Example #1
0
void CGameObject::OnRender			()
{
	if (!ai().get_level_graph())
		return;

	CDebugRenderer					&renderer = Level().debug_renderer();
	if (/**bDebug && /**/Visual()) {
		float						half_cell_size = 1.f*ai().level_graph().header().cell_size()*.5f;
		Fvector						additional = Fvector().set(half_cell_size,half_cell_size,half_cell_size);

		render_box					(Visual(),XFORM(),Fvector().set(0.f,0.f,0.f),true,color_rgba(0,0,255,255));
		render_box					(Visual(),XFORM(),additional,false,color_rgba(0,255,0,255));
	}

	if (0) {
		Fvector						bc,bd; 
		Visual()->getVisData().box.get_CD	(bc,bd);
		Fmatrix						M = Fidentity;
		float						half_cell_size = ai().level_graph().header().cell_size()*.5f;
		bd.add						(Fvector().set(half_cell_size,half_cell_size,half_cell_size));
		M.scale						(bd);
		Fmatrix						T = XFORM();
		T.c.add						(bc);
		renderer.draw_obb			(T,bd,color_rgba(255,255,255,255));
	}
}
Example #2
0
void CDrawUtilities::DrawSphere(const Fmatrix& parent, const Fvector& center, float radius, u32 clr_s, u32 clr_w, BOOL bSolid, BOOL bWire)
{
    Fmatrix B;
    B.scale				(radius,radius,radius);
    B.translate_over	(center);
    B.mulA_43			(parent);
    RCache.set_xform_world(B);
    DrawIdentSphere		(bSolid, bWire, clr_s,clr_w);
}
Example #3
0
void CDrawUtilities::DrawAABB(const Fvector& p0, const Fvector& p1, u32 clr_s, u32 clr_w, BOOL bSolid, BOOL bWire)
{
    Fmatrix			R;
	Fvector	C; C.set((p1.x+p0.x)*0.5f,(p1.y+p0.y)*0.5f,(p1.z+p0.z)*0.5f);
    R.scale			(_abs(p1.x-p0.x),_abs(p1.y-p0.y),_abs(p1.z-p0.z));
    R.translate_over(C);
	RCache.set_xform_world(R);
	DrawIdentBox	(bSolid,bWire,clr_s,clr_w);
}
Example #4
0
void BuildMatrix		(Fmatrix &mView, float invsz, const Fvector norm, const Fvector& from)
{
	// build projection
	Fmatrix				mScale;
	Fvector				at,up,right,y;
	at.sub				(from,norm);
	y.set				(0,1,0);
	if (_abs(norm.y)>.99f) y.set(1,0,0);
	right.crossproduct	(y,norm);
	up.crossproduct		(norm,right);
	mView.build_camera	(from,at,up);
	mScale.scale		(invsz,invsz,invsz);
	mView.mulA_43		(mScale);
}
Example #5
0
void CWallmarksEngine::BuildMatrix	(Fmatrix &mView, float invsz, const Fvector& from)
{
	// build projection
	Fmatrix				mScale;
    Fvector				at,up,right,y;
	at.sub				(from,sml_normal);
	y.set				(0,1,0);
	if (_abs(sml_normal.y)>.99f) y.set(1,0,0);
	right.crossproduct	(y,sml_normal);
	up.crossproduct		(sml_normal,right);
	mView.build_camera	(from,at,up);
	mScale.scale		(invsz,invsz,invsz);
	mView.mulA_43		(mScale);
}
Example #6
0
void CEditShape::Render(int priority, bool strictB2F)
{
	inherited::Render(priority, strictB2F);
    if (1==priority){
        if (strictB2F){
	        Device.SetShader			(Device.m_WireShader);
            Device.SetRS				(D3DRS_CULLMODE,D3DCULL_NONE);
            u32 clr 					= Selected()?subst_alpha(m_DrawTranspColor, color_get_A(m_DrawTranspColor)*2):m_DrawTranspColor;
                
            Fvector zero				={0.f,0.f,0.f};
            for (ShapeIt it=shapes.begin(); it!=shapes.end(); ++it)
            {
                switch(it->type)
                {
                case cfSphere:
                {
                    Fsphere& S			= it->data.sphere;
                    Fmatrix B;
                    B.scale				(S.R,S.R,S.R);
                    B.translate_over	(S.P);
                    B.mulA_43			(_Transform());
                    RCache.set_xform_world(B);
                    Device.SetShader	(Device.m_WireShader);
                    DU_impl.DrawCross	(zero,1.f,m_DrawEdgeColor,false);
                    DU_impl.DrawIdentSphere	(true,true,clr,m_DrawEdgeColor);
                }break;
                case cfBox:
                {
                    Fmatrix B			= it->data.box;
                    B.mulA_43			(_Transform());
                    RCache.set_xform_world(B);
                    DU_impl.DrawIdentBox(true,true,clr,m_DrawEdgeColor);
                }break;
                }
            }
            Device.SetRS(D3DRS_CULLMODE,D3DCULL_CCW);
        }else{
            if( Selected()&&m_Box.is_valid() ){
		        Device.SetShader		(Device.m_SelectionShader);
                RCache.set_xform_world	(_Transform());
                u32 clr 				= 0xFFFFFFFF;
                Device.SetShader		(Device.m_WireShader);
                DU_impl.DrawSelectionBox(m_Box,&clr);
            }
        }
    }
}
Example #7
0
bool CLevelTool::GetSelectionPosition(Fmatrix& result)
{
	if(pCurTool)
    {
    	Fvector 			center;
    	Fbox 				BB;
        BB.invalidate		();
//    	pCurTool->GetBBox	(BB, true);

        const CCustomObject* object = pCurTool->LastSelected();
        if(!object)
        	return false;
            
        object->GetBox		(BB);
        
        BB.getcenter		(center);
        center.y			= BB.max.y;

		Fvector2			pt_ss;
        pt_ss.set			(10000,-10000);
        Fvector				pt_ss_3d;
        BB.setb				(center, Fvector().set(1.0f,1.0f,1.0f));
        for(int k=0;k<8;++k)
        {
        	Fvector pt;
        	BB.getpoint(k,pt);
			EDevice.mFullTransform.transform(pt_ss_3d, pt);
            
            pt_ss.x = _min(pt_ss.x, pt_ss_3d.y);
            pt_ss.y = _max(pt_ss.y, pt_ss_3d.y);
        }

        float r_bb_ss	 = pt_ss.y - pt_ss.x;
        clamp(r_bb_ss, 0.0f,0.10f);
        float des_radius = 0.2f; 
        float csale 	 = des_radius/r_bb_ss;
        
        result.scale	(csale,csale,csale);
        result.c 		= center;
        return 			true;
    }else
		return 			false;
}
Example #8
0
BOOL CBlackGraviArtefact::net_Spawn(CSE_Abstract* DC)
{
	if(!inherited::net_Spawn(DC)) return FALSE;



	CParticlesObject* pStaticPG;
	pStaticPG = CParticlesObject::Create("anomaly\\galantine",FALSE);
	Fmatrix pos;
	//pos.rotateY(1.57);
	//pos.mulA(pos);
	pos.scale(0.7f,0.7f,0.7f);
	pos.translate_over(XFORM().c);
	
	Fvector vel;
	vel.set(0,0,0);
	pStaticPG->UpdateParent(pos, vel); 
	pStaticPG->Play();



	return TRUE;
}
Example #9
0
void CDrawUtilities::DrawCone	(const Fmatrix& parent, const Fvector& apex, const Fvector& dir, float height, float radius, u32 clr_s, u32 clr_w, BOOL bSolid, BOOL bWire)
{
    Fmatrix mScale;
    mScale.scale		(2.f*radius,2.f*radius,height);
    
    // build final rotation / translation
    Fvector             L_dir,L_up,L_right;
    L_dir.set           (dir);       		    L_dir.normalize			();
    L_up.set            (0,1,0);				if (_abs(L_up.dotproduct(L_dir))>.99f)  L_up.set(0,0,1);
    L_right.crossproduct(L_up,L_dir);           L_right.normalize       ();
    L_up.crossproduct   (L_dir,L_right);        L_up.normalize          ();

    Fmatrix         	mR;
    mR.i                = L_right;              mR._14          = 0;
    mR.j                = L_up;                 mR._24          = 0;
    mR.k                = L_dir;                mR._34          = 0;
    mR.c                = apex;			  		mR._44          = 1;

    // final xform
    Fmatrix xf;			xf.mul (mR,mScale);
    xf.mulA_43			(parent);
    RCache.set_xform_world(xf);
	DrawIdentCone		(bSolid,bWire,clr_s,clr_w);
}
Example #10
0
// Xforms
void	light::xform_calc			()
{
	if	(Device.dwFrame == m_xform_frame)	return;
	m_xform_frame	= Device.dwFrame;

	// build final rotation / translation
	Fvector					L_dir,L_up,L_right;

	// dir
	L_dir.set				(direction);
	float l_dir_m			= L_dir.magnitude();
	if (_valid(l_dir_m) && l_dir_m>EPS_S)	L_dir.div(l_dir_m);
	else									L_dir.set(0,0,1);

	// R&N
	if (right.square_magnitude()>EPS)				{
		// use specified 'up' and 'right', just enshure ortho-normalization
		L_right.set					(right);				L_right.normalize	();
		L_up.crossproduct			(L_dir,L_right);		L_up.normalize		();
		L_right.crossproduct		(L_up,L_dir);			L_right.normalize	();
	} else {
		// auto find 'up' and 'right' vectors
		L_up.set					(0,1,0);				if (_abs(L_up.dotproduct(L_dir))>.99f)	L_up.set(0,0,1);
		L_right.crossproduct		(L_up,L_dir);			L_right.normalize	();
		L_up.crossproduct			(L_dir,L_right);		L_up.normalize		();
	}

	// matrix
	Fmatrix					mR;
	mR.i					= L_right;	mR._14	= 0;
	mR.j					= L_up;		mR._24	= 0;
	mR.k					= L_dir;	mR._34	= 0;
	mR.c					= position;	mR._44	= 1;

	// switch
	switch(flags.type)	{
	case IRender_Light::REFLECTED	:
	case IRender_Light::POINT		:
		{
			// scale of identity sphere
			float		L_R			= range;
			Fmatrix		mScale;		mScale.scale	(L_R,L_R,L_R);
			m_xform.mul_43			(mR,mScale);
		}
		break;
	case IRender_Light::SPOT		:
		{
			// scale to account range and angle
			float		s			= 2.f*range*tanf(cone/2.f);	
			Fmatrix		mScale;		mScale.scale(s,s,range);	// make range and radius
			m_xform.mul_43			(mR,mScale);
		}
		break;
	case IRender_Light::OMNIPART	:
		{
			float		L_R			= 2*range;		// volume is half-radius
			Fmatrix		mScale;		mScale.scale	(L_R,L_R,L_R);
			m_xform.mul_43			(mR,mScale);
		}
		break;
	default:
		m_xform.identity	();
		break;
	}
}
Example #11
0
void CLightProjector::calculate	()
{
	#ifdef _GPA_ENABLED	
		TAL_SCOPED_TASK_NAMED( "CLightProjector::calculate()" );
	#endif // _GPA_ENABLED

	if (receivers.empty())		return;

	// perform validate / markup
	for (u32 r_it=0; r_it<receivers.size(); r_it++)
	{
		// validate
		BOOL				bValid	= TRUE;
		IRenderable*		O		= receivers[r_it];
		CROS_impl*			LT		= (CROS_impl*)O->renderable_ROS();
		int					slot	= LT->shadow_recv_slot;
		if (slot<0 || slot>=P_o_count)								bValid = FALSE;	// invalid slot
		else if (cache[slot].O!=O)									bValid = FALSE;	// not the same object
		else {
			// seems to be valid
			Fbox	bb;		bb.xform		(O->renderable.visual->getVisData().box,O->renderable.xform);
			if (cache[slot].BB.contains(bb))	{
				// inside, but maybe timelimit exceeded?
				if (Device.dwTimeGlobal > cache[slot].dwTimeValid)	bValid = FALSE;	// timeout
			} else													bValid = FALSE;	// out of bounds
		}

		// 
		if (bValid)			{
			// Ok, use cached version
			cache[slot].dwFrame	= Device.dwFrame;
		} else {
			taskid.push_back	(r_it);
		}
	}
	if (taskid.empty())			return;

	// Begin
	Device.Statistic->RenderDUMP_Pcalc.Begin	();
	RCache.set_RT				(RT->pRT);
	RCache.set_ZB				(RImplementation.Target->pTempZB);
	CHK_DX(HW.pDevice->Clear	(0,0, D3DCLEAR_ZBUFFER | (HW.Caps.bStencil?D3DCLEAR_STENCIL:0), 0,1,0 ));
	RCache.set_xform_world		(Fidentity);

	// reallocate/reassociate structures + perform all the work
	for (u32 c_it=0; c_it<cache.size(); c_it++)
	{
		if (taskid.empty())							break;
		if (Device.dwFrame==cache[c_it].dwFrame)	continue;

		// found not used slot
		int				tid		= taskid.back();	taskid.pop_back();
		recv&			R		= cache		[c_it];
		IRenderable*	O		= receivers	[tid];
		const vis_data& vis = O->renderable.visual->getVisData();
		CROS_impl*	LT		= (CROS_impl*)O->renderable_ROS();
		VERIFY2			(_valid(O->renderable.xform),"Invalid object transformation");
		VERIFY2			(_valid(vis.sphere.P),"Invalid object's visual sphere");

		Fvector			C;		O->renderable.xform.transform_tiny		(C,vis.sphere.P);
		R.O						= O;
		R.C						= C;
		R.C.y					+= vis.sphere.R*0.1f;		//. YURA: 0.1 can be more
		R.BB.xform				(vis.box,O->renderable.xform).scale(0.1f);
		R.dwTimeValid			= Device.dwTimeGlobal + ::Random.randI(time_min,time_max);
		LT->shadow_recv_slot	= c_it; 

		// Msg					("[%f,%f,%f]-%f",C.C.x,C.C.y,C.C.z,C.O->renderable.visual->vis.sphere.R);
		// calculate projection-matrix
		Fmatrix		mProject;
		float		p_R			=	R.O->renderable.visual->getVisData().sphere.R * 1.1f;
		//VERIFY2		(p_R>EPS_L,"Object has no physical size");
		VERIFY3		(p_R>EPS_L,"Object has no physical size", R.O->renderable.visual->getDebugName().c_str());
		float		p_hat		=	p_R/P_cam_dist;
		float		p_asp		=	1.f;
		float		p_near		=	P_cam_dist-EPS_L;									
		float		p_far		=	P_cam_dist+p_R+P_cam_range;	
		mProject.build_projection_HAT	(p_hat,p_asp,p_near,p_far);
		RCache.set_xform_project		(mProject);
		
		// calculate view-matrix
		Fmatrix		mView;
		Fvector		v_C, v_Cs, v_N;
		v_C.set					(R.C);
		v_Cs					= v_C;
		v_C.y					+=	P_cam_dist;
		v_N.set					(0,0,1);
		VERIFY					(_valid(v_C) && _valid(v_Cs) && _valid(v_N));

		// validate
		Fvector		v;
		v.sub		(v_Cs,v_C);;
#ifdef DEBUG
		if ((v.x*v.x+v.y*v.y+v.z*v.z)<=flt_zero)	{
			CObject* OO = dynamic_cast<CObject*>(R.O);
			Msg("Object[%s] Visual[%s] has invalid position. ",*OO->cName(),*OO->cNameVisual());
			Fvector cc;
			OO->Center(cc);
			Log("center=",cc);

			Log("visual_center=",OO->Visual()->getVisData().sphere.P);
			
			Log("full_matrix=",OO->XFORM());

			Log	("v_N",v_N);
			Log	("v_C",v_C);
			Log	("v_Cs",v_Cs);

			Log("all bones transform:--------");
			CKinematics* K = dynamic_cast<CKinematics*>(OO->Visual());
			
			for(u16 ii=0; ii<K->LL_BoneCount();++ii){
				Fmatrix tr;

				tr = K->LL_GetTransform(ii);
				Log("bone ",K->LL_BoneName_dbg(ii));
				Log("bone_matrix",tr);
			}
			Log("end-------");
		}
#endif
		// handle invalid object-bug
		if ((v.x*v.x+v.y*v.y+v.z*v.z)<=flt_zero)	{
			// invalidate record, so that object will be unshadowed, but doesn't crash
			R.dwTimeValid			= Device.dwTimeGlobal;
			LT->shadow_recv_frame	= Device.dwFrame-1;
			LT->shadow_recv_slot	= -1; 
			continue				;
		}

		mView.build_camera		(v_C,v_Cs,v_N);
		RCache.set_xform_view	(mView);

		// Select slot, set viewport
		int		s_x				=	c_it%P_o_line;
		int		s_y				=	c_it/P_o_line;
		D3DVIEWPORT9 VP			=	{s_x*P_o_size,s_y*P_o_size,P_o_size,P_o_size,0,1 };
		CHK_DX					(HW.pDevice->SetViewport(&VP));

		// Clear color to ambience
		Fvector&	cap			=	LT->get_approximate();
		CHK_DX					(HW.pDevice->Clear(0,0, D3DCLEAR_TARGET, color_rgba_f(cap.x,cap.y,cap.z, (cap.x+cap.y+cap.z)/4.f), 1, 0 ));

		// calculate uv-gen matrix and clamper
		Fmatrix					mCombine;		mCombine.mul	(mProject,mView);
		Fmatrix					mTemp;
		float					fSlotSize		= float(P_o_size)/float(P_rt_size);
		float					fSlotX			= float(s_x*P_o_size)/float(P_rt_size);
		float					fSlotY			= float(s_y*P_o_size)/float(P_rt_size);
		float					fTexelOffs		= (.5f / P_rt_size);
		Fmatrix					m_TexelAdjust	= 
		{
			0.5f/*x-scale*/,	0.0f,							0.0f,				0.0f,
			0.0f,				-0.5f/*y-scale*/,				0.0f,				0.0f,
			0.0f,				0.0f,							1.0f/*z-range*/,	0.0f,
			0.5f/*x-bias*/,		0.5f + fTexelOffs/*y-bias*/,	0.0f/*z-bias*/,		1.0f
		};
		R.UVgen.mul				(m_TexelAdjust,mCombine);
		mTemp.scale				(fSlotSize,fSlotSize,1);
		R.UVgen.mulA_44			(mTemp);
		mTemp.translate			(fSlotX+fTexelOffs,fSlotY+fTexelOffs,0);
		R.UVgen.mulA_44			(mTemp);

		// Build bbox and render
		Fvector					min,max;
		Fbox					BB;
		min.set					(R.C.x-p_R,	R.C.y-(p_R+P_cam_range),	R.C.z-p_R);
		max.set					(R.C.x+p_R,	R.C.y+0,					R.C.z+p_R);
		BB.set					(min,max);
		R.UVclamp_min.set		(min).add	(.05f);	// shrink a little
		R.UVclamp_max.set		(max).sub	(.05f);	// shrink a little
		ISpatial*	spatial		= dynamic_cast<ISpatial*>	(O);
		if (spatial)			{
			spatial->spatial_updatesector			();
			if (spatial->spatial.sector)			RImplementation.r_dsgraph_render_R1_box	(spatial->spatial.sector,BB,SE_R1_LMODELS);
		}
		//if (spatial)		RImplementation.r_dsgraph_render_subspace	(spatial->spatial.sector,mCombine,v_C,FALSE);
	}

	// Blur
	/*
	{
		// Fill vertex buffer
		u32							Offset;
		FVF::TL4uv* pv				= (FVF::TL4uv*) RCache.Vertex.Lock	(4,geom_Blur.stride(),Offset);
		RImplementation.ApplyBlur4	(pv,P_rt_size,P_rt_size,P_blur_kernel);
		RCache.Vertex.Unlock		(4,geom_Blur.stride());

		// Actual rendering (pass0, temp2real)
		RCache.set_RT				(RT->pRT);
		RCache.set_ZB				(NULL);
		RCache.set_Shader			(sh_BlurTR	);
		RCache.set_Geometry			(geom_Blur	);
		RCache.Render				(D3DPT_TRIANGLELIST,Offset,0,4,0,2);
	}
	*/

	// Finita la comedia
	Device.Statistic->RenderDUMP_Pcalc.End	();
	
	RCache.set_xform_project	(Device.mProject);
	RCache.set_xform_view		(Device.mView);
}
Example #12
0
void CMatrix::Calculate()
{
	if (dwFrame==Device.dwFrame)	return;
	dwFrame		= Device.dwFrame;

	// Switch on mode
	switch (dwMode) {
		case modeProgrammable:
		case modeDetail:
			return;
		case modeTCM:
			{
				Fmatrix		T;
				float		sU=1,sV=1,t=Device.fTimeGlobal;
				tc_trans	(xform,.5f,.5f);
				if (tcm&tcmRotate) {
					T.rotateZ		(rotate.Calculate(t)*t);
					xform.mulA_43	(T);
				}
				if (tcm&tcmScale) {
					sU				= scaleU.Calculate(t);
					sV				= scaleV.Calculate(t);
					T.scale			(sU,sV,1);
					xform.mulA_43	(T);
				}
				if (tcm&tcmScroll) {
					float u = scrollU.Calculate(t)*t;
					float v = scrollV.Calculate(t)*t;
					u*=sU;
					v*=sV;
					tc_trans	(T, u, v );
					xform.mulA_43	(T);
				}
				tc_trans		(T, -0.5f, -0.5f );
				xform.mulB_43	(T);
			}
			return;
		case modeS_refl:
			{
				float Ux= .5f*Device.mView._11, Uy= .5f*Device.mView._21, Uz= .5f*Device.mView._31, Uw = .5f;
				float Vx=-.5f*Device.mView._12, Vy=-.5f*Device.mView._22, Vz=-.5f*Device.mView._32, Vw = .5f;

				xform._11=Ux; xform._12=Vx; xform._13=0; xform._14=0;
				xform._21=Uy; xform._22=Vy; xform._23=0; xform._24=0;
				xform._31=Uz; xform._32=Vz; xform._33=0; xform._34=0;
				xform._41=Uw; xform._42=Vw; xform._43=0; xform._44=0;
			}
			return;
		case modeC_refl:
			{
				Fmatrix	M	= Device.mView;
				M._41		= 0.f;
				M._42		= 0.f;
				M._43		= 0.f;
				xform.invert(M);
			}
			return;
		default:
			return;
	}
}