Exemplo n.º 1
0
//------------------------------------------------------------------------------
static void
createHbrMesh(Shape * shape, int maxlevel) {

    Stopwatch s;
    s.Start();

    // create Hbr mesh using functions from hbr_utils
    Hmesh * hmesh = createMesh<Vertex>(shape->scheme, /*fvarwidth*/ 0);

    createVerticesWithPositions<Vertex>(shape, hmesh);

    createTopology<Vertex>(shape, hmesh, shape->scheme);
    s.Stop();

    std::vector<Hface const *>   coarseFaces,  // list of Hbr coarse faces
                                 refinedFaces; // list of Hbr faces refined at maxlevel

    int nfaces = hmesh->GetNumFaces();

    { // create control cage GL mesh
        coarseFaces.resize(nfaces);
        for (int i=0; i<nfaces; ++i) {
            coarseFaces[i] = hmesh->GetFace(i);
        }

        GLMesh::Options coarseOptions;
        coarseOptions.vertColorMode=GLMesh::VERTCOLOR_BY_SHARPNESS;
        coarseOptions.edgeColorMode=GLMesh::EDGECOLOR_BY_SHARPNESS;
        coarseOptions.faceColorMode=GLMesh::FACECOLOR_SOLID;

        g_base_glmesh.Initialize(coarseOptions, coarseFaces);
        g_base_glmesh.InitializeDeviceBuffers();
    }

    { // create maxlevel refined GL mesh
        s.Start();

        OpenSubdiv::Far::PatchTables const * patchTables = 0;

        if (g_Adaptive) {
            int maxvalence = RefineAdaptive(*hmesh, maxlevel, refinedFaces);

            patchTables = CreatePatchTables(*hmesh, maxvalence);

            patchTables->GetNumPatches();

            delete patchTables;
        } else {
            RefineUniform(*hmesh, maxlevel, refinedFaces);
        }

        s.Stop();
        //printf("Hbr time: %f ms\n", float(s.GetElapsed())*1000.0f);

        if (g_HbrDrawVertIDs) {
            createVertNumbers(refinedFaces);
        }

        // Hbr is a half-edge rep, so edges do not have unique IDs that
        // can be displayed

        if (g_HbrDrawEdgeSharpness) {
            createEdgeNumbers(refinedFaces);
        }

        if (g_HbrDrawFaceIDs) {
            createFaceNumbers(refinedFaces, /*ptex*/ false);
        }

        if (g_HbrDrawPtexIDs) {
            createFaceNumbers(refinedFaces, /*ptex*/ true);
        }

        GLMesh::Options refinedOptions;
        refinedOptions.vertColorMode=GLMesh::VERTCOLOR_BY_SHARPNESS;
        refinedOptions.edgeColorMode=GLMesh::EDGECOLOR_BY_SHARPNESS;
        refinedOptions.faceColorMode=GLMesh::FACECOLOR_SOLID;

        g_hbr_glmesh.Initialize(refinedOptions, refinedFaces);
        g_hbr_glmesh.SetDiffuseColor(1.0f,0.75f,0.9f, 1.0f);
    }

    g_hbr_glmesh.InitializeDeviceBuffers();

    delete hmesh;
}
Exemplo n.º 2
0
//------------------------------------------------------------------------------
static void
createVtrMesh(Shape * shape, int maxlevel) {

    Stopwatch s;
    s.Start();

    // create Vtr mesh (topology)
    OpenSubdiv::Sdc::Type       sdctype = GetSdcType(*shape);
    OpenSubdiv::Sdc::Options sdcoptions = GetSdcOptions(*shape);

    OpenSubdiv::Far::TopologyRefiner * refiner =
        OpenSubdiv::Far::TopologyRefinerFactory<Shape>::Create(sdctype, sdcoptions, *shape);

    OpenSubdiv::Far::PatchTables * patchTables = 0;

    if (g_Adaptive) {

        refiner->RefineAdaptive(maxlevel, /*fullTopology*/true);

        patchTables = OpenSubdiv::Far::PatchTablesFactory::Create(*refiner);

        g_numPatches = patchTables->GetNumPatches();
    } else {
        refiner->RefineUniform(maxlevel, /*fullTopology*/true);
    }
    s.Stop();

    // create vertex primvar data buffer
    std::vector<Vertex> vertexBuffer(refiner->GetNumVerticesTotal());
    Vertex * verts = &vertexBuffer[0];

    //printf("Vtr time: %f ms (topology)\n", float(s.GetElapsed())*1000.0f);

    // copy coarse vertices positions
    int ncoarseverts = shape->GetNumVertices();
    for (int i=0; i<ncoarseverts; ++i) {
        float * ptr = &shape->verts[i*3];
        verts[i].SetPosition(ptr[0], ptr[1], ptr[2]);
    }

//#define no_stencils
#ifdef no_stencils
    {
        s.Start();
        // populate buffer with Vtr interpolated vertex data
        refiner->Interpolate(verts, verts + ncoarseverts);
        s.Stop();
        //printf("          %f ms (interpolate)\n", float(s.GetElapsed())*1000.0f);
        //printf("          %f ms (total)\n", float(s.GetTotalElapsed())*1000.0f);
    }
#else
    {
        OpenSubdiv::Far::StencilTablesFactory::Options options;
        options.generateOffsets=true;
        options.generateAllLevels=true;
        options.sortBySize=false;

        OpenSubdiv::Far::StencilTables const * stencilTables =
            OpenSubdiv::Far::StencilTablesFactory::Create(*refiner, options);

        stencilTables->UpdateValues(verts, verts + ncoarseverts);
    }
#endif

    if (g_VtrDrawVertIDs) {
        createVertNumbers(*refiner, vertexBuffer);
    }

    if (g_VtrDrawFaceIDs) {
        createFaceNumbers(*refiner, vertexBuffer);
    }

    if (g_VtrDrawPtexIDs and patchTables) {
        createPtexNumbers(*patchTables, vertexBuffer);
    }

    if (g_Adaptive and patchTables) {
        createPatchNumbers(*patchTables, vertexBuffer);
    }

    createEdgeNumbers(*refiner, vertexBuffer, g_VtrDrawEdgeIDs!=0, g_VtrDrawEdgeSharpness!=0);

    GLMesh::Options options;
    options.vertColorMode=g_Adaptive ? GLMesh::VERTCOLOR_BY_LEVEL : GLMesh::VERTCOLOR_BY_SHARPNESS;
    options.edgeColorMode=g_Adaptive ? GLMesh::EDGECOLOR_BY_PATCHTYPE : GLMesh::EDGECOLOR_BY_SHARPNESS;
    options.faceColorMode=g_Adaptive ? GLMesh::FACECOLOR_BY_PATCHTYPE :GLMesh::FACECOLOR_SOLID;

    if (g_Adaptive) {
        g_vtr_glmesh.Initialize(options, *refiner, patchTables, (float *)&verts[0]);
        g_vtr_glmesh.SetDiffuseColor(1.0f, 1.0f, 1.0f, 1.0f);
    } else {
        g_vtr_glmesh.Initialize(options, *refiner, patchTables, (float *)&verts[0]);
        g_vtr_glmesh.SetDiffuseColor(0.75f, 0.9f, 1.0f, 1.0f);
    }


    //setFaceColors(*refiner);

    g_vtr_glmesh.InitializeDeviceBuffers();

    delete refiner;
    delete patchTables;
}
Exemplo n.º 3
0
//------------------------------------------------------------------------------
static void
createFarGLMesh(Shape * shape, int maxlevel) {

    Stopwatch s;
    s.Start();

    using namespace OpenSubdiv;

    // create Far mesh (topology)
    Sdc::SchemeType sdctype = GetSdcType(*shape);
    Sdc::Options    sdcoptions = GetSdcOptions(*shape);

    sdcoptions.SetFVarLinearInterpolation(g_fvarInterpolation);

    Far::TopologyRefiner * refiner =
        Far::TopologyRefinerFactory<Shape>::Create(*shape,
            Far::TopologyRefinerFactory<Shape>::Options(sdctype, sdcoptions));

    if (g_Adaptive) {
        Far::TopologyRefiner::AdaptiveOptions options(maxlevel);
        options.useSingleCreasePatch = false;
        refiner->RefineAdaptive(options);
    } else {
        Far::TopologyRefiner::UniformOptions options(maxlevel);
        options.fullTopologyInLastLevel = true;
        refiner->RefineUniform(options);
    }

    int numTotalVerts = refiner->GetNumVerticesTotal();

    //
    // Patch table
    //
    std::vector<Vertex> fvarBuffer;
    Far::PatchTable * patchTable = 0;
    bool createFVarWire = g_FarDrawFVarPatches or g_FarDrawFVarVerts;

    if (g_Adaptive) {
        Far::PatchTableFactory::Options options;
        options.generateFVarTables = createFVarWire;
        options.shareEndCapPatchPoints = false;

        patchTable =
            Far::PatchTableFactory::Create(*refiner, options);

        // increase vertex buffer for the additional local points
        if (patchTable->GetLocalPointStencilTable()) {
            numTotalVerts += patchTable->GetLocalPointStencilTable()->GetNumStencils();
        }

        g_numPatches = patchTable->GetNumPatchesTotal();
        g_maxValence = patchTable->GetMaxValence();

        if (createFVarWire) {

            // interpolate fvar values

            int channel = 0;

            // XXXX should use a (u,v) vertex class
            fvarBuffer.resize(refiner->GetNumFVarValuesTotal(channel), 0);
            Vertex * values = &fvarBuffer[0];

            int nCoarseValues = refiner->GetLevel(0).GetNumFVarValues(channel);

            for (int i=0; i<nCoarseValues; ++i) {
                float const * ptr = &shape->uvs[i*2];
                values[i].SetPosition(ptr[0],  ptr[1], 0.0f);
            }

            int lastLevel = refiner->GetMaxLevel();
            Vertex * src = values;
            for (int level = 1; level <= lastLevel; ++level) {
                Vertex * dst = src + refiner->GetLevel(level-1).GetNumFVarValues(channel);
                Far::PrimvarRefiner(*refiner).InterpolateFaceVarying(level, src, dst, channel);
                src = dst;
            }
        }
    }

    //
    // interpolate vertices
    //

    // create vertex primvar data buffer
    std::vector<Vertex> vertexBuffer(numTotalVerts);
    Vertex * verts = &vertexBuffer[0];

    // copy coarse vertices positions
    int ncoarseverts = shape->GetNumVertices();
    for (int i=0; i<ncoarseverts; ++i) {
        float * ptr = &shape->verts[i*3];
        verts[i].SetPosition(ptr[0], ptr[1], ptr[2]);
    }

    s.Start();
    if (g_useStencils) {
        //
        // Stencil interpolation
        //
        Far::StencilTable const * stencilTable = 0;
        Far::StencilTableFactory::Options options;
        options.generateOffsets=true;
        options.generateIntermediateLevels=true;
        stencilTable = Far::StencilTableFactory::Create(*refiner, options);

        // append local point stencils if needed
        if (patchTable and patchTable->GetLocalPointStencilTable()) {
            if (Far::StencilTable const * stencilTableWithLocalPoints =
                Far::StencilTableFactory::AppendLocalPointStencilTable(
                    *refiner, stencilTable,
                    patchTable->GetLocalPointStencilTable())) {
                delete stencilTable;
                stencilTable = stencilTableWithLocalPoints;
            }
        }

        //
        // apply stencils
        //
        stencilTable->UpdateValues(verts, verts + ncoarseverts);

        delete stencilTable;
    } else {
        //
        // TopologyRefiner interpolation
        //
        // populate buffer with Far interpolated vertex data
        int lastLevel = refiner->GetMaxLevel();
        Vertex * src = verts;
        for (int level = 1; level <= lastLevel; ++level) {
            Vertex * dst = src + refiner->GetLevel(level-1).GetNumVertices();
            Far::PrimvarRefiner(*refiner).Interpolate(level, src, dst);
            src = dst;
        }
        //printf("          %f ms (interpolate)\n", float(s.GetElapsed())*1000.0f);
        //printf("          %f ms (total)\n", float(s.GetTotalElapsed())*1000.0f);

        // TODO: endpatch basis conversion comes here
    }
    s.Stop();

    //
    // Misc display
    //

    //printf("Far time: %f ms (topology)\n", float(s.GetElapsed())*1000.0f);

    if (g_FarDrawVertIDs) {
        createVertNumbers(*refiner, vertexBuffer);
    }

    if (g_FarDrawFaceIDs) {
        createFaceNumbers(*refiner, vertexBuffer);
    }

    if (g_FarDrawPtexIDs and patchTable) {
        createPtexNumbers(*patchTable, vertexBuffer);
    }

    if (g_Adaptive) {
        createPatchNumbers(*patchTable, vertexBuffer);
    }

    if (g_Adaptive and g_FarDrawGregogyBasis) {
        createGregoryBasis(*patchTable, vertexBuffer);
    }

    if (g_Adaptive and createFVarWire) {
        createFVarPatches(*refiner, *patchTable, fvarBuffer);
        createFVarPatchNumbers(*patchTable, fvarBuffer);
    }

    createEdgeNumbers(*refiner, vertexBuffer, g_FarDrawEdgeIDs!=0, g_FarDrawEdgeSharpness!=0);

    GLMesh::Options options;
    options.vertColorMode=g_Adaptive ? GLMesh::VERTCOLOR_BY_LEVEL : GLMesh::VERTCOLOR_BY_SHARPNESS;
    options.edgeColorMode=g_Adaptive ? GLMesh::EDGECOLOR_BY_PATCHTYPE : GLMesh::EDGECOLOR_BY_SHARPNESS;
    options.faceColorMode=g_Adaptive ? GLMesh::FACECOLOR_BY_PATCHTYPE :GLMesh::FACECOLOR_SOLID;

    g_far_glmesh.Initialize(options, *refiner, patchTable, (float *)&verts[0]);
    if (g_Adaptive) {
        g_far_glmesh.SetDiffuseColor(1.0f, 1.0f, 1.0f, 1.0f);
    } else {
        g_far_glmesh.SetDiffuseColor(0.75f, 0.9f, 1.0f, 1.0f);
    }


    //setFaceColors(*refiner);

    g_far_glmesh.InitializeDeviceBuffers();

    // save coarse topology (used for control mesh display)
    g_controlMeshDisplay.SetTopology(refiner->GetLevel(0));

    // save coarse points in a GPU buffer (used for control mesh display)
    if (not g_controlMeshDisplayVBO) {
        glGenBuffers(1, &g_controlMeshDisplayVBO);
    }
    glBindBuffer(GL_ARRAY_BUFFER, g_controlMeshDisplayVBO);
    glBufferData(GL_ARRAY_BUFFER,
                 3*sizeof(float)*vertexBuffer.size(), (GLfloat*)&vertexBuffer[0],
                 GL_STATIC_DRAW);
    glBindBuffer(GL_ARRAY_BUFFER, 0);

    // compute model bounds
    float min[3] = { FLT_MAX,  FLT_MAX,  FLT_MAX};
    float max[3] = {-FLT_MAX, -FLT_MAX, -FLT_MAX};
    for (size_t i=0; i <vertexBuffer.size(); ++i) {
        for(int j=0; j<3; ++j) {
            float v = vertexBuffer[i].GetPos()[j];
            min[j] = std::min(min[j], v);
            max[j] = std::max(max[j], v);
        }
    }
    for (int j=0; j<3; ++j) {
        g_center[j] = (min[j] + max[j]) * 0.5f;
        g_size += (max[j]-min[j])*(max[j]-min[j]);
    }
    g_size = sqrtf(g_size);

    delete refiner;
    delete patchTable;
}