEFT_PLANE].setConstant(worldPlane[LEFT_PLANE].getConstant() + frustumLeft); worldPlane[RIGHT_PLANE].setConstant(worldPlane[RIGHT_PLANE].getConstant() - frustumRight); worldPlane[TOP_PLANE].setConstant(worldPlane[TOP_PLANE].getConstant() - frustumTop); worldPlane[BOTTOM_PLANE].setConstant(worldPlane[BOTTOM_PLANE].getConstant() + frustumBottom); } // far plane worldPlane[FAR_PLANE].setNormal(left); worldPlane[FAR_PLANE].setNormal(-direction.x, -direction.y, -direction.z); worldPlane[FAR_PLANE].setConstant(-(dirDotLocation + frustumFar)); // near plane worldPlane[NEAR_PLANE].setNormal(direction.x, direction.y, direction.z); worldPlane[NEAR_PLANE].setConstant(dirDotLocation + frustumNear); viewMatrix.fromFrame(location, direction, up, left); vars.release(); // viewMatrix.transposeLocal(); updateViewProjection(); } /** * @return true if parallel projection is enable, false if in normal perspective mode * @see #setParallelProjection(boolean) */ public boolean isParallelProjection() { return this.parallelProjection; } /** * Enable/disable parallel projection. * * @param value true to set up this camera for parallel projection is enable, false to enter normal perspective mode */ public void setParallelProjection(final boolean value) { this.parallelProjection = value; onFrustumChange(); } /** * Computes the z value in projection space from the z value in view space * Note that the returned value is going non linearly from 0 to 1. * for more explanations on non linear z buffer see * http://www.sjbaker.org/steve/omniv/love_your_z_buffer.html * @param viewZPos the z value in view space. * @return the z value in projection space. */ public float getViewToProjectionZ(float viewZPos) { float far = getFrustumFar(); float near = getFrustumNear(); float a = far / (far - near); float b = far * near / (near - far); return a + b / viewZPos; } /** * Computes a position in World space given a screen position in screen space (0,0 to width, height) * and a z position in projection space ( 0 to 1 non linear). * This former value is also known as the Z buffer value or non linear depth buffer. * for more explanations on non linear z buffer see * http://www.sjbaker.org/steve/omniv/love_your_z_buffer.html * * To compute the projection space z from the view space z (distance from cam to object) @see Camera#getViewToProjectionZ * * @param screenPos 2d coordinate in screen space * @param projectionZPos non linear z value in projection space * @return the position in world space. */ public Vector3f getWorldCoordinates(Vector2f screenPos, float projectionZPos) { return getWorldCoordinates(screenPos, projectionZPos, null); } /** * @see Camera#getWorldCoordinates */ public Vector3f getWorldCoordinates(Vector2f screenPosition, float projectionZPos, Vector3f store) { if (store == null) { store = new Vector3f(); } Matrix4f inverseMat = new Matrix4f(viewProjectionMatrix); inverseMat.invertLocal(); store.set( (screenPosition.x / getWidth() - viewPortLeft) / (viewPortRight - viewPortLeft) * 2 - 1, (screenPosition.y / getHeight() - viewPortBottom) / (viewPortTop - viewPortBottom) * 2 - 1, projectionZPos * 2 - 1); float w = inverseMat.multProj(store, store); store.multLocal(1f / w); return store; } /** * Converts the given position from world space to screen space. * * @see Camera#getScreenCoordinates */ public Vector3f getScreenCoordinates(Vector3f worldPos) { return getScreenCoordinates(worldPos, null); } /** * Converts the given position from world space to screen space. * * @see Camera#getScreenCoordinates(Vector3f, Vector3f) */ public Vector3f getScreenCoordinates(Vector3f worldPosition, Vector3f store) { if (store == null) { store = new Vector3f(); } // TempVars vars = vars.lock(); // Quaternion tmp_quat = vars.quat1; // tmp_quat.set( worldPosition.x, worldPosition.y, worldPosition.z, 1 ); // viewProjectionMatrix.mult(tmp_quat, tmp_quat); // tmp_quat.multLocal( 1.0f / tmp_quat.getW() ); // store.x = ( ( tmp_quat.getX() + 1 ) * ( viewPortRight - viewPortLeft ) / 2 + viewPortLeft ) * getWidth(); // store.y = ( ( tmp_quat.getY() + 1 ) * ( viewPortTop - viewPortBottom ) / 2 + viewPortBottom ) * getHeight(); // store.z = ( tmp_quat.getZ() + 1 ) / 2; // vars.release(); float w = viewProjectionMatrix.multProj(worldPosition, store); store.divideLocal(w); store.x = ((store.x + 1f) * (viewPortRight - viewPortLeft) / 2f + viewPortLeft) * getWidth(); store.y = ((store.y + 1f) * (viewPortTop - viewPortBottom) / 2f + viewPortBottom) * getHeight(); store.z = (store.z + 1f) / 2f; return store; } /** * @return the width/resolution of the display. */ public int getWidth() { return width; } /** * @return the height/resolution of the display. */ public int getHeight() { return height; } @Override public String toString() { return "Camera[location=" + location + "\n, direction=" + getDirection() + "\n" + "res=" + width + "x" + height + ", parallel=" + parallelProjection + "\n" + "near=" + frustumNear + ", far=" + frustumFar + "]"; } public void write(JmeExporter e) throws IOException { OutputCapsule capsule = e.getCapsule(this); capsule.write(location, "location", Vector3f.ZERO); capsule.write(rotation, "rotation", Quaternion.DIRECTION_Z); capsule.write(frustumNear, "frustumNear", 1); capsule.write(frustumFar, "frustumFar", 2); capsule.write(frustumLeft, "frustumLeft", -0.5f); capsule.write(frustumRight, "frustumRight", 0.5f); capsule.write(frustumTop, "frustumTop", 0.5f); capsule.write(frustumBottom, "frustumBottom", -0.5f); capsule.write(coeffLeft, "coeffLeft", new float[2]); capsule.write(coeffRight, "coeffRight", new float[2]); capsule.write(coeffBottom, "coeffBottom", new float[2]); capsule.write(coeffTop, "coeffTop", new float[2]); capsule.write(viewPortLeft, "viewPortLeft", 0); capsule.write(viewPortRight, "viewPortRight", 1); capsule.write(viewPortTop, "viewPortTop", 1); capsule.write(viewPortBottom, "viewPortBottom", 0); capsule.write(width, "width", 0); capsule.write(height, "height", 0); capsule.write(name, "name", null); } public void read(JmeImporter e) throws IOException { InputCapsule capsule = e.getCapsule(this); location = (Vector3f) capsule.readSavable("location", Vector3f.ZERO.clone()); rotation = (Quaternion) capsule.readSavable("rotation", Quaternion.DIRECTION_Z.clone()); frustumNear = capsule.readFloat("frustumNear", 1); frustumFar = capsule.readFloat("frustumFar", 2); frustumLeft = capsule.readFloat("frustumLeft", -0.5f); frustumRight = capsule.readFloat("frustumRight", 0.5f); frustumTop = capsule.readFloat("frustumTop", 0.5f); frustumBottom = capsule.readFloat("frustumBottom", -0.5f); coeffLeft = capsule.readFloatArray("coeffLeft", new float[2]); coeffRight = capsule.readFloatArray("coeffRight", new float[2]); coeffBottom = capsule.readFloatArray("coeffBottom", new float[2]); coeffTop = capsule.readFloatArray("coeffTop", new float[2]); viewPortLeft = capsule.readFloat("viewPortLeft", 0); viewPortRight = capsule.readFloat("viewPortRight", 1); viewPortTop = capsule.readFloat("viewPortTop", 1); viewPortBottom = capsule.readFloat("viewPortBottom", 0); width = capsule.readInt("width", 1); height = capsule.readInt("height", 1); name = capsule.readString("name", null); onFrustumChange(); onViewPortChange(); onFrameChange(); } }




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