Ejemplo n.º 1
0
int HWDrawInfo::SetupLightsForOtherPlane(subsector_t * sub, FDynLightData &lightdata, const secplane_t *plane)
{
	if (Level->HasDynamicLights && !isFullbrightScene())
	{
		Plane p;

		FLightNode * node = sub->section->lighthead;

		lightdata.Clear();
		while (node)
		{
			FDynamicLight * light = node->lightsource;

			if (!light->IsActive())
			{
				node = node->nextLight;
				continue;
			}
			iter_dlightf++;

			p.Set(plane->Normal(), plane->fD());
			draw_dlightf += lightdata.GetLight(sub->sector->PortalGroup, p, light, true);
			node = node->nextLight;
		}

		return screen->mLights->UploadLights(lightdata);
	}
	else return -1;
}
Ejemplo n.º 2
0
void GLFlat::SetupSubsectorLights(int pass, subsector_t * sub, int *dli)
{
	Plane p;

	if (dli != NULL && *dli != -1)
	{
		gl_RenderState.ApplyLightIndex(GLRenderer->mLights->GetIndex(*dli));
		(*dli)++;
		return;
	}

	lightdata.Clear();
	FLightNode * node = sub->lighthead;
	while (node)
	{
		ADynamicLight * light = node->lightsource;
			
		if (light->flags2&MF2_DORMANT)
		{
			node=node->nextLight;
			continue;
		}
		iter_dlightf++;

		// we must do the side check here because gl_SetupLight needs the correct plane orientation
		// which we don't have for Legacy-style 3D-floors
		fixed_t planeh = plane.plane.ZatPoint(light->x, light->y);
		if (gl_lights_checkside && ((planeh<light->z && ceiling) || (planeh>light->z && !ceiling)))
		{
			node=node->nextLight;
			continue;
		}

		p.Set(plane.plane);
		gl_GetLight(p, light, false, false, lightdata);
		node = node->nextLight;
	}

	int d = GLRenderer->mLights->UploadLights(lightdata);
	if (pass == GLPASS_LIGHTSONLY)
	{
		GLRenderer->mLights->StoreIndex(d);
	}
	else
	{
		gl_RenderState.ApplyLightIndex(d);
	}
}
Ejemplo n.º 3
0
// seppt3
//---------------------------------------------------------------------------
int SeparatePointSets3D (
	// convex hull 0
	int n0, const Point pts0[],	int fCount0, const Triangle* face0,
	// convex hull 1
	int n1, const Point pts1[], int fCount1, const Triangle* face1,
	
	// result plane, if result >0
	Plane &plane)
{
	int i, j0, j1, j2, side0, side1;
	//hg was double 
	float	ux, uy, uz, vx, vy, vz;
	float   xNor,yNor,zNor,c;

	// test faces of hull 0 for possible separation of points
	for (i = 0; i < fCount0; i++)
	{
		// lookup face (assert: j0 != j1 && j0 != j2 && j1 != j2)
		j0 = face0[i][0];
		j1 = face0[i][1];
		j2 = face0[i][2];

		// compute perpendicular to face (assert: (xNor,yNor,zNor) != (0,0,0))
		ux = pts0[j1].x-pts0[j0].x;
		uy = pts0[j1].y-pts0[j0].y;
		uz = pts0[j1].z-pts0[j0].z;
		vx = pts0[j2].x-pts0[j0].x;
		vy = pts0[j2].y-pts0[j0].y;
		vz = pts0[j2].z-pts0[j0].z;

		xNor = uy*vz-uz*vy;
		yNor = uz*vx-ux*vz;
		zNor = ux*vy-uy*vx;

		if (xNor == 0 && yNor == 0 && zNor == 0) {
			TRACE("BAD NORMAL in hull !!!!!!\n");
			continue;
		}

		// compute plane constant
		c = xNor*pts0[j0].x+yNor*pts0[j0].y+zNor*pts0[j0].z;

		// determine if hull 1 is on same side of plane
		side1 = OnSameSide(xNor,yNor,zNor,c,fCount1,face1,pts1);
		if ( side1 )
		{
			// determine which side of plane hull 0 lies
			side0 = WhichSide(xNor,yNor,zNor,c,fCount0,face0,pts0);
			if ( side0*side1 <= 0 ) { // plane separates hulls
				plane.Set(xNor,yNor,zNor,c);
				return 1;
			}
		}
	}

	// test faces of hull 1 for possible separation of points
	for (i = 0; i < fCount1; i++)
	{
		// lookup edge (assert: j0 != j1 && j0 != j2 && j1 != j2)
		j0 = face1[i][0];
		j1 = face1[i][1];
		j2 = face1[i][2];

		// compute perpendicular to face (assert: (xNor,yNor,zNor) != (0,0,0))
		ux = pts1[j1].x-pts1[j0].x;
		uy = pts1[j1].y-pts1[j0].y;
		uz = pts1[j1].z-pts1[j0].z;
		vx = pts1[j2].x-pts1[j0].x;
		vy = pts1[j2].y-pts1[j0].y;
		vz = pts1[j2].z-pts1[j0].z;
		xNor = uy*vz-uz*vy;
		yNor = uz*vx-ux*vz;
		zNor = ux*vy-uy*vx;


		if (xNor == 0 && yNor == 0 && zNor == 0) {
			TRACE("BAD NORMAL in hull !!!!!!\n");
			continue;
		}

		// compute plane constant
		c = xNor*pts1[j0].x+yNor*pts1[j0].y+zNor*pts1[j0].z;

		// determine if hull 0 is on same side of plane
		side0 = OnSameSide(xNor,yNor,zNor,c,fCount0,face0,pts0);
		if ( side0 )
		{
			// determine which side of plane hull 1 lies
			side1 = WhichSide(xNor,yNor,zNor,c,fCount1,face1,pts1);
			if ( side0*side1 <= 0 ) {  // plane separates hulls
/*
				// normalize 
				float l = sqrt(xNor*xNor + yNor*yNor + zNor*zNor);
				
				if (l != 0.0)  {
					l= 1.0/l; 
					xNor *= l; yNor *=l; zNor*=l;
				}
				c = xNor*pts1[j0].x+yNor*pts1[j0].y+zNor*pts1[j0].z;
*/
				plane.Set(xNor,yNor,zNor,c);
				return 1;
			}
		}
	}
#if 0
	// what if two hulls are on same plane ?
	// don't do the full test 
	return (0);
#endif

	
	// build edge list for hull 0
	EdgeNode* list0 = 0;
	for (i = 0; i < fCount0; i++)
	{
		// lookup face (assert: j0 != j1 && j0 != j2 && j1 != j2)
		j0 = face0[i][0];
		j1 = face0[i][1];
		j2 = face0[i][2];
		AddEdge(list0,j0,j1);
		AddEdge(list0,j0,j2);
		AddEdge(list0,j1,j2);
	}

	// build edge list for hull 1
	EdgeNode* list1 = 0;
	for (i = 0; i < fCount1; i++)
	{
		// lookup face (assert: j0 != j1 && j0 != j2 && j1 != j2)
		j0 = face1[i][0];
		j1 = face1[i][1];
		j2 = face1[i][2];
		AddEdge(list1,j0,j1);
		AddEdge(list1,j0,j2);
		AddEdge(list1,j1,j2);
	}

	// Test planes whose normals are cross products of two edges,
	// one from each hull.
	for (EdgeNode* node0 = list0; node0; node0 = node0->next)
	{
		// get edge
		ux = pts0[node0->v1].x-pts0[node0->v0].x;
		uy = pts0[node0->v1].y-pts0[node0->v0].y;
		uz = pts0[node0->v1].z-pts0[node0->v0].z;

		for (EdgeNode* node1 = list1; node1; node1 = node1->next)
		{
			vx = pts1[node1->v1].x-pts1[node1->v0].x;
			vy = pts1[node1->v1].y-pts1[node1->v0].y;
			vz = pts1[node1->v1].z-pts1[node1->v0].z;

			// compute plane normal
			xNor = uy*vz-uz*vy;
			yNor = uz*vx-ux*vz;
			zNor = ux*vy-uy*vx;

			if (xNor == 0 && yNor == 0 && zNor == 0) {
				TRACE("BAD NORMAL in hull !!!!!!\n");
				continue;
			}

			// compute plane constant
			c = xNor*pts0[node0->v0].x+yNor*pts0[node0->v0].y+zNor*pts0[node0->v0].z;

			// determine if hull 0 is on same side of plane
			side0 = OnSameSide(xNor,yNor,zNor,c,fCount0,face0,pts0);
			side1 = OnSameSide(xNor,yNor,zNor,c,fCount1,face1,pts1);
			if ( side0*side1 < 0 ) { // plane separates hulls
				DeleteList(list0); // hg
				DeleteList(list1);
				plane.Set(xNor,yNor,zNor,c);
				return 1;
			}
		}
	}

	DeleteList(list0);
	DeleteList(list1);

	return 0;
}
Ejemplo n.º 4
0
void MeshEnt::UnSelectFaces( Area<S32> * rect) // = NULL
{
  if (!selData)
  {
    return;
  }

  MeshRoot & root = RootPriv();

  if (!rect)
  {
    selData->verts.DisposeAll();
    selData->faces.DisposeAll();
  }
  else
  {
    // get temp memory
    Vector * verts;
    U8 * hits;
    U32 heapSize = Vid::Heap::ReqVector( &verts, root.vertices.count, &hits, root.vertices.count);
    Utils::Memset( hits, 0, root.vertices.count);

    // set up transform matrices and transform verts to view space
    Matrix tranys[MAXMESHPERGROUP];
    Bool doMultiWeight = (root.rootControlFlags & controlMULTIWEIGHT) && Vid::renderState.status.multiWeight ? TRUE : FALSE;
    root.SetVertsView( statesR, tranys, verts, root.vertices.count, doMultiWeight);

    // transform verts and clip in Z
    //
    U16 i, j;
    for (i = 0; i < root.faces.count; i++)
    {
      FaceObj &face = root.faces[i];
      BucketLock &bucky = buckys[face.buckyIndex];

      if (!(bucky.flags0 & RS_2SIDED))
      {
        // backface cull
        //
        Plane plane;
        plane.Set( verts[face.verts[0]], verts[face.verts[2]], verts[face.verts[1]]);
        if (plane.Dot( verts[face.verts[0]]) <= 0.0f)
        {
          continue;
        }
      }

      for (j = 0; j < 3; j++)
      {
        Vector & vect = verts[face.verts[j]];
        if (vect.z < Vid::Math::nearPlane || vect.z >= Vid::Math::farPlane)
        {
          // done or 3D clip
          continue;
        }

        // project
        //
        VertexTL v;
        Vid::ProjectFromCamera_I( v, vect);

        if (v.vv.x >= rect->p0.x && v.vv.x < rect->p1.x
         && v.vv.y >= rect->p0.y && v.vv.y < rect->p1.y)
        {
          // if a vert is inside the on screen box
          //
          UnSelectFace( i);
          break;
        }
      }
    }
    
    Vid::Heap::Restore( heapSize);
  }
}
void COpenGLSkydomeRenderer::DoDrawReflectionSkydomeRenderBatch()
{
	if( m_SkydomeStaticBuffer == NULL )
		return;

	COpenGLShaderManager *pShaderManager = static_cast<COpenGLShaderManager*>(m_pRenderDevice->GetShaderManager());

	Matrix4x4 SkydomeWorldMatrix;
	Plane ReflectionPlane;
	ReflectionPlane.Set( Vector3D(0, 1, 0), -m_pRenderDevice->GetWorldSystemManager()->getWater()->m_fWaterHeight );
	SkydomeWorldMatrix.ReflectPlane( ReflectionPlane );

	Vector4D newCamPos = m_pRenderDevice->getOpenGLCamera()->m_CameraPos * SkydomeWorldMatrix;
	SkydomeWorldMatrix = m_SkydomeWorldMatrix;

	SkydomeWorldMatrix.Translate( newCamPos.x, newCamPos.y, newCamPos.z );

	Matrix4x4 MVP = SkydomeWorldMatrix * m_pRenderDevice->getOpenGLWaterRenderer()->m_MirrorViewMatrix * m_pRenderDevice->getOpenGLWaterRenderer()->m_ObliqueNearPlaneReflectionProjMatrix;
	Matrix4x4 MV = SkydomeWorldMatrix * m_pRenderDevice->getOpenGLWaterRenderer()->m_MirrorViewMatrix;

	ISGPMaterialSystem::MaterialList &Mat_List = m_pRenderDevice->GetMaterialSystem()->GetMaterialList();
	const ISGPMaterialSystem::SGPMaterialInfo &SkydomeMaterial_info = Mat_List.getReference(ISGPMaterialSystem::eMaterial_skydome);
	m_pRenderDevice->getOpenGLMaterialRenderer()->PushMaterial( SkydomeMaterial_info.m_material, MM_Add );

	m_pRenderDevice->getOpenGLMaterialRenderer()->ComputeMaterialPass();
	m_pRenderDevice->getOpenGLMaterialRenderer()->OnePassPreRenderMaterial(0);

	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->useProgram();

	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("modelViewProjMatrix", MVP);
	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("modelViewMatrix", MV);
	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("InvSunDir", m_SunDir);
	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("HGg", m_HGg);
	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("BetaRPlusBetaM", m_BetaRPlusBetaM);
	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("Multipliers", m_Multipliers);
	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("BetaDashR", m_BetaDashR);
	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("BetaDashM", m_BetaDashM);
	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("OneOverBetaRPlusBetaM", m_OneOverBetaRPlusBetaM);
	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("SunColorAndIntensity", m_SunColorAndIntensity);

	m_pRenderDevice->GetTextureManager()->getTextureByID(m_SkydomeMaterialSkin.nTextureID[0])->pSGPTexture->BindTexture2D(0);
	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("gSampler0", 0);
	if( m_SkydomeMaterialSkin.nTextureNum == 2 )
	{
		m_pRenderDevice->GetTextureManager()->getTextureByID(m_SkydomeMaterialSkin.nTextureID[1])->pSGPTexture->BindTexture2D(1);
		pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("gSampler1", 1);
	}

	pShaderManager->GetGLSLShaderProgram(m_SkydomeMaterialSkin.nShaderType)->setShaderUniform("cloudParam", m_SkydomeCloudParam);


	
	m_SkydomeStaticBuffer->pVBO->bindVAO();

	glDrawElements( m_pRenderDevice->primitiveTypeToGL( m_SkydomeMaterialSkin.nPrimitiveType ),
					m_SkydomeStaticBuffer->nNumIndis, 
					GL_UNSIGNED_SHORT,
					(void*)0 );

	m_SkydomeStaticBuffer->pVBO->unBindVAO();



	m_pRenderDevice->getOpenGLMaterialRenderer()->OnePassPostRenderMaterial(0);
	m_pRenderDevice->getOpenGLMaterialRenderer()->PopMaterial();

}
Ejemplo n.º 6
0
void GLWall::SetupLights()
{
	if (RenderStyle == STYLE_Add && !glset.lightadditivesurfaces) return;	// no lights on additively blended surfaces.

	// check for wall types which cannot have dynamic lights on them (portal types never get here so they don't need to be checked.)
	switch (type)
	{
	case RENDERWALL_FOGBOUNDARY:
	case RENDERWALL_MIRRORSURFACE:
	case RENDERWALL_COLOR:
		return;
	}

	float vtx[]={glseg.x1,zbottom[0],glseg.y1, glseg.x1,ztop[0],glseg.y1, glseg.x2,ztop[1],glseg.y2, glseg.x2,zbottom[1],glseg.y2};
	Plane p;

	lightdata.Clear();
	p.Set(&glseg);

	/*
	if (!p.ValidNormal()) 
	{
		return;
	}
	*/
	FLightNode *node;
	if (seg->sidedef == NULL)
	{
		node = NULL;
	}
	else if (!(seg->sidedef->Flags & WALLF_POLYOBJ))
	{
		node = seg->sidedef->lighthead;
	}
	else if (sub)
	{
		// Polobject segs cannot be checked per sidedef so use the subsector instead.
		node = sub->lighthead;
	}
	else node = NULL;

	// Iterate through all dynamic lights which touch this wall and render them
	while (node)
	{
		if (!(node->lightsource->flags2&MF2_DORMANT))
		{
			iter_dlight++;

			DVector3 posrel = node->lightsource->PosRelative(seg->frontsector);
			float x = posrel.X;
			float y = posrel.Y;
			float z = posrel.Z;
			float dist = fabsf(p.DistToPoint(x, z, y));
			float radius = node->lightsource->GetRadius();
			float scale = 1.0f / ((2.f * radius) - dist);
			FVector3 fn, pos;

			if (radius > 0.f && dist < radius)
			{
				FVector3 nearPt, up, right;

				pos = { x, z, y };
				fn = p.Normal();

				fn.GetRightUp(right, up);

				FVector3 tmpVec = fn * dist;
				nearPt = pos + tmpVec;

				FVector3 t1;
				int outcnt[4]={0,0,0,0};
				texcoord tcs[4];

				// do a quick check whether the light touches this polygon
				for(int i=0;i<4;i++)
				{
					t1 = FVector3(&vtx[i*3]);
					FVector3 nearToVert = t1 - nearPt;
					tcs[i].u = ((nearToVert | right) * scale) + 0.5f;
					tcs[i].v = ((nearToVert | up) * scale) + 0.5f;

					if (tcs[i].u<0) outcnt[0]++;
					if (tcs[i].u>1) outcnt[1]++;
					if (tcs[i].v<0) outcnt[2]++;
					if (tcs[i].v>1) outcnt[3]++;

				}
				if (outcnt[0]!=4 && outcnt[1]!=4 && outcnt[2]!=4 && outcnt[3]!=4) 
				{
					gl_GetLight(seg->frontsector->PortalGroup, p, node->lightsource, true, lightdata);
				}
			}
		}
		node = node->nextLight;
	}

	dynlightindex = GLRenderer->mLights->UploadLights(lightdata);
}