Exemplo n.º 1
0
        static void RunHighQualityReduction(ISimplygonSDK sdk, string readFrom, string writeTo)
        {
            spWavefrontImporter objReader = sdk.CreateWavefrontImporter();

            objReader.SetExtractGroups(false); //This makes the .obj reader import into a single geometry object instead of multiple
            objReader.SetImportFilePath(readFrom);
            if (!objReader.RunImport())
            {
                Console.WriteLine("Failed to read: " + readFrom);
                return;
            }
            spGeometryData  originalGeom      = objReader.GetFirstGeometry(); //Only contains a single geom, so "first" is fine
            spMaterialTable originalMaterials = objReader.GetMaterials();

            //Create a copy of the original geometry on which we will run the reduction
            spGeometryData lodGeom = originalGeom.NewCopy(true);

            // Create the reduction-processor, and set the geometry to reduce
            spReductionProcessor reductionProcessor = sdk.CreateReductionProcessor();

            reductionProcessor.SetGeometry(lodGeom);

            ///////////////////////////////////////////////////////////////////////////////////////////////
            // SETTINGS - Most of these are set to the same value by default, but are set anyway for clarity

            // The reduction settings object contains settings pertaining to the actual decimation
            spReductionSettings reductionSettings = reductionProcessor.GetReductionSettings();

            reductionSettings.SetEnablePreprocessing(true);                                                        //This enables the pre-processing block, which contains welding and t-junction removal
            reductionSettings.SetEnablePostprocessing(true);                                                       //This enables the post-processing block, which contains normal recalculation and mapping image generation
            reductionSettings.SetKeepSymmetry(true);                                                               //Try, when possible to reduce symmetrically
            reductionSettings.SetUseAutomaticSymmetryDetection(true);                                              //Auto-detect the symmetry plane, if one exists. Can, if required, be set manually instead.
            reductionSettings.SetUseHighQualityNormalCalculation(true);                                            //Drastically increases the quality of the LODs normals, at the cost of extra processing time.
            reductionSettings.SetReductionHeuristics((uint)ReductionHeuristics.SG_REDUCTIONHEURISTICS_CONSISTENT); //Choose between "fast" and "consistent" processing. Fast will look as good, but may cause inconsistent
            //triangle counts when comparing MaxDeviation targets to the corresponding percentage targets.

            // The reducer uses a feature flags mask to tell it what kind of borders to respect during reduction.
            FeatureFlags featureFlagsMask = 0;

            featureFlagsMask |= FeatureFlags.SG_FEATUREFLAGS_GROUP;    //Respect borders between group ids
            featureFlagsMask |= FeatureFlags.SG_FEATUREFLAGS_MATERIAL; //Respect borders between material ids
            featureFlagsMask |= FeatureFlags.SG_FEATUREFLAGS_TEXTURE0; //Respect discontinuities in the first texcoord field
            featureFlagsMask |= FeatureFlags.SG_FEATUREFLAGS_SHADING;  //Respect hard shading borders
            reductionSettings.SetFeatureFlags((uint)featureFlagsMask);

            // The reducer uses importance weights for all features to decide where and how to reduce.
            // These are advanced settings and should only be changed if you have some specific reduction requirement
            /*reductionSettings.SetShadingImportance(2.f); //This would make the shading twice as important to the reducer as the other features.*/

            // The actual reduction triangle target are controlled by these three settings
            reductionSettings.SetStopCondition((uint)StopCondition.SG_STOPCONDITION_EITHER_IS_REACHED); //The reduction stops when either of the targets is reached
            reductionSettings.SetReductionRatio(0.5f);                                                  //Stops at 50% of the original triangle count
            reductionSettings.SetMaxDeviation(SimplygonSDK.REAL_MAX);                                   //Stops when an error of the specified size has been reached. As set here it never happens.
            //This condition corresponds to the on-screen size target presented in the Simplygon GUI, with a simple formula to convert between the two.

            // The repair settings object contains settings for the pre-processing block
            spRepairSettings repairSettings = reductionProcessor.GetRepairSettings();

            repairSettings.SetTjuncDist(0.0f); //Removes t-junctions with distance 0.0f
            repairSettings.SetWeldDist(0.0f);  //Welds overlapping vertices

            // The normal calculation settings deal with the normal-specific reduction settings
            spNormalCalculationSettings normalSettings = reductionProcessor.GetNormalCalculationSettings();

            normalSettings.SetReplaceNormals(false); //If true, this will turn off normal handling in the reducer and recalculate them all afterwards instead.
            //If false, the reducer will try to preserve the original normals as well as possible
            /*normalSettings.SetHardEdgeAngle( 60.f ); //If the normals are recalculated, this sets the hard-edge angle.*/

            //END SETTINGS
            ///////////////////////////////////////////////////////////////////////////////////////////////


            // Run the actual processing. After this, the set geometry will have been reduced according to the settings
            reductionProcessor.RunProcessing();

            //Create an .obj exporter to save our result
            spWavefrontExporter objExporter = sdk.CreateWavefrontExporter();

            // Do the actual exporting
            objExporter.SetExportFilePath(writeTo + ".obj");
            objExporter.SetSingleGeometry(lodGeom);      //This is the geometry we set as the processing geom of the reducer
            objExporter.SetMaterials(originalMaterials); //Same material set as input
            if (!objExporter.RunExport())
            {
                Console.WriteLine("Failed to write target file");
            }

            //Done! LOD created.
        }
Exemplo n.º 2
0
        static void RunCascadedLodChainReduction(ISimplygonSDK sdk, string readFrom, string writeToLod1, string writeToLod2, string writeToLod3)
        {
            // Load input geometry from file
            spWavefrontImporter objReader = sdk.CreateWavefrontImporter();

            objReader.SetExtractGroups(false); //This makes the .obj reader import into a single geometry object instead of multiple
            objReader.SetImportFilePath(readFrom);
            if (!objReader.RunImport())
            {
                return;
            }

            // Get geometry and materials from importer
            spGeometryData  originalGeometry      = objReader.GetFirstGeometry(); //Only contains a single geom, so "first" is fine
            spMaterialTable originalMaterialTable = objReader.GetMaterials();

            //Create a copy of the original geometry on which we will run the reduction
            spGeometryData lodGeometry = originalGeometry.NewCopy(true);

            // Create the reduction-processor, and set the geometry to reduce
            spReductionProcessor reductionProcessor = sdk.CreateReductionProcessor();

            reductionProcessor.SetGeometry(lodGeometry);


            ///////////////////////////////////////////////////////////////////////////////////////////////
            // SETTINGS

            // The reduction settings object contains settings pertaining to the actual decimation
            spReductionSettings reductionSettings = reductionProcessor.GetReductionSettings();

            reductionSettings.SetReductionHeuristics((uint)ReductionHeuristics.SG_REDUCTIONHEURISTICS_FAST); //Choose between "fast" and "consistent" processing.

            // The normal calculation settings deal with the normal-specific reduction settings
            spNormalCalculationSettings normalSettings = reductionProcessor.GetNormalCalculationSettings();

            normalSettings.SetReplaceNormals(true); //If true, this will turn off normal handling in the reducer and recalculate them all afterwards instead.
            normalSettings.SetHardEdgeAngle(70.0f); //If the normals are recalculated, this sets the hard-edge angle.

            // The actual reduction triangle target are controlled by these three settings
            reductionSettings.SetStopCondition((uint)StopCondition.SG_STOPCONDITION_EITHER_IS_REACHED); //The reduction stops when either of the targets is reached
            reductionSettings.SetReductionRatio(0.0f);                                                  //Never stop at a triangle percentage, will hit MaxDeviation instead.


            //END SETTINGS
            ///////////////////////////////////////////////////////////////////////////////////////////////

            //Create an .obj exporter to save our result
            spWavefrontExporter objExporter = sdk.CreateWavefrontExporter();

            objExporter.SetSingleGeometry(lodGeometry);      //This is the geometry we set as the processing geom of the reducer
            objExporter.SetMaterials(originalMaterialTable); //Same materials as original

            //Set reduction targets using on-screen size to set the maximum deviation
            originalGeometry.CalculateExtents(true); //This calculates the bounds of the geometry
            float[] geometryInf = new float[3];
            float[] geometrySup = new float[3];
            originalGeometry.GetInf(geometryInf);
            originalGeometry.GetSup(geometrySup);
            float geometryDiagonalLength = (float)Math.Sqrt((double)((geometrySup[0] - geometryInf[0]) * (geometrySup[0] - geometryInf[0]) +
                                                                     (geometrySup[1] - geometryInf[1]) * (geometrySup[1] - geometryInf[1]) +
                                                                     (geometrySup[2] - geometryInf[2]) * (geometrySup[2] - geometryInf[2])));

            float[] maxDeviationTargets = new float[3];               //To find an approximate MaxDeviation for a pixelsize on screen, we just divide the diagonal by our wanted pixelsize
            maxDeviationTargets[0] = geometryDiagonalLength / 500.0f; //Gives a deviation of max 1 pixel at ~500 pixels on-screen
            maxDeviationTargets[1] = geometryDiagonalLength / 100.0f; //Gives a deviation of max 1 pixel at ~100 pixels on-screen
            maxDeviationTargets[2] = geometryDiagonalLength / 50.0f;  //Gives a deviation of max 1 pixel at ~50 pixels on-screen

            //Generate the output filenames
            string[] outputGeomFilename = new string[3];
            outputGeomFilename[0] = writeToLod1 + ".obj";
            outputGeomFilename[1] = writeToLod2 + ".obj";
            outputGeomFilename[2] = writeToLod3 + ".obj";

            // Run the iterative processing, saving the output geometry after every process
            for (int reductionIteration = 0; reductionIteration < 3; ++reductionIteration)
            {
                // The geometry still uses the same pointer, so it does not need to be re-set for the exporter or reducer after each pass.
                reductionSettings.SetMaxDeviation(maxDeviationTargets[reductionIteration]); //Stops when an error of the specified size has been reached.
                reductionProcessor.RunProcessing();

                // Do the exporting
                objExporter.SetMaterialFilePath(null); //Reset the material file path so it's set by ExportFilePath
                objExporter.SetExportFilePath(outputGeomFilename[reductionIteration]);
                if (!objExporter.RunExport())
                {
                    Console.WriteLine("Failed to write target file");
                }
            }

            //Done! 3 cascaded LODs created.
        }
Exemplo n.º 3
0
        private static void RunHighQualityReduction(ISimplygonSDK SDK, string writeTo)
        {
            const int vertex_count   = 12;
            const int triangle_count = 4;

            // 4 triangles x 3 indices ( or 3 corners )
            int[] corner_ids = { 0,  1, 2,
                                 3,  4, 5,
                                 6,  7, 8,
                                 9, 10, 11 };

            // 12 vertices with values for the x, y and z coordinates.
            float[] vertex_coordinates = { 0.0f, 0.0f, 0.0f,
                                           1.0f, 0.0f, 0.0f,
                                           1.0f, 1.0f, 0.0f,

                                           1.0f, 1.0f, 0.0f,
                                           0.0f, 1.0f, 0.0f,
                                           0.0f, 0.0f, 0.0f,

                                           1.0f, 0.0f, 0.0f,
                                           2.0f, 0.0f, 0.0f,
                                           2.0f, 1.0f, 0.0f,

                                           2.0f, 1.0f, 0.0f,
                                           1.0f, 1.0f, 0.0f,
                                           1.0f, 0.0f, 0.0f };

            spGeometryData g      = SDK.CreateGeometryData();
            spRealArray    coords = g.GetCoords();
            spRidArray     ids    = g.GetVertexIds();

            g.SetVertexCount(vertex_count);
            g.SetTriangleCount(triangle_count);
            for (int i = 0; i < vertex_count; ++i)
            {
                //coords.SetTuple(i, vertex_coordinates[i * 3]);
                //coords[i] = vertex_coordinates[i * 3];
                float[] v = { 0.0f, 0.0f, 0.0f };
                for (int j = 0; j < 3; ++j)
                {
                    v[j] = vertex_coordinates[i * 3 + j];
                }

                coords.SetTuple(i, v);
            }
            for (int i = 0; i < corner_ids.Length; ++i)
            {
                ids.SetItem(i, corner_ids[i]);
            }

            // Create the reduction-processor, and set which scene to reduce
            using (var reductionProcessor = SDK.CreateReductionProcessor())
            {
                spScene     scene    = SDK.CreateScene();
                spSceneNode root     = scene.GetRootNode();
                spSceneMesh meshNode = SDK.CreateSceneMesh();
                meshNode.SetGeometry(g);
                //auto meshTransform = meshNode->GetRelativeTransform();
                //meshTransform->SetToTranslationTransform(100, 0, 0);
                root.AddChild(meshNode);
                reductionProcessor.SetSceneRoot(root);


                ///////////////////////////////////////////////////////////////////////////////////////////////
                // SETTINGS - Most of these are set to the same value by default, but are set anyway for clarity

                // The reduction settings object contains settings pertaining to the actual decimation
                var reductionSettings = reductionProcessor.GetReductionSettings();
                reductionSettings.SetKeepSymmetry(true);                                                               //Try, when possible to reduce symmetrically
                reductionSettings.SetUseAutomaticSymmetryDetection(true);                                              //Auto-detect the symmetry plane, if one exists. Can, if required, be set manually instead.
                reductionSettings.SetUseHighQualityNormalCalculation(true);                                            //Drastically increases the quality of the LODs normals, at the cost of extra processing time.
                reductionSettings.SetReductionHeuristics((uint)ReductionHeuristics.SG_REDUCTIONHEURISTICS_CONSISTENT); //Choose between "fast" and "consistent" processing. Fast will look as good, but may cause inconsistent
                //triangle counts when comparing MaxDeviation targets to the corresponding percentage targets.

                // The reducer uses importance weights for all features to decide where and how to reduce.
                // These are advanced settings and should only be changed if you have some specific reduction requirement
                //reductionSettings.SetShadingImportance(2.f); //This would make the shading twice as important to the reducer as the other features./

                // The actual reduction triangle target are controlled by these settings
                reductionSettings.SetStopCondition((uint)StopCondition.SG_STOPCONDITION_EITHER_IS_REACHED); //The reduction stops when any of the targets below is reached
                reductionSettings.SetReductionRatio(0.5f);                                                  //Targets at 50% of the original triangle count
                reductionSettings.SetMaxDeviation(float.MaxValue);                                          //Targets when an error of the specified size has been reached. As set here it never happens.

                // The repair settings object contains settings to fix the geometries
                var repairSettings = reductionProcessor.GetRepairSettings();
                repairSettings.SetTjuncDist(0.0f); //Removes t-junctions with distance 0.0f
                repairSettings.SetWeldDist(0.0f);  //Welds overlapping vertices

                // The normal calculation settings deal with the normal-specific reduction settings
                var normalSettings = reductionProcessor.GetNormalCalculationSettings();
                normalSettings.SetReplaceNormals(false); //If true, this will turn off normal handling in the reducer and recalculate them all afterwards instead.
                //If false, the reducer will try to preserve the original normals as well as possible
                //normalSettings.SetHardEdgeAngle( 60.f ); //If the normals are recalculated, this sets the hard-edge angle./

                //END SETTINGS
                ///////////////////////////////////////////////////////////////////////////////////////////////

                // Run the actual processing. After this, the set geometry will have been reduced according to the settings
                reductionProcessor.RunProcessing();

                // For this reduction, the LOD will use the same material set as the original, and hence no further processing is required

                //Create an .obj exporter to save our result
                using (var objExporter = SDK.CreateWavefrontExporter())
                {
                    // Generate the output filenames
                    string      outputGeomFilename = writeTo + ".obj";
                    spSceneMesh topmesh            = Utils.SimplygonCast <spSceneMesh>(scene.GetRootNode().GetChild(0), false);


                    // Do the actual exporting
                    objExporter.SetExportFilePath(outputGeomFilename);
                    objExporter.SetSingleGeometry(topmesh.GetGeometry()); //This is the geometry we set as the processing geom of the reducer, retaining the materials in the original scene
                    objExporter.RunExport();

                    //Done! LOD created.
                }
            }
        }
Exemplo n.º 4
0
        static void RunReductionWithTextureCasting(ISimplygonSDK sdk, string readFrom, string writeTo)
        {
            // Load input geometry from file
            spWavefrontImporter objReader = sdk.CreateWavefrontImporter();

            objReader.SetExtractGroups(false); //This makes the .obj reader import into a single geometry object instead of multiple
            objReader.SetImportFilePath(readFrom);
            if (!objReader.RunImport())
            {
                Console.WriteLine("Failed to read: " + readFrom);
                return;
            }

            // Get geometry and materials from importer
            spGeometryData  originalGeom          = objReader.GetFirstGeometry(); //Only contains a single geom, so "first" is fine
            spMaterialTable originalMaterialTable = objReader.GetMaterials();

            // Create a copy of the original geometry on which we will run the reduction
            spGeometryData lodGeometry = originalGeom.NewCopy(true);

            // Create the reduction-processor, and set the geometry to reduce
            spReductionProcessor reductionProcessor = sdk.CreateReductionProcessor();

            reductionProcessor.SetGeometry(lodGeometry);


            ///////////////////////////////////////////////////////////////////////////////////////////////
            // SETTINGS - Most of these are set to the same value by default, but are set anyway for clarity

            // The reduction settings object contains settings pertaining to the actual decimation
            spReductionSettings reductionSettings = reductionProcessor.GetReductionSettings();

            reductionSettings.SetReductionHeuristics((uint)ReductionHeuristics.SG_REDUCTIONHEURISTICS_FAST); //Choose between "fast" and "consistent" processing.

            // The actual reduction triangle target are controlled by these three settings
            reductionSettings.SetStopCondition((uint)StopCondition.SG_STOPCONDITION_EITHER_IS_REACHED); //The reduction stops when either of the targets is reached
            reductionSettings.SetReductionRatio(0.5f);                                                  //Stops at 50% of the original triangle count
            reductionSettings.SetMaxDeviation(SimplygonSDK.REAL_MAX);                                   //Stops when an error of the specified size has been reached. As set here it never happens.

            // The normal calculation settings deal with the normal-specific reduction settings
            spNormalCalculationSettings normalSettings = reductionProcessor.GetNormalCalculationSettings();

            normalSettings.SetReplaceNormals(true); //If true, this will turn off normal handling in the reducer and recalculate them all afterwards instead.
            normalSettings.SetHardEdgeAngle(70.0f); //If the normals are recalculated, this sets the hard-edge angle.

            // The Image Mapping Settings, specifically needed for the texture baking we are doing later
            spMappingImageSettings mappingSettings = reductionProcessor.GetMappingImageSettings();

            mappingSettings.SetGenerateMappingImage(true); //Without this we cannot fetch data from the original geometry, and thus not generate diffuse and normal-maps later on.
            mappingSettings.SetGenerateTexCoords(true);    //Set to generate new texture coordinates.
            mappingSettings.SetMaxStretch(0.4f);           //The higher the number, the fewer texture-borders.
            mappingSettings.SetGutterSpace(2);             //Buffer space for when texture is mip-mapped, so color values don't blend over. Greatly influences packing efficiency
            mappingSettings.SetTexCoordLevel(0);           //Sets the output texcoord level. For this asset, this will overwrite the original coords
            mappingSettings.SetWidth(1024);
            mappingSettings.SetHeight(1024);
            mappingSettings.SetMultisamplingLevel(2);

            //END SETTINGS
            ///////////////////////////////////////////////////////////////////////////////////////////////


            // Run the actual processing. After this, the set geometry will have been reduced according to the settings
            reductionProcessor.RunProcessing();


            ///////////////////////////////////////////////////////////////////////////////////////////////
            // CASTING

            // Now, we need to retrieve the generated mapping image and use it to cast the old materials into a new one, for each channel.
            spMappingImage mappingImage = reductionProcessor.GetMappingImage();

            // Now, for each channel, we want to cast the 9 input materials into a single output material, with one texture per channel.
            // First, create a new material table.
            spMaterialTable lodMaterialTable = sdk.CreateMaterialTable();
            // Create new material for the table.
            spMaterial lodMaterial = sdk.CreateMaterial();

            lodMaterial.SetName("SimplygonBakedMaterial");
            lodMaterialTable.AddMaterial(lodMaterial);
            // Cast diffuse and specular texture data with a color caster
            {
                // Set the material properties
                lodMaterial.SetColor(SimplygonSDK.SG_MATERIAL_CHANNEL_AMBIENT, 0, 0, 0, 0);
                lodMaterial.SetColor(SimplygonSDK.SG_MATERIAL_CHANNEL_DIFFUSE, 1, 1, 1, 1);
                lodMaterial.SetColor(SimplygonSDK.SG_MATERIAL_CHANNEL_SPECULAR, 1, 1, 1, 128);
                //Note the 128 on the specular channels alpha. Simplygon bakes shininess
                //to the alpha channel of the specular map if the caster is set to 4 channel
                //output, and it is scaled between 0 and 1 internally. To get the correct
                //scale on the output, it should be multiplied by 128.

                // Cast the data using a color caster
                spColorCaster colorCaster = sdk.CreateColorCaster();
                colorCaster.SetSourceMaterials(originalMaterialTable);
                colorCaster.SetDestMaterial(lodMaterial);  //This modulates the cast color with the base colors set for the dest material above.
                //It means the internal shininess is multiplied by 128 before baking to texture.
                colorCaster.SetMappingImage(mappingImage); //The mapping image we got from the reduction process.
                colorCaster.SetOutputChannelBitDepth(8);   //8 bits per channel. So in this case we will have 24bit colors RGB.
                colorCaster.SetDilation(10);               //To avoid mip-map artifacts, the empty pixels on the map needs to be filled to a degree as well.

                colorCaster.SetColorType(SimplygonSDK.SG_MATERIAL_CHANNEL_DIFFUSE);
                colorCaster.SetOutputChannels(3);                        //RGB, 3 channels! (1 would be for grey scale, and 4 would be for RGBA.)
                colorCaster.SetOutputFilePath("combinedDiffuseMap.png"); //Where the texture map will be saved to file.
                colorCaster.CastMaterials();                             //Do the actual casting and write to texture.

                colorCaster.SetColorType(SimplygonSDK.SG_MATERIAL_CHANNEL_SPECULAR);
                colorCaster.SetOutputChannels(4);                         //RGBA, 4 channels! Stores spec power in A
                colorCaster.SetOutputFilePath("combinedSpecularMap.png"); //Where the texture map will be saved to file.
                colorCaster.CastMaterials();                              //Do the actual casting and write to texture.


                lodMaterial.SetTexture(SimplygonSDK.SG_MATERIAL_CHANNEL_DIFFUSE, "combinedDiffuseMap.png");   //Set material to point to the texture we cast to above
                lodMaterial.SetTexture(SimplygonSDK.SG_MATERIAL_CHANNEL_SPECULAR, "combinedSpecularMap.png"); //Set material to point to the texture we cast to above
            }

            // Cast normal map texture data with the normal caster. This also compensates for any geometric errors that have appeared in the reduction process.
            {
                // cast the data using a normal caster
                spNormalCaster normalCaster = sdk.CreateNormalCaster();
                normalCaster.SetSourceMaterials(originalMaterialTable);
                normalCaster.SetMappingImage(mappingImage);
                normalCaster.SetOutputChannels(3); // RGB, 3 channels! (But really the x, y and z values for the normal)
                normalCaster.SetOutputChannelBitDepth(8);
                normalCaster.SetDilation(10);
                normalCaster.SetOutputFilePath("combinedNormalMap.png");
                normalCaster.SetFlipBackfacingNormals(false);
                normalCaster.SetGenerateTangentSpaceNormals(true);
                normalCaster.CastMaterials();

                // Set normal map of the created material to point to the combined normal map
                lodMaterial.SetTexture(SimplygonSDK.SG_MATERIAL_CHANNEL_NORMALS, "combinedNormalMap.png");
            }

            // END CASTING
            ///////////////////////////////////////////////////////////////////////////////////////////////

            //Create an .obj exporter to save our result
            spWavefrontExporter objExporter = sdk.CreateWavefrontExporter();

            // Generate the output filenames
            // Do the actual exporting
            objExporter.SetExportFilePath(writeTo + ".obj");
            objExporter.SetSingleGeometry(lodGeometry); //This is the geometry we set as the processing geom of the reducer
            objExporter.SetMaterials(lodMaterialTable); //Our new cast material
            if (!objExporter.RunExport())
            {
                Console.WriteLine("Failed to write target file");
            }

            //Done! LOD and material created.
        }
Exemplo n.º 5
0
        static void RunReductionProcessing(ISimplygonSDK sdk, spScene scene, float max_dev, float keep_bone_ratio)
        {
            // Create the reduction processor. Set the scene that is to be processed
            spReductionProcessor red = sdk.CreateReductionProcessor();

            red.SetSceneRoot(scene.GetRootNode());

            ///////////////////////////////////////////////////
            //	Set the bone settings
            spBoneSettings boneSettings = red.GetBoneSettings();

            // Reduce bones based on percentage of bones in the scene.
            // Bone lod process tells the reduction processor the method
            // to use for bone reduction.
            boneSettings.SetBoneLodProcess((uint)BoneRemovalProcessing.SG_BONEPROCESSING_RATIO_PROCESSING);

            // Set the ratio of bones to keep in the scene
            boneSettings.SetBoneLodRatio(keep_bone_ratio);

            ///////////////////////////////////////////////////
            //
            // Set the Repair Settings. Current settings will mean that all visual gaps will remain in the geometry and thus
            // hinder the reduction on geometries that contains gaps, holes and t-junctions.
            spRepairSettings repair_settings = red.GetRepairSettings();

            // Only vertices that actually share the same position will be welded together
            repair_settings.SetWeldDist(0.0f);

            // Only t-junctions with no actual visual distance will be fixed.
            repair_settings.SetTjuncDist(0.0f);

            ///////////////////////////////////////////////////
            //
            // Set the Reduction Settings.
            spReductionSettings reduction_settings = red.GetReductionSettings();

            // These flags will make the reduction process respect group and material setups,
            // as well as preserve UV coordinates.
            FeatureFlags BorderFlagsMask = 0;

            BorderFlagsMask |= FeatureFlags.SG_FEATUREFLAGS_GROUP;
            BorderFlagsMask |= FeatureFlags.SG_FEATUREFLAGS_MATERIAL;
            BorderFlagsMask |= FeatureFlags.SG_FEATUREFLAGS_TEXTURE0;

            reduction_settings.SetFeatureFlags((uint)BorderFlagsMask);

            // Reduce until we reach max deviation.
            reduction_settings.SetMaxDeviation(max_dev);

            ///////////////////////////////////////////////////
            //
            // Set the Normal Calculation Settings.
            spNormalCalculationSettings normal_settings = red.GetNormalCalculationSettings();

            // Will completely recalculate the normals.
            normal_settings.SetReplaceNormals(true);
            normal_settings.SetHardEdgeAngle(90.0f);

            // Run the process
            red.RunProcessing();
        }