CWE-ou-minkata/MOULOpenSourceClientPlugin/Plasma20/Sources/Plasma/PubUtilLib/plParticleSystem/plConvexVolume.cpp

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*==LICENSE==*/
#include "hsTypes.h"
#include "hsGeometry3.h"
#include "hsMatrix44.h"
#include "plConvexVolume.h"
#include "hsStream.h"

plConvexVolume::plConvexVolume()
{
	//fFlags = nil;
	fLocalPlanes = nil;
	fWorldPlanes = nil;
	fNumPlanes = 0;
}

plConvexVolume::~plConvexVolume()
{
	IClear();
}

void plConvexVolume::IClear()
{
	//delete [] fFlags;
	delete [] fLocalPlanes;
	delete [] fWorldPlanes;
}

hsBool plConvexVolume::AddPlane(const hsPlane3 &plane)
{
	// First check for a redundant plane (since we're convex, a comparison of normals should do)
	int i;
	// Start the comparison with the most recently added plane, it's most likely to match
	for (i = fNumPlanes - 1; i >= 0; i--)
	{
		const float MIN_COS_THETA = 0.99999f; // translates to < 0.25 degree angle
		// If the angle betwen the normals is close enough, count them as equal.		
		if (fLocalPlanes[i].fN.InnerProduct(plane.fN) >= MIN_COS_THETA)
			return false; // no need to add it
	}
	fNumPlanes++;
	//delete [] fFlags;
	//fFlags = TRACKED_NEW UInt32[fNumPlanes];

	hsPlane3 *tempPlanes = TRACKED_NEW hsPlane3[fNumPlanes];
	for (i = 0; i < fNumPlanes - 1; i++)
	{
		tempPlanes[i] = fLocalPlanes[i];
	}
	tempPlanes[fNumPlanes - 1] = plane;

	delete [] fLocalPlanes;
	fLocalPlanes = tempPlanes;
	delete [] fWorldPlanes;
	fWorldPlanes = TRACKED_NEW hsPlane3[fNumPlanes];
	
	return true;
}

void plConvexVolume::Update(const hsMatrix44 &l2w)
{
	int i;
	hsPoint3 planePt;
	for (i = 0; i < fNumPlanes; i++)
	{
		// Since fN is an hsVector3, it will only apply the rotational aspect of the transform...
		fWorldPlanes[i].fN = l2w * fLocalPlanes[i].fN; 
		planePt.Set(&(fLocalPlanes[i].fN * fLocalPlanes[i].fD));
		fWorldPlanes[i].fD = -(l2w * planePt).InnerProduct(fWorldPlanes[i].fN);
	}
}

void plConvexVolume::SetNumPlanesAndClear(const UInt32 num)
{
	IClear();
	//fFlags = TRACKED_NEW UInt32[num];
	fLocalPlanes = TRACKED_NEW hsPlane3[num];
	fWorldPlanes = TRACKED_NEW hsPlane3[num];
	fNumPlanes = num;
}

void plConvexVolume::SetPlane(const hsPlane3 &plane, const UInt32 index)
{
	fLocalPlanes[index] = plane;
}

hsBool plConvexVolume::IsInside(const hsPoint3 &pos) const
{
	int i;
	for( i = 0; i < fNumPlanes; i++ )
	{
		if (!TestPlane(pos, fWorldPlanes[i]))
			return false;
	}

	return true;
}

hsBool plConvexVolume::ResolvePoint(hsPoint3 &pos) const
{
	hsScalar minDist = 1.e33f;
	Int32 minIndex = -1;

	hsScalar currDist;
	int i;
	for (i = 0; i < fNumPlanes; i++)
	{
		currDist = -fWorldPlanes[i].fD - fWorldPlanes[i].fN.InnerProduct(pos);
		if (currDist < 0)
			return false; // We're not inside this plane, and thus outside the volume

		if (currDist < minDist)
		{
			minDist = currDist;
			minIndex = i;
		}
	}
	pos += (-fWorldPlanes[minIndex].fD - fWorldPlanes[minIndex].fN.InnerProduct(pos)) * fWorldPlanes[minIndex].fN;
	return true;
}

hsBool plConvexVolume::BouncePoint(hsPoint3 &pos, hsVector3 &velocity, hsScalar bounce, hsScalar friction) const
{
	hsScalar minDist = 1.e33f;
	Int32 minIndex = -1;

	hsScalar currDist;
	int i;
	for (i = 0; i < fNumPlanes; i++)
	{
		currDist = -fWorldPlanes[i].fD - fWorldPlanes[i].fN.InnerProduct(pos);
		if (currDist < 0)
			return false; // We're not inside this plane, and thus outside the volume

		if (currDist < minDist)
		{
			minDist = currDist;
			minIndex = i;
		}
	}
	pos += (-fWorldPlanes[minIndex].fD - fWorldPlanes[minIndex].fN.InnerProduct(pos)) * fWorldPlanes[minIndex].fN;
	hsVector3 bnc = -velocity.InnerProduct(fWorldPlanes[minIndex].fN) * fWorldPlanes[minIndex].fN;
	velocity += bnc;
	velocity *= 1.f - friction;
	velocity += bnc * bounce;
//	velocity += (velocity.InnerProduct(fWorldPlanes[minIndex].fN) * -(1.f + bounce)) * fWorldPlanes[minIndex].fN;
	return true;
}

void plConvexVolume::Read(hsStream* s, hsResMgr *mgr)
{
	SetNumPlanesAndClear(s->ReadSwap32());
	int i;
	for (i = 0; i < fNumPlanes; i++)
	{
		fLocalPlanes[i].Read(s);
		//fFlags[i] = s->ReadSwap32();
	}
}

void plConvexVolume::Write(hsStream* s, hsResMgr *mgr)
{
	s->WriteSwap32(fNumPlanes);
	int i;
	for (i = 0; i < fNumPlanes; i++)
	{
		fLocalPlanes[i].Write(s);
		//s->WriteSwap32(fFlags[i]);
	}
}