src/parsec/disk-image/parsec/parsec-benchmark/pkgs/libs/mesa/src/src/mesa/math/m_norm_tmp.h - public/gem5-resources - Git at Google


 /*
  * Mesa 3-D graphics library
  * Version:  5.1
  *
  * Copyright (C) 1999-2003  Brian Paul   All Rights Reserved.
  *
  * Permission is hereby granted, free of charge, to any person obtaining a
  * copy of this software and associated documentation files (the "Software"),
  * to deal in the Software without restriction, including without limitation
  * the rights to use, copy, modify, merge, publish, distribute, sublicense,
  * and/or sell copies of the Software, and to permit persons to whom the
  * Software is furnished to do so, subject to the following conditions:
  *
  * The above copyright notice and this permission notice shall be included
  * in all copies or substantial portions of the Software.
  *
  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
  * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
  * BRIAN PAUL BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN
  * AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
  * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
  */

 /*
  * New (3.1) transformation code written by Keith Whitwell.
  */

 /* Functions to tranform a vector of normals.  This includes applying
  * the transformation matrix, rescaling and normalization.
  */

 /*
  * mat - the 4x4 transformation matrix
  * scale - uniform scale factor of the transformation matrix (not always used)
  * in - the source vector of normals
  * lengths - length of each incoming normal (may be NULL) (a display list
  *           optimization)
  * dest - the destination vector of normals
  */
 static void _XFORMAPI
 TAG(transform_normalize_normals)( const GLmatrix *mat,
                                   GLfloat scale,
                                   const GLvector4f *in,
                                   const GLfloat *lengths,
                                   GLvector4f *dest )
 {
    GLfloat (*out)[4] = (GLfloat (*)[4])dest->start;
    const GLfloat *from = in->start;
    const GLuint stride = in->stride;
    const GLuint count = in->count;
    const GLfloat *m = mat->inv;
    GLfloat m0 = m[0],  m4 = m[4],  m8 = m[8];
    GLfloat m1 = m[1],  m5 = m[5],  m9 = m[9];
    GLfloat m2 = m[2],  m6 = m[6],  m10 = m[10];
    GLuint i;

    if (!lengths) {
       STRIDE_LOOP {
 	 GLfloat tx, ty, tz;
 	 {
 	    const GLfloat ux = from[0],  uy = from[1],  uz = from[2];
 	    tx = ux * m0 + uy * m1 + uz * m2;
 	    ty = ux * m4 + uy * m5 + uz * m6;
 	    tz = ux * m8 + uy * m9 + uz * m10;
 	 }
 	 {
 	    GLdouble len = tx*tx + ty*ty + tz*tz;
 	    if (len > 1e-20) {
 	       GLfloat scale = INV_SQRTF(len);
 	       out[i][0] = tx * scale;
 	       out[i][1] = ty * scale;
 	       out[i][2] = tz * scale;
 	    }
 	    else {
 	       out[i][0] = out[i][1] = out[i][2] = 0;
 	    }
 	 }
       }
    }
    else {
       if (scale != 1.0) {
 	 m0 *= scale,  m4 *= scale,  m8 *= scale;
 	 m1 *= scale,  m5 *= scale,  m9 *= scale;
 	 m2 *= scale,  m6 *= scale,  m10 *= scale;
       }

       STRIDE_LOOP {
 	 GLfloat tx, ty, tz;
 	 {
 	    const GLfloat ux = from[0],  uy = from[1],  uz = from[2];
 	    tx = ux * m0 + uy * m1 + uz * m2;
 	    ty = ux * m4 + uy * m5 + uz * m6;
 	    tz = ux * m8 + uy * m9 + uz * m10;
 	 }
 	 {
 	    GLfloat len = lengths[i];
 	    out[i][0] = tx * len;
 	    out[i][1] = ty * len;
 	    out[i][2] = tz * len;
 	 }
       }
    }
    dest->count = in->count;
 }


 static void _XFORMAPI
 TAG(transform_normalize_normals_no_rot)( const GLmatrix *mat,
                                          GLfloat scale,
                                          const GLvector4f *in,
                                          const GLfloat *lengths,
                                          GLvector4f *dest )
 {
    GLfloat (*out)[4] = (GLfloat (*)[4])dest->start;
    const GLfloat *from = in->start;
    const GLuint stride = in->stride;
    const GLuint count = in->count;
    const GLfloat *m = mat->inv;
    GLfloat m0 = m[0];
    GLfloat m5 = m[5];
    GLfloat m10 = m[10];
    GLuint i;

    if (!lengths) {
       STRIDE_LOOP {
 	 GLfloat tx, ty, tz;
 	 {
 	    const GLfloat ux = from[0],  uy = from[1],  uz = from[2];
 	    tx = ux * m0                    ;
 	    ty =           uy * m5          ;
 	    tz =                     uz * m10;
 	 }
 	 {
 	    GLdouble len = tx*tx + ty*ty + tz*tz;
 	    if (len > 1e-20) {
 	       GLfloat scale = INV_SQRTF(len);
 	       out[i][0] = tx * scale;
 	       out[i][1] = ty * scale;
 	       out[i][2] = tz * scale;
 	    }
 	    else {
 	       out[i][0] = out[i][1] = out[i][2] = 0;
 	    }
 	 }
       }
    }
    else {
       m0 *= scale;
       m5 *= scale;
       m10 *= scale;

       STRIDE_LOOP {
 	 GLfloat tx, ty, tz;
 	 {
 	    const GLfloat ux = from[0],  uy = from[1],  uz = from[2];
 	    tx = ux * m0                    ;
 	    ty =           uy * m5          ;
 	    tz =                     uz * m10;
 	 }
 	 {
 	    GLfloat len = lengths[i];
 	    out[i][0] = tx * len;
 	    out[i][1] = ty * len;
 	    out[i][2] = tz * len;
 	 }
       }
    }
    dest->count = in->count;
 }


 static void _XFORMAPI
 TAG(transform_rescale_normals_no_rot)( const GLmatrix *mat,
                                        GLfloat scale,
                                        const GLvector4f *in,
                                        const GLfloat *lengths,
                                        GLvector4f *dest )
 {
    GLfloat (*out)[4] = (GLfloat (*)[4])dest->start;
    const GLfloat *from = in->start;
    const GLuint stride = in->stride;
    const GLuint count = in->count;
    const GLfloat *m = mat->inv;
    const GLfloat m0 = scale*m[0];
    const GLfloat m5 = scale*m[5];
    const GLfloat m10 = scale*m[10];
    GLuint i;

    (void) lengths;

    STRIDE_LOOP {
       GLfloat ux = from[0],  uy = from[1],  uz = from[2];
       out[i][0] = ux * m0;
       out[i][1] =           uy * m5;
       out[i][2] =                     uz * m10;
    }
    dest->count = in->count;
 }


 static void _XFORMAPI
 TAG(transform_rescale_normals)( const GLmatrix *mat,
                                 GLfloat scale,
                                 const GLvector4f *in,
                                 const GLfloat *lengths,
                                 GLvector4f *dest )
 {
    GLfloat (*out)[4] = (GLfloat (*)[4])dest->start;
    const GLfloat *from = in->start;
    const GLuint stride = in->stride;
    const GLuint count = in->count;
    /* Since we are unlikely to have < 3 vertices in the buffer,
     * it makes sense to pre-multiply by scale.
     */
    const GLfloat *m = mat->inv;
    const GLfloat m0 = scale*m[0],  m4 = scale*m[4],  m8 = scale*m[8];
    const GLfloat m1 = scale*m[1],  m5 = scale*m[5],  m9 = scale*m[9];
    const GLfloat m2 = scale*m[2],  m6 = scale*m[6],  m10 = scale*m[10];
    GLuint i;

    (void) lengths;

    STRIDE_LOOP {
       GLfloat ux = from[0],  uy = from[1],  uz = from[2];
       out[i][0] = ux * m0 + uy * m1 + uz * m2;
       out[i][1] = ux * m4 + uy * m5 + uz * m6;
       out[i][2] = ux * m8 + uy * m9 + uz * m10;
    }
    dest->count = in->count;
 }


 static void _XFORMAPI
 TAG(transform_normals_no_rot)( const GLmatrix *mat,
 			       GLfloat scale,
 			       const GLvector4f *in,
 			       const GLfloat *lengths,
 			       GLvector4f *dest )
 {
    GLfloat (*out)[4] = (GLfloat (*)[4])dest->start;
    const GLfloat *from = in->start;
    const GLuint stride = in->stride;
    const GLuint count = in->count;
    const GLfloat *m = mat->inv;
    const GLfloat m0 = m[0];
    const GLfloat m5 = m[5];
    const GLfloat m10 = m[10];
    GLuint i;

    (void) scale;
    (void) lengths;

    STRIDE_LOOP {
       GLfloat ux = from[0],  uy = from[1],  uz = from[2];
       out[i][0] = ux * m0;
       out[i][1] =           uy * m5;
       out[i][2] =                     uz * m10;
    }
    dest->count = in->count;
 }


 static void _XFORMAPI
 TAG(transform_normals)( const GLmatrix *mat,
                         GLfloat scale,
                         const GLvector4f *in,
                         const GLfloat *lengths,
                         GLvector4f *dest )
 {
    GLfloat (*out)[4] = (GLfloat (*)[4])dest->start;
    const GLfloat *from = in->start;
    const GLuint stride = in->stride;
    const GLuint count = in->count;
    const GLfloat *m = mat->inv;
    const GLfloat m0 = m[0],  m4 = m[4],  m8 = m[8];
    const GLfloat m1 = m[1],  m5 = m[5],  m9 = m[9];
    const GLfloat m2 = m[2],  m6 = m[6],  m10 = m[10];
    GLuint i;

    (void) scale;
    (void) lengths;

    STRIDE_LOOP {
       GLfloat ux = from[0],  uy = from[1],  uz = from[2];
       out[i][0] = ux * m0 + uy * m1 + uz * m2;
       out[i][1] = ux * m4 + uy * m5 + uz * m6;
       out[i][2] = ux * m8 + uy * m9 + uz * m10;
    }
    dest->count = in->count;
 }


 static void _XFORMAPI
 TAG(normalize_normals)( const GLmatrix *mat,
                         GLfloat scale,
                         const GLvector4f *in,
                         const GLfloat *lengths,
                         GLvector4f *dest )
 {
    GLfloat (*out)[4] = (GLfloat (*)[4])dest->start;
    const GLfloat *from = in->start;
    const GLuint stride = in->stride;
    const GLuint count = in->count;
    GLuint i;

    (void) mat;
    (void) scale;

    if (lengths) {
       STRIDE_LOOP {
 	 const GLfloat x = from[0], y = from[1], z = from[2];
 	 GLfloat invlen = lengths[i];
 	 out[i][0] = x * invlen;
 	 out[i][1] = y * invlen;
 	 out[i][2] = z * invlen;
       }
    }
    else {
       STRIDE_LOOP {
 	 const GLfloat x = from[0], y = from[1], z = from[2];
 	 GLdouble len = x * x + y * y + z * z;
 	 if (len > 1e-50) {
 	    len = INV_SQRTF(len);
 	    out[i][0] = (GLfloat)(x * len);
 	    out[i][1] = (GLfloat)(y * len);
 	    out[i][2] = (GLfloat)(z * len);
 	 }
 	 else {
 	    out[i][0] = x;
 	    out[i][1] = y;
 	    out[i][2] = z;
 	 }
       }
    }
    dest->count = in->count;
 }


 static void _XFORMAPI
 TAG(rescale_normals)( const GLmatrix *mat,
                       GLfloat scale,
                       const GLvector4f *in,
                       const GLfloat *lengths,
                       GLvector4f *dest )
 {
    GLfloat (*out)[4] = (GLfloat (*)[4])dest->start;
    const GLfloat *from = in->start;
    const GLuint stride = in->stride;
    const GLuint count = in->count;
    GLuint i;

    (void) mat;
    (void) lengths;

    STRIDE_LOOP {
       SCALE_SCALAR_3V( out[i], scale, from );
    }
    dest->count = in->count;
 }


 static void _XFORMAPI
 TAG(init_c_norm_transform)( void )
 {
    _mesa_normal_tab[NORM_TRANSFORM_NO_ROT] =
       TAG(transform_normals_no_rot);

    _mesa_normal_tab[NORM_TRANSFORM_NO_ROT | NORM_RESCALE] =
       TAG(transform_rescale_normals_no_rot);

    _mesa_normal_tab[NORM_TRANSFORM_NO_ROT | NORM_NORMALIZE] =
       TAG(transform_normalize_normals_no_rot);

    _mesa_normal_tab[NORM_TRANSFORM] =
       TAG(transform_normals);

    _mesa_normal_tab[NORM_TRANSFORM | NORM_RESCALE] =
       TAG(transform_rescale_normals);

    _mesa_normal_tab[NORM_TRANSFORM | NORM_NORMALIZE] =
       TAG(transform_normalize_normals);

    _mesa_normal_tab[NORM_RESCALE] =
       TAG(rescale_normals);

    _mesa_normal_tab[NORM_NORMALIZE] =
       TAG(normalize_normals);
 }

	/*
	* Mesa 3-D graphics library
	* Version: 5.1
	*
	* Copyright (C) 1999-2003 Brian Paul All Rights Reserved.
	*
	* Permission is hereby granted, free of charge, to any person obtaining a
	* copy of this software and associated documentation files (the "Software"),
	* to deal in the Software without restriction, including without limitation
	* the rights to use, copy, modify, merge, publish, distribute, sublicense,
	* and/or sell copies of the Software, and to permit persons to whom the
	* Software is furnished to do so, subject to the following conditions:
	*
	* The above copyright notice and this permission notice shall be included
	* in all copies or substantial portions of the Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
	* OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
	* BRIAN PAUL BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN
	* AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
	* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
	*/

	/*
	* New (3.1) transformation code written by Keith Whitwell.
	*/

	/* Functions to tranform a vector of normals. This includes applying
	* the transformation matrix, rescaling and normalization.
	*/

	/*
	* mat - the 4x4 transformation matrix
	* scale - uniform scale factor of the transformation matrix (not always used)
	* in - the source vector of normals
	* lengths - length of each incoming normal (may be NULL) (a display list
	* optimization)
	* dest - the destination vector of normals
	*/
	static void _XFORMAPI
	TAG(transform_normalize_normals)( const GLmatrix *mat,
	GLfloat scale,
	const GLvector4f *in,
	const GLfloat *lengths,
	GLvector4f *dest )
	{
	GLfloat (out)[4] = (GLfloat ()[4])dest->start;
	const GLfloat *from = in->start;
	const GLuint stride = in->stride;
	const GLuint count = in->count;
	const GLfloat *m = mat->inv;
	GLfloat m0 = m[0], m4 = m[4], m8 = m[8];
	GLfloat m1 = m[1], m5 = m[5], m9 = m[9];
	GLfloat m2 = m[2], m6 = m[6], m10 = m[10];
	GLuint i;

	if (!lengths) {
	STRIDE_LOOP {
	GLfloat tx, ty, tz;
	{
	const GLfloat ux = from[0], uy = from[1], uz = from[2];
	tx = ux * m0 + uy * m1 + uz * m2;
	ty = ux * m4 + uy * m5 + uz * m6;
	tz = ux * m8 + uy * m9 + uz * m10;
	}
	{
	GLdouble len = txtx + tyty + tz*tz;
	if (len > 1e-20) {
	GLfloat scale = INV_SQRTF(len);
	out[i][0] = tx * scale;
	out[i][1] = ty * scale;
	out[i][2] = tz * scale;
	}
	else {
	out[i][0] = out[i][1] = out[i][2] = 0;
	}
	}
	}
	}
	else {
	if (scale != 1.0) {
	m0 = scale, m4 = scale, m8 *= scale;
	m1 = scale, m5 = scale, m9 *= scale;
	m2 = scale, m6 = scale, m10 *= scale;
	}

	STRIDE_LOOP {
	GLfloat tx, ty, tz;
	{
	const GLfloat ux = from[0], uy = from[1], uz = from[2];
	tx = ux * m0 + uy * m1 + uz * m2;
	ty = ux * m4 + uy * m5 + uz * m6;
	tz = ux * m8 + uy * m9 + uz * m10;
	}
	{
	GLfloat len = lengths[i];
	out[i][0] = tx * len;
	out[i][1] = ty * len;
	out[i][2] = tz * len;
	}
	}
	}
	dest->count = in->count;
	}


	static void _XFORMAPI
	TAG(transform_normalize_normals_no_rot)( const GLmatrix *mat,
	GLfloat scale,
	const GLvector4f *in,
	const GLfloat *lengths,
	GLvector4f *dest )
	{
	GLfloat (out)[4] = (GLfloat ()[4])dest->start;
	const GLfloat *from = in->start;
	const GLuint stride = in->stride;
	const GLuint count = in->count;
	const GLfloat *m = mat->inv;
	GLfloat m0 = m[0];
	GLfloat m5 = m[5];
	GLfloat m10 = m[10];
	GLuint i;

	if (!lengths) {
	STRIDE_LOOP {
	GLfloat tx, ty, tz;
	{
	const GLfloat ux = from[0], uy = from[1], uz = from[2];
	tx = ux * m0 ;
	ty = uy * m5 ;
	tz = uz * m10;
	}
	{
	GLdouble len = txtx + tyty + tz*tz;
	if (len > 1e-20) {
	GLfloat scale = INV_SQRTF(len);
	out[i][0] = tx * scale;
	out[i][1] = ty * scale;
	out[i][2] = tz * scale;
	}
	else {
	out[i][0] = out[i][1] = out[i][2] = 0;
	}
	}
	}
	}
	else {
	m0 *= scale;
	m5 *= scale;
	m10 *= scale;

	STRIDE_LOOP {
	GLfloat tx, ty, tz;
	{
	const GLfloat ux = from[0], uy = from[1], uz = from[2];
	tx = ux * m0 ;
	ty = uy * m5 ;
	tz = uz * m10;
	}
	{
	GLfloat len = lengths[i];
	out[i][0] = tx * len;
	out[i][1] = ty * len;
	out[i][2] = tz * len;
	}
	}
	}
	dest->count = in->count;
	}


	static void _XFORMAPI
	TAG(transform_rescale_normals_no_rot)( const GLmatrix *mat,
	GLfloat scale,
	const GLvector4f *in,
	const GLfloat *lengths,
	GLvector4f *dest )
	{
	GLfloat (out)[4] = (GLfloat ()[4])dest->start;
	const GLfloat *from = in->start;
	const GLuint stride = in->stride;
	const GLuint count = in->count;
	const GLfloat *m = mat->inv;
	const GLfloat m0 = scale*m[0];
	const GLfloat m5 = scale*m[5];
	const GLfloat m10 = scale*m[10];
	GLuint i;

	(void) lengths;

	STRIDE_LOOP {
	GLfloat ux = from[0], uy = from[1], uz = from[2];
	out[i][0] = ux * m0;
	out[i][1] = uy * m5;
	out[i][2] = uz * m10;
	}
	dest->count = in->count;
	}


	static void _XFORMAPI
	TAG(transform_rescale_normals)( const GLmatrix *mat,
	GLfloat scale,
	const GLvector4f *in,
	const GLfloat *lengths,
	GLvector4f *dest )
	{
	GLfloat (out)[4] = (GLfloat ()[4])dest->start;
	const GLfloat *from = in->start;
	const GLuint stride = in->stride;
	const GLuint count = in->count;
	/* Since we are unlikely to have < 3 vertices in the buffer,
	* it makes sense to pre-multiply by scale.
	*/
	const GLfloat *m = mat->inv;
	const GLfloat m0 = scalem[0], m4 = scalem[4], m8 = scale*m[8];
	const GLfloat m1 = scalem[1], m5 = scalem[5], m9 = scale*m[9];
	const GLfloat m2 = scalem[2], m6 = scalem[6], m10 = scale*m[10];
	GLuint i;

	(void) lengths;

	STRIDE_LOOP {
	GLfloat ux = from[0], uy = from[1], uz = from[2];
	out[i][0] = ux * m0 + uy * m1 + uz * m2;
	out[i][1] = ux * m4 + uy * m5 + uz * m6;
	out[i][2] = ux * m8 + uy * m9 + uz * m10;
	}
	dest->count = in->count;
	}


	static void _XFORMAPI
	TAG(transform_normals_no_rot)( const GLmatrix *mat,
	GLfloat scale,
	const GLvector4f *in,
	const GLfloat *lengths,
	GLvector4f *dest )
	{
	GLfloat (out)[4] = (GLfloat ()[4])dest->start;
	const GLfloat *from = in->start;
	const GLuint stride = in->stride;
	const GLuint count = in->count;
	const GLfloat *m = mat->inv;
	const GLfloat m0 = m[0];
	const GLfloat m5 = m[5];
	const GLfloat m10 = m[10];
	GLuint i;

	(void) scale;
	(void) lengths;

	STRIDE_LOOP {
	GLfloat ux = from[0], uy = from[1], uz = from[2];
	out[i][0] = ux * m0;
	out[i][1] = uy * m5;
	out[i][2] = uz * m10;
	}
	dest->count = in->count;
	}


	static void _XFORMAPI
	TAG(transform_normals)( const GLmatrix *mat,
	GLfloat scale,
	const GLvector4f *in,
	const GLfloat *lengths,
	GLvector4f *dest )
	{
	GLfloat (out)[4] = (GLfloat ()[4])dest->start;
	const GLfloat *from = in->start;
	const GLuint stride = in->stride;
	const GLuint count = in->count;
	const GLfloat *m = mat->inv;
	const GLfloat m0 = m[0], m4 = m[4], m8 = m[8];
	const GLfloat m1 = m[1], m5 = m[5], m9 = m[9];
	const GLfloat m2 = m[2], m6 = m[6], m10 = m[10];
	GLuint i;

	(void) scale;
	(void) lengths;

	STRIDE_LOOP {
	GLfloat ux = from[0], uy = from[1], uz = from[2];
	out[i][0] = ux * m0 + uy * m1 + uz * m2;
	out[i][1] = ux * m4 + uy * m5 + uz * m6;
	out[i][2] = ux * m8 + uy * m9 + uz * m10;
	}
	dest->count = in->count;
	}


	static void _XFORMAPI
	TAG(normalize_normals)( const GLmatrix *mat,
	GLfloat scale,
	const GLvector4f *in,
	const GLfloat *lengths,
	GLvector4f *dest )
	{
	GLfloat (out)[4] = (GLfloat ()[4])dest->start;
	const GLfloat *from = in->start;
	const GLuint stride = in->stride;
	const GLuint count = in->count;
	GLuint i;

	(void) mat;
	(void) scale;

	if (lengths) {
	STRIDE_LOOP {
	const GLfloat x = from[0], y = from[1], z = from[2];
	GLfloat invlen = lengths[i];
	out[i][0] = x * invlen;
	out[i][1] = y * invlen;
	out[i][2] = z * invlen;
	}
	}
	else {
	STRIDE_LOOP {
	const GLfloat x = from[0], y = from[1], z = from[2];
	GLdouble len = x * x + y * y + z * z;
	if (len > 1e-50) {
	len = INV_SQRTF(len);
	out[i][0] = (GLfloat)(x * len);
	out[i][1] = (GLfloat)(y * len);
	out[i][2] = (GLfloat)(z * len);
	}
	else {
	out[i][0] = x;
	out[i][1] = y;
	out[i][2] = z;
	}
	}
	}
	dest->count = in->count;
	}


	static void _XFORMAPI
	TAG(rescale_normals)( const GLmatrix *mat,
	GLfloat scale,
	const GLvector4f *in,
	const GLfloat *lengths,
	GLvector4f *dest )
	{
	GLfloat (out)[4] = (GLfloat ()[4])dest->start;
	const GLfloat *from = in->start;
	const GLuint stride = in->stride;
	const GLuint count = in->count;
	GLuint i;

	(void) mat;
	(void) lengths;

	STRIDE_LOOP {
	SCALE_SCALAR_3V( out[i], scale, from );
	}
	dest->count = in->count;
	}


	static void _XFORMAPI
	TAG(init_c_norm_transform)( void )
	{
	_mesa_normal_tab[NORM_TRANSFORM_NO_ROT] =
	TAG(transform_normals_no_rot);

	_mesa_normal_tab[NORM_TRANSFORM_NO_ROT \| NORM_RESCALE] =
	TAG(transform_rescale_normals_no_rot);

	_mesa_normal_tab[NORM_TRANSFORM_NO_ROT \| NORM_NORMALIZE] =
	TAG(transform_normalize_normals_no_rot);

	_mesa_normal_tab[NORM_TRANSFORM] =
	TAG(transform_normals);

	_mesa_normal_tab[NORM_TRANSFORM \| NORM_RESCALE] =
	TAG(transform_rescale_normals);

	_mesa_normal_tab[NORM_TRANSFORM \| NORM_NORMALIZE] =
	TAG(transform_normalize_normals);

	_mesa_normal_tab[NORM_RESCALE] =
	TAG(rescale_normals);

	_mesa_normal_tab[NORM_NORMALIZE] =
	TAG(normalize_normals);
	}