src/share/demo/applets/WireFrame/Matrix3D.java - toolchain/jdk/jdk9_jdk - Git at Google

 /*
  * Copyright (c) 1995, 2006, Oracle and/or its affiliates. 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 Oracle 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.
  */

 /*
  */

 /** A fairly conventional 3D matrix object that can transform sets of
     3D points and perform a variety of manipulations on the transform */
 class Matrix3D {
     float xx, xy, xz, xo;
     float yx, yy, yz, yo;
     float zx, zy, zz, zo;
     static final double pi = 3.14159265;
     /** Create a new unit matrix */
     Matrix3D () {
         xx = 1.0f;
         yy = 1.0f;
         zz = 1.0f;
     }
     /** Scale by f in all dimensions */
     void scale(float f) {
         xx *= f;
         xy *= f;
         xz *= f;
         xo *= f;
         yx *= f;
         yy *= f;
         yz *= f;
         yo *= f;
         zx *= f;
         zy *= f;
         zz *= f;
         zo *= f;
     }
     /** Scale along each axis independently */
     void scale(float xf, float yf, float zf) {
         xx *= xf;
         xy *= xf;
         xz *= xf;
         xo *= xf;
         yx *= yf;
         yy *= yf;
         yz *= yf;
         yo *= yf;
         zx *= zf;
         zy *= zf;
         zz *= zf;
         zo *= zf;
     }
     /** Translate the origin */
     void translate(float x, float y, float z) {
         xo += x;
         yo += y;
         zo += z;
     }
     /** rotate theta degrees about the y axis */
     void yrot(double theta) {
         theta *= (pi / 180);
         double ct = Math.cos(theta);
         double st = Math.sin(theta);

         float Nxx = (float) (xx * ct + zx * st);
         float Nxy = (float) (xy * ct + zy * st);
         float Nxz = (float) (xz * ct + zz * st);
         float Nxo = (float) (xo * ct + zo * st);

         float Nzx = (float) (zx * ct - xx * st);
         float Nzy = (float) (zy * ct - xy * st);
         float Nzz = (float) (zz * ct - xz * st);
         float Nzo = (float) (zo * ct - xo * st);

         xo = Nxo;
         xx = Nxx;
         xy = Nxy;
         xz = Nxz;
         zo = Nzo;
         zx = Nzx;
         zy = Nzy;
         zz = Nzz;
     }
     /** rotate theta degrees about the x axis */
     void xrot(double theta) {
         theta *= (pi / 180);
         double ct = Math.cos(theta);
         double st = Math.sin(theta);

         float Nyx = (float) (yx * ct + zx * st);
         float Nyy = (float) (yy * ct + zy * st);
         float Nyz = (float) (yz * ct + zz * st);
         float Nyo = (float) (yo * ct + zo * st);

         float Nzx = (float) (zx * ct - yx * st);
         float Nzy = (float) (zy * ct - yy * st);
         float Nzz = (float) (zz * ct - yz * st);
         float Nzo = (float) (zo * ct - yo * st);

         yo = Nyo;
         yx = Nyx;
         yy = Nyy;
         yz = Nyz;
         zo = Nzo;
         zx = Nzx;
         zy = Nzy;
         zz = Nzz;
     }
     /** rotate theta degrees about the z axis */
     void zrot(double theta) {
         theta *= (pi / 180);
         double ct = Math.cos(theta);
         double st = Math.sin(theta);

         float Nyx = (float) (yx * ct + xx * st);
         float Nyy = (float) (yy * ct + xy * st);
         float Nyz = (float) (yz * ct + xz * st);
         float Nyo = (float) (yo * ct + xo * st);

         float Nxx = (float) (xx * ct - yx * st);
         float Nxy = (float) (xy * ct - yy * st);
         float Nxz = (float) (xz * ct - yz * st);
         float Nxo = (float) (xo * ct - yo * st);

         yo = Nyo;
         yx = Nyx;
         yy = Nyy;
         yz = Nyz;
         xo = Nxo;
         xx = Nxx;
         xy = Nxy;
         xz = Nxz;
     }
     /** Multiply this matrix by a second: M = M*R */
     void mult(Matrix3D rhs) {
         float lxx = xx * rhs.xx + yx * rhs.xy + zx * rhs.xz;
         float lxy = xy * rhs.xx + yy * rhs.xy + zy * rhs.xz;
         float lxz = xz * rhs.xx + yz * rhs.xy + zz * rhs.xz;
         float lxo = xo * rhs.xx + yo * rhs.xy + zo * rhs.xz + rhs.xo;

         float lyx = xx * rhs.yx + yx * rhs.yy + zx * rhs.yz;
         float lyy = xy * rhs.yx + yy * rhs.yy + zy * rhs.yz;
         float lyz = xz * rhs.yx + yz * rhs.yy + zz * rhs.yz;
         float lyo = xo * rhs.yx + yo * rhs.yy + zo * rhs.yz + rhs.yo;

         float lzx = xx * rhs.zx + yx * rhs.zy + zx * rhs.zz;
         float lzy = xy * rhs.zx + yy * rhs.zy + zy * rhs.zz;
         float lzz = xz * rhs.zx + yz * rhs.zy + zz * rhs.zz;
         float lzo = xo * rhs.zx + yo * rhs.zy + zo * rhs.zz + rhs.zo;

         xx = lxx;
         xy = lxy;
         xz = lxz;
         xo = lxo;

         yx = lyx;
         yy = lyy;
         yz = lyz;
         yo = lyo;

         zx = lzx;
         zy = lzy;
         zz = lzz;
         zo = lzo;
     }

     /** Reinitialize to the unit matrix */
     void unit() {
         xo = 0;
         xx = 1;
         xy = 0;
         xz = 0;
         yo = 0;
         yx = 0;
         yy = 1;
         yz = 0;
         zo = 0;
         zx = 0;
         zy = 0;
         zz = 1;
     }
     /** Transform nvert points from v into tv.  v contains the input
         coordinates in floating point.  Three successive entries in
         the array constitute a point.  tv ends up holding the transformed
         points as integers; three successive entries per point */
     void transform(float v[], int tv[], int nvert) {
         float lxx = xx, lxy = xy, lxz = xz, lxo = xo;
         float lyx = yx, lyy = yy, lyz = yz, lyo = yo;
         float lzx = zx, lzy = zy, lzz = zz, lzo = zo;
         for (int i = nvert * 3; (i -= 3) >= 0;) {
             float x = v[i];
             float y = v[i + 1];
             float z = v[i + 2];
             tv[i    ] = (int) (x * lxx + y * lxy + z * lxz + lxo);
             tv[i + 1] = (int) (x * lyx + y * lyy + z * lyz + lyo);
             tv[i + 2] = (int) (x * lzx + y * lzy + z * lzz + lzo);
         }
     }
     public String toString() {
         return ("[" + xo + "," + xx + "," + xy + "," + xz + ";"
                 + yo + "," + yx + "," + yy + "," + yz + ";"
                 + zo + "," + zx + "," + zy + "," + zz + "]");
     }
 }
	/*
	* Copyright (c) 1995, 2006, Oracle and/or its affiliates. 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 Oracle 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.
	*/

	/*
	*/

	/** A fairly conventional 3D matrix object that can transform sets of
	3D points and perform a variety of manipulations on the transform */
	class Matrix3D {
	float xx, xy, xz, xo;
	float yx, yy, yz, yo;
	float zx, zy, zz, zo;
	static final double pi = 3.14159265;
	/** Create a new unit matrix */
	Matrix3D () {
	xx = 1.0f;
	yy = 1.0f;
	zz = 1.0f;
	}
	/** Scale by f in all dimensions */
	void scale(float f) {
	xx *= f;
	xy *= f;
	xz *= f;
	xo *= f;
	yx *= f;
	yy *= f;
	yz *= f;
	yo *= f;
	zx *= f;
	zy *= f;
	zz *= f;
	zo *= f;
	}
	/** Scale along each axis independently */
	void scale(float xf, float yf, float zf) {
	xx *= xf;
	xy *= xf;
	xz *= xf;
	xo *= xf;
	yx *= yf;
	yy *= yf;
	yz *= yf;
	yo *= yf;
	zx *= zf;
	zy *= zf;
	zz *= zf;
	zo *= zf;
	}
	/** Translate the origin */
	void translate(float x, float y, float z) {
	xo += x;
	yo += y;
	zo += z;
	}
	/** rotate theta degrees about the y axis */
	void yrot(double theta) {
	theta *= (pi / 180);
	double ct = Math.cos(theta);
	double st = Math.sin(theta);

	float Nxx = (float) (xx * ct + zx * st);
	float Nxy = (float) (xy * ct + zy * st);
	float Nxz = (float) (xz * ct + zz * st);
	float Nxo = (float) (xo * ct + zo * st);

	float Nzx = (float) (zx * ct - xx * st);
	float Nzy = (float) (zy * ct - xy * st);
	float Nzz = (float) (zz * ct - xz * st);
	float Nzo = (float) (zo * ct - xo * st);

	xo = Nxo;
	xx = Nxx;
	xy = Nxy;
	xz = Nxz;
	zo = Nzo;
	zx = Nzx;
	zy = Nzy;
	zz = Nzz;
	}
	/** rotate theta degrees about the x axis */
	void xrot(double theta) {
	theta *= (pi / 180);
	double ct = Math.cos(theta);
	double st = Math.sin(theta);

	float Nyx = (float) (yx * ct + zx * st);
	float Nyy = (float) (yy * ct + zy * st);
	float Nyz = (float) (yz * ct + zz * st);
	float Nyo = (float) (yo * ct + zo * st);

	float Nzx = (float) (zx * ct - yx * st);
	float Nzy = (float) (zy * ct - yy * st);
	float Nzz = (float) (zz * ct - yz * st);
	float Nzo = (float) (zo * ct - yo * st);

	yo = Nyo;
	yx = Nyx;
	yy = Nyy;
	yz = Nyz;
	zo = Nzo;
	zx = Nzx;
	zy = Nzy;
	zz = Nzz;
	}
	/** rotate theta degrees about the z axis */
	void zrot(double theta) {
	theta *= (pi / 180);
	double ct = Math.cos(theta);
	double st = Math.sin(theta);

	float Nyx = (float) (yx * ct + xx * st);
	float Nyy = (float) (yy * ct + xy * st);
	float Nyz = (float) (yz * ct + xz * st);
	float Nyo = (float) (yo * ct + xo * st);

	float Nxx = (float) (xx * ct - yx * st);
	float Nxy = (float) (xy * ct - yy * st);
	float Nxz = (float) (xz * ct - yz * st);
	float Nxo = (float) (xo * ct - yo * st);

	yo = Nyo;
	yx = Nyx;
	yy = Nyy;
	yz = Nyz;
	xo = Nxo;
	xx = Nxx;
	xy = Nxy;
	xz = Nxz;
	}
	/** Multiply this matrix by a second: M = MR /
	void mult(Matrix3D rhs) {
	float lxx = xx * rhs.xx + yx * rhs.xy + zx * rhs.xz;
	float lxy = xy * rhs.xx + yy * rhs.xy + zy * rhs.xz;
	float lxz = xz * rhs.xx + yz * rhs.xy + zz * rhs.xz;
	float lxo = xo * rhs.xx + yo * rhs.xy + zo * rhs.xz + rhs.xo;

	float lyx = xx * rhs.yx + yx * rhs.yy + zx * rhs.yz;
	float lyy = xy * rhs.yx + yy * rhs.yy + zy * rhs.yz;
	float lyz = xz * rhs.yx + yz * rhs.yy + zz * rhs.yz;
	float lyo = xo * rhs.yx + yo * rhs.yy + zo * rhs.yz + rhs.yo;

	float lzx = xx * rhs.zx + yx * rhs.zy + zx * rhs.zz;
	float lzy = xy * rhs.zx + yy * rhs.zy + zy * rhs.zz;
	float lzz = xz * rhs.zx + yz * rhs.zy + zz * rhs.zz;
	float lzo = xo * rhs.zx + yo * rhs.zy + zo * rhs.zz + rhs.zo;

	xx = lxx;
	xy = lxy;
	xz = lxz;
	xo = lxo;

	yx = lyx;
	yy = lyy;
	yz = lyz;
	yo = lyo;

	zx = lzx;
	zy = lzy;
	zz = lzz;
	zo = lzo;
	}

	/** Reinitialize to the unit matrix */
	void unit() {
	xo = 0;
	xx = 1;
	xy = 0;
	xz = 0;
	yo = 0;
	yx = 0;
	yy = 1;
	yz = 0;
	zo = 0;
	zx = 0;
	zy = 0;
	zz = 1;
	}
	/** Transform nvert points from v into tv. v contains the input
	coordinates in floating point. Three successive entries in
	the array constitute a point. tv ends up holding the transformed
	points as integers; three successive entries per point */
	void transform(float v[], int tv[], int nvert) {
	float lxx = xx, lxy = xy, lxz = xz, lxo = xo;
	float lyx = yx, lyy = yy, lyz = yz, lyo = yo;
	float lzx = zx, lzy = zy, lzz = zz, lzo = zo;
	for (int i = nvert * 3; (i -= 3) >= 0;) {
	float x = v[i];
	float y = v[i + 1];
	float z = v[i + 2];
	tv[i ] = (int) (x * lxx + y * lxy + z * lxz + lxo);
	tv[i + 1] = (int) (x * lyx + y * lyy + z * lyz + lyo);
	tv[i + 2] = (int) (x * lzx + y * lzy + z * lzz + lzo);
	}
	}
	public String toString() {
	return ("[" + xo + "," + xx + "," + xy + "," + xz + ";"
	+ yo + "," + yx + "," + yy + "," + yz + ";"
	+ zo + "," + zx + "," + zy + "," + zz + "]");
	}
	}