source: GTP/branches/IllumWPdeliver2008dec/IlluminationWP/demos/Standalone/PathMap [DirectX]/PathMapEffect.junk @ 3255

#include "dxstdafx.h"
#include ".\pathmapeffect.h"
#include "Material.hpp"
#include "TexturedMaterial.h"
#include "WoodMaterial.hpp"
#include "TriangleMesh.h"
#include "Transformed.h"
#include "Entity.h"
#include "SubEntity.h"
#include "shlwapi.h"
#include <queue>
#include <fstream>


//! D3D vector-matrix multiplication
D3DVECTOR operator *(const D3DVECTOR& v, const D3DMATRIX& m)
{
        D3DVECTOR r;
        r.x = v.x * m._11 + v.y * m._21 + v.z * m._31 + m._41;
        r.y = v.x * m._12 + v.y * m._22 + v.z * m._32 + m._42;
        r.z = v.x * m._13 + v.y * m._23 + v.z * m._33 + m._43;
        float h = v.x * m._14 + v.y * m._24 + v.z * m._34 + m._44;
        if(h > 0.00001f || h < 0.00001f)
        {
                r.x /= h;
                r.y /= h;
                r.z /= h;
        }
        return r;
}

//! method name strings to be displayed on screen
const wchar_t* PathMapEffect::Method::methodNames[10] =
{
        L"PRM",
        L"PRM texture",
        L"_",
        L"_"
        , NULL, NULL, NULL, NULL, NULL, NULL
};

//! method constants
const PathMapEffect::Method PathMapEffect::Method::PRM(0);
const PathMapEffect::Method PathMapEffect::Method::SHOWTEX(1);
const PathMapEffect::Method PathMapEffect::Method::LAST(2);

//! constructor
PathMapEffect::PathMapEffect(LPDIRECT3DDEVICE9 device)
:method(Method::PRM)
{
        NRADIONS = (4096);
        NCLUSTERS = 64;
        DEPTHMAPRES     = 512;


        float* weights = new float[NCLUSTERS];                  
        unsigned int* clusterLenghts = new unsigned int[NCLUSTERS];

        clusterSweepCurrentIndex = 0;

        rayId = 1;
        this->device = device;

        //first person camera allows more freedom of movement
        camera = new CFirstPersonCamera();
        lightCamera = new CFirstPersonCamera();

        HRESULT hr;
        DWORD effectCompileFlag=0;
        
        LPD3DXBUFFER compilationErrors;
        if(FAILED(
                hr = 
                        D3DXCreateEffectFromFile(
                                device,
                                L"pathMap.fx",
                                NULL,
                                NULL,
                                0,
                                NULL,
                                &effect,
                                &compilationErrors) )){
                MessageBoxA( NULL, (LPSTR)compilationErrors->GetBufferPointer(), "Failed to load effect file!", MB_OK);
                exit(-1);
        }

        //store buffers so we can reset them after rendering to texture render targets
        device->GetRenderTarget(0, &frameColorBuffer);
        device->GetDepthStencilSurface(&frameDepthStencilBuffer);
        
        //load empty texture
        D3DXCreateTextureFromFile(device, L"media\\empty.bmp", &emptyTexture);

        //set up a scene

        loadScene("media\\space.txt");

        //load hangar mesh
//      loadMesh( L"media\\hangar.x" );
//      loadMesh( L"media\\fulltexchamber.x" );

/*      //create hangar entity
        Entity e1;
        e1.owner = this;
        e1.renderMesh = renderMeshes.at(0);
        D3DXMatrixIdentity(&e1.modelWorldTransform);
//      D3DXMatrixScaling(&e1.modelWorldTransform, 20.0f, 20.0f, 20.0f);
        D3DXMatrixScaling(&e1.modelWorldTransform, 0.5f, 1.0f, 0.5f);
        D3DXMatrixIdentity(&e1.inverseTransposedModelWorldTransform);
//      D3DXMatrixScaling(&e1.inverseTransposedModelWorldTransform, 1.0f/20.0f, 1.0f/20.0f, 1.0f/20.0f);
        D3DXMatrixScaling(&e1.inverseTransposedModelWorldTransform, 1.0f/0.5f, 1.0f, 1.0f/0.5f);

        e1.createRayTraceEntity();
        
        entities.push_back(e1);


        //load 'steps' mesh
        loadMesh( L"media\\steps.x" );

        //create step entities
        for(int eitor=0; eitor < 4; eitor++)
        {
                D3DXMATRIX urr;
                D3DXMATRIX rx;          D3DXMatrixRotationY(&rx, Vector::PI * 0.5f * eitor);
                Entity e2;
                e2.owner = this;
                e2.renderMesh = renderMeshes.at(1);

                D3DXMatrixTranslation(&urr, -15.0f, -14.0f, -7.0f);
                D3DXMatrixMultiply( &e2.modelWorldTransform, &urr, &rx);
                D3DXMatrixInverse(&e2.inverseTransposedModelWorldTransform, NULL, &e2.modelWorldTransform);

                e2.createRayTraceEntity();
                entities.push_back(e2);

                D3DXMATRIX trasi, roti;
                D3DXMatrixTranslation(&trasi, -15.0f + 7.0f, 14.0f, -7.0f -7.0f);               //7.25f, 13.5, -7.25); //rot 90 -90 90 trans 7.25 13.5 -7.25
                D3DXMatrixRotationYawPitchRoll(&roti, -Vector::PI * 0.5, Vector::PI, 0.0);
                D3DXMatrixMultiply(&urr, &roti, &trasi);

                D3DXMatrixMultiply( &e2.modelWorldTransform, &urr, &rx);

                D3DXMatrixInverse(&e2.inverseTransposedModelWorldTransform, NULL, &e2.modelWorldTransform);
                e2.createRayTraceEntity();
                entities.push_back(e2);
        }
*/

        loadMesh( L"media\\fighter.x", 0, "", 1);

        //compute the surface area of the complete geometry. useful for random sampling.
        sumSurfaceArea = 0.0;
        std::vector<Entity*>::iterator entityIterator = entities.begin();
        while(entityIterator != entities.end())
        {
                sumSurfaceArea += (*entityIterator)->getSurfaceArea();
                entityIterator++;
        }

        //initialize camera
        camera->SetViewParams( &D3DXVECTOR3(0.0f, 0.0f, 4.0f), &D3DXVECTOR3(0.0f, 0.0f, 0.0f));
        D3DSURFACE_DESC fbdesc;
        frameColorBuffer->GetDesc(&fbdesc);
        camera->SetProjParams( D3DX_PI/2, (float)fbdesc.Width / fbdesc.Height, 0.1f, 300.0f );

        //create resources for entities
        createPRMTextures();

        //set up spotlight
        lightCamera->SetViewParams( &D3DXVECTOR3(5.0f, 0.0f, 0.0f), &D3DXVECTOR3(0.0f, 0.0f, 0.0f));
        lightCamera->SetProjParams( D3DX_PI/1.9, 1.0f, 0.1f, 300.0f );

        //create ray tracing kd-tree containing ray-traceable versions of entities 
        Intersectable** objs = new Intersectable*[entities.size()];
        for(int u=0; u<entities.size(); u++)
                objs[u] = entities.at(u).rayTraceEntity;
        kdtree = new KDTree(objs, entities.size());
        delete [] objs;

        //create dummy render target texture for depth map rendering
        device->CreateTexture(DEPTHMAPRES, DEPTHMAPRES, 1, D3DUSAGE_RENDERTARGET, D3DFMT_R32F, D3DPOOL_DEFAULT, &fakeTexture, NULL);
        fakeTexture->GetSurfaceLevel(0, &fakeSurface);

        //create a depthstencil texture for depth map rendering
        device->CreateTexture(DEPTHMAPRES, DEPTHMAPRES, 1,
                D3DUSAGE_DEPTHSTENCIL, D3DFMT_D24X8, D3DPOOL_DEFAULT, &depthMapTexture, NULL);
        depthMapTexture->GetSurfaceLevel(0, &depthMapDepthStencilBuffer);

#ifdef GENERATE_PATH_MAPS
        precompute();
#else
        loadPathMaps();
#endif

        //create a texture for radion data (will be used for weight computations on the GPU)
        device->CreateTexture(2 * NRADIONS / 4096, 4096, 1, 0, D3DFMT_A32B32G32R32F, D3DPOOL_DEFAULT, &radionTexture, NULL);
        radionTexture->GetSurfaceLevel(0, &radionSurface);

        //fill texture with data
        uploadRadions();

        //create weights render target
        device->CreateTexture(4096, NRADIONS / 4096, 1, D3DUSAGE_RENDERTARGET, D3DFMT_R32F, D3DPOOL_DEFAULT, &weightsTexture, NULL);
        weightsTexture->GetSurfaceLevel(0, &weightsSurface);

        //create a sytem memory duplicate of the weights render target to be able to read back weights data
        device->CreateTexture(4096, NRADIONS / 4096, 1, 0, D3DFMT_R32F, D3DPOOL_SYSTEMMEM, &sysMemWeightsTexture, NULL);
        sysMemWeightsTexture->GetSurfaceLevel(0, &sysMemWeightsSurface);

        //create a vertex buffer to be able to visualize entry radion positions
        device->CreateVertexBuffer(NRADIONS * sizeof(float) * 6, D3DUSAGE_WRITEONLY, D3DFVF_XYZ | D3DFVF_NORMAL, D3DPOOL_DEFAULT, 
                &starterVertexBuffer, NULL);
        void* pData;
        starterVertexBuffer->Lock(0, 0, &pData, 0);
        fillRadionPosArray(pData);
        starterVertexBuffer->Unlock();


        exportEntityData();

#ifdef GENERATE_PATH_MAPS
        savePathMaps();
#endif
}

PathMapEffect::~PathMapEffect(void)
{
        delete weights;
        delete clusterLenghts;

        //release all resources allocated in the constructor
        starterVertexBuffer->Release();

        depthMapTexture->Release();
        depthMapDepthStencilBuffer->Release();
        fakeTexture->Release();
        fakeSurface->Release();

        sysMemWeightsTexture->Release();
        sysMemWeightsSurface->Release();
        weightsTexture->Release();
        weightsSurface->Release();
        radionTexture->Release();
        radionSurface->Release();

        delete kdtree;
        emptyTexture->Release();
        releaseTextures();
        releaseMeshes();
        releaseEntities();

        frameColorBuffer->Release();
        frameDepthStencilBuffer->Release();

        effect->Release();
        delete camera;
        delete lightCamera;
}

void PathMapEffect::loadMesh(LPCWSTR fileName, int prmAtlasSize, const char* name, int dividePcs, bool generateUV, bool generateTBN)
{
        Mesh* mesh = new Mesh(this, fileName, prmAtlasSize, name, dividePcs, generateUV, generateTBN);
        meshes.push_back(mesh);

/*      RenderMesh** slabs = new RenderMesh*[dividePcs];
        int* slabNTris = new int[dividePcs];
        int nTris = renderMesh->mesh->GetNumFaces();


        if(dividePcs == 1)
        {
                renderMesh->slabIndex = 0;
                slabs[0] = renderMesh;
                slabNTris[0] = nTris;
        }
        else
        {
                LPDIRECT3DVERTEXBUFFER9 vertexBuffer;
                renderMesh->mesh->GetVertexBuffer(&vertexBuffer);
                D3DVERTEX* vertexData;
                vertexBuffer->Lock(0,renderMesh->mesh->GetNumVertices()*renderMesh->mesh->GetNumBytesPerVertex(),(void**)&vertexData,0);
                LPDIRECT3DINDEXBUFFER9 indexBuffer;
                renderMesh->mesh->GetIndexBuffer(&indexBuffer);
                unsigned short* indexData;
                indexBuffer->Lock(0,nTris*3*sizeof(unsigned short),(void**)&indexData,0);

                Tri* tris = new Tri[nTris];
                //partition to small meshes
                for(int g=0; g<nTris; g++)
                {
                        tris[g].origMeshIndex = g;
                        tris[g].pos =   (vertexData[indexData[g * 3]].pos + 
                                                        vertexData[indexData[g * 3 + 1]].pos + 
                                                        vertexData[indexData[g * 3 + 2]].pos) * 0.33333333333333;
                        tris[g].normal =        (vertexData[indexData[g * 3]].normal + 
                                                        vertexData[indexData[g * 3 + 1]].normal + 
                                                        vertexData[indexData[g * 3 + 2]].normal);
                        tris[g].normal.normalize();
                }


                clusterTrisKMeans(tris, nTris, dividePcs, slabNTris);
                int triClusterStart = 0;

                for(int ict=0; ict<dividePcs; ict++)
                {
                        slabs[ict] = new RenderMesh();
                        slabs[ict]->prmAtlasSize = renderMesh->prmAtlasSize;
                        strcpy(slabs[ict]->name, renderMesh->name);
                        slabs[ict]->slabIndex = ict;
                        slabs[ict]->rayTraceMaterial = renderMesh->rayTraceMaterial;
                        slabs[ict]->nSubsets = renderMesh->nSubsets;
                        slabs[ict]->textures = new LPDIRECT3DTEXTURE9[renderMesh->nSubsets];
                        for(int qu=0; qu < renderMesh->nSubsets; qu++)
                                slabs[ict]->textures[qu] = renderMesh->textures[qu];
                        // count vertices
                        unsigned short* ill = new unsigned short[renderMesh->mesh->GetNumVertices()];
                        for(int zzz=0; zzz<renderMesh->mesh->GetNumVertices(); zzz++)
                                ill[zzz] = 0;
                        for(int rmi = triClusterStart; rmi<triClusterStart + slabNTris[ict]; rmi++)
                        {
                                ill[indexData[tris[rmi].origMeshIndex*3]] = 1;
                                ill[indexData[tris[rmi].origMeshIndex*3+1]] = 1;
                                ill[indexData[tris[rmi].origMeshIndex*3+2]] = 1;
                        }

                        int nVertices = 0;
                        for(int ccc=0; ccc<renderMesh->mesh->GetNumVertices(); ccc++)
                                if(ill[ccc])
                                        nVertices++;

                        // create new mesh
                        HRESULT dhre = D3DXCreateMeshFVF(
                                slabNTris[ict],
                                nVertices,
                                0,
                                D3DFVF_XYZ | D3DFVF_NORMAL | D3DFVF_TEX4 | D3DFVF_TEXCOORDSIZE2(0) | D3DFVF_TEXCOORDSIZE2(1) |
                                D3DFVF_TEXCOORDSIZE3(2) | D3DFVF_TEXCOORDSIZE3(3),
                                device,
                                &slabs[ict]->mesh);
                        // fill with tris
                        LPDIRECT3DVERTEXBUFFER9 svertexBuffer;
                        slabs[ict]->mesh->GetVertexBuffer(&svertexBuffer);
                        D3DVERTEX* svertexData;
                        svertexBuffer->Lock(0, nVertices*slabs[ict]->mesh->GetNumBytesPerVertex(),(void**)&svertexData,0);
                        LPDIRECT3DINDEXBUFFER9 sindexBuffer;
                        slabs[ict]->mesh->GetIndexBuffer(&sindexBuffer);
                        unsigned short* sindexData;
                        sindexBuffer->Lock(0,slabNTris[ict]*3*sizeof(unsigned short),(void**)&sindexData,0);

                        int ufi = 0;
                        for(int ifi=0; ifi<renderMesh->mesh->GetNumVertices(); ifi++)
                                if(ill[ifi])
                                {
                                        svertexData[ufi] = vertexData[ifi];
                                        ill[ifi] = ufi;
                                        ufi++;
                                }
                                else
                                        ill[ifi] = 0xffff;

                        for(int trifi=0; trifi<slabNTris[ict]; trifi++)
                        {
                                sindexData[trifi*3] = ill[indexData[tris[trifi+triClusterStart].origMeshIndex*3]];
                                sindexData[trifi*3+1] = ill[indexData[tris[trifi+triClusterStart].origMeshIndex*3+1]];
                                sindexData[trifi*3+2] = ill[indexData[tris[trifi+triClusterStart].origMeshIndex*3+2]];
                        }

                        svertexBuffer->Unlock();
                        sindexBuffer->Unlock();
                        svertexBuffer->Release();
                        sindexBuffer->Release();

                        triClusterStart += slabNTris[ict];
                }

                vertexBuffer->Unlock();
                indexBuffer->Unlock();
                vertexBuffer->Release();
                indexBuffer->Release();

                renderMesh->mesh->Release();
                delete renderMesh;
        }

        for(unsigned int fi=0; fi < dividePcs; fi++)
        {
                RenderMesh*& renderMesh = slabs[fi];

                //lock the buffers and create ray tracing meshes from the data
                LPDIRECT3DVERTEXBUFFER9 vertexBuffer;
                renderMesh->mesh->GetVertexBuffer(&vertexBuffer);
                D3DVERTEX* vertexData;
                vertexBuffer->Lock(0,renderMesh->mesh->GetNumVertices()*renderMesh->mesh->GetNumBytesPerVertex(),(void**)&vertexData,0);
                LPDIRECT3DINDEXBUFFER9 indexBuffer;
                renderMesh->mesh->GetIndexBuffer(&indexBuffer);
                unsigned short* indexData;
                indexBuffer->Lock(0,renderMesh->mesh->GetNumFaces()*3*sizeof(unsigned short),(void**)&indexData,0);

                //create a TriangleMesh for ray-tracing
                renderMesh->rayTraceMesh = new TriangleMesh(renderMesh->rayTraceMaterial, indexData, renderMesh->mesh->GetNumFaces(),
                        vertexData, renderMesh->mesh->GetNumVertices());

                vertexBuffer->Unlock();
                indexBuffer->Unlock();
                vertexBuffer->Release();
                indexBuffer->Release();

                renderMesh->slabIndex = fi;
                renderMesh->generateUVAtlas();
                renderMesh->buildEdgeVertexBuffer(device);
                renderMeshes.push_back(renderMesh);
        }
        delete [] slabs;*/
}

LPDIRECT3DTEXTURE9 PathMapEffect::loadTexture(LPCWSTR fileName, Material** rayTraceMaterial)
{
        if(fileName == NULL || wcscmp(fileName, L"") == 0)
                return NULL;
        wchar_t* mediaFileName = new wchar_t[wcslen(fileName) + 64];
        //we assume the x file was in folder .\media
        wcscpy(mediaFileName, L"media\\");
        wcscat(mediaFileName, fileName);
        LPDIRECT3DTEXTURE9 tex;

        D3DXIMAGE_INFO bobo;
        if(S_OK != 
                D3DXCreateTextureFromFileEx(device, mediaFileName, D3DX_DEFAULT, D3DX_DEFAULT, 1, 0,
                D3DFMT_FROM_FILE, D3DPOOL_MANAGED, D3DX_DEFAULT, D3DX_DEFAULT, 0, &bobo, NULL, &tex
                ))
        {
                 MessageBox(NULL, mediaFileName, L"Could not load texture file!", MB_OK);
                 return NULL;
        }
        
        materialTextures.push_back(tex);

        if(rayTraceMaterial != NULL)
        {
                D3DLOCKED_RECT lrect;
                HRESULT hr = tex->LockRect(0, &lrect, NULL, D3DLOCK_READONLY);
                LPDIRECT3DSURFACE9 texsurf; 
                tex->GetSurfaceLevel(0, &texsurf);
                D3DSURFACE_DESC desc;
                texsurf->GetDesc(&desc);
                *rayTraceMaterial = new TexturedMaterial(lrect.pBits, lrect.Pitch, desc.Width);
                texsurf->Release();
                tex->UnlockRect(0);
        }
        return tex;
}

void PathMapEffect::releaseTextures()
{
        std::vector<LPDIRECT3DTEXTURE9>::iterator i = materialTextures.begin();
        while(i != materialTextures.end())
        {
                (*i)->Release();
                i++;
        }

        std::vector<Material*>::iterator z = rayTraceMaterials.begin();
        while(z != rayTraceMaterials.end())
        {
                delete (*z);
                z++;
        }
}

void PathMapEffect::releaseMeshes()
{
        std::vector<PathMapEffect::RenderMesh*>::iterator i = renderMeshes.begin();
        while(i != renderMeshes.end())
        {
//              if((*i)->bumpTexture)
//                      (*i)->bumpTexture->Release();
                if((*i)->normalTexture)
                        (*i)->normalTexture->Release();
                (*i)->mesh->Release();
                delete (*i)->rayTraceMesh;
                if((*i)->edgeVertexBuffer)
                        (*i)->edgeVertexBuffer->Release();
                delete *i;
                i++;
        }
}

void PathMapEffect::renderWithPRM()
{
        // first pass: render depth

        device->SetRenderTarget(0, fakeSurface);
        device->SetDepthStencilSurface(depthMapDepthStencilBuffer);
        device->Clear( 0, NULL, D3DCLEAR_ZBUFFER, D3DCOLOR_ARGB(255, 0, 0, 0), 1.0f, 0 );
        //no color writes
        device->SetRenderState(D3DRS_COLORWRITEENABLE, 0);
        //render back faces (avoids Z-fighting, no need for comparison bias)
        device->SetRenderState(D3DRS_CULLMODE, D3DCULL_CW);
        
        if( SUCCEEDED( device->BeginScene() ) )
        {
                effect->SetTechnique("Depth");
                UINT nPasses;
                effect->Begin(&nPasses, 0);
                effect->BeginPass(0);
                //loop through all entities, all mesh subsets, set proper transformations

                std::vector<Entity*>::iterator entityIterator = entities.begin();
                while(entityIterator != entities.end())
                {
                        effect->SetMatrix("modelToProjMatrix", 
                                &( entityIterator->modelWorldTransform * *lightCamera->GetViewMatrix() * *lightCamera->GetProjMatrix() ) );
                        effect->CommitChanges();
                        unsigned int nSubsets = entityIterator->renderMesh->nSubsets;
                        for(int i = 0; i< nSubsets; i++)
                        {
                                entityIterator->renderMesh->mesh->DrawSubset(i);
                        }
                        entityIterator++;
                }

                effect->EndPass();
                effect->End();
                device->EndScene();
        }

        //reset front face rendering, color writes
        device->SetRenderState(D3DRS_CULLMODE, D3DCULL_CCW);
        HRESULT hr = S_OK;
        hr = device->SetRenderState(D3DRS_COLORWRITEENABLE, D3DCOLORWRITEENABLE_ALPHA| D3DCOLORWRITEENABLE_BLUE| D3DCOLORWRITEENABLE_GREEN | D3DCOLORWRITEENABLE_RED);

        // 2. pass: compute weights

        // simple parallel computation for all pixels: no 3D, depth, shadows, only a full-texture quad
        hr = device->SetRenderState(D3DRS_ZENABLE, D3DZB_FALSE);
        hr = device->SetRenderState(D3DRS_STENCILENABLE, false);
        hr = device->SetRenderTarget(0,weightsSurface);
        hr = device->SetDepthStencilSurface(NULL);
        D3DXVECTOR3 lightPos = *lightCamera->GetEyePt();
        D3DXVECTOR3 lightDir = *lightCamera->GetWorldAhead();
        lightDir /= D3DXVec3Length( &lightDir );
        float ffl = parameters->Get(fLightScale) * 10.0f;
        D3DXVECTOR3 lightPower(ffl, ffl, ffl);

        device->Clear( 0, NULL, D3DCLEAR_TARGET,        D3DCOLOR_XRGB(0,0,0), 1.0f, 0 );

        if( SUCCEEDED( device->BeginScene() ) ){
                if( effect != NULL ){
                        D3DXHANDLE hTechnique = NULL;
                        hTechnique = effect->GetTechniqueByName((LPSTR)"ComputeWeights");
                        if(hTechnique==NULL){
                                return;
                        }
                        effect->SetTechnique( hTechnique );

                        UINT nPasses = 0;
                        effect->Begin( &nPasses, 0 );
                        for(UINT j=0;j<nPasses;j++){ 
                                effect->BeginPass(j);
                                hr = effect->SetTexture("radions", radionTexture);
                                static float opttme[9] = {0.5f, 0.0f, 0.0f,
                                                                                0.0f, -0.5f, 0.0f,
                                                                                0.5f + (0.5f / DEPTHMAPRES), 0.5f + (0.5f / DEPTHMAPRES), 1.0f};

                                //set global params
                                effect->SetFloatArray("occProjToTexMatrix", opttme, 9);
                                effect->SetMatrix("occWorldToProjMatrix", &(*lightCamera->GetViewMatrix() * *lightCamera->GetProjMatrix()));

                                effect->SetTexture("depthMap", depthMapTexture);
                                hr = effect->SetInt("nRadionColumns", NRADIONS / 4096);
                                hr = effect->SetFloatArray("lightPower", (float*)&lightPower, 3);
                                hr = effect->SetFloatArray("lightPos", (float*)&lightPos, 3);
                                hr = effect->SetFloatArray("lightDir", (float*)&lightDir, 3);
                                effect->CommitChanges();
                                renderFullScreen();
                                effect->EndPass();
                        }
                        effect->End();
                }
                device->EndScene();
        }

        // read the weights back

        D3DLOCKED_RECT rData;
        hr = device->GetRenderTargetData(weightsSurface, sysMemWeightsSurface);
        hr =  sysMemWeightsSurface->LockRect(&rData, NULL, D3DLOCK_READONLY);
        float* allEntryWeights = (float*)rData.pBits;

        // average weights per cluster
        float sumWeightsAll = 0.0;
        unsigned int iRadion = 0;
        for(int iCluster=0; iCluster < NCLUSTERS; iCluster++)
        {
                weights[iCluster] = 0.0;
                float clusterrad = 0.0;
                for(int clusterSummer=0; clusterSummer < clusterLenghts[iCluster]; clusterSummer++, iRadion++)
                {
                        float radrad = bushStarters[iRadion].radiance.sum();
                        weights[iCluster] += allEntryWeights[iRadion] * radrad;
                        clusterrad += radrad;
                }
                if(clusterrad > 0.01)
                        weights[iCluster] /= clusterrad; //(double)clusterLenghts[iCluster];
                else
                        weights[iCluster] = 0.0f;
//              if(iCluster != TEST_CLUST)
//                      weights[iCluster] = 0.0;
//              if(weights[iCluster] > 0.005)
//                      weights[iCluster] = 0.005;
                sumWeightsAll += weights[iCluster];
        }
        sysMemWeightsSurface->UnlockRect();

        // 3. pass: render scene using weights to combine PRM texture atlases

        
        device->SetRenderTarget(0, frameColorBuffer);
        device->SetDepthStencilSurface(frameDepthStencilBuffer);
        // use backface culling, depth test
        hr = device->SetRenderState(D3DRS_CULLMODE, D3DCULL_CCW);
        hr = device->SetRenderState(D3DRS_ZENABLE, D3DZB_TRUE);

        device->Clear( 0, NULL, D3DCLEAR_TARGET | D3DCLEAR_ZBUFFER,     D3DCOLOR_XRGB(0,0,0), 1.0f, 0 );
        
        if( SUCCEEDED( device->BeginScene() ) )
        {
                effect->SetTechnique("walk");
                UINT nPasses;
                effect->Begin(&nPasses, 0);
                effect->BeginPass(0);

                static float opttme[9] = {0.5f, 0.0f, 0.0f,
                                                                0.0f, -0.5f, 0.0f,
                                                                0.5f + (0.5f / DEPTHMAPRES), 0.5f + (0.5f / DEPTHMAPRES), 1.0f};

                //set global params
                effect->SetFloatArray("occProjToTexMatrix", opttme, 9);
                effect->SetMatrix("occWorldToProjMatrix", &(*lightCamera->GetViewMatrix() * *lightCamera->GetProjMatrix()));

                effect->SetTexture("depthMap", depthMapTexture);

                //loop through entities
                std::vector<PathMapEffect::Entity>::iterator entityIterator = entities.begin();
                while(entityIterator != entities.end())
                {
                        //set entity params
                        // nearestIdx -> bushId
                        float* weightsa = new float[entityIterator->nNearClusters];
                        for(unsigned int y=0; y<entityIterator->nNearClusters; y++)
                        {
//                              Entity e = *entityIterator;
                                weightsa[y] = weights[entityIterator->nearClusterIndices[y]];
                        }
                        hr = effect->SetFloatArray("weightsa", weightsa, entityIterator->nNearClusters);
                        effect->SetMatrix("modelToWorldMatrix", &entityIterator->modelWorldTransform);
                        effect->SetMatrix("inverseTransposedModelToWorldMatrix", &entityIterator->inverseTransposedModelWorldTransform);
                        D3DXMATRIX t = entityIterator->modelWorldTransform;
                        if(parameters->Get(bLookFromLight))
                                effect->SetMatrix("modelToProjMatrix", &(entityIterator->modelWorldTransform * *lightCamera->GetViewMatrix()  * *lightCamera->GetProjMatrix()  ));
                        else
                        {
                                D3DXVECTOR3 wa = *camera->GetWorldAhead();
                                wa = wa * (1.0 / D3DXVec3Length(&wa));
                                D3DXVECTOR3 eye = *camera->GetEyePt();
                                D3DXVECTOR3 shup = -eye * (1.0 / D3DXVec3Length(&eye));
                                float angle = acos(D3DXVec3Dot(&wa, &shup));
                                D3DXMATRIX maro;
                                D3DXVECTOR3 rotax;
                                D3DXVec3Cross(&rotax, &wa, &shup);
                                D3DXMatrixRotationAxis(&maro, &rotax, angle);
                                effect->SetMatrix("modelToProjMatrix", &(entityIterator->modelWorldTransform * maro * *camera->GetViewMatrix() * *camera->GetProjMatrix()  ));
                        }

                        effect->SetTexture("filteredAtlas", entityIterator->prmTexture);
                        effect->SetTexture("bumpMap", entityIterator->renderMesh->bumpTexture);
                        effect->SetTexture("normalMap", entityIterator->renderMesh->normalTexture);
                        hr = effect->SetFloatArray("lightPower", (float*)&lightPower, 3);
                        hr = effect->SetFloatArray("lightPos", (float*)&lightPos, 3);
                        hr = effect->SetFloatArray("lightDir", (float*)&lightDir, 3);
                        
                        int prmnt[2] = {entityIterator->renderMesh->prmxres / entityIterator->renderMesh->prmAtlasSize, 
                                entityIterator->renderMesh->prmyres / entityIterator->renderMesh->prmAtlasSize};
                        hr = effect->SetIntArray("prmAtlasTiles", prmnt, 2);
                        hr = effect->SetFloatArray("atlasHalfPixel", (float*)&Vector(
                                0.5 / entityIterator->renderMesh->prmxres, 0.5 / entityIterator->renderMesh->prmyres, 0.0), 2);

                        unsigned int nSubsets = entityIterator->renderMesh->nSubsets;
                        for(int i = 0; i< nSubsets; i++)
                        {
                                //set subset material texture
                                if(entityIterator->renderMesh->textures[i])
                                        effect->SetTexture("brdfMap", entityIterator->renderMesh->textures[i]);
                                else
                                        effect->SetTexture("brdfMap", emptyTexture);
                                effect->CommitChanges();
                                entityIterator->renderMesh->mesh->DrawSubset(i);
                        }
                        entityIterator++;

                        delete weightsa;
                }
                effect->EndPass();
                effect->End();
                device->EndScene();
        }

        if(!parameters->Get(bLookFromLight))
        if( SUCCEEDED( device->BeginScene() ) )
        {
                effect->SetTechnique("torch");
                UINT nPasses;
                effect->Begin(&nPasses, 0);
                effect->BeginPass(0);

                D3DXMATRIX scaleShip;
                D3DXMatrixScaling(&scaleShip, 0.05f, 0.05f, 0.05f);

                effect->SetTexture("brdfMap", renderMeshes[renderMeshes.size()-1]->textures[0]);
                effect->SetMatrix("modelToProjMatrix", &(scaleShip * *lightCamera->GetWorldMatrix() * *camera->GetViewMatrix()  * *camera->GetProjMatrix()  ));

                effect->CommitChanges();
                renderMeshes[renderMeshes.size()-1]->mesh->DrawSubset(0);

                effect->EndPass();
                effect->End();
                device->EndScene();
        }

}

HRESULT PathMapEffect::RenderMesh::setVertexFormat(DWORD fvf, LPDIRECT3DDEVICE9 device)
{
        LPD3DXMESH tempMesh;

        //clone the mesh to the appropriate format
    HRESULT hr = mesh->CloneMeshFVF( mesh->GetOptions(), 
                                  fvf , 
                                  device, &tempMesh );
        if(hr == S_OK)
        {
                DWORD* padj = new DWORD[mesh->GetNumFaces() * 3];
                mesh->GenerateAdjacency(0.00001f, padj);
                delete padj;
                //forget he old mesh
                mesh->Release();
                //use the cloned mesh
                mesh = tempMesh;
        }
        return hr;
}

HRESULT PathMapEffect::RenderMesh::generateUVAtlas()
{
        LPD3DXMESH tempMesh;

        float maxStretchApplied;
        unsigned int nCharts;

        HRESULT hr =
                D3DXUVAtlasCreate(
                        mesh,           //      LPD3DXMESH pMesh,
                        0,                      //      UINT dwMaxChartNumber,
                        1.0f,           //      FLOAT fMaxStretch,
                        prmAtlasSize - 4,               //      UINT dwWidth,
                        prmAtlasSize - 4,               //      UINT dwHeight,
                        2.0f,           //      FLOAT fGutter,
                        1,                      //      DWORD dwTextureIndex,
                        NULL,           //      CONST DWORD * pdwAdjacency,
                        NULL,           //      CONST CHAR * pcFalseEdges,
                        NULL,           //      FLOAT * pfIMTArray,
                        NULL,           //      LPD3DXUVATLASCB pCallback,
                        0.001f,         //      FLOAT fCallbackFrequency,
            NULL,               //      LPVOID pUserContent,
                        &tempMesh,      //      LPD3DXMESH * ppMeshOut,
                        NULL,           //      LPD3DXBUFFER * ppFacePartitioning,
                        NULL,           //      LPD3DXBUFFER * ppVertexRemapArray,
                        &maxStretchApplied,     //      FLOAT * pfMaxStretchOut,
                        &nCharts                        //      UINT * pdwNumChartsOut
                );

        if(hr == S_OK)
        {
                //forget he old mesh
                mesh->Release();
        }

        hr = 
                D3DXComputeTangentFrameEx(
                        tempMesh,                                       //  ID3DXMesh * pMesh,
                        D3DDECLUSAGE_TEXCOORD,  // DWORD dwTextureInSemantic,
                        0,                                              //  DWORD dwTextureInIndex,
                        D3DDECLUSAGE_TEXCOORD,  // DWORD dwUPartialOutSemantic,
                        2,                                              // DWORD dwUPartialOutIndex,
                        D3DDECLUSAGE_TEXCOORD,  // DWORD dwVPartialOutSemantic,
                        3,                                              // DWORD dwVPartialOutIndex,
                        D3DDECLUSAGE_NORMAL,    // DWORD dwNormalOutSemantic,
                        0,                                              // DWORD dwNormalOutIndex,
                        (D3DXTANGENT_WRAP_UV
//                      | D3DXTANGENT_DONT_ORTHOGONALIZE | D3DXTANGENT_DONT_NORMALIZE_PARTIALS)
                        )& !( D3DXTANGENT_CALCULATE_NORMALS ), // DWORD dwOptions,
                        NULL,                                   // CONST DWORD * pdwAdjacency,
                        0.2,                                    // FLOAT fPartialEdgeThreshold,
                        0.0,                                    // FLOAT fSingularPointThreshold,
                        0.2,                                    // FLOAT fNormalEdgeThreshold,
                        &mesh,                                  // ID3DXMesh ** ppMeshOut,
                        NULL                                    // ID3DXBuffer ** ppVertexMapping
                );

        if(hr == S_OK)
        {
                //forget he old mesh
                tempMesh->Release();
        }

        LPDIRECT3DVERTEXBUFFER9 vertexBuffer;
        mesh->GetVertexBuffer(&vertexBuffer);
        D3DVERTEX* vertexData;
        vertexBuffer->Lock(0,mesh->GetNumVertices()*mesh->GetNumBytesPerVertex(),(void**)&vertexData,0);

        for(unsigned int u=0; u < mesh->GetNumVertices(); u++ )
                vertexData[u].tex1 = (vertexData[u].tex1 * (prmAtlasSize - 4) + D3DXVECTOR2(2.0,2.0)) / (float)prmAtlasSize;

        vertexBuffer->Unlock();
        SAFE_RELEASE(vertexBuffer);

        
//      D3DXSaveMeshToX(L"media/om.x", mesh, NULL, NULL, 0, 0, 1 /*DXFILEFORMAT_TEXT*/);

        return hr;
}

void PathMapEffect::renderFullScreen(float depth)
{
        float fLeftU = 0.0f, fTopV = 0.0f, fRightU = 1.0f, fBottomV = 1.0f;

    D3DSURFACE_DESC dtdsdRT;
    PDIRECT3DSURFACE9 pSurfRT;

    // Acquire render target width and height
    device->GetRenderTarget(0, &pSurfRT);
    pSurfRT->GetDesc(&dtdsdRT);
    pSurfRT->Release();

    // Ensure that we're directly mapping texels to pixels by offset by 0.5
    // For more info see the doc page titled "Directly Mapping Texels to Pixels"
    FLOAT fWidth5 = (FLOAT)dtdsdRT.Width - 0.5f;
    FLOAT fHeight5 = (FLOAT)dtdsdRT.Height - 0.5f;

    // Draw the quad
        struct D3DVERTEX{
                D3DXVECTOR3 pos;
                D3DXVECTOR2 tex0;
        };

    D3DVERTEX svQuad[4];

    svQuad[0].pos=D3DXVECTOR3(-1, 1, depth);
    svQuad[0].tex0 = D3DXVECTOR2(fLeftU, fTopV);

    svQuad[1].pos = D3DXVECTOR3(1, 1, depth);
    svQuad[1].tex0 = D3DXVECTOR2(fRightU, fTopV);

    svQuad[2].pos = D3DXVECTOR3(-1, -1, depth);
    svQuad[2].tex0 = D3DXVECTOR2(fLeftU, fBottomV);

    svQuad[3].pos = D3DXVECTOR3(1, -1, depth);
    svQuad[3].tex0 = D3DXVECTOR2(fRightU, fBottomV);
        
        device->SetRenderState(D3DRS_CULLMODE,D3DCULL_NONE);
        device->SetFVF(D3DFVF_XYZ | D3DFVF_TEX1 | D3DFVF_TEXCOORDSIZE2(0));
    device->DrawPrimitiveUP(D3DPT_TRIANGLESTRIP, 2, svQuad, sizeof(D3DVERTEX));
}

void PathMapEffect::move(float fElapsedTime)
{
        clusterSweepCurrentIndex += fElapsedTime * 2.0f;
        if(clusterSweepCurrentIndex > NCLUSTERS)
                clusterSweepCurrentIndex -= NCLUSTERS;
        //apply some rotation to one of the entities
        if(parameters->Get(bTurbo))
        {
                camera->FrameMove(fElapsedTime * 10.0f);
                lightCamera->FrameMove(fElapsedTime * 10.0f);
        }
        else
        {
                camera->FrameMove(fElapsedTime);
                lightCamera->FrameMove(fElapsedTime);
        }
/*      D3DXMATRIX rot;
        D3DXMatrixRotationY(&rot, fElapsedTime * 0.1f);
        D3DXMatrixMultiply( &entities.at(0).modelWorldTransform, 
                                                &rot,
                                                &entities.at(0).modelWorldTransform);
        D3DXMatrixInverse(  &entities.at(0).inverseTransposedModelWorldTransform, NULL, 
                                                &entities.at(0).modelWorldTransform);
        D3DXMatrixTranspose( &entities.at(0).inverseTransposedModelWorldTransform, &entities.at(0).inverseTransposedModelWorldTransform);

        if(entities.size() > 1)
        {
                D3DXMatrixTranslation(&entities.at(1).modelWorldTransform, 0.0f, parameters->Get(fSecondModelHeight) * 5.0f , 0.0f);
                D3DXMatrixTranslation(&entities.at(1).inverseTransposedModelWorldTransform, 0.0f, -parameters->Get(fSecondModelHeight) * 5.0f , 0.0f);
        }*/
}

LRESULT PathMapEffect::handleMessage( HWND hWnd, UINT uMsg, WPARAM wParam, LPARAM lParam)

{
        if(parameters->Get(bMoveLight))
                return lightCamera->HandleMessages(hWnd, uMsg, wParam, lParam);
        else
                return camera->HandleMessages(hWnd, uMsg, wParam, lParam);
}

void PathMapEffect::addUiParameters(Parameters* parameters)
{
        PathMapEffect::parameters = parameters;
        parameters->Add( bLookFromLight, "Look from light", 1);
        parameters->Add( bMoveLight, "Move light", 1);
        parameters->Add( bDots, "Entry points", 1);
        parameters->Add( bTurbo, "Turbo", 1);
        parameters->Add( fLightScale, "Tone scale", 100, 'V', 'B', convert100);
}

void PathMapEffect::setUiParameterDefaults(Parameters* parameters)
{
}

Parameters*     PathMapEffect::parameters = NULL;

void PathMapEffect::render()
{
        if(method == Method::PRM)
                renderWithPRM();
        else
                showPRMTexture();
        if(parameters->Get(bDots))
        {
                float psf = 8.0f;
                HRESULT hr = device->SetRenderState(D3DRS_POINTSIZE, *((DWORD*)&psf));
                hr = device->SetRenderState(D3DRS_ZENABLE, D3DZB_TRUE);
                if( SUCCEEDED( device->BeginScene() ) )
                {
                        D3DXHANDLE hTechnique = NULL;
                        hTechnique = effect->GetTechniqueByName((LPSTR)"Dots");
                        effect->SetTechnique( hTechnique );
                        UINT nPasses = 0;
                        effect->Begin( &nPasses, 0 );
                        for(UINT j=0;j<nPasses;j++){
                                effect->BeginPass(j);
                                        hr = effect->SetTexture("depthMap",depthMapTexture);
                                        if(parameters->Get(bLookFromLight))
                                                effect->SetMatrix("worldToProjMatrix", &(*lightCamera->GetViewMatrix()  * *lightCamera->GetProjMatrix()  ));
                                        else
                                                effect->SetMatrix("worldToProjMatrix", &(*camera->GetViewMatrix()  * *camera->GetProjMatrix()  ));

                                                        static float opttme[9] = {0.5f, 0.0f, 0.0f,
                                                                0.0f, -0.5f, 0.0f,
                                                                0.5f + (0.5f / DEPTHMAPRES), 0.5f + (0.5f / DEPTHMAPRES), 1.0f};

                                        effect->SetFloatArray("occProjToTexMatrix", opttme, 9);
                                        D3DXVECTOR3 lightPos = *lightCamera->GetEyePt();
                                        hr = effect->SetFloatArray("lightPos", (float*)&lightPos, 3);
                                        effect->CommitChanges();
                                        hr = device->SetFVF(D3DFVF_XYZ |  D3DFVF_NORMAL);
                                        hr = device->SetStreamSource(0, starterVertexBuffer, 0, sizeof(float) * 6);
                                        UINT offset = 0;
                                        for(int iClusterDraw=0; iClusterDraw < NCLUSTERS; iClusterDraw++)
                                        {
//                                              hr = effect->SetFloat("aClusterWeight", weights[iClusterDraw] * 10.0);
                                                hr = effect->SetFloat("aClusterWeight", (float)iClusterDraw);
                                                effect->CommitChanges();
//                                              if(iClusterDraw - clusterSweepCurrentIndex > -1.0 && 
//                                                      iClusterDraw - clusterSweepCurrentIndex < 0.0   )
                                                        device->DrawPrimitive(D3DPT_POINTLIST, offset, clusterLenghts[iClusterDraw]);
                                                offset += clusterLenghts[iClusterDraw];
                                        }
                                effect->EndPass();
                        }
                        effect->End();
                }
                device->EndScene();
        }
}

void PathMapEffect::releaseEntities()
{
        std::vector<PathMapEffect::Entity>::iterator entityIterator = entities.begin();
        while(entityIterator != entities.end())
        {
                delete entityIterator->rayTraceEntity;
                entityIterator->prmSurface->Release();
                entityIterator->prmTexture->Release();
                entityIterator++;
        }       
}

void PathMapEffect::sampleSphereDirection(Vector& outDir)
{
        do{
        outDir = Vector(-1.0 + 2.0 * (float)rand() / RAND_MAX, -1.0 + 2.0 * (float)rand() / RAND_MAX, -1.0 + 2.0 * (float)rand() / RAND_MAX);
        }while(outDir.norm2() > 1.0);
        outDir.normalize();
}

void PathMapEffect::sampleShootingDiffuseDirection(int depth, const Vector& normal, Vector& outDir)
{
        Vector u, v;
        if(fabsf(normal[0]) < 0.9f)
        {
                u.set(0.0f, -normal[2], normal[1]);
                u *= 1.0f / sqrtf(normal[2] * normal[2] + normal[1] * normal[1]);
        }
        else
        {
                u.set(normal[2], 0.0f, -normal[0]);
                u *= 1.0f / sqrtf(normal[2] * normal[2] + normal[0] * normal[0]);
        }
        v.setCrossProduct(normal, u);

        float phi = 2.0f * 3.14159265358979323846f * (float)rand() / RAND_MAX;
        float xi2 = (float)rand() / RAND_MAX;
        float cosPhi = cos(phi);
        float sinPhi = sin(phi);
        float cosTheta = sqrtf(xi2);
        float sinTheta = sqrtf(1.0f - xi2);

        outDir.setScaled(sinTheta * cosPhi, v);
        outDir.addScaled(sinTheta * sinPhi, u);
        outDir.addScaled(cosTheta, normal);
}

void PathMapEffect::precompute()
{
        // generate entry points
        for(unsigned int cRad=0; cRad < NRADIONS; cRad++)
        {
                Radion starter;
                sampleSurfaceRadion(starter);
                //sampleSurfaceRadionUniform(starter);
                bushStarters.push_back(starter);
        }

        // sort entry radions into clusters
        Radion* entryArray = (Radion*)&*bushStarters.begin();
        clusterRadions(entryArray, bushStarters.size(), 0);
        clusterRadionsKMeans();

        // for every entity, find the most relevant clusters
        std::vector<PathMapEffect::Entity>::iterator entityIterator = entities.begin();
        while(entityIterator != entities.end())
        {
                entityIterator->findNearClusters(bushStarters, NCLUSTERS);
                entityIterator++;
        }

        // for every entry radion, shoot a bush of radions, and add their
        // contributions to all PRMs of all entities
        unsigned int iCluster = 0;
        std::vector<Radion> bushRadions;
        for(int iStarter = 0; iStarter < NRADIONS; )
        {
                bushRadions.clear();
                for(int iric=0; iric < clusterLenghts[iCluster]; iric++, iStarter++)
                        shootRadionBush(bushStarters[iStarter], bushRadions);
                std::vector<PathMapEffect::Entity>::iterator entityIterator = entities.begin();
                while(entityIterator != entities.end())
                {
                        entityIterator->renderPRM(bushRadions, iCluster);
                        entityIterator++;
                }
                iCluster++;
        }

        //scale down multiple pixel writes
        entityIterator = entities.begin();
        while(entityIterator != entities.end())
        {
                entityIterator->normalizePRM();
                entityIterator++;
        }
}

int compareX(const void* a, const void* b)
{
        if( ((const Radion*)a)->position.x < ((const Radion*)b)->position.x )
                return -1;
        else
                return 1;
}

int compareY(const void* a, const void* b)
{
        if( ((const Radion*)a)->position.y < ((const Radion*)b)->position.y )
                return -1;
        else
                return 1;
}

int compareZ(const void* a, const void* b)
{
        if( ((const Radion*)a)->position.z < ((const Radion*)b)->position.z )
                return -1;
        else
                return 1;
}

int compareDirX(const void* a, const void* b)
{
        if( ((const Radion*)a)->normal.x < ((const Radion*)b)->normal.x )
                return -1;
        else
                return 1;
}

int compareDirY(const void* a, const void* b)
{
        if( ((const Radion*)a)->normal.y < ((const Radion*)b)->normal.y )
                return -1;
        else
                return 1;
}

int compareDirZ(const void* a, const void* b)
{
        if( ((const Radion*)a)->normal.z < ((const Radion*)b)->normal.z )
                return -1;
        else
                return 1;
}


void PathMapEffect::clusterRadionsKMeans()
{
        Radion centroids[NCLUSTERS];
        std::vector<Radion> clusters[NCLUSTERS];
        //initial clusters: uniform length
        for(unsigned int i=0; i<NCLUSTERS; i++)
                clusterLenghts[i] = NRADIONS / NCLUSTERS;
        for(unsigned int iKMeans = 0; iKMeans < 128; iKMeans++)
        {
                //find centroids
                unsigned int iRadion = 0;
                for(unsigned int i=0; i<NCLUSTERS; i++)
                {
                        centroids[i].position = Vector::RGBBLACK;
                        centroids[i].normal = Vector::RGBBLACK;
                        for(unsigned int iRadionInCluster=0; iRadionInCluster < clusterLenghts[i]; iRadionInCluster++, iRadion++)
                        {
                                centroids[i].position += bushStarters.at(iRadion).position;
                                centroids[i].normal += bushStarters.at(iRadion).normal;
                        }
                        centroids[i].position *= 1.0f / (float)clusterLenghts[i];
                        centroids[i].normal.normalize();
                }
                
                for(unsigned int i=0; i<NCLUSTERS; i++)
                        clusters[i].clear();

                //sort radions to centroids
                iRadion = 0;
                for(unsigned int i=0; i<NCLUSTERS; i++)
                {
                        for(unsigned int iRadionInCluster=0; iRadionInCluster < clusterLenghts[i]; iRadionInCluster++, iRadion++)
                        {
                                unsigned int minimumDistanceClusterIndex = 0;
                                float minimumDistance = FLT_MAX;
                                for(unsigned int u=0; u<NCLUSTERS; u++)
                                {
                                        float dirDist = (bushStarters.at(iRadion).normal * centroids[u].normal);
                                        float dist = (bushStarters.at(iRadion).position - centroids[u].position).norm() * pow(6.0, 1.0 - (double)dirDist);
                                        if(dist < minimumDistance)
                                        {
                                                minimumDistanceClusterIndex = u;
                                                minimumDistance = dist;
                                        }
                                }
                                clusters[minimumDistanceClusterIndex].push_back( bushStarters.at(iRadion) );
                        }
                }
                //refill bushStarters, set cluster lengths
                iRadion = 0;
                for(unsigned int i=0; i<NCLUSTERS; i++)
                {
                        clusterLenghts[i] = clusters[i].size();
                        for(unsigned int iRadionInCluster=0; iRadionInCluster < clusterLenghts[i]; iRadionInCluster++, iRadion++)
                        {
                                bushStarters.at(iRadion) = clusters[i].at(iRadionInCluster);
                        }
                }
                //eliminate empty clusters
                for(unsigned int i=1; i<NCLUSTERS; i++)
                {
                        if(clusterLenghts[i] == 0)
                        {
                                clusterLenghts[i] = clusterLenghts[i-1] >> 1;
                                clusterLenghts[i-1] -= clusterLenghts[i-1] >> 1;
                        }
                }
                for(int i=NCLUSTERS - 1; i >= 0; i--)
                {
                        if(clusterLenghts[i] == 0)
                        {
                                clusterLenghts[i] = clusterLenghts[i+1] >> 1;
                                clusterLenghts[i+1] -= clusterLenghts[i+1] >> 1;
                        }
                }
        }
}

/*void PathMapEffect::clusterTrisKMeans(Tri* triArray, int nTris, int nClusters, int* clusterLenghts)
{
        Tri* centroids = new Tri[nClusters];
        std::vector<Tri>* result = new std::vector<Tri>[nClusters];

        //initial clusters: uniform length
        for(unsigned int i=0; i<nClusters; i++)
                clusterLenghts[i] = nTris / nClusters;
        for(unsigned int iKMeans = 0; iKMeans < 128; iKMeans++)
        {
                //find centroids
                unsigned int iTri = 0;
                for(unsigned int i=0; i<nClusters; i++)
                {
                        centroids[i].pos = Vector::RGBBLACK;
                        centroids[i].normal = Vector::RGBBLACK;
                        for(unsigned int iTriInCluster=0; iTriInCluster < clusterLenghts[i]; iTriInCluster++, iTri++)
                        {
                                centroids[i].pos += triArray[iTri].pos;
                                centroids[i].normal += triArray[iTri].normal;
                        }
                        centroids[i].pos *= 1.0f / (float)clusterLenghts[i];
                        centroids[i].normal.normalize();
                }
                
                for(unsigned int i=0; i<nClusters; i++)
                        result[i].clear();

                //sort radions to centroids
                iTri = 0;
                for(unsigned int i=0; i<nClusters; i++)
                {
                        for(unsigned int iTriInCluster=0; iTriInCluster < clusterLenghts[i]; iTriInCluster++, iTri++)
                        {
                                unsigned int minimumDistanceClusterIndex = 0;
                                float minimumDistance = FLT_MAX;
                                for(unsigned int u=0; u<nClusters; u++)
                                {
                                        float dirDist = (triArray[iTri].normal * centroids[u].normal);
                                        float dist = (triArray[iTri].pos - centroids[u].pos).norm() * pow(6.0, 1.0 - (double)dirDist);
                                        if(dist < minimumDistance)
                                        {
                                                minimumDistanceClusterIndex = u;
                                                minimumDistance = dist;
                                        }
                                }
                                result[minimumDistanceClusterIndex].push_back( triArray[iTri] );
                        }
                }
                //refill bushStarters, set cluster lengths
                iTri = 0;
                for(unsigned int i=0; i<nClusters; i++)
                {
                        clusterLenghts[i] = result[i].size();
                        for(unsigned int iTriInCluster=0; iTriInCluster < clusterLenghts[i]; iTriInCluster++, iTri++)
                        {
                                triArray[iTri] = result[i].at(iTriInCluster);
                        }
                }
                //eliminate empty clusters
                for(unsigned int i=1; i<nClusters; i++)
                {
                        if(clusterLenghts[i] == 0)
                        {
                                clusterLenghts[i] = clusterLenghts[i-1] >> 1;
                                clusterLenghts[i-1] -= clusterLenghts[i-1] >> 1;
                        }
                }
                for(int i=nClusters - 1; i >= 0; i--)
                {
                        if(clusterLenghts[i] == 0)
                        {
                                clusterLenghts[i] = clusterLenghts[i+1] >> 1;
                                clusterLenghts[i+1] -= clusterLenghts[i+1] >> 1;
                        }
                }
        }
        delete [] centroids;
        delete [] result;
}
*/

int PathMapEffect::clusterRadions(Radion* partition, int psize, char axis)
{
/*      if(psize < 2)
                return 1;
        if(axis == 0)
                qsort(partition, psize, sizeof(Radion), compareDirX);
        else if(axis == 1)
                qsort(partition, psize, sizeof(Radion), compareDirY);
        else if(axis == 2)
                qsort(partition, psize, sizeof(Radion), compareDirZ);
        else if(axis == 3)
                qsort(partition, psize, sizeof(Radion), compareX);
        else if(axis == 4)
                qsort(partition, psize, sizeof(Radion), compareY);
        else if(axis == 5)
                qsort(partition, psize, sizeof(Radion), compareZ);
        clusterRadions(partition, psize >> 1, (axis+1)%6);
        clusterRadions(partition + (psize >> 1), psize - (psize >> 1), (axis+1)%6);
        return 1;
/*/     if(psize < 2)
                return 1;
        if(axis == 0)
                qsort(partition, psize, sizeof(Radion), compareX);
        else if(axis == 1)
                qsort(partition, psize, sizeof(Radion), compareY);
        else if(axis == 2)
                qsort(partition, psize, sizeof(Radion), compareZ);
        clusterRadions(partition, psize >> 1, (axis+1)%3);
        clusterRadions(partition + (psize >> 1), psize - (psize >> 1), (axis+1)%3);
        return 1;//*/
}


void PathMapEffect::shootRadionBush(Radion& starter, std::vector<Radion>& bushRadions)
{
        bushRadions.push_back(starter);

        int nPhotonsShotForLight = 1;   //branching factor
        for(int iPhoton = 0; iPhoton < nPhotonsShotForLight; iPhoton++)
        {
                unsigned int depth = 0;
                ray.id = rayId++;
                ray.isShadowRay = false;
                ray.origin = starter.position;
                Vector power = starter.radiance;
                float prob = starter.probability;
                prob *= nPhotonsShotForLight;
                power *= 1.0f / nPhotonsShotForLight;
                sampleShootingDiffuseDirection(depth, starter.normal, ray.dir);

                for(;;depth++)
                {
                        kdtree->traverse(ray, hitRec, 0.0f, FLT_MAX);
                        if(hitRec.isIntersect)
                        {
                                Radion nr;
                                nr.position = hitRec.point;
                                nr.normal = hitRec.normal;
                                nr.radiance = power;
                                nr.radiance %= hitRec.material->getTextureDiffuseBrdf(hitRec.texUV);
                                nr.probability = prob;
                                bushRadions.push_back(nr);
                        }
                        else
                                break;
                        if(depth >= 3)
                                break;
                        float rrRandom = (float)rand() / RAND_MAX;
                        float diffuseAlbedo = hitRec.material->getTextureDiffuseAlbedo(hitRec.texUV);
                        float idealAlbedo = hitRec.material->getTextureIdealAlbedo(hitRec.texUV);
                        float refractiveAlbedo = hitRec.material->getRefractiveAlbedo();
                        if(rrRandom < diffuseAlbedo)
                        {
                                ray.id = rayId++;
                                ray.isShadowRay = false;
                                ray.origin = hitRec.point;
                                power %= hitRec.material->getTextureDiffuseBrdf(hitRec.texUV);
                                power *= 1.0f / diffuseAlbedo;
                                prob *= diffuseAlbedo;
                                sampleShootingDiffuseDirection(depth, hitRec.normal, ray.dir);
                        }
                        else
                        {
                                rrRandom -= diffuseAlbedo;
                                if(rrRandom < idealAlbedo)
                                {
                                        ray.dir.setIdealReflectedDirection(ray.dir, hitRec.normal);
                                        ray.id = rayId++;
                                        ray.isShadowRay = false;
                                        ray.origin = hitRec.point;
                                        power %= hitRec.material->getIdealBrdf();
                                        power *= 1.0f / idealAlbedo;
                                        prob *= idealAlbedo;
                                }
                                else
                                        break;
                        }
                }
        }
}

void PathMapEffect::sampleSurfaceRadion(Radion& starter)
{
        float randa = ((double)rand() / RAND_MAX) * entities.size();
//&     float randa = ((double)rand() / RAND_MAX) * sumSurfaceArea;
        float uptonowSurfaceArea = 0.0;
        Entity* e = NULL;
        std::vector<Entity*>::iterator entityIterator = entities.begin();
        while(entityIterator != entities.end())
        {
                uptonowSurfaceArea += 1.0f;
//&             uptonowSurfaceArea += (*entityIterator)->getSurfaceArea();
                if(uptonowSurfaceArea >= randa)
                {
                        e = *entityIterator;
                        break;
                }
                entityIterator++;
        }

        SubEntity* se = e->sampleSurface(starter);

        float surfa = starter.radiance.z;

        Vector rtexc = starter.radiance;
        starter.radiance = se->getRayTraceEntity()->getMaterial()->getTextureDiffuseBrdf(rtexc);
        starter.radiance *= (surfa / NRADIONS) * entities.size();
//&     starter.radiance *= sumSurfaceArea / NRADIONS;
        starter.probability = (float)NRADIONS / (entities.size() * surfa );
}

void PathMapEffect::sampleSurfaceRadionUniform(Radion& starter)
{
        float randa = ((double)rand() / RAND_MAX) * sumSurfaceArea;
        float uptonowSurfaceArea = 0.0;
        Entity* e = NULL;
        std::vector<Entity*>::iterator entityIterator = entities.begin();
        while(entityIterator != entities.end())
        {
                uptonowSurfaceArea += (*entityIterator)->getSurfaceArea();
                if(uptonowSurfaceArea >= randa)
                {
                        e = *entityIterator;
                        break;
                }
                entityIterator++;
        }

        SubEntity* se = e->sampleSurface(starter);

        float surfa = starter.radiance.z;

        Vector rtexc = starter.radiance;
        starter.radiance = se->getRayTraceEntity()->getMaterial()->getTextureDiffuseBrdf(rtexc);
        starter.radiance *= sumSurfaceArea / NRADIONS;
        starter.probability = (float)NRADIONS / (entities.size() * surfa );
}


/*
void PathMapEffect::showPRMTexture()
{
        device->SetRenderTarget(0, frameColorBuffer);
        device->SetDepthStencilSurface(frameDepthStencilBuffer);

        device->Clear( 0, NULL, D3DCLEAR_TARGET | D3DCLEAR_ZBUFFER,     D3DCOLOR_XRGB(0,0,0), 1.0f, 0 );

        if( SUCCEEDED( device->BeginScene() ) ){
                if( effect != NULL ){
                        D3DXHANDLE hTechnique = effect->GetTechniqueByName((LPSTR)"ShowTex");
                        if(hTechnique==NULL){
                                return;
                        }
                        effect->SetTechnique( hTechnique );
                        UINT nPasses = 0;
                        effect->Begin( &nPasses, 0 );
                        for(UINT j=0;j<nPasses;j++){
                                effect->BeginPass(j);
                
                                //loop through entities
                                std::vector<PathMapEffect::Entity>::iterator entityIterator = entities.begin();
                                //while(entityIterator != entities.end())
                                {
                                        //set entity params
                                        effect->SetMatrix("modelToWorldMatrix", &entityIterator->modelWorldTransform);
                                        effect->SetMatrix("inverseTransposedModelToWorldMatrix", &entityIterator->inverseTransposedModelWorldTransform);
                                        D3DXMATRIX t = entityIterator->modelWorldTransform;
                                        if(parameters->Get(bLookFromLight))
                                                effect->SetMatrix("modelToProjMatrix", &(entityIterator->modelWorldTransform * *lightCamera->GetViewMatrix()  * *lightCamera->GetProjMatrix()  ));
                                        else
                                                effect->SetMatrix("modelToProjMatrix", &(entityIterator->modelWorldTransform * *camera->GetViewMatrix()  * *camera->GetProjMatrix()  ));

                                        effect->SetTexture("filteredAtlas", entityIterator->prmTexture);

                                        unsigned int nSubsets = entityIterator->renderMesh->nSubsets;
                                        for(int i = 0; i< nSubsets; i++)
                                        {
                                                //set subset material texture
                                                effect->SetTexture("texToShow", entityIterator->prmTexture);
                                                effect->CommitChanges();
                                                renderFullScreen();
//                                              effect->CommitChanges();
//                                              entityIterator->renderMesh->mesh->DrawSubset(i);
                                        }
                                        entityIterator++;
                                }
                                effect->EndPass();
                        }
                        effect->End();
                }
                device->EndScene();
        }

}
*/

void PathMapEffect::uploadRadions()
{
        int nRadions = bushStarters.size();
        struct TMR{
                float pos[4];
                float dir[4];
//              float pow[4];
        };
        TMR* tm = new TMR[nRadions];
        for(int i=0; i<nRadions; i++)
        {
//*
                tm[i].pos[0] = bushStarters[i].position[0];
                tm[i].pos[1] = bushStarters[i].position[1];
                tm[i].pos[2] = bushStarters[i].position[2];
                tm[i].pos[3] = 1.0;
                tm[i].dir[0] = bushStarters[i].normal[0];
                tm[i].dir[1] = bushStarters[i].normal[1];
                tm[i].dir[2] = bushStarters[i].normal[2];
                tm[i].dir[3] = 1.0;
//              tm[i].pow[0] = bushStarters[i].radiance[0];
//              tm[i].pow[1] = bushStarters[i].radiance[1];
//              tm[i].pow[2] = bushStarters[i].radiance[2];
//              tm[i].pow[3] = 1.0;
/*/
                tm[i].pos[0] = 0.9;
                tm[i].pos[1] = 0.2;
                tm[i].pos[2] = 0.2;
                tm[i].pos[3] = 1.0;
                tm[i].dir[0] = 0.2;
                tm[i].dir[1] = 0.9;
                tm[i].dir[2] = 0.2;
                tm[i].dir[3] = 1.0;
                tm[i].pow[0] = 0.2;
                tm[i].pow[1] = 0.2;
                tm[i].pow[2] = 0.9;     //blue
                tm[i].pow[3] = 0.99;
//*/
        }

        RECT imgSize;
        imgSize.top = imgSize.left = 0;
        imgSize.bottom =  nRadions;
        imgSize.right = 2 * nRadions / 4096;
        D3DXLoadSurfaceFromMemory(radionSurface, NULL, NULL, tm, D3DFMT_A32B32G32R32F, 
                imgSize.right * 4 * sizeof(float), NULL, &imgSize, D3DX_FILTER_NONE, 0);

        delete [] tm;
}

void PathMapEffect::fillRadionPosArray(void* pData)
{
        int nRadions = NRADIONS;
        struct TMR{
                float pos[3];
                float rad[3];
        };
        TMR* tm = (TMR*)pData;
        for(int i=0; i<nRadions; i++)
        {
                tm[i].pos[0] = bushStarters[i].position[0];
                tm[i].pos[1] = bushStarters[i].position[1];
                tm[i].pos[2] = bushStarters[i].position[2];
                tm[i].rad[0] = bushStarters[i].radiance[0];
                tm[i].rad[1] = bushStarters[i].radiance[1];
                tm[i].rad[2] = bushStarters[i].radiance[2];
        }
}

const wchar_t* PathMapEffect::getWeightsString()
{
        static wchar_t ws[512];
        ws[0] = 0;
        char wan[64];
        float sumw = 0.0f;
        for(int i=0; i<33; i++)
        {
//              StrCpy(wan, L"%f ");
                if(i == 32)
                        sprintf(wan, "%.3f ", (double)sumw);
                else
                {
                        sumw += weights[i];
                        sprintf(wan, "%.3f ", (double)weights[i]);
                }
                wchar_t* wideValue = new wchar_t[MultiByteToWideChar(CP_ACP, 0, wan, -1, NULL, 0)];
                MultiByteToWideChar(CP_ACP, 0, wan, -1, wideValue, 511);
                StrCatW(ws, wideValue);
                delete wideValue;
        }
        return ws;
}


void PathMapEffect::savePathMaps()
{
        std::fstream entryPointFile("prm\\prmEntryPoints.dat", std::ios::out | std::ios::binary);

        for(unsigned int u=0; u < NRADIONS; u++)
        {
                entryPointFile << bushStarters.at(u);
        }
        
        for(unsigned int c=0; c < NCLUSTERS; c++)
        {
                entryPointFile.write((char*)&clusterLenghts[c], sizeof(unsigned int));
        }

        entryPointFile.flush();
        entryPointFile.close();

        unsigned int iEntity = 0;
        std::vector<Entity*>::iterator entityIterator = entities.begin();
        while(entityIterator != entities.end())
        {
                (*entityIterator)->savePRMs();

                entityIterator++;
                iEntity++;
        }

}

void PathMapEffect::loadPathMaps()
{
        std::fstream entryPointFile("prm\\prmEntryPoints.dat", std::ios::in | std::ios::binary);

        bushStarters.clear();

        for(unsigned int u=0; u < NRADIONS; u++)
        {
                Radion ri;
                entryPointFile >> ri;
                bushStarters.push_back(ri);
        }
        
        for(unsigned int c=0; c < NCLUSTERS; c++)
        {
                entryPointFile.read((char*)&clusterLenghts[c], sizeof(unsigned int));           
        }

        entryPointFile.close();

        unsigned int iEntity = 0;
        std::vector<Entity*>::iterator entityIterator = entities.begin();
        while(entityIterator != entities.end())
        {
                entityIterator->findNearClusters(bushStarters, NCLUSTERS);

                wchar_t prmFileName[256];
//              wsprintf(prmFileName, L"prm\\prm_%08d.hdr", iEntity);
                MultiByteToWideChar(CP_ACP, 0, entityIterator->prmfilename, -1, prmFileName, 255);
                D3DXLoadSurfaceFromFile(entityIterator->prmSurface, NULL, NULL, prmFileName, NULL, D3DX_DEFAULT, 0, NULL);
                entityIterator++;
                iEntity++;
        }
}

void PathMapEffect::exportEntityData()
{
        std::fstream entryPointFile("media\\entityPathMapData.txt", std::ios::out);

        unsigned int iEntity = 0;
        std::vector<PathMapEffect::Entity>::iterator entityIterator = entities.begin();
        while(entityIterator != entities.end())
        {
                entryPointFile << "entity " << entityIterator->name << '\n';
                entryPointFile << "{" << '\n';
                entryPointFile << " pathmapfile " << entityIterator->prmfilename << '\n';
                entryPointFile << " clusters ";
                for(int i=0; i<entityIterator->nNearClusters; i++)
                        entryPointFile << entityIterator->nearClusterIndices[i] << " ";
                entryPointFile << '\n';
                entryPointFile << "}" << '\n';
                entryPointFile << '\n';

//              for(int i=0; i<16; i++)
//                      entryPointFile << entityIterator->modelWorldTransform.m[i%4][i/4] << " ";
                entryPointFile << '\n';
                entityIterator++;
                iEntity++;
        }

        entryPointFile.flush();
        entryPointFile.close();

}

void PathMapEffect::loadScene(const char* sceneFileName)
{
        std::fstream sceneFile(sceneFileName, std::ios::in);

        char keyword[256];
        while(!sceneFile.eof())
        {
                sceneFile >> keyword;
                if(strcmp(keyword, "mesh") == 0)
                {
                        int meshAtlasSize = 128;
                        bool needsUV = true;
                        bool needsTBN = false;
                        int dividePcs = 1;
                        double bumpScale = 1.0;
                        char meshname[256];
                        wchar_t* wide = NULL;
                        wchar_t* wBump = NULL;
                        Vector color = Vector::RGBWHITE;

                        sceneFile >> meshname;
                        if(strcmp(meshname, "{") == 0)
                                strcpy(meshname, "mesh");
                        while(strcmp(keyword, "}") != 0 && !sceneFile.eof())
                        {
                                sceneFile >> keyword;
                                if(strcmp(keyword, "xfile") == 0)
                                {
                                        sceneFile >> keyword;
                                        if(keyword)
                                        {
                                                wide = L::l+keyword;
                                        }

                                }
                                if(strcmp(keyword, "pathmapresolution") == 0)
                                {
                                        sceneFile >> meshAtlasSize;
                                }
                                if(strcmp(keyword, "divide") == 0)
                                {
                                        sceneFile >> dividePcs;
                                }
                        }
                        if(wide)
                        {
                                loadMesh(wide, meshAtlasSize, meshname, dividePcs, needsUV, needsTBN);
                                delete wide;
                        }

                }

                if(strcmp(keyword, "entity") == 0)
                {
                        Entity e;
                        e.owner = this;

                        char entityname[256];
                        sceneFile >> entityname;
                        if(strcmp(entityname, "{") == 0)
                                strcpy(entityname, "noname");

                        strcpy(e.name, entityname);

                        while(strcmp(keyword, "}") != 0 && !sceneFile.eof())
                        {
                                sceneFile >> keyword;
                                if(strcmp(keyword, "pathmapfile") == 0)
                                {
                                        sceneFile >> keyword;
                                        strcpy(e.prmfilename, keyword);
                                }
                                if(strcmp(keyword, "mesh") == 0)
                                {
                                        sceneFile >> keyword;

                                        std::vector<PathMapEffect::RenderMesh*>::iterator i = renderMeshes.begin();
                                        while(i != renderMeshes.end())
                                        {
                                                if(strcmp((*i)->name, keyword) == 0)
                                                {
                                                        e.renderMesh = *i;
                                                        break;
                                                }
                                                i++;
                                        }
                                }
                                if(strcmp(keyword, "transformation") == 0)
                                {
                                        for(int i=0; i<16; i++)
                                                sceneFile >> e.modelWorldTransform.m[i%4][i/4];
                                        D3DXMatrixInverse(&e.inverseTransposedModelWorldTransform, NULL, &e.modelWorldTransform);
                                }
                                if(strcmp(keyword, "pathmapclusters") == 0)
                                {
                                        sceneFile >> e.nNearClusters;
                                }
                        }
                        std::vector<PathMapEffect::RenderMesh*>::iterator i = renderMeshes.begin();
                        while(i != renderMeshes.end())
                        {
                                if(strcmp((*i)->name, e.renderMesh->name) == 0)
                                {
                                        Entity eslab;
                                        eslab.renderMesh = *i;
                                        sprintf(eslab.prmfilename, "%s_s%d.hdr", e.prmfilename, eslab.renderMesh->slabIndex);
                                        eslab.modelWorldTransform = e.modelWorldTransform;
                                        eslab.inverseTransposedModelWorldTransform = e.inverseTransposedModelWorldTransform;
                                        eslab.owner = this;
                                        eslab.nNearClusters = e.nNearClusters;

                                        eslab.createRayTraceEntity();
                                        entities.push_back(eslab);
                                }
                                i++;
                        }
                }
        }
        sceneFile.close();
}


LPDIRECT3DSURFACE9 renderScene(const RenderStrategy& renderStrategy)
{
        renderStrategy.applyTargets(this);

        renderStrategy.applyRenderState();

        if( SUCCEEDED( device->BeginScene() ) )
        {
                renderStrategy.applyTechnique();
                UINT nPasses;
                effect->Begin( &nPasses, 0 );
                for(UINT j=0;j<nPasses;j++)
                {
                        effect->BeginPass(j);

                        //loop through all entities
                        std::vector<Entity>::iterator entityIterator = pathMapEffect->entities.begin();
                        while(entityIterator != pathMapEffect->entities.end())
                        {

                                (*entityIterator)->drawAllSubEntities(renderStrategy);
                                entityIterator++;
                        }

                        effect->EndPass();
                }
                effect->End();
                device->EndScene();
        }

        renderStrategy.resetRenderState();

}