androidx/renderscript/Matrix4f.java - platform/prebuilts/fullsdk/sources/android-29 - Git at Google

 /*
  * Copyright (C) 2009-2012 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 package androidx.renderscript;

 import java.lang.Math;
 import android.util.Log;


 /**
  * Class for exposing the native RenderScript rs_matrix4x4 type back to the Android system.
  *
  **/
 public class Matrix4f {

     /**
     * Creates a new identity 4x4 matrix
     */
     public Matrix4f() {
         mMat = new float[16];
         loadIdentity();
     }

     /**
     * Creates a new matrix and sets its values from the given
     * parameter
     *
     * @param dataArray values to set the matrix to, must be 16
     *                  floats long
     */
     public Matrix4f(float[] dataArray) {
         mMat = new float[16];
         System.arraycopy(dataArray, 0, mMat, 0, mMat.length);
     }

     /**
     * Return a reference to the internal array representing matrix
     * values. Modifying this array will also change the matrix
     *
     * @return internal array representing the matrix
     */
     public float[] getArray() {
         return mMat;
     }

     /**
     * Returns the value for a given row and column
     *
     * @param x column of the value to return
     * @param y row of the value to return
     *
     * @return value in the yth row and xth column
     */
     public float get(int x, int y) {
         return mMat[x*4 + y];
     }

     /**
     * Sets the value for a given row and column
     *
     * @param x column of the value to set
     * @param y row of the value to set
     */
     public void set(int x, int y, float v) {
         mMat[x*4 + y] = v;
     }

     /**
     * Sets the matrix values to identity
     */
     public void loadIdentity() {
         mMat[0] = 1;
         mMat[1] = 0;
         mMat[2] = 0;
         mMat[3] = 0;

         mMat[4] = 0;
         mMat[5] = 1;
         mMat[6] = 0;
         mMat[7] = 0;

         mMat[8] = 0;
         mMat[9] = 0;
         mMat[10] = 1;
         mMat[11] = 0;

         mMat[12] = 0;
         mMat[13] = 0;
         mMat[14] = 0;
         mMat[15] = 1;
     }

     /**
     * Sets the values of the matrix to those of the parameter
     *
     * @param src matrix to load the values from
     */
     public void load(Matrix4f src) {
         System.arraycopy(src.getArray(), 0, mMat, 0, mMat.length);
     }

     /**
     * Sets the values of the matrix to those of the parameter
     *
     * @param src matrix to load the values from
     * @hide
     */
     public void load(Matrix3f src) {
         mMat[0] = src.mMat[0];
         mMat[1] = src.mMat[1];
         mMat[2] = src.mMat[2];
         mMat[3] = 0;

         mMat[4] = src.mMat[3];
         mMat[5] = src.mMat[4];
         mMat[6] = src.mMat[5];
         mMat[7] = 0;

         mMat[8] = src.mMat[6];
         mMat[9] = src.mMat[7];
         mMat[10] = src.mMat[8];
         mMat[11] = 0;

         mMat[12] = 0;
         mMat[13] = 0;
         mMat[14] = 0;
         mMat[15] = 1;
     }

     /**
     * Sets current values to be a rotation matrix of certain angle
     * about a given axis
     *
     * @param rot angle of rotation
     * @param x rotation axis x
     * @param y rotation axis y
     * @param z rotation axis z
     */
     public void loadRotate(float rot, float x, float y, float z) {
         float c, s;
         mMat[3] = 0;
         mMat[7] = 0;
         mMat[11]= 0;
         mMat[12]= 0;
         mMat[13]= 0;
         mMat[14]= 0;
         mMat[15]= 1;
         rot *= (float)(java.lang.Math.PI / 180.0f);
         c = (float)java.lang.Math.cos(rot);
         s = (float)java.lang.Math.sin(rot);

         float len = (float)java.lang.Math.sqrt(x*x + y*y + z*z);
         if (!(len != 1)) {
             float recipLen = 1.f / len;
             x *= recipLen;
             y *= recipLen;
             z *= recipLen;
         }
         float nc = 1.0f - c;
         float xy = x * y;
         float yz = y * z;
         float zx = z * x;
         float xs = x * s;
         float ys = y * s;
         float zs = z * s;
         mMat[ 0] = x*x*nc +  c;
         mMat[ 4] =  xy*nc - zs;
         mMat[ 8] =  zx*nc + ys;
         mMat[ 1] =  xy*nc + zs;
         mMat[ 5] = y*y*nc +  c;
         mMat[ 9] =  yz*nc - xs;
         mMat[ 2] =  zx*nc - ys;
         mMat[ 6] =  yz*nc + xs;
         mMat[10] = z*z*nc +  c;
     }

     /**
     * Sets current values to be a scale matrix of given dimensions
     *
     * @param x scale component x
     * @param y scale component y
     * @param z scale component z
     */
     public void loadScale(float x, float y, float z) {
         loadIdentity();
         mMat[0] = x;
         mMat[5] = y;
         mMat[10] = z;
     }

     /**
     * Sets current values to be a translation matrix of given
     * dimensions
     *
     * @param x translation component x
     * @param y translation component y
     * @param z translation component z
     */
     public void loadTranslate(float x, float y, float z) {
         loadIdentity();
         mMat[12] = x;
         mMat[13] = y;
         mMat[14] = z;
     }

     /**
     * Sets current values to be the result of multiplying two given
     * matrices
     *
     * @param lhs left hand side matrix
     * @param rhs right hand side matrix
     */
     public void loadMultiply(Matrix4f lhs, Matrix4f rhs) {
         for (int i=0 ; i<4 ; i++) {
             float ri0 = 0;
             float ri1 = 0;
             float ri2 = 0;
             float ri3 = 0;
             for (int j=0 ; j<4 ; j++) {
                 float rhs_ij = rhs.get(i,j);
                 ri0 += lhs.get(j,0) * rhs_ij;
                 ri1 += lhs.get(j,1) * rhs_ij;
                 ri2 += lhs.get(j,2) * rhs_ij;
                 ri3 += lhs.get(j,3) * rhs_ij;
             }
             set(i,0, ri0);
             set(i,1, ri1);
             set(i,2, ri2);
             set(i,3, ri3);
         }
     }

     /**
     * Set current values to be an orthographic projection matrix
     *
     * @param l location of the left vertical clipping plane
     * @param r location of the right vertical clipping plane
     * @param b location of the bottom horizontal clipping plane
     * @param t location of the top horizontal clipping plane
     * @param n location of the near clipping plane
     * @param f location of the far clipping plane
     */
     public void loadOrtho(float l, float r, float b, float t, float n, float f) {
         loadIdentity();
         mMat[0] = 2 / (r - l);
         mMat[5] = 2 / (t - b);
         mMat[10]= -2 / (f - n);
         mMat[12]= -(r + l) / (r - l);
         mMat[13]= -(t + b) / (t - b);
         mMat[14]= -(f + n) / (f - n);
     }

     /**
     * Set current values to be an orthographic projection matrix
     * with the right and bottom clipping planes set to the given
     * values. Left and top clipping planes are set to 0. Near and
     * far are set to -1, 1 respectively
     *
     * @param w location of the right vertical clipping plane
     * @param h location of the bottom horizontal clipping plane
     *
     */
     public void loadOrthoWindow(int w, int h) {
         loadOrtho(0,w, h,0, -1,1);
     }

     /**
     * Sets current values to be a perspective projection matrix
     *
     * @param l location of the left vertical clipping plane
     * @param r location of the right vertical clipping plane
     * @param b location of the bottom horizontal clipping plane
     * @param t location of the top horizontal clipping plane
     * @param n location of the near clipping plane, must be positive
     * @param f location of the far clipping plane, must be positive
     *
     */
     public void loadFrustum(float l, float r, float b, float t, float n, float f) {
         loadIdentity();
         mMat[0] = 2 * n / (r - l);
         mMat[5] = 2 * n / (t - b);
         mMat[8] = (r + l) / (r - l);
         mMat[9] = (t + b) / (t - b);
         mMat[10]= -(f + n) / (f - n);
         mMat[11]= -1;
         mMat[14]= -2*f*n / (f - n);
         mMat[15]= 0;
     }

     /**
     * Sets current values to be a perspective projection matrix
     *
     * @param fovy vertical field of view angle in degrees
     * @param aspect aspect ratio of the screen
     * @param near near cliping plane, must be positive
     * @param far far clipping plane, must be positive
     */
     public void loadPerspective(float fovy, float aspect, float near, float far) {
         float top = near * (float)Math.tan((float) (fovy * Math.PI / 360.0f));
         float bottom = -top;
         float left = bottom * aspect;
         float right = top * aspect;
         loadFrustum(left, right, bottom, top, near, far);
     }

     /**
     * Helper function to set the current values to a perspective
     * projection matrix with aspect ratio defined by the parameters
     * and (near, far), (bottom, top) mapping to (-1, 1) at z = 0
     *
     * @param w screen width
     * @param h screen height
     */
     public void loadProjectionNormalized(int w, int h) {
         // range -1,1 in the narrow axis at z = 0.
         Matrix4f m1 = new Matrix4f();
         Matrix4f m2 = new Matrix4f();

         if(w > h) {
             float aspect = ((float)w) / h;
             m1.loadFrustum(-aspect,aspect,  -1,1,  1,100);
         } else {
             float aspect = ((float)h) / w;
             m1.loadFrustum(-1,1, -aspect,aspect, 1,100);
         }

         m2.loadRotate(180, 0, 1, 0);
         m1.loadMultiply(m1, m2);

         m2.loadScale(-2, 2, 1);
         m1.loadMultiply(m1, m2);

         m2.loadTranslate(0, 0, 2);
         m1.loadMultiply(m1, m2);

         load(m1);
     }

     /**
     * Post-multiplies the current matrix by a given parameter
     *
     * @param rhs right hand side to multiply by
     */
     public void multiply(Matrix4f rhs) {
         Matrix4f tmp = new Matrix4f();
         tmp.loadMultiply(this, rhs);
         load(tmp);
     }
     /**
     * Modifies the current matrix by post-multiplying it with a
     * rotation matrix of certain angle about a given axis
     *
     * @param rot angle of rotation
     * @param x rotation axis x
     * @param y rotation axis y
     * @param z rotation axis z
     */
     public void rotate(float rot, float x, float y, float z) {
         Matrix4f tmp = new Matrix4f();
         tmp.loadRotate(rot, x, y, z);
         multiply(tmp);
     }

     /**
     * Modifies the current matrix by post-multiplying it with a
     * scale matrix of given dimensions
     *
     * @param x scale component x
     * @param y scale component y
     * @param z scale component z
     */
     public void scale(float x, float y, float z) {
         Matrix4f tmp = new Matrix4f();
         tmp.loadScale(x, y, z);
         multiply(tmp);
     }

     /**
     * Modifies the current matrix by post-multiplying it with a
     * translation matrix of given dimensions
     *
     * @param x translation component x
     * @param y translation component y
     * @param z translation component z
     */
     public void translate(float x, float y, float z) {
         Matrix4f tmp = new Matrix4f();
         tmp.loadTranslate(x, y, z);
         multiply(tmp);
     }
     private float computeCofactor(int i, int j) {
         int c0 = (i+1) % 4;
         int c1 = (i+2) % 4;
         int c2 = (i+3) % 4;
         int r0 = (j+1) % 4;
         int r1 = (j+2) % 4;
         int r2 = (j+3) % 4;

         float minor = (mMat[c0 + 4*r0] * (mMat[c1 + 4*r1] * mMat[c2 + 4*r2] -
                                             mMat[c1 + 4*r2] * mMat[c2 + 4*r1]))
                      - (mMat[c0 + 4*r1] * (mMat[c1 + 4*r0] * mMat[c2 + 4*r2] -
                                             mMat[c1 + 4*r2] * mMat[c2 + 4*r0]))
                      + (mMat[c0 + 4*r2] * (mMat[c1 + 4*r0] * mMat[c2 + 4*r1] -
                                             mMat[c1 + 4*r1] * mMat[c2 + 4*r0]));

         float cofactor = ((i+j) & 1) != 0 ? -minor : minor;
         return cofactor;
     }

     /**
     * Sets the current matrix to its inverse
     */
     public boolean inverse() {

         Matrix4f result = new Matrix4f();

         for (int i = 0; i < 4; ++i) {
             for (int j = 0; j < 4; ++j) {
                 result.mMat[4*i + j] = computeCofactor(i, j);
             }
         }

         // Dot product of 0th column of source and 0th row of result
         float det = mMat[0]*result.mMat[0] + mMat[4]*result.mMat[1] +
                      mMat[8]*result.mMat[2] + mMat[12]*result.mMat[3];

         if (Math.abs(det) < 1e-6) {
             return false;
         }

         det = 1.0f / det;
         for (int i = 0; i < 16; ++i) {
             mMat[i] = result.mMat[i] * det;
         }

         return true;
     }

     /**
     * Sets the current matrix to its inverse transpose
     */
     public boolean inverseTranspose() {

         Matrix4f result = new Matrix4f();

         for (int i = 0; i < 4; ++i) {
             for (int j = 0; j < 4; ++j) {
                 result.mMat[4*j + i] = computeCofactor(i, j);
             }
         }

         float det = mMat[0]*result.mMat[0] + mMat[4]*result.mMat[4] +
                      mMat[8]*result.mMat[8] + mMat[12]*result.mMat[12];

         if (Math.abs(det) < 1e-6) {
             return false;
         }

         det = 1.0f / det;
         for (int i = 0; i < 16; ++i) {
             mMat[i] = result.mMat[i] * det;
         }

         return true;
     }

     /**
     * Sets the current matrix to its transpose
     */
     public void transpose() {
         for(int i = 0; i < 3; ++i) {
             for(int j = i + 1; j < 4; ++j) {
                 float temp = mMat[i*4 + j];
                 mMat[i*4 + j] = mMat[j*4 + i];
                 mMat[j*4 + i] = temp;
             }
         }
     }

     final float[] mMat;
 }
	/*
	* Copyright (C) 2009-2012 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	package androidx.renderscript;

	import java.lang.Math;
	import android.util.Log;


	/**
	* Class for exposing the native RenderScript rs_matrix4x4 type back to the Android system.
	*
	**/
	public class Matrix4f {

	/**
	* Creates a new identity 4x4 matrix
	*/
	public Matrix4f() {
	mMat = new float[16];
	loadIdentity();
	}

	/**
	* Creates a new matrix and sets its values from the given
	* parameter
	*
	* @param dataArray values to set the matrix to, must be 16
	* floats long
	*/
	public Matrix4f(float[] dataArray) {
	mMat = new float[16];
	System.arraycopy(dataArray, 0, mMat, 0, mMat.length);
	}

	/**
	* Return a reference to the internal array representing matrix
	* values. Modifying this array will also change the matrix
	*
	* @return internal array representing the matrix
	*/
	public float[] getArray() {
	return mMat;
	}

	/**
	* Returns the value for a given row and column
	*
	* @param x column of the value to return
	* @param y row of the value to return
	*
	* @return value in the yth row and xth column
	*/
	public float get(int x, int y) {
	return mMat[x*4 + y];
	}

	/**
	* Sets the value for a given row and column
	*
	* @param x column of the value to set
	* @param y row of the value to set
	*/
	public void set(int x, int y, float v) {
	mMat[x*4 + y] = v;
	}

	/**
	* Sets the matrix values to identity
	*/
	public void loadIdentity() {
	mMat[0] = 1;
	mMat[1] = 0;
	mMat[2] = 0;
	mMat[3] = 0;

	mMat[4] = 0;
	mMat[5] = 1;
	mMat[6] = 0;
	mMat[7] = 0;

	mMat[8] = 0;
	mMat[9] = 0;
	mMat[10] = 1;
	mMat[11] = 0;

	mMat[12] = 0;
	mMat[13] = 0;
	mMat[14] = 0;
	mMat[15] = 1;
	}

	/**
	* Sets the values of the matrix to those of the parameter
	*
	* @param src matrix to load the values from
	*/
	public void load(Matrix4f src) {
	System.arraycopy(src.getArray(), 0, mMat, 0, mMat.length);
	}

	/**
	* Sets the values of the matrix to those of the parameter
	*
	* @param src matrix to load the values from
	* @hide
	*/
	public void load(Matrix3f src) {
	mMat[0] = src.mMat[0];
	mMat[1] = src.mMat[1];
	mMat[2] = src.mMat[2];
	mMat[3] = 0;

	mMat[4] = src.mMat[3];
	mMat[5] = src.mMat[4];
	mMat[6] = src.mMat[5];
	mMat[7] = 0;

	mMat[8] = src.mMat[6];
	mMat[9] = src.mMat[7];
	mMat[10] = src.mMat[8];
	mMat[11] = 0;

	mMat[12] = 0;
	mMat[13] = 0;
	mMat[14] = 0;
	mMat[15] = 1;
	}

	/**
	* Sets current values to be a rotation matrix of certain angle
	* about a given axis
	*
	* @param rot angle of rotation
	* @param x rotation axis x
	* @param y rotation axis y
	* @param z rotation axis z
	*/
	public void loadRotate(float rot, float x, float y, float z) {
	float c, s;
	mMat[3] = 0;
	mMat[7] = 0;
	mMat[11]= 0;
	mMat[12]= 0;
	mMat[13]= 0;
	mMat[14]= 0;
	mMat[15]= 1;
	rot *= (float)(java.lang.Math.PI / 180.0f);
	c = (float)java.lang.Math.cos(rot);
	s = (float)java.lang.Math.sin(rot);

	float len = (float)java.lang.Math.sqrt(xx + yy + z*z);
	if (!(len != 1)) {
	float recipLen = 1.f / len;
	x *= recipLen;
	y *= recipLen;
	z *= recipLen;
	}
	float nc = 1.0f - c;
	float xy = x * y;
	float yz = y * z;
	float zx = z * x;
	float xs = x * s;
	float ys = y * s;
	float zs = z * s;
	mMat[ 0] = xxnc + c;
	mMat[ 4] = xy*nc - zs;
	mMat[ 8] = zx*nc + ys;
	mMat[ 1] = xy*nc + zs;
	mMat[ 5] = yync + c;
	mMat[ 9] = yz*nc - xs;
	mMat[ 2] = zx*nc - ys;
	mMat[ 6] = yz*nc + xs;
	mMat[10] = zznc + c;
	}

	/**
	* Sets current values to be a scale matrix of given dimensions
	*
	* @param x scale component x
	* @param y scale component y
	* @param z scale component z
	*/
	public void loadScale(float x, float y, float z) {
	loadIdentity();
	mMat[0] = x;
	mMat[5] = y;
	mMat[10] = z;
	}

	/**
	* Sets current values to be a translation matrix of given
	* dimensions
	*
	* @param x translation component x
	* @param y translation component y
	* @param z translation component z
	*/
	public void loadTranslate(float x, float y, float z) {
	loadIdentity();
	mMat[12] = x;
	mMat[13] = y;
	mMat[14] = z;
	}

	/**
	* Sets current values to be the result of multiplying two given
	* matrices
	*
	* @param lhs left hand side matrix
	* @param rhs right hand side matrix
	*/
	public void loadMultiply(Matrix4f lhs, Matrix4f rhs) {
	for (int i=0 ; i<4 ; i++) {
	float ri0 = 0;
	float ri1 = 0;
	float ri2 = 0;
	float ri3 = 0;
	for (int j=0 ; j<4 ; j++) {
	float rhs_ij = rhs.get(i,j);
	ri0 += lhs.get(j,0) * rhs_ij;
	ri1 += lhs.get(j,1) * rhs_ij;
	ri2 += lhs.get(j,2) * rhs_ij;
	ri3 += lhs.get(j,3) * rhs_ij;
	}
	set(i,0, ri0);
	set(i,1, ri1);
	set(i,2, ri2);
	set(i,3, ri3);
	}
	}

	/**
	* Set current values to be an orthographic projection matrix
	*
	* @param l location of the left vertical clipping plane
	* @param r location of the right vertical clipping plane
	* @param b location of the bottom horizontal clipping plane
	* @param t location of the top horizontal clipping plane
	* @param n location of the near clipping plane
	* @param f location of the far clipping plane
	*/
	public void loadOrtho(float l, float r, float b, float t, float n, float f) {
	loadIdentity();
	mMat[0] = 2 / (r - l);
	mMat[5] = 2 / (t - b);
	mMat[10]= -2 / (f - n);
	mMat[12]= -(r + l) / (r - l);
	mMat[13]= -(t + b) / (t - b);
	mMat[14]= -(f + n) / (f - n);
	}

	/**
	* Set current values to be an orthographic projection matrix
	* with the right and bottom clipping planes set to the given
	* values. Left and top clipping planes are set to 0. Near and
	* far are set to -1, 1 respectively
	*
	* @param w location of the right vertical clipping plane
	* @param h location of the bottom horizontal clipping plane
	*
	*/
	public void loadOrthoWindow(int w, int h) {
	loadOrtho(0,w, h,0, -1,1);
	}

	/**
	* Sets current values to be a perspective projection matrix
	*
	* @param l location of the left vertical clipping plane
	* @param r location of the right vertical clipping plane
	* @param b location of the bottom horizontal clipping plane
	* @param t location of the top horizontal clipping plane
	* @param n location of the near clipping plane, must be positive
	* @param f location of the far clipping plane, must be positive
	*
	*/
	public void loadFrustum(float l, float r, float b, float t, float n, float f) {
	loadIdentity();
	mMat[0] = 2 * n / (r - l);
	mMat[5] = 2 * n / (t - b);
	mMat[8] = (r + l) / (r - l);
	mMat[9] = (t + b) / (t - b);
	mMat[10]= -(f + n) / (f - n);
	mMat[11]= -1;
	mMat[14]= -2fn / (f - n);
	mMat[15]= 0;
	}

	/**
	* Sets current values to be a perspective projection matrix
	*
	* @param fovy vertical field of view angle in degrees
	* @param aspect aspect ratio of the screen
	* @param near near cliping plane, must be positive
	* @param far far clipping plane, must be positive
	*/
	public void loadPerspective(float fovy, float aspect, float near, float far) {
	float top = near * (float)Math.tan((float) (fovy * Math.PI / 360.0f));
	float bottom = -top;
	float left = bottom * aspect;
	float right = top * aspect;
	loadFrustum(left, right, bottom, top, near, far);
	}

	/**
	* Helper function to set the current values to a perspective
	* projection matrix with aspect ratio defined by the parameters
	* and (near, far), (bottom, top) mapping to (-1, 1) at z = 0
	*
	* @param w screen width
	* @param h screen height
	*/
	public void loadProjectionNormalized(int w, int h) {
	// range -1,1 in the narrow axis at z = 0.
	Matrix4f m1 = new Matrix4f();
	Matrix4f m2 = new Matrix4f();

	if(w > h) {
	float aspect = ((float)w) / h;
	m1.loadFrustum(-aspect,aspect, -1,1, 1,100);
	} else {
	float aspect = ((float)h) / w;
	m1.loadFrustum(-1,1, -aspect,aspect, 1,100);
	}

	m2.loadRotate(180, 0, 1, 0);
	m1.loadMultiply(m1, m2);

	m2.loadScale(-2, 2, 1);
	m1.loadMultiply(m1, m2);

	m2.loadTranslate(0, 0, 2);
	m1.loadMultiply(m1, m2);

	load(m1);
	}

	/**
	* Post-multiplies the current matrix by a given parameter
	*
	* @param rhs right hand side to multiply by
	*/
	public void multiply(Matrix4f rhs) {
	Matrix4f tmp = new Matrix4f();
	tmp.loadMultiply(this, rhs);
	load(tmp);
	}
	/**
	* Modifies the current matrix by post-multiplying it with a
	* rotation matrix of certain angle about a given axis
	*
	* @param rot angle of rotation
	* @param x rotation axis x
	* @param y rotation axis y
	* @param z rotation axis z
	*/
	public void rotate(float rot, float x, float y, float z) {
	Matrix4f tmp = new Matrix4f();
	tmp.loadRotate(rot, x, y, z);
	multiply(tmp);
	}

	/**
	* Modifies the current matrix by post-multiplying it with a
	* scale matrix of given dimensions
	*
	* @param x scale component x
	* @param y scale component y
	* @param z scale component z
	*/
	public void scale(float x, float y, float z) {
	Matrix4f tmp = new Matrix4f();
	tmp.loadScale(x, y, z);
	multiply(tmp);
	}

	/**
	* Modifies the current matrix by post-multiplying it with a
	* translation matrix of given dimensions
	*
	* @param x translation component x
	* @param y translation component y
	* @param z translation component z
	*/
	public void translate(float x, float y, float z) {
	Matrix4f tmp = new Matrix4f();
	tmp.loadTranslate(x, y, z);
	multiply(tmp);
	}
	private float computeCofactor(int i, int j) {
	int c0 = (i+1) % 4;
	int c1 = (i+2) % 4;
	int c2 = (i+3) % 4;
	int r0 = (j+1) % 4;
	int r1 = (j+2) % 4;
	int r2 = (j+3) % 4;

	float minor = (mMat[c0 + 4r0] (mMat[c1 + 4r1] mMat[c2 + 4*r2] -
	mMat[c1 + 4r2] mMat[c2 + 4*r1]))
	- (mMat[c0 + 4r1] (mMat[c1 + 4r0] mMat[c2 + 4*r2] -
	mMat[c1 + 4r2] mMat[c2 + 4*r0]))
	+ (mMat[c0 + 4r2] (mMat[c1 + 4r0] mMat[c2 + 4*r1] -
	mMat[c1 + 4r1] mMat[c2 + 4*r0]));

	float cofactor = ((i+j) & 1) != 0 ? -minor : minor;
	return cofactor;
	}

	/**
	* Sets the current matrix to its inverse
	*/
	public boolean inverse() {

	Matrix4f result = new Matrix4f();

	for (int i = 0; i < 4; ++i) {
	for (int j = 0; j < 4; ++j) {
	result.mMat[4*i + j] = computeCofactor(i, j);
	}
	}

	// Dot product of 0th column of source and 0th row of result
	float det = mMat[0]result.mMat[0] + mMat[4]result.mMat[1] +
	mMat[8]result.mMat[2] + mMat[12]result.mMat[3];

	if (Math.abs(det) < 1e-6) {
	return false;
	}

	det = 1.0f / det;
	for (int i = 0; i < 16; ++i) {
	mMat[i] = result.mMat[i] * det;
	}

	return true;
	}

	/**
	* Sets the current matrix to its inverse transpose
	*/
	public boolean inverseTranspose() {

	Matrix4f result = new Matrix4f();

	for (int i = 0; i < 4; ++i) {
	for (int j = 0; j < 4; ++j) {
	result.mMat[4*j + i] = computeCofactor(i, j);
	}
	}

	float det = mMat[0]result.mMat[0] + mMat[4]result.mMat[4] +
	mMat[8]result.mMat[8] + mMat[12]result.mMat[12];

	if (Math.abs(det) < 1e-6) {
	return false;
	}

	det = 1.0f / det;
	for (int i = 0; i < 16; ++i) {
	mMat[i] = result.mMat[i] * det;
	}

	return true;
	}

	/**
	* Sets the current matrix to its transpose
	*/
	public void transpose() {
	for(int i = 0; i < 3; ++i) {
	for(int j = i + 1; j < 4; ++j) {
	float temp = mMat[i*4 + j];
	mMat[i4 + j] = mMat[j4 + i];
	mMat[j*4 + i] = temp;
	}
	}
	}

	final float[] mMat;
	}