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/*
 * Copyright (c) 2002-2008 LWJGL Project
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions are
 * met:
 *
 * * Redistributions of source code must retain the above copyright
 *   notice, this list of conditions and the following disclaimer.
 *
 * * Redistributions in binary form must reproduce the above copyright
 *   notice, this list of conditions and the following disclaimer in the
 *   documentation and/or other materials provided with the distribution.
 *
 * * Neither the name of 'LWJGL' nor the names of
 *   its contributors may be used to endorse or promote products derived
 *   from this software without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
 * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR
 * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
 * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
 * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
 * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
 * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
 * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
 * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 */
package org.lwjgl.util.vector;

import java.io.Serializable;
import java.nio.FloatBuffer;

/**
 *
 * Holds a 3x3 matrix.
 *
 * @author cix_foo 
 * @version $Revision$
 * $Id$
 */

public class Matrix3f extends Matrix implements Serializable {

	private static final long serialVersionUID = 1L;

	public float m00,
		m01,
		m02,
		m10,
		m11,
		m12,
		m20,
		m21,
		m22;

	/**
	 * Constructor for Matrix3f. Matrix is initialised to the identity.
	 */
	public Matrix3f() {
		super();
		setIdentity();
	}

	/**
	 * Load from another matrix
	 * @param src The source matrix
	 * @return this
	 */
	public Matrix3f load(Matrix3f src) {
		return load(src, this);
	}

	/**
	 * Copy source matrix to destination matrix
	 * @param src The source matrix
	 * @param dest The destination matrix, or null of a new matrix is to be created
	 * @return The copied matrix
	 */
	public static Matrix3f load(Matrix3f src, Matrix3f dest) {
		if (dest == null)
			dest = new Matrix3f();

		dest.m00 = src.m00;
		dest.m10 = src.m10;
		dest.m20 = src.m20;
		dest.m01 = src.m01;
		dest.m11 = src.m11;
		dest.m21 = src.m21;
		dest.m02 = src.m02;
		dest.m12 = src.m12;
		dest.m22 = src.m22;

		return dest;
	}

	/**
	 * Load from a float buffer. The buffer stores the matrix in column major
	 * (OpenGL) order.
	 *
	 * @param buf A float buffer to read from
	 * @return this
	 */
	public Matrix load(FloatBuffer buf) {

		m00 = buf.get();
		m01 = buf.get();
		m02 = buf.get();
		m10 = buf.get();
		m11 = buf.get();
		m12 = buf.get();
		m20 = buf.get();
		m21 = buf.get();
		m22 = buf.get();

		return this;
	}

	/**
	 * Load from a float buffer. The buffer stores the matrix in row major
	 * (maths) order.
	 *
	 * @param buf A float buffer to read from
	 * @return this
	 */
	public Matrix loadTranspose(FloatBuffer buf) {

		m00 = buf.get();
		m10 = buf.get();
		m20 = buf.get();
		m01 = buf.get();
		m11 = buf.get();
		m21 = buf.get();
		m02 = buf.get();
		m12 = buf.get();
		m22 = buf.get();

		return this;
	}

	/**
	 * Store this matrix in a float buffer. The matrix is stored in column
	 * major (openGL) order.
	 * @param buf The buffer to store this matrix in
	 */
	public Matrix store(FloatBuffer buf) {
		buf.put(m00);
		buf.put(m01);
		buf.put(m02);
		buf.put(m10);
		buf.put(m11);
		buf.put(m12);
		buf.put(m20);
		buf.put(m21);
		buf.put(m22);
		return this;
	}

	/**
	 * Store this matrix in a float buffer. The matrix is stored in row
	 * major (maths) order.
	 * @param buf The buffer to store this matrix in
	 */
	public Matrix storeTranspose(FloatBuffer buf) {
		buf.put(m00);
		buf.put(m10);
		buf.put(m20);
		buf.put(m01);
		buf.put(m11);
		buf.put(m21);
		buf.put(m02);
		buf.put(m12);
		buf.put(m22);
		return this;
	}

	/**
	 * Add two matrices together and place the result in a third matrix.
	 * @param left The left source matrix
	 * @param right The right source matrix
	 * @param dest The destination matrix, or null if a new one is to be created
	 * @return the destination matrix
	 */
	public static Matrix3f add(Matrix3f left, Matrix3f right, Matrix3f dest) {
		if (dest == null)
			dest = new Matrix3f();

		dest.m00 = left.m00 + right.m00;
		dest.m01 = left.m01 + right.m01;
		dest.m02 = left.m02 + right.m02;
		dest.m10 = left.m10 + right.m10;
		dest.m11 = left.m11 + right.m11;
		dest.m12 = left.m12 + right.m12;
		dest.m20 = left.m20 + right.m20;
		dest.m21 = left.m21 + right.m21;
		dest.m22 = left.m22 + right.m22;

		return dest;
	}

	/**
	 * Subtract the right matrix from the left and place the result in a third matrix.
	 * @param left The left source matrix
	 * @param right The right source matrix
	 * @param dest The destination matrix, or null if a new one is to be created
	 * @return the destination matrix
	 */
	public static Matrix3f sub(Matrix3f left, Matrix3f right, Matrix3f dest) {
		if (dest == null)
			dest = new Matrix3f();

		dest.m00 = left.m00 - right.m00;
		dest.m01 = left.m01 - right.m01;
		dest.m02 = left.m02 - right.m02;
		dest.m10 = left.m10 - right.m10;
		dest.m11 = left.m11 - right.m11;
		dest.m12 = left.m12 - right.m12;
		dest.m20 = left.m20 - right.m20;
		dest.m21 = left.m21 - right.m21;
		dest.m22 = left.m22 - right.m22;

		return dest;
	}

	/**
	 * Multiply the right matrix by the left and place the result in a third matrix.
	 * @param left The left source matrix
	 * @param right The right source matrix
	 * @param dest The destination matrix, or null if a new one is to be created
	 * @return the destination matrix
	 */
	public static Matrix3f mul(Matrix3f left, Matrix3f right, Matrix3f dest) {
		if (dest == null)
			dest = new Matrix3f();

		float m00 =
			left.m00 * right.m00 + left.m10 * right.m01 + left.m20 * right.m02;
		float m01 =
			left.m01 * right.m00 + left.m11 * right.m01 + left.m21 * right.m02;
		float m02 =
			left.m02 * right.m00 + left.m12 * right.m01 + left.m22 * right.m02;
		float m10 =
			left.m00 * right.m10 + left.m10 * right.m11 + left.m20 * right.m12;
		float m11 =
			left.m01 * right.m10 + left.m11 * right.m11 + left.m21 * right.m12;
		float m12 =
			left.m02 * right.m10 + left.m12 * right.m11 + left.m22 * right.m12;
		float m20 =
			left.m00 * right.m20 + left.m10 * right.m21 + left.m20 * right.m22;
		float m21 =
			left.m01 * right.m20 + left.m11 * right.m21 + left.m21 * right.m22;
		float m22 =
			left.m02 * right.m20 + left.m12 * right.m21 + left.m22 * right.m22;

		dest.m00 = m00;
		dest.m01 = m01;
		dest.m02 = m02;
		dest.m10 = m10;
		dest.m11 = m11;
		dest.m12 = m12;
		dest.m20 = m20;
		dest.m21 = m21;
		dest.m22 = m22;

		return dest;
	}

	/**
	 * Transform a Vector by a matrix and return the result in a destination
	 * vector.
	 * @param left The left matrix
	 * @param right The right vector
	 * @param dest The destination vector, or null if a new one is to be created
	 * @return the destination vector
	 */
	public static Vector3f transform(Matrix3f left, Vector3f right, Vector3f dest) {
		if (dest == null)
			dest = new Vector3f();

		float x = left.m00 * right.x + left.m10 * right.y + left.m20 * right.z;
		float y = left.m01 * right.x + left.m11 * right.y + left.m21 * right.z;
		float z = left.m02 * right.x + left.m12 * right.y + left.m22 * right.z;

		dest.x = x;
		dest.y = y;
		dest.z = z;

		return dest;
	}

	/**
	 * Transpose this matrix
	 * @return this
	 */
	public Matrix transpose() {
		return transpose(this, this);
	}

	/**
	 * Transpose this matrix and place the result in another matrix
	 * @param dest The destination matrix or null if a new matrix is to be created
	 * @return the transposed matrix
	 */
	public Matrix3f transpose(Matrix3f dest) {
		return transpose(this, dest);
	}

	/**
	 * Transpose the source matrix and place the result into the destination matrix
	 * @param src The source matrix to be transposed
	 * @param dest The destination matrix or null if a new matrix is to be created
	 * @return the transposed matrix
	 */
	public static Matrix3f transpose(Matrix3f src, Matrix3f dest) {
		if (dest == null)
		   dest = new Matrix3f();
		float m00 = src.m00;
		float m01 = src.m10;
		float m02 = src.m20;
		float m10 = src.m01;
		float m11 = src.m11;
		float m12 = src.m21;
		float m20 = src.m02;
		float m21 = src.m12;
		float m22 = src.m22;

		dest.m00 = m00;
		dest.m01 = m01;
		dest.m02 = m02;
		dest.m10 = m10;
		dest.m11 = m11;
		dest.m12 = m12;
		dest.m20 = m20;
		dest.m21 = m21;
		dest.m22 = m22;
		return dest;
	}

	/**
	 * @return the determinant of the matrix
	 */
	public float determinant() {
		float f =
			m00 * (m11 * m22 - m12 * m21)
				+ m01 * (m12 * m20 - m10 * m22)
				+ m02 * (m10 * m21 - m11 * m20);
		return f;
	}

	/**
	 * Returns a string representation of this matrix
	 */
	public String toString() {
		StringBuilder buf = new StringBuilder();
		buf.append(m00).append(' ').append(m10).append(' ').append(m20).append(' ').append('\n');
		buf.append(m01).append(' ').append(m11).append(' ').append(m21).append(' ').append('\n');
		buf.append(m02).append(' ').append(m12).append(' ').append(m22).append(' ').append('\n');
		return buf.toString();
	}

	/**
	 * Invert this matrix
	 * @return this if successful, null otherwise
	 */
	public Matrix invert() {
		return invert(this, this);
	}

	/**
	 * Invert the source matrix and put the result into the destination matrix
	 * @param src The source matrix to be inverted
	 * @param dest The destination matrix, or null if a new one is to be created
	 * @return The inverted matrix if successful, null otherwise
	 */
	public static Matrix3f invert(Matrix3f src, Matrix3f dest) {
		float determinant = src.determinant();

		if (determinant != 0) {
			if (dest == null)
				dest = new Matrix3f();
			 /* do it the ordinary way
			  *
			  * inv(A) = 1/det(A) * adj(T), where adj(T) = transpose(Conjugate Matrix)
			  *
			  * m00 m01 m02
			  * m10 m11 m12
			  * m20 m21 m22
			  */
			 float determinant_inv = 1f/determinant;

			 // get the conjugate matrix
			 float t00 = src.m11 * src.m22 - src.m12* src.m21;
			 float t01 = - src.m10 * src.m22 + src.m12 * src.m20;
			 float t02 = src.m10 * src.m21 - src.m11 * src.m20;
			 float t10 = - src.m01 * src.m22 + src.m02 * src.m21;
			 float t11 = src.m00 * src.m22 - src.m02 * src.m20;
			 float t12 = - src.m00 * src.m21 + src.m01 * src.m20;
			 float t20 = src.m01 * src.m12 - src.m02 * src.m11;
			 float t21 = -src.m00 * src.m12 + src.m02 * src.m10;
			 float t22 = src.m00 * src.m11 - src.m01 * src.m10;

			 dest.m00 = t00*determinant_inv;
			 dest.m11 = t11*determinant_inv;
			 dest.m22 = t22*determinant_inv;
			 dest.m01 = t10*determinant_inv;
			 dest.m10 = t01*determinant_inv;
			 dest.m20 = t02*determinant_inv;
			 dest.m02 = t20*determinant_inv;
			 dest.m12 = t21*determinant_inv;
			 dest.m21 = t12*determinant_inv;
			 return dest;
		} else
			 return null;
	}


	/**
	 * Negate this matrix
	 * @return this
	 */
	public Matrix negate() {
		return negate(this);
	}

	/**
	 * Negate this matrix and place the result in a destination matrix.
	 * @param dest The destination matrix, or null if a new matrix is to be created
	 * @return the negated matrix
	 */
	public Matrix3f negate(Matrix3f dest) {
		return negate(this, dest);
	}

	/**
	 * Negate the source matrix and place the result in the destination matrix.
	 * @param src The source matrix
	 * @param dest The destination matrix, or null if a new matrix is to be created
	 * @return the negated matrix
	 */
	public static Matrix3f negate(Matrix3f src, Matrix3f dest) {
		if (dest == null)
			dest = new Matrix3f();

		dest.m00 = -src.m00;
		dest.m01 = -src.m02;
		dest.m02 = -src.m01;
		dest.m10 = -src.m10;
		dest.m11 = -src.m12;
		dest.m12 = -src.m11;
		dest.m20 = -src.m20;
		dest.m21 = -src.m22;
		dest.m22 = -src.m21;
		return dest;
	}

	/**
	 * Set this matrix to be the identity matrix.
	 * @return this
	 */
	public Matrix setIdentity() {
		return setIdentity(this);
	}

	/**
	 * Set the matrix to be the identity matrix.
	 * @param m The matrix to be set to the identity
	 * @return m
	 */
	public static Matrix3f setIdentity(Matrix3f m) {
		m.m00 = 1.0f;
		m.m01 = 0.0f;
		m.m02 = 0.0f;
		m.m10 = 0.0f;
		m.m11 = 1.0f;
		m.m12 = 0.0f;
		m.m20 = 0.0f;
		m.m21 = 0.0f;
		m.m22 = 1.0f;
		return m;
	}

	/**
	 * Set this matrix to 0.
	 * @return this
	 */
	public Matrix setZero() {
		return setZero(this);
	}

	/**
	 * Set the matrix matrix to 0.
	 * @param m The matrix to be set to 0
	 * @return m
	 */
	public static Matrix3f setZero(Matrix3f m) {
		m.m00 = 0.0f;
		m.m01 = 0.0f;
		m.m02 = 0.0f;
		m.m10 = 0.0f;
		m.m11 = 0.0f;
		m.m12 = 0.0f;
		m.m20 = 0.0f;
		m.m21 = 0.0f;
		m.m22 = 0.0f;
		return m;
	}
}




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