CWE-ou-minkata/Sources/Plasma/PubUtilLib/plDrawable/plCutter.cpp

/*==LICENSE==*

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*==LICENSE==*/

#include "hsTypes.h"
#include "plCutter.h"
#include "plAccessSpan.h"
#include "hsFastMath.h"
#include "plAccessGeometry.h"

#include "hsStream.h"

// Test hack
#include "plDrawableSpans.h"
#include "plDrawableGenerator.h"
#include "../pnSceneObject/plSceneObject.h"
#include "../pnSceneObject/plDrawInterface.h"
#include "../plScene/plSceneNode.h"
#include "../plScene/plPageTreeMgr.h"
#include "../plSurface/hsGMaterial.h"
#include "../plSurface/plLayerInterface.h"

void plCutter::Read(hsStream* stream, hsResMgr* mgr)
{
	plCreatable::Read(stream, mgr);

	fLengthU = stream->ReadSwapScalar();
	fLengthV = stream->ReadSwapScalar();
	fLengthW = stream->ReadSwapScalar();
}

void plCutter::Write(hsStream* stream, hsResMgr* mgr)
{
	plCreatable::Write(stream, mgr);

	stream->WriteSwapScalar(fLengthU);
	stream->WriteSwapScalar(fLengthV);
	stream->WriteSwapScalar(fLengthW);
}


void plCutter::Set(const hsPoint3& pos, const hsVector3& dir, const hsVector3& out, hsBool flip)
{
	hsVector3 du = dir % out;
	hsVector3 dv = out % du;
	hsVector3 dw = out;

	hsFastMath::NormalizeAppr(du);
	hsFastMath::NormalizeAppr(dv);
	hsFastMath::NormalizeAppr(dw);

	fBackDir = dw;

	if( flip )
		du = -du;

	fDirU = du / fLengthU;
	fDirV = dv / -fLengthV;
	fDirW = dw / fLengthW;

	du *= fLengthU * 0.5f;
	dv *= fLengthV * 0.5f;
	dw *= fLengthW * 0.5f;

	hsPoint3 corner = pos;
	corner += -du;
	corner += dv;
	corner += -dw;

	fDistU = corner.InnerProduct(fDirU);
	fDistV = corner.InnerProduct(fDirV);
	fDistW = corner.InnerProduct(fDirW);

	hsMatrix44 l2w;
	l2w.NotIdentity();
	int i;
	for( i = 0; i < 3; i++ )
	{
		l2w.fMap[i][0] = du[i];
		l2w.fMap[i][1] = dv[i];
		l2w.fMap[i][2] = dw[i];
		l2w.fMap[i][3] = pos[i];
	}
	l2w.fMap[3][0] = l2w.fMap[3][1] = l2w.fMap[3][2] = 0;
	l2w.fMap[3][3] = 1.f;


	hsPoint3 p;
	p.Set(1.f, 1.f, 1.f);
	fWorldBounds.Reset(&p);
	p.Set(-1.f, -1.f, -1.f);
	fWorldBounds.Union(&p);
	fWorldBounds.Transform(&l2w);

	fIsect.SetBounds(fWorldBounds);
}


inline void plCutter::ISetPosNorm(hsScalar parm, const plCutoutVtx& inVtx, const plCutoutVtx& outVtx, plCutoutVtx& dst) const
{
	dst.fPos = outVtx.fPos;
	dst.fPos += parm * (inVtx.fPos - outVtx.fPos);

	dst.fNorm = outVtx.fNorm;
	dst.fNorm += parm * (inVtx.fNorm - outVtx.fNorm);

	dst.fColor = outVtx.fColor;
	dst.fColor += parm * (inVtx.fColor - outVtx.fColor);
}

// A note on where the interpolation parameter is coming from.
// 
// For the lower cases, we're looking for the point where Dot(pos, fDir) - fDist = 0.
// Starting with p = outVtx + parm * (inVtx - outVtx) and Dot(p, fDir) == fDist, we get:
// parm = (fDist - Dot(fDir,outVtx.fPos)) / (Dot(fDir, invVtx.fPos) - Dot(fDir, outVtx.fPos))
//
// UVW = Dot(fDir, fPos) - fDist
// Dot(fDir, fPos) = UVW + fDist
// So:
// parm = (fDist - (outVtx.fUVW - fDist)) / ((invVtx.fUVW - fDist) - (outVtx.fUVW - fDist))
//		= -outVtx.fUVW / (inVtx.fUVW - outVtx.fUVW)
//		= outVtx.fUVW / (outVtx.fUVW - inVtx.fUVW)

inline void plCutter::ICutoutVtxLoU(const plCutoutVtx& inVtx, const plCutoutVtx& outVtx, plCutoutVtx& dst) const
{
	hsScalar parm = outVtx.fUVW.fX / (outVtx.fUVW.fX - inVtx.fUVW.fX);

	ISetPosNorm(parm, inVtx, outVtx, dst);

	dst.fUVW.fX = 0;
	dst.fUVW.fY = outVtx.fUVW.fY + parm * (inVtx.fUVW.fY - outVtx.fUVW.fY);
	dst.fUVW.fZ = outVtx.fUVW.fZ + parm * (inVtx.fUVW.fZ - outVtx.fUVW.fZ);
}

inline void plCutter::ICutoutVtxLoV(const plCutoutVtx& inVtx, const plCutoutVtx& outVtx, plCutoutVtx& dst) const
{
	hsScalar parm = outVtx.fUVW.fY / (outVtx.fUVW.fY - inVtx.fUVW.fY);

	ISetPosNorm(parm, inVtx, outVtx, dst);

	dst.fUVW.fX = outVtx.fUVW.fX + parm * (inVtx.fUVW.fX - outVtx.fUVW.fX);
	dst.fUVW.fY = 0;
	dst.fUVW.fZ = outVtx.fUVW.fZ + parm * (inVtx.fUVW.fZ - outVtx.fUVW.fZ);
}

inline void plCutter::ICutoutVtxLoW(const plCutoutVtx& inVtx, const plCutoutVtx& outVtx, plCutoutVtx& dst) const
{
	hsScalar parm = outVtx.fUVW.fZ / (outVtx.fUVW.fZ - inVtx.fUVW.fZ);

	ISetPosNorm(parm, inVtx, outVtx, dst);

	dst.fUVW.fX = outVtx.fUVW.fX + parm * (inVtx.fUVW.fX - outVtx.fUVW.fX);
	dst.fUVW.fY = outVtx.fUVW.fY + parm * (inVtx.fUVW.fY - outVtx.fUVW.fY);
	dst.fUVW.fZ = 0;
}

// Now for the upper cases, we start with Dot(pos, fDir) - fDist = 1.f
// So parm = (fDist + 1.f - Dot(fDir, outVtx.fPos) / (Dot(fDir, invVtx.fPos) - Dot(fDir, outVtx.fPos))
// and doing the same substitution gets
// parm = (outVtx.fUVW - 1.f) / (outVtx.fUVW - inVtx.fUVW)
inline void plCutter::ICutoutVtxHiU(const plCutoutVtx& inVtx, const plCutoutVtx& outVtx, plCutoutVtx& dst) const
{
	hsScalar parm = (outVtx.fUVW.fX - 1.f) / (outVtx.fUVW.fX - inVtx.fUVW.fX);

	ISetPosNorm(parm, inVtx, outVtx, dst);

	dst.fUVW.fX = 1.f;
	dst.fUVW.fY = outVtx.fUVW.fY + parm * (inVtx.fUVW.fY - outVtx.fUVW.fY);
	dst.fUVW.fZ = outVtx.fUVW.fZ + parm * (inVtx.fUVW.fZ - outVtx.fUVW.fZ);
}

inline void plCutter::ICutoutVtxHiV(const plCutoutVtx& inVtx, const plCutoutVtx& outVtx, plCutoutVtx& dst) const
{
	hsScalar parm = (outVtx.fUVW.fY - 1.f) / (outVtx.fUVW.fY - inVtx.fUVW.fY);

	ISetPosNorm(parm, inVtx, outVtx, dst);

	dst.fUVW.fX = outVtx.fUVW.fX + parm * (inVtx.fUVW.fX - outVtx.fUVW.fX);
	dst.fUVW.fY = 1.f;
	dst.fUVW.fZ = outVtx.fUVW.fZ + parm * (inVtx.fUVW.fZ - outVtx.fUVW.fZ);
}

inline void plCutter::ICutoutVtxHiW(const plCutoutVtx& inVtx, const plCutoutVtx& outVtx, plCutoutVtx& dst) const
{
	hsScalar parm = (outVtx.fUVW.fZ - 1.f) / (outVtx.fUVW.fZ - inVtx.fUVW.fZ);

	ISetPosNorm(parm, inVtx, outVtx, dst);

	dst.fUVW.fX = outVtx.fUVW.fX + parm * (inVtx.fUVW.fX - outVtx.fUVW.fX);
	dst.fUVW.fY = outVtx.fUVW.fY + parm * (inVtx.fUVW.fY - outVtx.fUVW.fY);
	dst.fUVW.fZ = 1.f;
}


// Now for the split down the middle cases, we start with Dot(pos, fDir) - fDist = 0.5f
// So parm = (fDist + 0.5f - Dot(fDir, outVtx.fPos) / (Dot(fDir, invVtx.fPos) - Dot(fDir, outVtx.fPos))
// and doing the same substitution gets
// parm = (outVtx.fUVW - 0.5f) / (outVtx.fUVW - inVtx.fUVW)
inline void plCutter::ICutoutVtxMidU(const plCutoutVtx& inVtx, const plCutoutVtx& outVtx, plCutoutVtx& dst) const
{
	hsScalar parm = (outVtx.fUVW.fX - 0.5f) / (outVtx.fUVW.fX - inVtx.fUVW.fX);

	ISetPosNorm(parm, inVtx, outVtx, dst);

	dst.fUVW.fX = outVtx.fUVW.fX + parm * (inVtx.fUVW.fX - outVtx.fUVW.fX); // TEST

	dst.fUVW.fX = 0.5f;
	dst.fUVW.fY = outVtx.fUVW.fY + parm * (inVtx.fUVW.fY - outVtx.fUVW.fY);
	dst.fUVW.fZ = outVtx.fUVW.fZ + parm * (inVtx.fUVW.fZ - outVtx.fUVW.fZ);
}

inline void plCutter::ICutoutVtxMidV(const plCutoutVtx& inVtx, const plCutoutVtx& outVtx, plCutoutVtx& dst) const
{
	hsScalar parm = (outVtx.fUVW.fY - 0.5f) / (outVtx.fUVW.fY - inVtx.fUVW.fY);

	ISetPosNorm(parm, inVtx, outVtx, dst);

	dst.fUVW.fY = outVtx.fUVW.fY + parm * (inVtx.fUVW.fY - outVtx.fUVW.fY); // TEST

	dst.fUVW.fX = outVtx.fUVW.fX + parm * (inVtx.fUVW.fX - outVtx.fUVW.fX);
	dst.fUVW.fY = 0.5f;
	dst.fUVW.fZ = outVtx.fUVW.fZ + parm * (inVtx.fUVW.fZ - outVtx.fUVW.fZ);
}

inline void plCutter::ICutoutVtxMidW(const plCutoutVtx& inVtx, const plCutoutVtx& outVtx, plCutoutVtx& dst) const
{
	hsScalar parm = (outVtx.fUVW.fZ - 0.5f) / (outVtx.fUVW.fZ - inVtx.fUVW.fZ);

	ISetPosNorm(parm, inVtx, outVtx, dst);

	dst.fUVW.fZ = outVtx.fUVW.fZ + parm * (inVtx.fUVW.fZ - outVtx.fUVW.fZ); // TEST

	dst.fUVW.fX = outVtx.fUVW.fX + parm * (inVtx.fUVW.fX - outVtx.fUVW.fX);
	dst.fUVW.fY = outVtx.fUVW.fY + parm * (inVtx.fUVW.fY - outVtx.fUVW.fY);
	dst.fUVW.fZ = 0.5f;
}

// IPolyClip
hsBool plCutter::IPolyClip(hsTArray<plCutoutVtx>& poly, const hsPoint3 vPos[]) const
{
	static hsTArray<plCutoutVtx> accum;
	accum.SetCount(0);

	poly[0].fUVW.fX = vPos[0].InnerProduct(fDirU) - fDistU;
	poly[0].fUVW.fY = vPos[0].InnerProduct(fDirV) - fDistV;
	poly[0].fUVW.fZ = vPos[0].InnerProduct(fDirW) - fDistW;

	poly[1].fUVW.fX = vPos[1].InnerProduct(fDirU) - fDistU;
	poly[1].fUVW.fY = vPos[1].InnerProduct(fDirV) - fDistV;
	poly[1].fUVW.fZ = vPos[1].InnerProduct(fDirW) - fDistW;

	poly[2].fUVW.fX = vPos[2].InnerProduct(fDirU) - fDistU;
	poly[2].fUVW.fY = vPos[2].InnerProduct(fDirV) - fDistV;
	poly[2].fUVW.fZ = vPos[2].InnerProduct(fDirW) - fDistW;

	// Try an early out test.
	int i;
	for( i = 0; i < 3; i++ )
	{
		int lo = 1;
		int hi = 1;
		int j;
		for( j = 0; j < 3; j++ )
		{
			lo &= poly[j].fUVW[i] <= 0;
			hi &= poly[j].fUVW[i] >= 1.f;
		}
		if( lo || hi )
		{
			poly.SetCount(0);
			return false;
		}
	}


	// First trim to lower bounds.
	for( i = 0; i < poly.GetCount(); i++ )
	{
		int j = i ? i-1 : poly.GetCount()-1;

		int test = ((poly[i].fUVW.fX < 0) << 1) | (poly[j].fUVW.fX < 0);
		switch(test)
		{
		case 0:
			// Both in
			// Add this vert to outList
			accum.Append(poly[i]);
			break;
		case 1:
			// This in, last out
			// Add ClipVert(j, j-1) to outList
			// Add this vert to outList
			accum.Push();
			ICutoutVtxLoU(poly[i], poly[j], accum[accum.GetCount()-1]);
			accum.Append(poly[i]);
			break;
		case 2:
			// This out, last in
			// Add ClipVert(j-1, j) to outList
			accum.Push();
			ICutoutVtxLoU(poly[j], poly[i], accum[accum.GetCount()-1]);
			break;
		case 3:
			// Both out
			break;
		}
	}
	poly.Swap(accum);
	accum.SetCount(0);

	for( i = 0; i < poly.GetCount(); i++ )
	{
		int j = i ? i-1 : poly.GetCount()-1;

		int test = ((poly[i].fUVW.fY < 0) << 1) | (poly[j].fUVW.fY < 0);
		switch(test)
		{
		case 0:
			// Both in
			// Add this vert to outList
			accum.Append(poly[i]);
			break;
		case 1:
			// This in, last out
			// Add ClipVert(j, j-1) to outList
			// Add this vert to outList
			accum.Push();
			ICutoutVtxLoV(poly[i], poly[j], accum[accum.GetCount()-1]);
			accum.Append(poly[i]);
			break;
		case 2:
			// This out, last in
			// Add ClipVert(j-1, j) to outList
			accum.Push();
			ICutoutVtxLoV(poly[j], poly[i], accum[accum.GetCount()-1]);
			break;
		case 3:
			// Both out
			break;
		}
	}
	poly.Swap(accum);
	accum.SetCount(0);

	for( i = 0; i < poly.GetCount(); i++ )
	{
		int j = i ? i-1 : poly.GetCount()-1;

		int test = ((poly[i].fUVW.fZ < 0) << 1) | (poly[j].fUVW.fZ < 0);
		switch(test)
		{
		case 0:
			// Both in
			// Add this vert to outList
			accum.Append(poly[i]);
			break;
		case 1:
			// This in, last out
			// Add ClipVert(j, j-1) to outList
			// Add this vert to outList
			accum.Push();
			ICutoutVtxLoW(poly[i], poly[j], accum[accum.GetCount()-1]);
			accum.Append(poly[i]);
			break;
		case 2:
			// This out, last in
			// Add ClipVert(j-1, j) to outList
			accum.Push();
			ICutoutVtxLoW(poly[j], poly[i], accum[accum.GetCount()-1]);
			break;
		case 3:
			// Both out
			break;
		}
	}
	poly.Swap(accum);
	accum.SetCount(0);

	// Now upper bounds
	for( i = 0; i < poly.GetCount(); i++ )
	{
		int j = i ? i-1 : poly.GetCount()-1;

		int test = ((poly[i].fUVW.fX > 1.f) << 1) | (poly[j].fUVW.fX > 1.f);
		switch(test)
		{
		case 0:
			// Both in
			// Add this vert to outList
			accum.Append(poly[i]);
			break;
		case 1:
			// This in, last out
			// Add ClipVert(j, j-1) to outList
			// Add this vert to outList
			accum.Push();
			ICutoutVtxHiU(poly[i], poly[j], accum[accum.GetCount()-1]);
			accum.Append(poly[i]);
			break;
		case 2:
			// This out, last in
			// Add ClipVert(j-1, j) to outList
			accum.Push();
			ICutoutVtxHiU(poly[j], poly[i], accum[accum.GetCount()-1]);
			break;
		case 3:
			// Both out
			break;
		}
	}
	poly.Swap(accum);
	accum.SetCount(0);

	for( i = 0; i < poly.GetCount(); i++ )
	{
		int j = i ? i-1 : poly.GetCount()-1;

		int test = ((poly[i].fUVW.fY > 1.f) << 1) | (poly[j].fUVW.fY > 1.f);
		switch(test)
		{
		case 0:
			// Both in
			// Add this vert to outList
			accum.Append(poly[i]);
			break;
		case 1:
			// This in, last out
			// Add ClipVert(j, j-1) to outList
			// Add this vert to outList
			accum.Push();
			ICutoutVtxHiV(poly[i], poly[j], accum[accum.GetCount()-1]);
			accum.Append(poly[i]);
			break;
		case 2:
			// This out, last in
			// Add ClipVert(j-1, j) to outList
			accum.Push();
			ICutoutVtxHiV(poly[j], poly[i], accum[accum.GetCount()-1]);
			break;
		case 3:
			// Both out
			break;
		}
	}
	poly.Swap(accum);
	accum.SetCount(0);

	for( i = 0; i < poly.GetCount(); i++ )
	{
		int j = i ? i-1 : poly.GetCount()-1;

		int test = ((poly[i].fUVW.fZ > 1.f) << 1) | (poly[j].fUVW.fZ > 1.f);
		switch(test)
		{
		case 0:
			// Both in
			// Add this vert to outList
			accum.Append(poly[i]);
			break;
		case 1:
			// This in, last out
			// Add ClipVert(j, j-1) to outList
			// Add this vert to outList
			accum.Push();
			ICutoutVtxHiW(poly[i], poly[j], accum[accum.GetCount()-1]);
			accum.Append(poly[i]);
			break;
		case 2:
			// This out, last in
			// Add ClipVert(j-1, j) to outList
			accum.Push();
			ICutoutVtxHiW(poly[j], poly[i], accum[accum.GetCount()-1]);
			break;
		case 3:
			// Both out
			break;
		}
	}
	poly.Swap(accum);
	accum.SetCount(0);

	return poly.GetCount() > 2;
}

// IPolyClip
hsBool plCutter::IFindHitPoint(const hsTArray<plCutoutVtx>& inPoly, plCutoutHit& hit) const
{
	static hsTArray<plCutoutVtx> accum;
	static hsTArray<plCutoutVtx> poly;
	accum.SetCount(0);

	poly = inPoly;

	// First trim to lower bounds.
	int i;
	for( i = 0; i < poly.GetCount(); i++ )
	{
		int j = i ? i-1 : poly.GetCount()-1;

		int test = ((poly[i].fUVW.fX < 0.5f) << 1) | (poly[j].fUVW.fX < 0.5f);
		switch(test)
		{
		case 0:
			// Both in
			// Add this vert to outList
			accum.Append(poly[i]);
			break;
		case 1:
			// This in, last out
			// Add ClipVert(j, j-1) to outList
			// Add this vert to outList
			accum.Push();
			ICutoutVtxMidU(poly[i], poly[j], accum[accum.GetCount()-1]);
			accum.Append(poly[i]);
			break;
		case 2:
			// This out, last in
			// Add ClipVert(j-1, j) to outList
			accum.Push();
			ICutoutVtxMidU(poly[j], poly[i], accum[accum.GetCount()-1]);
			break;
		case 3:
			// Both out
			break;
		}
	}
	poly.Swap(accum);
	accum.SetCount(0);

	for( i = 0; i < poly.GetCount(); i++ )
	{
		int j = i ? i-1 : poly.GetCount()-1;

		int test = ((poly[i].fUVW.fY < 0.5f) << 1) | (poly[j].fUVW.fY < 0.5f);
		switch(test)
		{
		case 0:
			// Both in
			// Add this vert to outList
			accum.Append(poly[i]);
			break;
		case 1:
			// This in, last out
			// Add ClipVert(j, j-1) to outList
			// Add this vert to outList
			accum.Push();
			ICutoutVtxMidV(poly[i], poly[j], accum[accum.GetCount()-1]);
			accum.Append(poly[i]);
			break;
		case 2:
			// This out, last in
			// Add ClipVert(j-1, j) to outList
			accum.Push();
			ICutoutVtxMidV(poly[j], poly[i], accum[accum.GetCount()-1]);
			break;
		case 3:
			// Both out
			break;
		}
	}
	poly.Swap(accum);
	accum.SetCount(0);

	// Now upper bounds
	for( i = 0; i < poly.GetCount(); i++ )
	{
		int j = i ? i-1 : poly.GetCount()-1;

		int test = ((poly[i].fUVW.fX > 0.5f) << 1) | (poly[j].fUVW.fX > 0.5f);
		switch(test)
		{
		case 0:
			// Both in
			// Add this vert to outList
			accum.Append(poly[i]);
			break;
		case 1:
			// This in, last out
			// Add ClipVert(j, j-1) to outList
			// Add this vert to outList
			accum.Push();
			ICutoutVtxMidU(poly[i], poly[j], accum[accum.GetCount()-1]);
			accum.Append(poly[i]);
			break;
		case 2:
			// This out, last in
			// Add ClipVert(j-1, j) to outList
			accum.Push();
			ICutoutVtxMidU(poly[j], poly[i], accum[accum.GetCount()-1]);
			break;
		case 3:
			// Both out
			break;
		}
	}
	poly.Swap(accum);
	accum.SetCount(0);

	for( i = 0; i < poly.GetCount(); i++ )
	{
		int j = i ? i-1 : poly.GetCount()-1;

		int test = ((poly[i].fUVW.fY > 0.5f) << 1) | (poly[j].fUVW.fY > 0.5f);
		switch(test)
		{
		case 0:
			// Both in
			// Add this vert to outList
			accum.Append(poly[i]);
			break;
		case 1:
			// This in, last out
			// Add ClipVert(j, j-1) to outList
			// Add this vert to outList
			accum.Push();
			ICutoutVtxMidV(poly[i], poly[j], accum[accum.GetCount()-1]);
			accum.Append(poly[i]);
			break;
		case 2:
			// This out, last in
			// Add ClipVert(j-1, j) to outList
			accum.Push();
			ICutoutVtxMidV(poly[j], poly[i], accum[accum.GetCount()-1]);
			break;
		case 3:
			// Both out
			break;
		}
	}

	// At this point, if we hit, all verts should be identical, interpolated
	// into the center of the cutter.
	// No verts means no hit.
	if( !accum.GetCount() )
		return false;

	if( accum[0].fNorm.InnerProduct(fDirW) < 0 )
		return false;

	hit.fPos = accum[0].fPos;
	hit.fNorm = accum[0].fNorm;

	return true;
}


hsBool plCutter::FindHitPoints(const hsTArray<plCutoutPoly>& src, hsTArray<plCutoutHit>& hits) const
{
	hits.SetCount(0);

	int iPoly;
	for( iPoly = 0; iPoly < src.GetCount(); iPoly++ )
	{
		hsBool loU = false;
		hsBool hiU = false;
		hsBool loV = false;
		hsBool hiV = false;

		const plCutoutPoly& poly = src[iPoly];
		int iv;
		for( iv = 0; iv < poly.fVerts.GetCount(); iv++ )
		{
			const hsPoint3& uvw = poly.fVerts[iv].fUVW;
			if( uvw.fX < 0.5f )
				loU = true;
			else
				hiU = true;
			if( uvw.fY < 0.5f )
				loV = true;
			else
				hiV = true;

			if( loU && hiU && loV && hiV )
			{
				plCutoutHit hit;
				if( IFindHitPoint(poly.fVerts, hit) )
					hits.Append(hit);
				break;
			}
		}
	}

	return hits.GetCount() > 0;
}

hsBool plCutter::FindHitPointsConstHeight(const hsTArray<plCutoutPoly>& src, hsTArray<plCutoutHit>& hits, hsScalar height) const
{
	if( FindHitPoints(src, hits) )
	{
		int i;
		for( i = 0; i < hits.GetCount(); i++ )
			hits[i].fPos.fZ = height;
		
		return true;
	}

	return false;
}

void plCutter::ICutoutTransformedConstHeight(plAccessSpan& src, hsTArray<plCutoutPoly>& dst) const
{
	const hsMatrix44& l2w = src.GetLocalToWorld();
	hsMatrix44 l2wNorm;
	src.GetWorldToLocal().GetTranspose(&l2wNorm);

	hsBool baseHasAlpha = 0 != (src.GetMaterial()->GetLayer(0)->GetBlendFlags() & hsGMatState::kBlendAlpha);

	plAccTriIterator tri(&src.AccessTri());
	// For each tri
	for( tri.Begin(); tri.More(); tri.Advance() )
	{
		// Do a polygon clip of tri to box
		static hsTArray<plCutoutVtx> poly;
		poly.SetCount(3);

		// Not sure about this, whether the constant water height should be world space or local.
		// We'll leave it in local for now.
		const hsVector3 up(0, 0, 1.f);
		hsPoint3 vPos[3];
		vPos[0] = l2w * hsPoint3(tri.Position(0).fX, tri.Position(0).fY, src.GetWaterHeight());
		vPos[1] = l2w * hsPoint3(tri.Position(1).fX, tri.Position(1).fY, src.GetWaterHeight());
		vPos[2] = l2w * hsPoint3(tri.Position(2).fX, tri.Position(2).fY, src.GetWaterHeight());

		poly[0].Init(l2w * hsPoint3(tri.Position(0).fX, tri.Position(0).fY, tri.Position(0).fZ), l2wNorm * up, tri.DiffuseRGBA(0));
		poly[1].Init(l2w * hsPoint3(tri.Position(1).fX, tri.Position(1).fY, tri.Position(1).fZ), l2wNorm * up, tri.DiffuseRGBA(1));
		poly[2].Init(l2w * hsPoint3(tri.Position(2).fX, tri.Position(2).fY, tri.Position(2).fZ), l2wNorm * up, tri.DiffuseRGBA(2));

		// If we got a polygon
		if( IPolyClip(poly, vPos) )
		{
			// tessalate the polygon into dst
			IConstruct(dst, poly, baseHasAlpha);
		}
	}
}

// We usually don't need to do any transform, because the kind of surface you
// would leave prints on tends to be static, with the transform folded into the
// verts. So it's worth having 2 separate versions of the function.
void plCutter::ICutoutTransformed(plAccessSpan& src, hsTArray<plCutoutPoly>& dst) const
{
	const hsMatrix44& l2w = src.GetLocalToWorld();
	hsMatrix44 l2wNorm;
	src.GetWorldToLocal().GetTranspose(&l2wNorm);

	hsBool baseHasAlpha = 0 != (src.GetMaterial()->GetLayer(0)->GetBlendFlags() & hsGMatState::kBlendAlpha);

	plAccTriIterator tri(&src.AccessTri());
	// For each tri
	for( tri.Begin(); tri.More(); tri.Advance() )
	{
		// Do a polygon clip of tri to box
		static hsTArray<plCutoutVtx> poly;
		poly.SetCount(3);

		hsPoint3 vPos[3];
		vPos[0] = l2w * tri.Position(0);
		vPos[1] = l2w * tri.Position(1);
		vPos[2] = l2w * tri.Position(2);

		poly[0].Init(vPos[0], l2wNorm * tri.Normal(0), tri.DiffuseRGBA(0));
		poly[1].Init(vPos[1], l2wNorm * tri.Normal(1), tri.DiffuseRGBA(1));
		poly[2].Init(vPos[2], l2wNorm * tri.Normal(2), tri.DiffuseRGBA(2));

		// If we got a polygon
		if( IPolyClip(poly, vPos) )
		{
			// tessalate the polygon into dst
			IConstruct(dst, poly, baseHasAlpha);
		}
	}
}

void plCutter::ICutoutConstHeight(plAccessSpan& src, hsTArray<plCutoutPoly>& dst) const
{
	if( !(src.GetLocalToWorld().fFlags & hsMatrix44::kIsIdent) )
	{
		ICutoutTransformedConstHeight(src, dst);
		return;
	}

	hsBool baseHasAlpha = 0 != (src.GetMaterial()->GetLayer(0)->GetBlendFlags() & hsGMatState::kBlendAlpha);

	plAccTriIterator tri(&src.AccessTri());
	// For each tri
	for( tri.Begin(); tri.More(); tri.Advance() )
	{
		// Do a polygon clip of tri to box
		static hsTArray<plCutoutVtx> poly;
		poly.SetCount(3);

		const hsVector3 up(0, 0, 1.f);

		hsPoint3 vPos[3];
		vPos[0].Set(tri.Position(0).fX, tri.Position(0).fY, src.GetWaterHeight());
		vPos[1].Set(tri.Position(1).fX, tri.Position(1).fY, src.GetWaterHeight());
		vPos[2].Set(tri.Position(2).fX, tri.Position(2).fY, src.GetWaterHeight());

		poly[0].Init(hsPoint3(tri.Position(0).fX, tri.Position(0).fY, tri.Position(0).fZ), up, tri.DiffuseRGBA(0));
		poly[1].Init(hsPoint3(tri.Position(1).fX, tri.Position(1).fY, tri.Position(1).fZ), up, tri.DiffuseRGBA(1));
		poly[2].Init(hsPoint3(tri.Position(2).fX, tri.Position(2).fY, tri.Position(2).fZ), up, tri.DiffuseRGBA(2));

		// If we got a polygon
		if( IPolyClip(poly, vPos) )
		{
			// tessalate the polygon into dst
			IConstruct(dst, poly, baseHasAlpha);
		}
	}
}

// Cutout
void plCutter::Cutout(plAccessSpan& src, hsTArray<plCutoutPoly>& dst) const
{
	if( !src.HasAccessTri() )
		return;

	if( src.HasWaterHeight() )
	{
		ICutoutConstHeight(src, dst);
		return;
	}

	if( !(src.GetLocalToWorld().fFlags & hsMatrix44::kIsIdent) )
	{
		ICutoutTransformed(src, dst);
		return;
	}

	hsBool baseHasAlpha = 0 != (src.GetMaterial()->GetLayer(0)->GetBlendFlags() & hsGMatState::kBlendAlpha);

	plAccTriIterator tri(&src.AccessTri());
	// For each tri
	for( tri.Begin(); tri.More(); tri.Advance() )
	{
		// Do a polygon clip of tri to box
		static hsTArray<plCutoutVtx> poly;
		poly.SetCount(3);

		hsPoint3 vPos[3];
		vPos[0] = tri.Position(0);
		vPos[1] = tri.Position(1);
		vPos[2] = tri.Position(2);

		poly[0].Init(vPos[0], tri.Normal(0), tri.DiffuseRGBA(0));
		poly[1].Init(vPos[1], tri.Normal(1), tri.DiffuseRGBA(1));
		poly[2].Init(vPos[2], tri.Normal(2), tri.DiffuseRGBA(2));

		// If we got a polygon
		if( IPolyClip(poly, vPos) )
		{
			// tessalate the polygon into dst
			IConstruct(dst, poly, baseHasAlpha);
		}
	}
}

void plCutter::IConstruct(hsTArray<plCutoutPoly>& dst, hsTArray<plCutoutVtx>& poly, hsBool baseHasAlpha) const
{
	int iDst = dst.GetCount();
	dst.Push();
	dst[iDst].fVerts.Swap(poly);
	dst[iDst].fBaseHasAlpha = baseHasAlpha;
}

/////////////////////////////////////////////////////////////////////////////////////////////////////

hsBool plCutter::CutoutGrid(int nWid, int nLen, plFlatGridMesh& grid) const
{
	hsVector3 halfU = fDirU * (fLengthU * fLengthU * 0.5f);
	hsVector3 halfV = fDirV * (fLengthV * fLengthV * 0.5f);
	return MakeGrid(nWid, nLen, fWorldBounds.GetCenter(), halfU, halfV, grid);
}

hsBool plCutter::MakeGrid(int nWid, int nLen, const hsPoint3& center, const hsVector3& halfU, const hsVector3& halfV, plFlatGridMesh& grid)
{
	if( nWid < 3 )
		nWid = 3;
	if( !(nWid & 0x1) )
		nWid++;
	if( nLen < 3 )
		nLen = 3;
	if( !(nLen & 0x1) )
		nLen++;

	grid.fVerts.SetCount(nWid * nLen);

	hsVector3 dux = halfU;
	hsVector3 dvx = halfV;
	dux.fZ = 0;
	dvx.fZ = 0;

	hsPoint3 corner = center;
	corner.fZ = 0;
	corner += -dux;
	corner += -dvx;

	hsScalar sWid = 1.f / hsScalar(nWid-1);
	hsScalar sLen = 1.f / hsScalar(nLen-1);

	dux *= 2.f * sWid;
	dvx *= 2.f * sLen;

	hsScalar du = sWid;
	hsScalar dv = sLen;
	int j;
	for( j = 0; j < nLen; j++ )
	{
		int i;
		for( i = 0; i < nWid; i++ )
		{
			plCutoutMiniVtx& vtx = grid.fVerts[j * nWid + i];

			vtx.fPos = corner;
			vtx.fPos += dux * (hsScalar)i;
			vtx.fPos += dvx * (hsScalar)j;

			vtx.fUVW.fX = du * i;
			vtx.fUVW.fY = dv * j;
			vtx.fUVW.fZ = 0.5f;
		}
	}

	int idx = 0;
	grid.fIdx.SetCount(2 * (nWid-1) * (nLen-1) * 3);
	for( j = 1; j < nLen; )
	{
		int i;
		for( i = 1; i < nWid; )
		{
			grid.fIdx[idx++] =  j    * nWid + (i-1);
			grid.fIdx[idx++] =  j    * nWid + i;
			grid.fIdx[idx++] = (j-1) * nWid + (i-1);

			grid.fIdx[idx++] = (j-1) * nWid + (i-1);
			grid.fIdx[idx++] =  j    * nWid + i;
			grid.fIdx[idx++] = (j-1) * nWid + i;

			i++;

			grid.fIdx[idx++] = (j-1) * nWid + (i-1);
			grid.fIdx[idx++] =  j    * nWid + (i-1);
			grid.fIdx[idx++] = (j-1) * nWid + i;

			grid.fIdx[idx++] = (j-1) * nWid + i;
			grid.fIdx[idx++] =  j    * nWid + (i-1);
			grid.fIdx[idx++] =  j    * nWid + i;

			i++;
		}

		j++;

		for( i = 1; i < nWid; )
		{
			grid.fIdx[idx++] = (j-1) * nWid + (i-1);
			grid.fIdx[idx++] =  j    * nWid + (i-1);
			grid.fIdx[idx++] = (j-1) * nWid + i;

			grid.fIdx[idx++] = (j-1) * nWid + i;
			grid.fIdx[idx++] =  j    * nWid + (i-1);
			grid.fIdx[idx++] =  j    * nWid + i;

			i++;

			grid.fIdx[idx++] =  j    * nWid + (i-1);
			grid.fIdx[idx++] =  j    * nWid + i;
			grid.fIdx[idx++] = (j-1) * nWid + (i-1);

			grid.fIdx[idx++] = (j-1) * nWid + (i-1);
			grid.fIdx[idx++] =  j    * nWid + i;
			grid.fIdx[idx++] = (j-1) * nWid + i;

			i++;
		}
		
		j++;
	}

	return grid.fIdx.GetCount() > 0;
}

/////////////////////////////////////////////////////////////////////////////////////////////////////
// Test hackage ensues
/////////////////////////////////////////////////////////////////////////////////////////////////////
void TestCutter(const plKey& key, const hsVector3& size, const hsPoint3& pos)
{
	plCutter cutter;

	cutter.SetLength(size);

	static hsVector3 dir(0, 1.f, 0);
	static hsVector3 up(0, 0, 1.f);

	cutter.Set(pos, dir, up);

	plSceneObject* so = plSceneObject::ConvertNoRef(key->ObjectIsLoaded());
	if( !so )
		return;
	const plDrawInterface* di = so->GetDrawInterface();
	if( !di )
		return;

	static plDrawableSpans* drawable = nil;
	hsBool newDrawable = !drawable;
	hsBool haveNormal = true;

	hsTArray<UInt32> retIndex;

	hsTArray<plAccessSpan> src;
	plAccessGeometry::Instance()->OpenRO(di, src);
	
	if( !src.GetCount() )
		return;

	int i;
	for( i = 0; i < src.GetCount(); i++ )
	{

		static hsTArray<plCutoutPoly> dst;
		dst.SetCount(0);
#if 1
		cutter.Cutout(src[i], dst);
#else
		hsPoint3 corner;
		hsVector3 ax[3];
		cutter.GetWorldBounds().GetCorner(&corner);
		cutter.GetWorldBounds().GetAxes(ax+0, ax+1, ax+2);
		int iAx = 0;
		int jAx = 1;
		dst.SetCount(6);
		int xx;
		for( xx = 0; xx < 3; xx++ )
		{
			dst[xx].fVerts.SetCount(4);
			
			dst[xx].fVerts[0].fPos = corner;
			dst[xx].fVerts[0].fNorm.Set(0,0,1.f);
			dst[xx].fVerts[0].fUVW.Set(0,0,0);

			dst[xx].fVerts[1].fPos = corner;
			dst[xx].fVerts[1].fPos += ax[iAx];
			dst[xx].fVerts[1].fNorm.Set(0,0,1.f);
			dst[xx].fVerts[1].fUVW.Set(1,0,0);

			dst[xx].fVerts[2].fPos = corner;
			dst[xx].fVerts[2].fPos += ax[iAx];
			dst[xx].fVerts[2].fPos += ax[jAx];
			dst[xx].fVerts[2].fNorm.Set(0,0,1.f);
			dst[xx].fVerts[2].fUVW.Set(1.f,1.f,0);

			dst[xx].fVerts[3].fPos = corner;
			dst[xx].fVerts[3].fPos += ax[jAx];
			dst[xx].fVerts[3].fNorm.Set(0,0,1.f);
			dst[xx].fVerts[3].fUVW.Set(0,1.f,0);

			iAx++;
			jAx = iAx > 1 ? 0 : iAx+1;
		}
		corner += ax[0];
		corner += ax[1];
		corner += ax[2];
		ax[0] = -ax[0];
		ax[1] = -ax[1];
		ax[2] = -ax[2];
		iAx = 0;
		jAx = 1;
		for( xx = 3; xx < 6; xx++ )
		{
			dst[xx].fVerts.SetCount(4);
			
			dst[xx].fVerts[0].fPos = corner;
			dst[xx].fVerts[0].fNorm.Set(0,0,1.f);
			dst[xx].fVerts[0].fUVW.Set(0,0,0);

			dst[xx].fVerts[3].fPos = corner;
			dst[xx].fVerts[3].fPos += ax[iAx];
			dst[xx].fVerts[3].fNorm.Set(0,0,1.f);
			dst[xx].fVerts[3].fUVW.Set(1.f,0,0);

			dst[xx].fVerts[2].fPos = corner;
			dst[xx].fVerts[2].fPos += ax[iAx];
			dst[xx].fVerts[2].fPos += ax[jAx];
			dst[xx].fVerts[2].fNorm.Set(0,0,1.f);
			dst[xx].fVerts[2].fUVW.Set(1.f,1.f,0);

			dst[xx].fVerts[1].fPos = corner;
			dst[xx].fVerts[1].fPos += ax[jAx];
			dst[xx].fVerts[1].fNorm.Set(0,0,1.f);
			dst[xx].fVerts[1].fUVW.Set(0,1.f,0);

			iAx++;
			jAx = iAx > 1 ? 0 : iAx+1;
		}
		haveNormal = false;
#endif

		// What's our total number of verts?
		// Total number of tris?
		int numVerts = 0;
		int numTris = 0;
		int j;
		for( j = 0; j < dst.GetCount(); j++ )
		{
			if( dst[j].fVerts.GetCount() )
			{
				numVerts += dst[j].fVerts.GetCount();
				numTris += dst[j].fVerts.GetCount()-2;
			}
		}
		if( !numTris )
			continue;

		hsTArray<hsPoint3> pos;
		pos.SetCount(numVerts);
		hsTArray<hsVector3> norm;
		norm.SetCount(numVerts);
		hsTArray<hsPoint3> uvw;
		uvw.SetCount(numVerts);
		hsTArray<hsColorRGBA> col;
		col.SetCount(numVerts);

		int iPoly = 0;
		int iVert = 0;
		int iv;
		for( iv = 0; iv < numVerts; iv++ )
		{
			pos[iv] = dst[iPoly].fVerts[iVert].fPos;
			norm[iv] = dst[iPoly].fVerts[iVert].fNorm;
			uvw[iv] = dst[iPoly].fVerts[iVert].fUVW;
			col[iv] = dst[iPoly].fVerts[iVert].fColor;

			hsScalar opac = uvw[iv].fZ < 0.25f 
				? uvw[iv].fZ * 4.f
				: uvw[iv].fZ > 0.75f
					? (1.f - uvw[iv].fZ) * 4.f
					: 1.f;

			opac *= norm[iv].fZ;
			if( opac < 0 )
				opac = 0;

			if( dst[iPoly].fBaseHasAlpha )
				col[iv].a *= opac;
			else
				col[iv].a = opac;

			if( ++iVert >= dst[iPoly].fVerts.GetCount() )
			{
				iVert = 0;
				iPoly++;
			}
		}

		hsTArray<UInt16> idx;

		UInt16 base = 0;
		for( j = 0; j < dst.GetCount(); j++ )
		{
			UInt16 next = base+1;
			int k;
			for( k = 2; k < dst[j].fVerts.GetCount(); k++ )
			{
				idx.Append(base);
				idx.Append(next++);
				idx.Append(next);
			}
			base = ++next;
		}

		drawable = plDrawableGenerator::GenerateDrawable( numVerts, pos.AcquireArray(), 
														haveNormal ? norm.AcquireArray() : nil, 
														uvw.AcquireArray(), 1, 
														col.AcquireArray(), 
														true, 
														nil,
														idx.GetCount(), idx.AcquireArray(), 
														src[i].GetMaterial(), 
														hsMatrix44::IdentityMatrix(), 
														true,
														&retIndex, 
														drawable);

	}

	if( drawable && newDrawable )
		drawable->SetSceneNode(so->GetSceneNode());

}

void TestCutter2(const plKey& key, const hsVector3& size, const hsPoint3& pos, hsBool flip)
{
	plCutter cutter;

	cutter.SetLength(size);

	static hsVector3 dir(0, 1.f, 0);
	static hsVector3 up(0, 0, 1.f);

	cutter.Set(pos, dir, up, flip);

	plSceneObject* so = plSceneObject::ConvertNoRef(key->ObjectIsLoaded());
	if( !so )
		return;

	plSceneNode* node = plSceneNode::ConvertNoRef(so->GetSceneNode()->ObjectIsLoaded());
	if( !node )
		return;

	static plDrawableSpans* drawable = nil;
	hsBool newDrawable = !drawable;
	hsBool haveNormal = true;

	hsTArray<UInt32> retIndex;

	hsTArray<plDrawVisList> drawVis;
	node->Harvest(&cutter.GetIsect(), drawVis);
	if( !drawVis.GetCount() )
		return;

	hsTArray<plAccessSpan> src;

	int numSpan = 0;
	int iDraw;
	for( iDraw = 0; iDraw < drawVis.GetCount(); iDraw++ )
		numSpan += drawVis[iDraw].fVisList.GetCount();

	src.SetCount(numSpan);

	int i;

	iDraw = 0;
	int iSpan = 0;
	for( i = 0; i < numSpan; i++ )
	{
		plAccessGeometry::Instance()->OpenRO(drawVis[iDraw].fDrawable, drawVis[iDraw].fVisList[iSpan], src[i]);

		if( ++iSpan >= drawVis[iDraw].fVisList.GetCount() )
		{
			iDraw++;
			iSpan = 0;
		}
	}

	
	for( i = 0; i < src.GetCount(); i++ )
	{
		static hsTArray<plCutoutPoly> dst;
		dst.SetCount(0);
		cutter.Cutout(src[i], dst);

		// What's our total number of verts?
		// Total number of tris?
		int numVerts = 0;
		int numTris = 0;
		int j;
		for( j = 0; j < dst.GetCount(); j++ )
		{
			if( dst[j].fVerts.GetCount() )
			{
				numVerts += dst[j].fVerts.GetCount();
				numTris += dst[j].fVerts.GetCount()-2;
			}
		}
		if( !numTris )
			continue;

		hsTArray<hsPoint3> pos;
		pos.SetCount(numVerts);
		hsTArray<hsVector3> norm;
		norm.SetCount(numVerts);
		hsTArray<hsPoint3> uvw;
		uvw.SetCount(numVerts);
		hsTArray<hsColorRGBA> col;
		col.SetCount(numVerts);

		int iPoly = 0;
		int iVert = 0;
		int iv;
		for( iv = 0; iv < numVerts; iv++ )
		{
			pos[iv] = dst[iPoly].fVerts[iVert].fPos;
			norm[iv] = dst[iPoly].fVerts[iVert].fNorm;
			uvw[iv] = dst[iPoly].fVerts[iVert].fUVW;
			col[iv] = dst[iPoly].fVerts[iVert].fColor;

			hsScalar opac = uvw[iv].fZ < 0.25f 
				? uvw[iv].fZ * 4.f
				: uvw[iv].fZ > 0.75f
					? (1.f - uvw[iv].fZ) * 4.f
					: 1.f;

			opac *= norm[iv].fZ;
			if( opac < 0 )
				opac = 0;

			if( dst[iPoly].fBaseHasAlpha )
				col[iv].a *= opac;
			else
				col[iv].a = opac;


			if( ++iVert >= dst[iPoly].fVerts.GetCount() )
			{
				iVert = 0;
				iPoly++;
			}
		}

		hsTArray<UInt16> idx;

		UInt16 base = 0;
		for( j = 0; j < dst.GetCount(); j++ )
		{
			UInt16 next = base+1;
			int k;
			for( k = 2; k < dst[j].fVerts.GetCount(); k++ )
			{
				idx.Append(base);
				idx.Append(next++);
				idx.Append(next);
			}
			base = ++next;
		}

		drawable = plDrawableGenerator::GenerateDrawable( numVerts, pos.AcquireArray(), 
														haveNormal ? norm.AcquireArray() : nil, 
														uvw.AcquireArray(), 1, 
														col.AcquireArray(), 
														false, 
														nil,
														idx.GetCount(), idx.AcquireArray(), 
														src[i].GetMaterial(), 
														hsMatrix44::IdentityMatrix(), 
														true,
														&retIndex, 
														drawable);

	}

	for( i = 0; i < numSpan; i++ )
	{
		plAccessGeometry::Instance()->Close(src[i]);
	}

	if( drawable && newDrawable )
		drawable->SetSceneNode(so->GetSceneNode());

}