third_party/PowerVR_SDK/Tools/PVRTMisc.cpp - SwiftShader - Git at Google

 /******************************************************************************

  @File         PVRTMisc.cpp

  @Title        PVRTMisc

  @Version

  @Copyright    Copyright (c) Imagination Technologies Limited.

  @Platform     ANSI compatible

  @Description  Miscellaneous functions used in 3D rendering.

 ******************************************************************************/
 #include <string.h>
 #include <stdlib.h>
 #include <ctype.h>
 #include <limits.h>
 #include <math.h>
 #include "PVRTGlobal.h"
 #include "PVRTContext.h"
 #include "PVRTFixedPoint.h"
 #include "PVRTMatrix.h"
 #include "PVRTMisc.h"


 /*!***************************************************************************
  @Function			PVRTMiscCalculateIntersectionLinePlane
  @Input				pfPlane			Length 4 [A,B,C,D], values for plane
 									equation
  @Input				pv0				A point on the line
  @Input				pv1				Another point on the line
  @Output			pvIntersection	The point of intersection
  @Description		Calculates coords of the intersection of a line and an
 					infinite plane
 *****************************************************************************/
 void PVRTMiscCalculateIntersectionLinePlane(
 	PVRTVECTOR3			* const pvIntersection,
 	const VERTTYPE		pfPlane[4],
 	const PVRTVECTOR3	* const pv0,
 	const PVRTVECTOR3	* const pv1)
 {
 	PVRTVECTOR3	vD;
 	VERTTYPE fN, fD, fT;

 	/* Calculate vector from point0 to point1 */
 	vD.x = pv1->x - pv0->x;
 	vD.y = pv1->y - pv0->y;
 	vD.z = pv1->z - pv0->z;

 	/* Denominator */
 	fD =
 		VERTTYPEMUL(pfPlane[0], vD.x) +
 		VERTTYPEMUL(pfPlane[1], vD.y) +
 		VERTTYPEMUL(pfPlane[2], vD.z);

 	/* Numerator */
 	fN =
 		VERTTYPEMUL(pfPlane[0], pv0->x) +
 		VERTTYPEMUL(pfPlane[1], pv0->y) +
 		VERTTYPEMUL(pfPlane[2], pv0->z) +
 		pfPlane[3];

 	fT = VERTTYPEDIV(-fN, fD);

 	/* And for a finale, calculate the intersection coordinate */
 	pvIntersection->x = pv0->x + VERTTYPEMUL(fT, vD.x);
 	pvIntersection->y = pv0->y + VERTTYPEMUL(fT, vD.y);
 	pvIntersection->z = pv0->z + VERTTYPEMUL(fT, vD.z);
 }


 /*!***************************************************************************
  @Function		PVRTMiscCalculateInfinitePlane
  @Input			nStride			Size of each vertex structure containing pfVtx
  @Input			pvPlane			Length 4 [A,B,C,D], values for plane equation
  @Input			pmViewProjInv	The inverse of the View Projection matrix
  @Input			pFrom			Position of the camera
  @Input			fFar			Far clipping distance
  @Output		pfVtx			Position of the first of 3 floats to receive
 								the position of vertex 0; up to 5 vertex positions
 								will be written (5 is the maximum number of vertices
 								required to draw an infinite polygon clipped to screen
 								and far clip plane).
  @Returns		Number of vertices in the polygon fan (Can be 0, 3, 4 or 5)
  @Description	Calculates world-space coords of a screen-filling
 				representation of an infinite plane The resulting vertices run
 				counter-clockwise around the screen, and can be simply drawn using
 				non-indexed TRIANGLEFAN
 *****************************************************************************/
 int PVRTMiscCalculateInfinitePlane(
 	VERTTYPE			* const pfVtx,
 	const int			nStride,
 	const PVRTVECTOR4	* const pvPlane,
 	const PVRTMATRIX 	* const pmViewProjInv,
 	const PVRTVECTOR3	* const pFrom,
 	const VERTTYPE		fFar)
 {
 	PVRTVECTOR3		pvWorld[5];
 	PVRTVECTOR3		*pvPolyPtr;
 	unsigned int	dwCount;
 	bool			bClip;
 	int				nVert;
 	VERTTYPE		fDotProduct;

 	/*
 		Check whether the plane faces the camera
 	*/
 	fDotProduct =
 		VERTTYPEMUL((pFrom->x + VERTTYPEMUL(pvPlane->x, pvPlane->w)), pvPlane->x) +
 		VERTTYPEMUL((pFrom->y + VERTTYPEMUL(pvPlane->y, pvPlane->w)), pvPlane->y) +
 		VERTTYPEMUL((pFrom->z + VERTTYPEMUL(pvPlane->z, pvPlane->w)), pvPlane->z);

 	if(fDotProduct < 0) {
 		/* Camera is behind plane, hence it's not visible */
 		return 0;
 	}

 	/*
 		Back transform front clipping plane into world space,
 		to give us a point on the line through each corner of the screen
 		(from the camera).
 	*/

 	/*             x = -1.0f;    y = -1.0f;     z = 1.0f;      w = 1.0f */
 	pvWorld[0].x = VERTTYPEMUL((-pmViewProjInv->f[ 0] - pmViewProjInv->f[ 4] + pmViewProjInv->f[ 8] + pmViewProjInv->f[12]), fFar);
 	pvWorld[0].y = VERTTYPEMUL((-pmViewProjInv->f[ 1] - pmViewProjInv->f[ 5] + pmViewProjInv->f[ 9] + pmViewProjInv->f[13]), fFar);
 	pvWorld[0].z = VERTTYPEMUL((-pmViewProjInv->f[ 2] - pmViewProjInv->f[ 6] + pmViewProjInv->f[10] + pmViewProjInv->f[14]), fFar);
 	/*             x =  1.0f,    y = -1.0f,     z = 1.0f;      w = 1.0f */
 	pvWorld[1].x = VERTTYPEMUL(( pmViewProjInv->f[ 0] - pmViewProjInv->f[ 4] + pmViewProjInv->f[ 8] + pmViewProjInv->f[12]), fFar);
 	pvWorld[1].y = VERTTYPEMUL(( pmViewProjInv->f[ 1] - pmViewProjInv->f[ 5] + pmViewProjInv->f[ 9] + pmViewProjInv->f[13]), fFar);
 	pvWorld[1].z = VERTTYPEMUL(( pmViewProjInv->f[ 2] - pmViewProjInv->f[ 6] + pmViewProjInv->f[10] + pmViewProjInv->f[14]), fFar);
 	/*             x =  1.0f,    y =  1.0f,     z = 1.0f;      w = 1.0f */
 	pvWorld[2].x = VERTTYPEMUL(( pmViewProjInv->f[ 0] + pmViewProjInv->f[ 4] + pmViewProjInv->f[ 8] + pmViewProjInv->f[12]), fFar);
 	pvWorld[2].y = VERTTYPEMUL(( pmViewProjInv->f[ 1] + pmViewProjInv->f[ 5] + pmViewProjInv->f[ 9] + pmViewProjInv->f[13]), fFar);
 	pvWorld[2].z = VERTTYPEMUL(( pmViewProjInv->f[ 2] + pmViewProjInv->f[ 6] + pmViewProjInv->f[10] + pmViewProjInv->f[14]), fFar);
 	/*             x = -1.0f,    y =  1.0f,     z = 1.0f;      w = 1.0f */
 	pvWorld[3].x = VERTTYPEMUL((-pmViewProjInv->f[ 0] + pmViewProjInv->f[ 4] + pmViewProjInv->f[ 8] + pmViewProjInv->f[12]), fFar);
 	pvWorld[3].y = VERTTYPEMUL((-pmViewProjInv->f[ 1] + pmViewProjInv->f[ 5] + pmViewProjInv->f[ 9] + pmViewProjInv->f[13]), fFar);
 	pvWorld[3].z = VERTTYPEMUL((-pmViewProjInv->f[ 2] + pmViewProjInv->f[ 6] + pmViewProjInv->f[10] + pmViewProjInv->f[14]), fFar);

 	/* We need to do a closed loop of the screen vertices, so copy the first vertex into the last */
 	pvWorld[4] = pvWorld[0];

 	/*
 		Now build a pre-clipped polygon
 	*/

 	/* Lets get ready to loop */
 	dwCount		= 0;
 	bClip		= false;
 	pvPolyPtr	= (PVRTVECTOR3*)pfVtx;

 	nVert = 5;
 	while(nVert)
 	{
 		nVert--;

 		/*
 			Check which side of the Plane this corner of the far clipping
 			plane is on. [A,B,C] of plane equation is the plane normal, D is
 			distance from origin; hence [pvPlane->x * -pvPlane->w,
 										 pvPlane->y * -pvPlane->w,
 										 pvPlane->z * -pvPlane->w]
 			is a point on the plane
 		*/
 		fDotProduct =
 			VERTTYPEMUL((pvWorld[nVert].x + VERTTYPEMUL(pvPlane->x, pvPlane->w)), pvPlane->x) +
 			VERTTYPEMUL((pvWorld[nVert].y + VERTTYPEMUL(pvPlane->y, pvPlane->w)), pvPlane->y) +
 			VERTTYPEMUL((pvWorld[nVert].z + VERTTYPEMUL(pvPlane->z, pvPlane->w)), pvPlane->z);

 		if(fDotProduct < 0)
 		{
 			/*
 				Behind plane; Vertex does NOT need clipping
 			*/
 			if(bClip == true)
 			{
 				/* Clipping finished */
 				bClip = false;

 				/*
 					We've been clipping, so we need to add an additional
 					point on the line to this point, where clipping was
 					stopped.
 				*/
 				PVRTMiscCalculateIntersectionLinePlane(pvPolyPtr, &pvPlane->x, &pvWorld[nVert+1], &pvWorld[nVert]);
 				pvPolyPtr = (PVRTVECTOR3*)((char*)pvPolyPtr + nStride);
 				dwCount++;
 			}

 			if(!nVert)
 			{
 				/* Abort, abort: we've closed the loop with the clipped point */
 				break;
 			}

 			/* Add the current point */
 			PVRTMiscCalculateIntersectionLinePlane(pvPolyPtr, &pvPlane->x, pFrom, &pvWorld[nVert]);
 			pvPolyPtr = (PVRTVECTOR3*)((char*)pvPolyPtr + nStride);
 			dwCount++;
 		}
 		else
 		{
 			/*
 				Before plane; Vertex DOES need clipping
 			*/
 			if(bClip == true)
 			{
 				/* Already in clipping, skip point */
 				continue;
 			}

 			/* Clipping initiated */
 			bClip = true;

 			/* Don't bother with entry point on first vertex; will take care of it on last vertex (which is a repeat of first vertex) */
 			if(nVert != 4)
 			{
 				/* We need to add an additional point on the line to this point, where clipping was started */
 				PVRTMiscCalculateIntersectionLinePlane(pvPolyPtr, &pvPlane->x, &pvWorld[nVert+1], &pvWorld[nVert]);
 				pvPolyPtr = (PVRTVECTOR3*)((char*)pvPolyPtr + nStride);
 				dwCount++;
 			}
 		}
 	}

 	/* Valid vertex counts are 0, 3, 4, 5 */
 	_ASSERT(dwCount <= 5);
 	_ASSERT(dwCount != 1);
 	_ASSERT(dwCount != 2);

 	return dwCount;
 }


 /*!***************************************************************************
  @Function			SetVertex
  @Modified			Vertices
  @Input				index
  @Input				x
  @Input				y
  @Input				z
  @Description		Writes a vertex in a vertex array
 *****************************************************************************/
 static void SetVertex(VERTTYPE** Vertices, int index, VERTTYPE x, VERTTYPE y, VERTTYPE z)
 {
 	(*Vertices)[index*3+0] = x;
 	(*Vertices)[index*3+1] = y;
 	(*Vertices)[index*3+2] = z;
 }

 /*!***************************************************************************
  @Function			SetUV
  @Modified			UVs
  @Input				index
  @Input				u
  @Input				v
  @Description		Writes a texture coordinate in a texture coordinate array
 *****************************************************************************/
 static void SetUV(VERTTYPE** UVs, int index, VERTTYPE u, VERTTYPE v)
 {
 	(*UVs)[index*2+0] = u;
 	(*UVs)[index*2+1] = v;
 }

 /*!***************************************************************************
  @Function		PVRTCreateSkybox
  @Input			scale			Scale the skybox
  @Input			adjustUV		Adjust or not UVs for PVRT compression
  @Input			textureSize		Texture size in pixels
  @Output		Vertices		Array of vertices
  @Output		UVs				Array of UVs
  @Description	Creates the vertices and texture coordinates for a skybox
 *****************************************************************************/
 void PVRTCreateSkybox(float scale, bool adjustUV, int textureSize, VERTTYPE** Vertices, VERTTYPE** UVs)
 {
 	*Vertices = new VERTTYPE[24*3];
 	*UVs = new VERTTYPE[24*2];

 	VERTTYPE unit = f2vt(1);
 	VERTTYPE a0 = 0, a1 = unit;

 	if (adjustUV)
 	{
 		VERTTYPE oneover = f2vt(1.0f / textureSize);
 		a0 = VERTTYPEMUL(f2vt(4.0f), oneover);
 		a1 = unit - a0;
 	}

 	// Front
 	SetVertex(Vertices, 0, -unit, +unit, -unit);
 	SetVertex(Vertices, 1, +unit, +unit, -unit);
 	SetVertex(Vertices, 2, -unit, -unit, -unit);
 	SetVertex(Vertices, 3, +unit, -unit, -unit);
 	SetUV(UVs, 0, a0, a1);
 	SetUV(UVs, 1, a1, a1);
 	SetUV(UVs, 2, a0, a0);
 	SetUV(UVs, 3, a1, a0);

 	// Right
 	SetVertex(Vertices, 4, +unit, +unit, -unit);
 	SetVertex(Vertices, 5, +unit, +unit, +unit);
 	SetVertex(Vertices, 6, +unit, -unit, -unit);
 	SetVertex(Vertices, 7, +unit, -unit, +unit);
 	SetUV(UVs, 4, a0, a1);
 	SetUV(UVs, 5, a1, a1);
 	SetUV(UVs, 6, a0, a0);
 	SetUV(UVs, 7, a1, a0);

 	// Back
 	SetVertex(Vertices, 8 , +unit, +unit, +unit);
 	SetVertex(Vertices, 9 , -unit, +unit, +unit);
 	SetVertex(Vertices, 10, +unit, -unit, +unit);
 	SetVertex(Vertices, 11, -unit, -unit, +unit);
 	SetUV(UVs, 8 , a0, a1);
 	SetUV(UVs, 9 , a1, a1);
 	SetUV(UVs, 10, a0, a0);
 	SetUV(UVs, 11, a1, a0);

 	// Left
 	SetVertex(Vertices, 12, -unit, +unit, +unit);
 	SetVertex(Vertices, 13, -unit, +unit, -unit);
 	SetVertex(Vertices, 14, -unit, -unit, +unit);
 	SetVertex(Vertices, 15, -unit, -unit, -unit);
 	SetUV(UVs, 12, a0, a1);
 	SetUV(UVs, 13, a1, a1);
 	SetUV(UVs, 14, a0, a0);
 	SetUV(UVs, 15, a1, a0);

 	// Top
 	SetVertex(Vertices, 16, -unit, +unit, +unit);
 	SetVertex(Vertices, 17, +unit, +unit, +unit);
 	SetVertex(Vertices, 18, -unit, +unit, -unit);
 	SetVertex(Vertices, 19, +unit, +unit, -unit);
 	SetUV(UVs, 16, a0, a1);
 	SetUV(UVs, 17, a1, a1);
 	SetUV(UVs, 18, a0, a0);
 	SetUV(UVs, 19, a1, a0);

 	// Bottom
 	SetVertex(Vertices, 20, -unit, -unit, -unit);
 	SetVertex(Vertices, 21, +unit, -unit, -unit);
 	SetVertex(Vertices, 22, -unit, -unit, +unit);
 	SetVertex(Vertices, 23, +unit, -unit, +unit);
 	SetUV(UVs, 20, a0, a1);
 	SetUV(UVs, 21, a1, a1);
 	SetUV(UVs, 22, a0, a0);
 	SetUV(UVs, 23, a1, a0);

 	for (int i=0; i<24*3; i++) (*Vertices)[i] = VERTTYPEMUL((*Vertices)[i], f2vt(scale));
 }

 /*!***************************************************************************
  @Function		PVRTDestroySkybox
  @Input			Vertices	Vertices array to destroy
  @Input			UVs			UVs array to destroy
  @Description	Destroy the memory allocated for a skybox
 *****************************************************************************/
 void PVRTDestroySkybox(VERTTYPE* Vertices, VERTTYPE* UVs)
 {
 	delete [] Vertices;
 	delete [] UVs;
 }

 /*!***************************************************************************
  @Function		PVRTGetPOTHigher
  @Input			uiOriginalValue	Base value
  @Input			iTimesHigher		Multiplier
  @Description	When iTimesHigher is one, this function will return the closest
 				power-of-two value above the base value.
 				For every increment beyond one for the iTimesHigher value,
 				the next highest power-of-two value will be calculated.
 *****************************************************************************/
 unsigned int PVRTGetPOTHigher(unsigned int uiOriginalValue, int iTimesHigher)
 {
 	if(uiOriginalValue == 0 || iTimesHigher < 0)
 	{
 		return 0;
 	}

 	unsigned int uiSize = 1;
 	while (uiSize < uiOriginalValue) uiSize *= 2;

 	// Keep increasing the POT value until the iTimesHigher value has been met
 	for(int i = 1 ; i < iTimesHigher; ++i)
 	{
 		uiSize *= 2;
 	}

 	return uiSize;
 }

 /*!***************************************************************************
  @Function		PVRTGetPOTLower
  @Input			uiOriginalValue	Base value
  @Input			iTimesLower		Multiplier
  @Description	When iTimesLower is one, this function will return the closest
 				power-of-two value below the base value.
 				For every increment beyond one for the iTimesLower value,
 				the next lowest power-of-two value will be calculated. The lowest
 				value that can be reached is 1.
 *****************************************************************************/
 // NOTE: This function should be optimised
 unsigned int PVRTGetPOTLower(unsigned int uiOriginalValue, int iTimesLower)
 {
 	if(uiOriginalValue == 0 || iTimesLower < 0)
 	{
 		return 0;
 	}
 	unsigned int uiSize = PVRTGetPOTHigher(uiOriginalValue,1);
 	uiSize >>= 1;//uiSize /=2;

 	for(int i = 1; i < iTimesLower; ++i)
 	{
 		uiSize >>= 1;//uiSize /=2;
 		if(uiSize == 1)
 		{
 			// Lowest possible value has been reached, so break
 			break;
 		}
 	}
 	return uiSize;
 }


 /*****************************************************************************
  End of file (PVRTMisc.cpp)
 *****************************************************************************/
	/******************************************************************************

	@File PVRTMisc.cpp

	@Title PVRTMisc

	@Version

	@Copyright Copyright (c) Imagination Technologies Limited.

	@Platform ANSI compatible

	@Description Miscellaneous functions used in 3D rendering.

	******************************************************************************/
	#include <string.h>
	#include <stdlib.h>
	#include <ctype.h>
	#include <limits.h>
	#include <math.h>
	#include "PVRTGlobal.h"
	#include "PVRTContext.h"
	#include "PVRTFixedPoint.h"
	#include "PVRTMatrix.h"
	#include "PVRTMisc.h"



	/!**************************************************************************
	@Function PVRTMiscCalculateIntersectionLinePlane
	@Input pfPlane Length 4 [A,B,C,D], values for plane
	equation
	@Input pv0 A point on the line
	@Input pv1 Another point on the line
	@Output pvIntersection The point of intersection
	@Description Calculates coords of the intersection of a line and an
	infinite plane
	*****************************************************************************/
	void PVRTMiscCalculateIntersectionLinePlane(
	PVRTVECTOR3 * const pvIntersection,
	const VERTTYPE pfPlane[4],
	const PVRTVECTOR3 * const pv0,
	const PVRTVECTOR3 * const pv1)
	{
	PVRTVECTOR3 vD;
	VERTTYPE fN, fD, fT;

	/* Calculate vector from point0 to point1 */
	vD.x = pv1->x - pv0->x;
	vD.y = pv1->y - pv0->y;
	vD.z = pv1->z - pv0->z;

	/* Denominator */
	fD =
	VERTTYPEMUL(pfPlane[0], vD.x) +
	VERTTYPEMUL(pfPlane[1], vD.y) +
	VERTTYPEMUL(pfPlane[2], vD.z);

	/* Numerator */
	fN =
	VERTTYPEMUL(pfPlane[0], pv0->x) +
	VERTTYPEMUL(pfPlane[1], pv0->y) +
	VERTTYPEMUL(pfPlane[2], pv0->z) +
	pfPlane[3];

	fT = VERTTYPEDIV(-fN, fD);

	/* And for a finale, calculate the intersection coordinate */
	pvIntersection->x = pv0->x + VERTTYPEMUL(fT, vD.x);
	pvIntersection->y = pv0->y + VERTTYPEMUL(fT, vD.y);
	pvIntersection->z = pv0->z + VERTTYPEMUL(fT, vD.z);
	}


	/!**************************************************************************
	@Function PVRTMiscCalculateInfinitePlane
	@Input nStride Size of each vertex structure containing pfVtx
	@Input pvPlane Length 4 [A,B,C,D], values for plane equation
	@Input pmViewProjInv The inverse of the View Projection matrix
	@Input pFrom Position of the camera
	@Input fFar Far clipping distance
	@Output pfVtx Position of the first of 3 floats to receive
	the position of vertex 0; up to 5 vertex positions
	will be written (5 is the maximum number of vertices
	required to draw an infinite polygon clipped to screen
	and far clip plane).
	@Returns Number of vertices in the polygon fan (Can be 0, 3, 4 or 5)
	@Description Calculates world-space coords of a screen-filling
	representation of an infinite plane The resulting vertices run
	counter-clockwise around the screen, and can be simply drawn using
	non-indexed TRIANGLEFAN
	*****************************************************************************/
	int PVRTMiscCalculateInfinitePlane(
	VERTTYPE * const pfVtx,
	const int nStride,
	const PVRTVECTOR4 * const pvPlane,
	const PVRTMATRIX * const pmViewProjInv,
	const PVRTVECTOR3 * const pFrom,
	const VERTTYPE fFar)
	{
	PVRTVECTOR3 pvWorld[5];
	PVRTVECTOR3 *pvPolyPtr;
	unsigned int dwCount;
	bool bClip;
	int nVert;
	VERTTYPE fDotProduct;

	/*
	Check whether the plane faces the camera
	*/
	fDotProduct =
	VERTTYPEMUL((pFrom->x + VERTTYPEMUL(pvPlane->x, pvPlane->w)), pvPlane->x) +
	VERTTYPEMUL((pFrom->y + VERTTYPEMUL(pvPlane->y, pvPlane->w)), pvPlane->y) +
	VERTTYPEMUL((pFrom->z + VERTTYPEMUL(pvPlane->z, pvPlane->w)), pvPlane->z);

	if(fDotProduct < 0) {
	/* Camera is behind plane, hence it's not visible */
	return 0;
	}

	/*
	Back transform front clipping plane into world space,
	to give us a point on the line through each corner of the screen
	(from the camera).
	*/

	/* x = -1.0f; y = -1.0f; z = 1.0f; w = 1.0f */
	pvWorld[0].x = VERTTYPEMUL((-pmViewProjInv->f[ 0] - pmViewProjInv->f[ 4] + pmViewProjInv->f[ 8] + pmViewProjInv->f[12]), fFar);
	pvWorld[0].y = VERTTYPEMUL((-pmViewProjInv->f[ 1] - pmViewProjInv->f[ 5] + pmViewProjInv->f[ 9] + pmViewProjInv->f[13]), fFar);
	pvWorld[0].z = VERTTYPEMUL((-pmViewProjInv->f[ 2] - pmViewProjInv->f[ 6] + pmViewProjInv->f[10] + pmViewProjInv->f[14]), fFar);
	/* x = 1.0f, y = -1.0f, z = 1.0f; w = 1.0f */
	pvWorld[1].x = VERTTYPEMUL(( pmViewProjInv->f[ 0] - pmViewProjInv->f[ 4] + pmViewProjInv->f[ 8] + pmViewProjInv->f[12]), fFar);
	pvWorld[1].y = VERTTYPEMUL(( pmViewProjInv->f[ 1] - pmViewProjInv->f[ 5] + pmViewProjInv->f[ 9] + pmViewProjInv->f[13]), fFar);
	pvWorld[1].z = VERTTYPEMUL(( pmViewProjInv->f[ 2] - pmViewProjInv->f[ 6] + pmViewProjInv->f[10] + pmViewProjInv->f[14]), fFar);
	/* x = 1.0f, y = 1.0f, z = 1.0f; w = 1.0f */
	pvWorld[2].x = VERTTYPEMUL(( pmViewProjInv->f[ 0] + pmViewProjInv->f[ 4] + pmViewProjInv->f[ 8] + pmViewProjInv->f[12]), fFar);
	pvWorld[2].y = VERTTYPEMUL(( pmViewProjInv->f[ 1] + pmViewProjInv->f[ 5] + pmViewProjInv->f[ 9] + pmViewProjInv->f[13]), fFar);
	pvWorld[2].z = VERTTYPEMUL(( pmViewProjInv->f[ 2] + pmViewProjInv->f[ 6] + pmViewProjInv->f[10] + pmViewProjInv->f[14]), fFar);
	/* x = -1.0f, y = 1.0f, z = 1.0f; w = 1.0f */
	pvWorld[3].x = VERTTYPEMUL((-pmViewProjInv->f[ 0] + pmViewProjInv->f[ 4] + pmViewProjInv->f[ 8] + pmViewProjInv->f[12]), fFar);
	pvWorld[3].y = VERTTYPEMUL((-pmViewProjInv->f[ 1] + pmViewProjInv->f[ 5] + pmViewProjInv->f[ 9] + pmViewProjInv->f[13]), fFar);
	pvWorld[3].z = VERTTYPEMUL((-pmViewProjInv->f[ 2] + pmViewProjInv->f[ 6] + pmViewProjInv->f[10] + pmViewProjInv->f[14]), fFar);

	/* We need to do a closed loop of the screen vertices, so copy the first vertex into the last */
	pvWorld[4] = pvWorld[0];

	/*
	Now build a pre-clipped polygon
	*/

	/* Lets get ready to loop */
	dwCount = 0;
	bClip = false;
	pvPolyPtr = (PVRTVECTOR3*)pfVtx;

	nVert = 5;
	while(nVert)
	{
	nVert--;

	/*
	Check which side of the Plane this corner of the far clipping
	plane is on. [A,B,C] of plane equation is the plane normal, D is
	distance from origin; hence [pvPlane->x * -pvPlane->w,
	pvPlane->y * -pvPlane->w,
	pvPlane->z * -pvPlane->w]
	is a point on the plane
	*/
	fDotProduct =
	VERTTYPEMUL((pvWorld[nVert].x + VERTTYPEMUL(pvPlane->x, pvPlane->w)), pvPlane->x) +
	VERTTYPEMUL((pvWorld[nVert].y + VERTTYPEMUL(pvPlane->y, pvPlane->w)), pvPlane->y) +
	VERTTYPEMUL((pvWorld[nVert].z + VERTTYPEMUL(pvPlane->z, pvPlane->w)), pvPlane->z);

	if(fDotProduct < 0)
	{
	/*
	Behind plane; Vertex does NOT need clipping
	*/
	if(bClip == true)
	{
	/* Clipping finished */
	bClip = false;

	/*
	We've been clipping, so we need to add an additional
	point on the line to this point, where clipping was
	stopped.
	*/
	PVRTMiscCalculateIntersectionLinePlane(pvPolyPtr, &pvPlane->x, &pvWorld[nVert+1], &pvWorld[nVert]);
	pvPolyPtr = (PVRTVECTOR3)((char)pvPolyPtr + nStride);
	dwCount++;
	}

	if(!nVert)
	{
	/* Abort, abort: we've closed the loop with the clipped point */
	break;
	}

	/* Add the current point */
	PVRTMiscCalculateIntersectionLinePlane(pvPolyPtr, &pvPlane->x, pFrom, &pvWorld[nVert]);
	pvPolyPtr = (PVRTVECTOR3)((char)pvPolyPtr + nStride);
	dwCount++;
	}
	else
	{
	/*
	Before plane; Vertex DOES need clipping
	*/
	if(bClip == true)
	{
	/* Already in clipping, skip point */
	continue;
	}

	/* Clipping initiated */
	bClip = true;

	/* Don't bother with entry point on first vertex; will take care of it on last vertex (which is a repeat of first vertex) */
	if(nVert != 4)
	{
	/* We need to add an additional point on the line to this point, where clipping was started */
	PVRTMiscCalculateIntersectionLinePlane(pvPolyPtr, &pvPlane->x, &pvWorld[nVert+1], &pvWorld[nVert]);
	pvPolyPtr = (PVRTVECTOR3)((char)pvPolyPtr + nStride);
	dwCount++;
	}
	}
	}

	/* Valid vertex counts are 0, 3, 4, 5 */
	_ASSERT(dwCount <= 5);
	_ASSERT(dwCount != 1);
	_ASSERT(dwCount != 2);

	return dwCount;
	}


	/!**************************************************************************
	@Function SetVertex
	@Modified Vertices
	@Input index
	@Input x
	@Input y
	@Input z
	@Description Writes a vertex in a vertex array
	*****************************************************************************/
	static void SetVertex(VERTTYPE** Vertices, int index, VERTTYPE x, VERTTYPE y, VERTTYPE z)
	{
	(Vertices)[index3+0] = x;
	(Vertices)[index3+1] = y;
	(Vertices)[index3+2] = z;
	}

	/!**************************************************************************
	@Function SetUV
	@Modified UVs
	@Input index
	@Input u
	@Input v
	@Description Writes a texture coordinate in a texture coordinate array
	*****************************************************************************/
	static void SetUV(VERTTYPE** UVs, int index, VERTTYPE u, VERTTYPE v)
	{
	(UVs)[index2+0] = u;
	(UVs)[index2+1] = v;
	}

	/!**************************************************************************
	@Function PVRTCreateSkybox
	@Input scale Scale the skybox
	@Input adjustUV Adjust or not UVs for PVRT compression
	@Input textureSize Texture size in pixels
	@Output Vertices Array of vertices
	@Output UVs Array of UVs
	@Description Creates the vertices and texture coordinates for a skybox
	*****************************************************************************/
	void PVRTCreateSkybox(float scale, bool adjustUV, int textureSize, VERTTYPE Vertices, VERTTYPE UVs)
	{
	Vertices = new VERTTYPE[243];
	UVs = new VERTTYPE[242];

	VERTTYPE unit = f2vt(1);
	VERTTYPE a0 = 0, a1 = unit;

	if (adjustUV)
	{
	VERTTYPE oneover = f2vt(1.0f / textureSize);
	a0 = VERTTYPEMUL(f2vt(4.0f), oneover);
	a1 = unit - a0;
	}

	// Front
	SetVertex(Vertices, 0, -unit, +unit, -unit);
	SetVertex(Vertices, 1, +unit, +unit, -unit);
	SetVertex(Vertices, 2, -unit, -unit, -unit);
	SetVertex(Vertices, 3, +unit, -unit, -unit);
	SetUV(UVs, 0, a0, a1);
	SetUV(UVs, 1, a1, a1);
	SetUV(UVs, 2, a0, a0);
	SetUV(UVs, 3, a1, a0);

	// Right
	SetVertex(Vertices, 4, +unit, +unit, -unit);
	SetVertex(Vertices, 5, +unit, +unit, +unit);
	SetVertex(Vertices, 6, +unit, -unit, -unit);
	SetVertex(Vertices, 7, +unit, -unit, +unit);
	SetUV(UVs, 4, a0, a1);
	SetUV(UVs, 5, a1, a1);
	SetUV(UVs, 6, a0, a0);
	SetUV(UVs, 7, a1, a0);

	// Back
	SetVertex(Vertices, 8 , +unit, +unit, +unit);
	SetVertex(Vertices, 9 , -unit, +unit, +unit);
	SetVertex(Vertices, 10, +unit, -unit, +unit);
	SetVertex(Vertices, 11, -unit, -unit, +unit);
	SetUV(UVs, 8 , a0, a1);
	SetUV(UVs, 9 , a1, a1);
	SetUV(UVs, 10, a0, a0);
	SetUV(UVs, 11, a1, a0);

	// Left
	SetVertex(Vertices, 12, -unit, +unit, +unit);
	SetVertex(Vertices, 13, -unit, +unit, -unit);
	SetVertex(Vertices, 14, -unit, -unit, +unit);
	SetVertex(Vertices, 15, -unit, -unit, -unit);
	SetUV(UVs, 12, a0, a1);
	SetUV(UVs, 13, a1, a1);
	SetUV(UVs, 14, a0, a0);
	SetUV(UVs, 15, a1, a0);

	// Top
	SetVertex(Vertices, 16, -unit, +unit, +unit);
	SetVertex(Vertices, 17, +unit, +unit, +unit);
	SetVertex(Vertices, 18, -unit, +unit, -unit);
	SetVertex(Vertices, 19, +unit, +unit, -unit);
	SetUV(UVs, 16, a0, a1);
	SetUV(UVs, 17, a1, a1);
	SetUV(UVs, 18, a0, a0);
	SetUV(UVs, 19, a1, a0);

	// Bottom
	SetVertex(Vertices, 20, -unit, -unit, -unit);
	SetVertex(Vertices, 21, +unit, -unit, -unit);
	SetVertex(Vertices, 22, -unit, -unit, +unit);
	SetVertex(Vertices, 23, +unit, -unit, +unit);
	SetUV(UVs, 20, a0, a1);
	SetUV(UVs, 21, a1, a1);
	SetUV(UVs, 22, a0, a0);
	SetUV(UVs, 23, a1, a0);

	for (int i=0; i<243; i++) (Vertices)[i] = VERTTYPEMUL((*Vertices)[i], f2vt(scale));
	}

	/!**************************************************************************
	@Function PVRTDestroySkybox
	@Input Vertices Vertices array to destroy
	@Input UVs UVs array to destroy
	@Description Destroy the memory allocated for a skybox
	*****************************************************************************/
	void PVRTDestroySkybox(VERTTYPE* Vertices, VERTTYPE* UVs)
	{
	delete [] Vertices;
	delete [] UVs;
	}

	/!**************************************************************************
	@Function PVRTGetPOTHigher
	@Input uiOriginalValue Base value
	@Input iTimesHigher Multiplier
	@Description When iTimesHigher is one, this function will return the closest
	power-of-two value above the base value.
	For every increment beyond one for the iTimesHigher value,
	the next highest power-of-two value will be calculated.
	*****************************************************************************/
	unsigned int PVRTGetPOTHigher(unsigned int uiOriginalValue, int iTimesHigher)
	{
	if(uiOriginalValue == 0 \|\| iTimesHigher < 0)
	{
	return 0;
	}

	unsigned int uiSize = 1;
	while (uiSize < uiOriginalValue) uiSize *= 2;

	// Keep increasing the POT value until the iTimesHigher value has been met
	for(int i = 1 ; i < iTimesHigher; ++i)
	{
	uiSize *= 2;
	}

	return uiSize;
	}

	/!**************************************************************************
	@Function PVRTGetPOTLower
	@Input uiOriginalValue Base value
	@Input iTimesLower Multiplier
	@Description When iTimesLower is one, this function will return the closest
	power-of-two value below the base value.
	For every increment beyond one for the iTimesLower value,
	the next lowest power-of-two value will be calculated. The lowest
	value that can be reached is 1.
	*****************************************************************************/
	// NOTE: This function should be optimised
	unsigned int PVRTGetPOTLower(unsigned int uiOriginalValue, int iTimesLower)
	{
	if(uiOriginalValue == 0 \|\| iTimesLower < 0)
	{
	return 0;
	}
	unsigned int uiSize = PVRTGetPOTHigher(uiOriginalValue,1);
	uiSize >>= 1;//uiSize /=2;

	for(int i = 1; i < iTimesLower; ++i)
	{
	uiSize >>= 1;//uiSize /=2;
	if(uiSize == 1)
	{
	// Lowest possible value has been reached, so break
	break;
	}
	}
	return uiSize;
	}



	/*****************************************************************************
	End of file (PVRTMisc.cpp)
	*****************************************************************************/