#ifndef NO_OPENGL3 /* Copyright (c) 2012 Advanced Micro Devices, Inc. This software is provided 'as-is', without any express or implied warranty. In no event will the authors be held liable for any damages arising from the use of this software. Permission is granted to anyone to use this software for any purpose, including commercial applications, and to alter it and redistribute it freely, subject to the following restrictions: 1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required. 2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software. 3. This notice may not be removed or altered from any source distribution. */ //Originally written by Erwin Coumans ///todo: make this configurable in the gui bool useShadowMap = true;// true;//false;//true; int shadowMapWidth= 4096; int shadowMapHeight= 4096; float shadowMapWorldSize=10; #define MAX_POINTS_IN_BATCH 1024 #define MAX_LINES_IN_BATCH 1024 #define MAX_TRIANGLES_IN_BATCH 8192 #include "OpenGLInclude.h" #include "../CommonInterfaces/CommonWindowInterface.h" //#include "Bullet3Common/b3MinMax.h" #ifdef B3_USE_GLFW #else #ifndef __APPLE__ #ifndef glVertexAttribDivisor #ifndef NO_GLEW #define glVertexAttribDivisor glVertexAttribDivisorARB #endif //NO_GLEW #endif //glVertexAttribDivisor #ifndef GL_COMPARE_REF_TO_TEXTURE #define GL_COMPARE_REF_TO_TEXTURE GL_COMPARE_R_TO_TEXTURE #endif //GL_COMPARE_REF_TO_TEXTURE #ifndef glDrawElementsInstanced #ifndef NO_GLEW #define glDrawElementsInstanced glDrawElementsInstancedARB #endif //NO_GLEW #endif #endif //__APPLE__ #endif//B3_USE_GLFW #include "GLInstancingRenderer.h" #include //#include "DemoSettings.h" #include #include "Bullet3Common/b3Vector3.h" #include "Bullet3Common/b3Quaternion.h" #include "Bullet3Common/b3Transform.h" #include "Bullet3Common/b3Matrix3x3.h" #include "Bullet3Common/b3ResizablePool.h" #include "LoadShader.h" #include "GLInstanceRendererInternalData.h" //GLSL shader strings, embedded using build3/stringify #include "Shaders/pointSpriteVS.h" #include "Shaders/pointSpritePS.h" #include "Shaders/instancingVS.h" #include "Shaders/instancingPS.h" #include "Shaders/createShadowMapInstancingVS.h" #include "Shaders/createShadowMapInstancingPS.h" #include "Shaders/useShadowMapInstancingVS.h" #include "Shaders/useShadowMapInstancingPS.h" #include "Shaders/linesPS.h" #include "Shaders/linesVS.h" #include "GLRenderToTexture.h" static const char* triangleVertexShaderText = "#version 330\n" "precision highp float;" "uniform mat4 MVP;\n" "uniform vec3 vCol;\n" "layout (location = 0) in vec3 vPos;\n" "layout (location = 1) in vec2 vUV;\n" "out vec3 clr;\n" "out vec2 uv0;\n" "void main()\n" "{\n" " gl_Position = MVP * vec4(vPos,1);\n" " clr = vCol;\n" " uv0 = vUV;\n" "}\n"; static const char* triangleFragmentShader = "#version 330\n" "precision highp float;" "in vec3 clr;\n" "in vec2 uv0;" "out vec4 color;" "uniform sampler2D Diffuse;" "void main()\n" "{\n" " vec4 texel = texture(Diffuse,uv0);\n" " color = vec4(clr,texel.r)*texel;\n" "}\n"; //#include "../../opencl/gpu_rigidbody_pipeline/b3GpuNarrowphaseAndSolver.h"//for m_maxNumObjectCapacity static InternalDataRenderer* sData2; GLint lineWidthRange[2]={1,1}; enum { eGfxTransparency=1, eGfxHasTexture = 2, }; struct b3GraphicsInstance { GLuint m_cube_vao; GLuint m_index_vbo; GLuint m_textureIndex; int m_numIndices; int m_numVertices; int m_numGraphicsInstances; b3AlignedObjectArray m_tempObjectUids; int m_instanceOffset; int m_vertexArrayOffset; int m_primitiveType; float m_materialShinyNess; b3Vector3 m_materialSpecularColor; int m_flags;//transparency etc b3GraphicsInstance() :m_cube_vao(-1), m_index_vbo(-1), m_textureIndex(-1), m_numIndices(-1), m_numVertices(-1), m_numGraphicsInstances(0), m_instanceOffset(0), m_vertexArrayOffset(0), m_primitiveType(B3_GL_TRIANGLES), m_materialShinyNess(41), m_materialSpecularColor(b3MakeVector3(.5,.5,.5)), m_flags(0) { } }; bool m_ortho = false; //static GLfloat depthLightModelviewMatrix[16]; static void checkError(const char *functionName) { GLenum error; while (( error = glGetError() ) != GL_NO_ERROR) { fprintf (stderr, "GL error 0x%X detected in %s\n", error, functionName); } } extern int gShapeIndex; struct InternalTextureHandle { GLuint m_glTexture; int m_width; int m_height; int m_enableFiltering; }; struct b3PublicGraphicsInstanceData { int m_shapeIndex; int m_internalInstanceIndex; GLfloat m_position[4]; GLfloat m_orientation[4]; GLfloat m_color[4]; GLfloat m_scale[4]; void clear() { } }; typedef b3PoolBodyHandle b3PublicGraphicsInstance; struct InternalDataRenderer : public GLInstanceRendererInternalData { SimpleCamera m_defaultCamera1; CommonCameraInterface* m_activeCamera; GLfloat m_projectionMatrix[16]; GLfloat m_viewMatrix[16]; GLfloat m_viewMatrixInverse[16]; b3Vector3 m_lightPos; b3Vector3 m_lightSpecularIntensity; GLuint m_defaultTexturehandle; b3AlignedObjectArray m_textureHandles; GLRenderToTexture* m_shadowMap; GLuint m_shadowTexture; GLuint m_renderFrameBuffer; b3ResizablePool< b3PublicGraphicsInstance> m_publicGraphicsInstances; InternalDataRenderer() : m_activeCamera(&m_defaultCamera1), m_shadowMap(0), m_shadowTexture(0), m_renderFrameBuffer(0) { m_lightPos=b3MakeVector3(-50,30,40); m_lightSpecularIntensity.setValue(1,1,1); //clear to zero to make it obvious if the matrix is used uninitialized for (int i=0;i<16;i++) { m_projectionMatrix[i]=0; m_viewMatrix[i]=0; m_viewMatrixInverse[i]=0; } } }; struct GLInstanceRendererInternalData* GLInstancingRenderer::getInternalData() { return m_data; } static GLuint triangleShaderProgram; static GLint triangle_mvp_location=-1; static GLint triangle_vpos_location=-1; static GLint triangle_vUV_location=-1; static GLint triangle_vcol_location=-1; static GLuint triangleVertexBufferObject=0; static GLuint triangleVertexArrayObject=0; static GLuint triangleIndexVbo=0; static GLuint linesShader; // The line renderer static GLuint useShadowMapInstancingShader; // The shadow instancing renderer static GLuint createShadowMapInstancingShader; // The shadow instancing renderer static GLuint instancingShader; // The instancing renderer static GLuint instancingShaderPointSprite; // The point sprite instancing renderer //static bool done = false; static GLint lines_ModelViewMatrix=0; static GLint lines_ProjectionMatrix=0; static GLint lines_position=0; static GLint lines_colour=0; GLuint lineVertexBufferObject=0; GLuint lineVertexArrayObject=0; GLuint lineIndexVbo = 0; GLuint linesVertexBufferObject=0; GLuint linesVertexArrayObject=0; GLuint linesIndexVbo = 0; static GLint useShadow_ViewMatrixInverse=0; static GLint useShadow_ModelViewMatrix=0; static GLint useShadow_lightSpecularIntensity = 0; static GLint useShadow_materialSpecularColor = 0; static GLint useShadow_MVP=0; static GLint useShadow_lightPosIn=0; static GLint useShadow_cameraPositionIn = 0; static GLint useShadow_materialShininessIn = 0; static GLint useShadow_ProjectionMatrix=0; static GLint useShadow_DepthBiasModelViewMatrix=0; static GLint useShadow_uniform_texture_diffuse = 0; static GLint useShadow_shadowMap = 0; static GLint createShadow_depthMVP=0; static GLint ModelViewMatrix=0; static GLint ProjectionMatrix=0; static GLint regularLightDirIn=0; static GLint uniform_texture_diffuse = 0; static GLint screenWidthPointSprite=0; static GLint ModelViewMatrixPointSprite=0; static GLint ProjectionMatrixPointSprite=0; //static GLint uniform_texture_diffusePointSprite= 0; GLInstancingRenderer::GLInstancingRenderer(int maxNumObjectCapacity, int maxShapeCapacityInBytes) : m_textureenabled(true), m_textureinitialized(false), m_screenWidth(0), m_screenHeight(0), m_upAxis(1) { m_data = new InternalDataRenderer; m_data->m_maxNumObjectCapacity = maxNumObjectCapacity; m_data->m_maxShapeCapacityInBytes=maxShapeCapacityInBytes; m_data->m_totalNumInstances = 0; sData2 = m_data; m_data->m_instance_positions_ptr.resize(m_data->m_maxNumObjectCapacity*4); m_data->m_instance_quaternion_ptr.resize(m_data->m_maxNumObjectCapacity*4); m_data->m_instance_colors_ptr.resize(m_data->m_maxNumObjectCapacity*4); m_data->m_instance_scale_ptr.resize(m_data->m_maxNumObjectCapacity*3); } void GLInstancingRenderer::removeAllInstances() { m_data->m_totalNumInstances = 0; for (int i=0;im_index_vbo) { glDeleteBuffers(1,&m_graphicsInstances[i]->m_index_vbo); } if (m_graphicsInstances[i]->m_cube_vao) { glDeleteVertexArrays(1,&m_graphicsInstances[i]->m_cube_vao); } delete m_graphicsInstances[i]; } m_graphicsInstances.clear(); m_data->m_publicGraphicsInstances.exitHandles(); m_data->m_publicGraphicsInstances.initHandles(); } GLInstancingRenderer::~GLInstancingRenderer() { delete m_data->m_shadowMap; glDeleteTextures(1,&m_data->m_shadowTexture); glDeleteTextures(1,&m_data->m_defaultTexturehandle); removeAllInstances(); sData2=0; if (m_data) { if (m_data->m_vbo) glDeleteBuffers(1,&m_data->m_vbo); } delete m_data; } int GLInstancingRenderer::getShapeIndexFromInstance(int srcIndex) { b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(srcIndex); if (pg) { return pg->m_shapeIndex; } return -1; } bool GLInstancingRenderer::readSingleInstanceTransformToCPU(float* position, float* orientation, int shapeIndex) { b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(shapeIndex); if (pg) { int srcIndex = pg->m_internalInstanceIndex; if ((srcIndexm_totalNumInstances) && (srcIndex>=0)) { position[0] = m_data->m_instance_positions_ptr[srcIndex*4+0]; position[1] = m_data->m_instance_positions_ptr[srcIndex*4+1]; position[2] = m_data->m_instance_positions_ptr[srcIndex*4+2]; orientation[0] = m_data->m_instance_quaternion_ptr[srcIndex*4+0]; orientation[1] = m_data->m_instance_quaternion_ptr[srcIndex*4+1]; orientation[2] = m_data->m_instance_quaternion_ptr[srcIndex*4+2]; orientation[3] = m_data->m_instance_quaternion_ptr[srcIndex*4+3]; return true; } } return false; } void GLInstancingRenderer::writeSingleInstanceTransformToCPU(const float* position, const float* orientation, int srcIndex2) { b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(srcIndex2); b3Assert(pg); if (pg==0) return; int srcIndex = pg->m_internalInstanceIndex; b3Assert(srcIndexm_totalNumInstances); b3Assert(srcIndex>=0); m_data->m_instance_positions_ptr[srcIndex*4+0]=position[0]; m_data->m_instance_positions_ptr[srcIndex*4+1]=position[1]; m_data->m_instance_positions_ptr[srcIndex*4+2]=position[2]; m_data->m_instance_positions_ptr[srcIndex*4+3]=1; m_data->m_instance_quaternion_ptr[srcIndex*4+0]=orientation[0]; m_data->m_instance_quaternion_ptr[srcIndex*4+1]=orientation[1]; m_data->m_instance_quaternion_ptr[srcIndex*4+2]=orientation[2]; m_data->m_instance_quaternion_ptr[srcIndex*4+3]=orientation[3]; } void GLInstancingRenderer::readSingleInstanceTransformFromCPU(int srcIndex2, float* position, float* orientation) { b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(srcIndex2); b3Assert(pg); int srcIndex = pg->m_internalInstanceIndex; b3Assert(srcIndexm_totalNumInstances); b3Assert(srcIndex>=0); position[0] = m_data->m_instance_positions_ptr[srcIndex*4+0]; position[1] = m_data->m_instance_positions_ptr[srcIndex*4+1]; position[2] = m_data->m_instance_positions_ptr[srcIndex*4+2]; orientation[0] = m_data->m_instance_quaternion_ptr[srcIndex*4+0]; orientation[1] = m_data->m_instance_quaternion_ptr[srcIndex*4+1]; orientation[2] = m_data->m_instance_quaternion_ptr[srcIndex*4+2]; orientation[3] = m_data->m_instance_quaternion_ptr[srcIndex*4+3]; } void GLInstancingRenderer::writeSingleInstanceColorToCPU(const double* color, int srcIndex2) { b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(srcIndex2); b3Assert(pg); int srcIndex = pg->m_internalInstanceIndex; m_data->m_instance_colors_ptr[srcIndex*4+0]=float(color[0]); m_data->m_instance_colors_ptr[srcIndex*4+1]=float(color[1]); m_data->m_instance_colors_ptr[srcIndex*4+2]=float(color[2]); m_data->m_instance_colors_ptr[srcIndex*4+3]=float(color[3]); } void GLInstancingRenderer::writeSingleInstanceColorToCPU(const float* color, int srcIndex2) { b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(srcIndex2); b3Assert(pg); int srcIndex = pg->m_internalInstanceIndex; m_data->m_instance_colors_ptr[srcIndex*4+0]=color[0]; m_data->m_instance_colors_ptr[srcIndex*4+1]=color[1]; m_data->m_instance_colors_ptr[srcIndex*4+2]=color[2]; m_data->m_instance_colors_ptr[srcIndex*4+3]=color[3]; } void GLInstancingRenderer::writeSingleInstanceScaleToCPU(const float* scale, int srcIndex2) { b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(srcIndex2); b3Assert(pg); int srcIndex = pg->m_internalInstanceIndex; m_data->m_instance_scale_ptr[srcIndex*3+0]=scale[0]; m_data->m_instance_scale_ptr[srcIndex*3+1]=scale[1]; m_data->m_instance_scale_ptr[srcIndex*3+2]=scale[2]; } void GLInstancingRenderer::writeSingleInstanceSpecularColorToCPU(const double* specular, int srcIndex2) { b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(srcIndex2); b3Assert(pg); int graphicsIndex = pg->m_internalInstanceIndex; int totalNumInstances = 0; int gfxObjIndex = -1; for (int i=0;im_numGraphicsInstances; if (srcIndex20) { m_graphicsInstances[gfxObjIndex]->m_materialSpecularColor[0] = specular[0]; m_graphicsInstances[gfxObjIndex]->m_materialSpecularColor[1] = specular[1]; m_graphicsInstances[gfxObjIndex]->m_materialSpecularColor[2] = specular[2]; } } void GLInstancingRenderer::writeSingleInstanceSpecularColorToCPU(const float* specular, int srcIndex2) { b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(srcIndex2); b3Assert(pg); int srcIndex = pg->m_internalInstanceIndex; int totalNumInstances = 0; int gfxObjIndex = -1; for (int i=0;im_numGraphicsInstances; if (srcIndex20) { m_graphicsInstances[gfxObjIndex]->m_materialSpecularColor[0] = specular[0]; m_graphicsInstances[gfxObjIndex]->m_materialSpecularColor[1] = specular[1]; m_graphicsInstances[gfxObjIndex]->m_materialSpecularColor[2] = specular[2]; } } void GLInstancingRenderer::writeSingleInstanceScaleToCPU(const double* scale, int srcIndex2) { b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(srcIndex2); b3Assert(pg); int srcIndex = pg->m_internalInstanceIndex; m_data->m_instance_scale_ptr[srcIndex*3+0]=scale[0]; m_data->m_instance_scale_ptr[srcIndex*3+1]=scale[1]; m_data->m_instance_scale_ptr[srcIndex*3+2]=scale[2]; } void GLInstancingRenderer::writeSingleInstanceTransformToGPU(float* position, float* orientation, int objectUniqueId) { glBindBuffer(GL_ARRAY_BUFFER, m_data->m_vbo); //glFlush(); b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(objectUniqueId); b3Assert(pg); int objectIndex = pg->m_internalInstanceIndex; char* orgBase = (char*)glMapBuffer( GL_ARRAY_BUFFER,GL_READ_WRITE); //b3GraphicsInstance* gfxObj = m_graphicsInstances[k]; int totalNumInstances= 0; for (int k=0;km_numGraphicsInstances; } int POSITION_BUFFER_SIZE = (totalNumInstances*sizeof(float)*4); char* base = orgBase; float* positions = (float*)(base+m_data->m_maxShapeCapacityInBytes); float* orientations = (float*)(base+m_data->m_maxShapeCapacityInBytes + POSITION_BUFFER_SIZE); positions[objectIndex*4] = position[0]; positions[objectIndex*4+1] = position[1]; positions[objectIndex*4+2] = position[2]; positions[objectIndex*4+3] = position[3]; orientations [objectIndex*4] = orientation[0]; orientations [objectIndex*4+1] = orientation[1]; orientations [objectIndex*4+2] = orientation[2]; orientations [objectIndex*4+3] = orientation[3]; glUnmapBuffer( GL_ARRAY_BUFFER); //glFlush(); } void GLInstancingRenderer::writeTransforms() { { //B3_PROFILE("b3Assert(glGetError() 1"); b3Assert(glGetError() ==GL_NO_ERROR); } { //B3_PROFILE("glBindBuffer"); glBindBuffer(GL_ARRAY_BUFFER, m_data->m_vbo); } { //B3_PROFILE("glFlush()"); //without the flush, the glBufferSubData can spike to really slow (seconds slow) glFlush(); } { //B3_PROFILE("b3Assert(glGetError() 2"); b3Assert(glGetError() ==GL_NO_ERROR); } #ifdef B3_DEBUG { //B3_PROFILE("m_data->m_totalNumInstances == totalNumInstances"); int totalNumInstances= 0; for (int k=0;km_numGraphicsInstances; } b3Assert(m_data->m_totalNumInstances == totalNumInstances); } #endif//B3_DEBUG int POSITION_BUFFER_SIZE = (m_data->m_totalNumInstances*sizeof(float)*4); int ORIENTATION_BUFFER_SIZE = (m_data->m_totalNumInstances*sizeof(float)*4); int COLOR_BUFFER_SIZE = (m_data->m_totalNumInstances*sizeof(float)*4); // int SCALE_BUFFER_SIZE = (totalNumInstances*sizeof(float)*3); #if 1 { // printf("m_data->m_totalNumInstances = %d\n", m_data->m_totalNumInstances); { //B3_PROFILE("glBufferSubData pos"); glBufferSubData( GL_ARRAY_BUFFER,m_data->m_maxShapeCapacityInBytes,m_data->m_totalNumInstances*sizeof(float)*4, &m_data->m_instance_positions_ptr[0]); } { // B3_PROFILE("glBufferSubData orn"); glBufferSubData( GL_ARRAY_BUFFER,m_data->m_maxShapeCapacityInBytes+POSITION_BUFFER_SIZE,m_data->m_totalNumInstances*sizeof(float)*4, &m_data->m_instance_quaternion_ptr[0]); } { // B3_PROFILE("glBufferSubData color"); glBufferSubData( GL_ARRAY_BUFFER,m_data->m_maxShapeCapacityInBytes+ POSITION_BUFFER_SIZE+ORIENTATION_BUFFER_SIZE, m_data->m_totalNumInstances*sizeof(float)*4, &m_data->m_instance_colors_ptr[0]); } { // B3_PROFILE("glBufferSubData scale"); glBufferSubData( GL_ARRAY_BUFFER, m_data->m_maxShapeCapacityInBytes+POSITION_BUFFER_SIZE+ORIENTATION_BUFFER_SIZE+COLOR_BUFFER_SIZE,m_data->m_totalNumInstances*sizeof(float)*3, &m_data->m_instance_scale_ptr[0]); } } #else char* orgBase = (char*)glMapBuffer( GL_ARRAY_BUFFER,GL_READ_WRITE); if (orgBase) { for (int k=0;km_maxShapeCapacityInBytes); float* orientations = (float*)(base+m_data->m_maxShapeCapacityInBytes + POSITION_BUFFER_SIZE); float* colors= (float*)(base+m_data->m_maxShapeCapacityInBytes + POSITION_BUFFER_SIZE+ORIENTATION_BUFFER_SIZE); float* scaling= (float*)(base+m_data->m_maxShapeCapacityInBytes + POSITION_BUFFER_SIZE+ORIENTATION_BUFFER_SIZE+COLOR_BUFFER_SIZE); //static int offset=0; //offset++; for (int i=0;im_numGraphicsInstances;i++) { int srcIndex=i+gfxObj->m_instanceOffset; positions[srcIndex*4] = m_data->m_instance_positions_ptr[srcIndex*4]; positions[srcIndex*4+1] = m_data->m_instance_positions_ptr[srcIndex*4+1]; positions[srcIndex*4+2] = m_data->m_instance_positions_ptr[srcIndex*4+2]; positions[srcIndex*4+3] = m_data->m_instance_positions_ptr[srcIndex*4+3]; orientations[srcIndex*4]=m_data->m_instance_quaternion_ptr[srcIndex*4]; orientations[srcIndex*4+1]=m_data->m_instance_quaternion_ptr[srcIndex*4+1]; orientations[srcIndex*4+2]=m_data->m_instance_quaternion_ptr[srcIndex*4+2]; orientations[srcIndex*4+3]=m_data->m_instance_quaternion_ptr[srcIndex*4+3]; colors[srcIndex*4]=m_data->m_instance_colors_ptr[srcIndex*4]; colors[srcIndex*4+1]=m_data->m_instance_colors_ptr[srcIndex*4+1]; colors[srcIndex*4+2]=m_data->m_instance_colors_ptr[srcIndex*4+2]; colors[srcIndex*4+3]=m_data->m_instance_colors_ptr[srcIndex*4+3]; scaling[srcIndex*3]=m_data->m_instance_scale_ptr[srcIndex*3]; scaling[srcIndex*3+1]=m_data->m_instance_scale_ptr[srcIndex*3+1]; scaling[srcIndex*3+2]=m_data->m_instance_scale_ptr[srcIndex*3+2]; } } } else { b3Error("ERROR glMapBuffer failed\n"); } b3Assert(glGetError() ==GL_NO_ERROR); glUnmapBuffer( GL_ARRAY_BUFFER); //if this glFinish is removed, the animation is not always working/blocks //@todo: figure out why //glFlush(); #endif { // B3_PROFILE("glBindBuffer 2"); glBindBuffer(GL_ARRAY_BUFFER, 0);//m_data->m_vbo); } { // B3_PROFILE("b3Assert(glGetError() 4"); b3Assert(glGetError() ==GL_NO_ERROR); } } int GLInstancingRenderer::registerGraphicsInstance(int shapeIndex, const double* pos1, const double* orn1, const double* color1, const double* scaling1) { float pos[4] = {(float)pos1[0],(float)pos1[1],(float)pos1[2],(float)pos1[3]}; float orn[4] = {(float)orn1[0],(float)orn1[1],(float)orn1[2],(float)orn1[3]}; float color[4] = {(float)color1[0],(float)color1[1],(float)color1[2],(float)color1[3]}; float scaling[4] = {(float)scaling1[0],(float)scaling1[1],(float)scaling1[2],(float)scaling1[3]}; return registerGraphicsInstance(shapeIndex,pos,orn,color,scaling); } void GLInstancingRenderer::rebuildGraphicsInstances() { m_data->m_totalNumInstances = 0; b3AlignedObjectArray usedObjects; m_data->m_publicGraphicsInstances.getUsedHandles(usedObjects); for (int i=0;im_publicGraphicsInstances.getHandle(srcIndex2); b3Assert(pg); int srcIndex = pg->m_internalInstanceIndex; pg->m_position[0] = m_data->m_instance_positions_ptr[srcIndex*4+0]; pg->m_position[1] = m_data->m_instance_positions_ptr[srcIndex*4+1]; pg->m_position[2] = m_data->m_instance_positions_ptr[srcIndex*4+2]; pg->m_orientation[0] = m_data->m_instance_quaternion_ptr[srcIndex*4+0]; pg->m_orientation[1] = m_data->m_instance_quaternion_ptr[srcIndex*4+1]; pg->m_orientation[2] = m_data->m_instance_quaternion_ptr[srcIndex*4+2]; pg->m_orientation[3] = m_data->m_instance_quaternion_ptr[srcIndex*4+3]; pg->m_color[0] = m_data->m_instance_colors_ptr[srcIndex*4+0]; pg->m_color[1] = m_data->m_instance_colors_ptr[srcIndex*4+1]; pg->m_color[2] = m_data->m_instance_colors_ptr[srcIndex*4+2]; pg->m_color[3] = m_data->m_instance_colors_ptr[srcIndex*4+3]; pg->m_scale[0] = m_data->m_instance_scale_ptr[srcIndex*3+0]; pg->m_scale[1] = m_data->m_instance_scale_ptr[srcIndex*3+1]; pg->m_scale[2] = m_data->m_instance_scale_ptr[srcIndex*3+2]; } for (int i=0;im_numGraphicsInstances = 0; m_graphicsInstances[i]->m_instanceOffset = 0; m_graphicsInstances[i]->m_tempObjectUids.clear(); } for (int i=0;im_publicGraphicsInstances.getHandle(srcIndex2); m_graphicsInstances[pg->m_shapeIndex]->m_tempObjectUids.push_back(srcIndex2); } int curOffset = 0; m_data->m_totalNumInstances = 0; for (int i=0;im_instanceOffset = curOffset; m_graphicsInstances[i]->m_numGraphicsInstances = 0; for (int g=0;gm_tempObjectUids.size();g++) { curOffset++; int objectUniqueId = m_graphicsInstances[i]->m_tempObjectUids[g]; b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(objectUniqueId); registerGraphicsInstanceInternal(objectUniqueId,pg->m_position,pg->m_orientation,pg->m_color,pg->m_scale); } } } void GLInstancingRenderer::removeGraphicsInstance(int instanceUid) { b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(instanceUid); b3Assert(pg); if (pg) { m_data->m_publicGraphicsInstances.freeHandle(instanceUid); rebuildGraphicsInstances(); } } int GLInstancingRenderer::registerGraphicsInstanceInternal(int newUid, const float* position, const float* quaternion, const float* color, const float* scaling) { b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(newUid); int shapeIndex = pg->m_shapeIndex; // b3Assert(pg); // int objectIndex = pg->m_internalInstanceIndex; b3GraphicsInstance* gfxObj = m_graphicsInstances[shapeIndex]; int index = gfxObj->m_numGraphicsInstances + gfxObj->m_instanceOffset; pg->m_internalInstanceIndex = index; int maxElements = m_data->m_instance_positions_ptr.size(); if (index*4m_instance_positions_ptr[index*4]=position[0]; m_data->m_instance_positions_ptr[index*4+1]=position[1]; m_data->m_instance_positions_ptr[index*4+2]=position[2]; m_data->m_instance_positions_ptr[index*4+3]=1; m_data->m_instance_quaternion_ptr[index*4]=quaternion[0]; m_data->m_instance_quaternion_ptr[index*4+1]=quaternion[1]; m_data->m_instance_quaternion_ptr[index*4+2]=quaternion[2]; m_data->m_instance_quaternion_ptr[index*4+3]=quaternion[3]; m_data->m_instance_colors_ptr[index*4]=color[0]; m_data->m_instance_colors_ptr[index*4+1]=color[1]; m_data->m_instance_colors_ptr[index*4+2]=color[2]; m_data->m_instance_colors_ptr[index*4+3]=color[3]; m_data->m_instance_scale_ptr[index*3] = scaling[0]; m_data->m_instance_scale_ptr[index*3+1] = scaling[1]; m_data->m_instance_scale_ptr[index*3+2] = scaling[2]; if (color[3]<1 && color[3]>0) { gfxObj->m_flags |= eGfxTransparency; } gfxObj->m_numGraphicsInstances++; m_data->m_totalNumInstances++; } else { b3Error("registerGraphicsInstance out of range, %d\n", maxElements); return -1; } return newUid;//gfxObj->m_numGraphicsInstances; } int GLInstancingRenderer::registerGraphicsInstance(int shapeIndex, const float* position, const float* quaternion, const float* color, const float* scaling) { int newUid = m_data->m_publicGraphicsInstances.allocHandle(); b3PublicGraphicsInstance* pg = m_data->m_publicGraphicsInstances.getHandle(newUid); pg->m_shapeIndex = shapeIndex; //b3Assert(shapeIndex == (m_graphicsInstances.size()-1)); b3Assert(m_graphicsInstances.size()m_maxNumObjectCapacity-1); if (shapeIndex == (m_graphicsInstances.size()-1)) { registerGraphicsInstanceInternal(newUid, position,quaternion,color,scaling); } else { int srcIndex = m_data->m_totalNumInstances++; pg->m_internalInstanceIndex = srcIndex; m_data->m_instance_positions_ptr[srcIndex*4+0] = position[0]; m_data->m_instance_positions_ptr[srcIndex*4+1] = position[1]; m_data->m_instance_positions_ptr[srcIndex*4+2] = position[2]; m_data->m_instance_positions_ptr[srcIndex*4+3] = 1.; m_data->m_instance_quaternion_ptr[srcIndex*4+0] = quaternion[0]; m_data->m_instance_quaternion_ptr[srcIndex*4+1] = quaternion[1]; m_data->m_instance_quaternion_ptr[srcIndex*4+2] = quaternion[2]; m_data->m_instance_quaternion_ptr[srcIndex*4+3] = quaternion[3]; m_data->m_instance_colors_ptr[srcIndex*4+0] = color[0]; m_data->m_instance_colors_ptr[srcIndex*4+1] = color[1]; m_data->m_instance_colors_ptr[srcIndex*4+2] = color[2]; m_data->m_instance_colors_ptr[srcIndex*4+3] = color[3]; m_data->m_instance_scale_ptr[srcIndex*3+0] = scaling[0]; m_data->m_instance_scale_ptr[srcIndex*3+1] = scaling[1]; m_data->m_instance_scale_ptr[srcIndex*3+2] = scaling[2]; rebuildGraphicsInstances(); } return newUid; } int GLInstancingRenderer::registerTexture(const unsigned char* texels, int width, int height, bool flipPixelsY) { B3_PROFILE("GLInstancingRenderer::registerTexture"); b3Assert(glGetError() ==GL_NO_ERROR); glActiveTexture(GL_TEXTURE0); int textureIndex = m_data->m_textureHandles.size(); // const GLubyte* image= (const GLubyte*)texels; GLuint textureHandle; glGenTextures(1,(GLuint*)&textureHandle); glBindTexture(GL_TEXTURE_2D,textureHandle); b3Assert(glGetError() ==GL_NO_ERROR); InternalTextureHandle h; h.m_glTexture = textureHandle; h.m_width = width; h.m_height = height; h.m_enableFiltering = true; m_data->m_textureHandles.push_back(h); if (texels) { B3_PROFILE("updateTexture"); updateTexture(textureIndex, texels, flipPixelsY); } return textureIndex; } void GLInstancingRenderer::replaceTexture(int shapeIndex, int textureId) { if ((shapeIndex >=0) && (shapeIndex < m_graphicsInstances.size())) { b3GraphicsInstance* gfxObj = m_graphicsInstances[shapeIndex]; if (textureId>=0 && textureId < m_data->m_textureHandles.size()) { gfxObj->m_textureIndex = textureId; gfxObj->m_flags |= eGfxHasTexture; } } } void GLInstancingRenderer::updateTexture(int textureIndex, const unsigned char* texels, bool flipPixelsY) { B3_PROFILE("updateTexture"); if ((textureIndex>=0) && (textureIndex < m_data->m_textureHandles.size())) { glActiveTexture(GL_TEXTURE0); b3Assert(glGetError() ==GL_NO_ERROR); InternalTextureHandle& h = m_data->m_textureHandles[textureIndex]; glBindTexture(GL_TEXTURE_2D,h.m_glTexture); b3Assert(glGetError() ==GL_NO_ERROR); if (flipPixelsY) { B3_PROFILE("flipPixelsY"); //textures need to be flipped for OpenGL... b3AlignedObjectArray flippedTexels; flippedTexels.resize(h.m_width* h.m_height * 3); for (int j = 0; j < h.m_height; j++) { for (int i = 0; i < h.m_width; i++) { flippedTexels[(i + j*h.m_width) * 3] = texels[(i + (h.m_height - 1 -j )*h.m_width) * 3]; flippedTexels[(i + j*h.m_width) * 3+1] = texels[(i + (h.m_height - 1 - j)*h.m_width) * 3+1]; flippedTexels[(i + j*h.m_width) * 3+2] = texels[(i + (h.m_height - 1 - j)*h.m_width) * 3+2]; } } glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB, h.m_width,h.m_height,0,GL_RGB,GL_UNSIGNED_BYTE,&flippedTexels[0]); } else { glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB, h.m_width,h.m_height,0,GL_RGB,GL_UNSIGNED_BYTE,&texels[0]); } b3Assert(glGetError() ==GL_NO_ERROR); if (h.m_enableFiltering) { B3_PROFILE("glGenerateMipmap"); glGenerateMipmap(GL_TEXTURE_2D); } b3Assert(glGetError() ==GL_NO_ERROR); } } void GLInstancingRenderer::activateTexture(int textureIndex) { glActiveTexture(GL_TEXTURE0); if (textureIndex>=0 && textureIndex < m_data->m_textureHandles.size()) { glBindTexture(GL_TEXTURE_2D,m_data->m_textureHandles[textureIndex].m_glTexture); } else { glBindTexture(GL_TEXTURE_2D,0); } } void GLInstancingRenderer::updateShape(int shapeIndex, const float* vertices) { b3GraphicsInstance* gfxObj = m_graphicsInstances[shapeIndex]; int numvertices = gfxObj->m_numVertices; glBindBuffer(GL_ARRAY_BUFFER, m_data->m_vbo); char* dest= (char*)glMapBuffer( GL_ARRAY_BUFFER,GL_WRITE_ONLY);//GL_WRITE_ONLY int vertexStrideInBytes = 9*sizeof(float); int sz = numvertices*vertexStrideInBytes; memcpy(dest+vertexStrideInBytes*gfxObj->m_vertexArrayOffset,vertices,sz); glUnmapBuffer( GL_ARRAY_BUFFER); } int GLInstancingRenderer::registerShape(const float* vertices, int numvertices, const int* indices, int numIndices,int primitiveType, int textureId) { b3GraphicsInstance* gfxObj = new b3GraphicsInstance; if (textureId>=0) { gfxObj->m_textureIndex = textureId; gfxObj->m_flags |= eGfxHasTexture; } gfxObj->m_primitiveType = primitiveType; if (m_graphicsInstances.size()) { b3GraphicsInstance* prevObj = m_graphicsInstances[m_graphicsInstances.size()-1]; gfxObj->m_instanceOffset = prevObj->m_instanceOffset + prevObj->m_numGraphicsInstances; gfxObj->m_vertexArrayOffset = prevObj->m_vertexArrayOffset + prevObj->m_numVertices; } else { gfxObj->m_instanceOffset = 0; } m_graphicsInstances.push_back(gfxObj); gfxObj->m_numIndices = numIndices; gfxObj->m_numVertices = numvertices; int vertexStrideInBytes = 9*sizeof(float); int sz = numvertices*vertexStrideInBytes; int totalUsed = vertexStrideInBytes*gfxObj->m_vertexArrayOffset+sz; b3Assert(totalUsedm_maxShapeCapacityInBytes); if (totalUsed>=m_data->m_maxShapeCapacityInBytes) { return -1; } glBindBuffer(GL_ARRAY_BUFFER, m_data->m_vbo); #if 0 char* dest= (char*)glMapBuffer( GL_ARRAY_BUFFER,GL_WRITE_ONLY);//GL_WRITE_ONLY #ifdef B3_DEBUG #endif//B3_DEBUG memcpy(dest+vertexStrideInBytes*gfxObj->m_vertexArrayOffset,vertices,sz); glUnmapBuffer( GL_ARRAY_BUFFER); #else glBufferSubData( GL_ARRAY_BUFFER,vertexStrideInBytes*gfxObj->m_vertexArrayOffset,sz, vertices); #endif glGenBuffers(1, &gfxObj->m_index_vbo); glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, gfxObj->m_index_vbo); int indexBufferSizeInBytes = gfxObj->m_numIndices*sizeof(int); glBufferData(GL_ELEMENT_ARRAY_BUFFER, indexBufferSizeInBytes, NULL, GL_STATIC_DRAW); glBufferSubData(GL_ELEMENT_ARRAY_BUFFER,0,indexBufferSizeInBytes,indices); glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0); glGenVertexArrays(1, &gfxObj->m_cube_vao); glBindVertexArray(gfxObj->m_cube_vao); glBindBuffer(GL_ARRAY_BUFFER, m_data->m_vbo); glBindVertexArray(0); glBindBuffer(GL_ARRAY_BUFFER,0); glBindVertexArray(0); return m_graphicsInstances.size()-1; } void GLInstancingRenderer::InitShaders() { int POSITION_BUFFER_SIZE = (m_data->m_maxNumObjectCapacity*sizeof(float)*4); int ORIENTATION_BUFFER_SIZE = (m_data->m_maxNumObjectCapacity*sizeof(float)*4); int COLOR_BUFFER_SIZE = (m_data->m_maxNumObjectCapacity*sizeof(float)*4); int SCALE_BUFFER_SIZE = (m_data->m_maxNumObjectCapacity*sizeof(float)*3); { triangleShaderProgram = gltLoadShaderPair(triangleVertexShaderText,triangleFragmentShader); //triangle_vpos_location = glGetAttribLocation(triangleShaderProgram, "vPos"); //triangle_vUV_location = glGetAttribLocation(triangleShaderProgram, "vUV"); triangle_mvp_location = glGetUniformLocation(triangleShaderProgram, "MVP"); triangle_vcol_location = glGetUniformLocation(triangleShaderProgram, "vCol"); glLinkProgram(triangleShaderProgram); glUseProgram(triangleShaderProgram); glGenVertexArrays(1, &triangleVertexArrayObject); glBindVertexArray(triangleVertexArrayObject); glGenBuffers(1, &triangleVertexBufferObject); glGenBuffers(1, &triangleIndexVbo); int sz = MAX_TRIANGLES_IN_BATCH*sizeof(GfxVertexFormat0); glBindVertexArray(triangleVertexArrayObject); glBindBuffer(GL_ARRAY_BUFFER, triangleVertexBufferObject); glBufferData(GL_ARRAY_BUFFER, sz, 0, GL_DYNAMIC_DRAW); glBindVertexArray(0); } linesShader = gltLoadShaderPair(linesVertexShader,linesFragmentShader); lines_ModelViewMatrix = glGetUniformLocation(linesShader, "ModelViewMatrix"); lines_ProjectionMatrix = glGetUniformLocation(linesShader, "ProjectionMatrix"); lines_colour=glGetUniformLocation(linesShader, "colour"); lines_position=glGetAttribLocation(linesShader, "position"); glLinkProgram(linesShader); glUseProgram(linesShader); { glGenVertexArrays(1, &linesVertexArrayObject); glBindVertexArray(linesVertexArrayObject); glGenBuffers(1, &linesVertexBufferObject); glGenBuffers(1, &linesIndexVbo); int sz = MAX_LINES_IN_BATCH*sizeof(b3Vector3); glBindVertexArray(linesVertexArrayObject); glBindBuffer(GL_ARRAY_BUFFER, linesVertexBufferObject); glBufferData(GL_ARRAY_BUFFER, sz, 0, GL_DYNAMIC_DRAW); glBindVertexArray(0); } { glGenVertexArrays(1, &lineVertexArrayObject); glBindVertexArray(lineVertexArrayObject); glGenBuffers(1, &lineVertexBufferObject); glGenBuffers(1, &lineIndexVbo); int sz = MAX_POINTS_IN_BATCH*sizeof(b3Vector3); glBindVertexArray(lineVertexArrayObject); glBindBuffer(GL_ARRAY_BUFFER, lineVertexBufferObject); glBufferData(GL_ARRAY_BUFFER, sz, 0, GL_DYNAMIC_DRAW); glBindVertexArray(0); } //glGetIntegerv(GL_ALIASED_LINE_WIDTH_RANGE, range); glGetIntegerv(GL_SMOOTH_LINE_WIDTH_RANGE, lineWidthRange); useShadowMapInstancingShader = gltLoadShaderPair(useShadowMapInstancingVertexShader,useShadowMapInstancingFragmentShader); glLinkProgram(useShadowMapInstancingShader); glUseProgram(useShadowMapInstancingShader); useShadow_ViewMatrixInverse = glGetUniformLocation(useShadowMapInstancingShader, "ViewMatrixInverse"); useShadow_ModelViewMatrix = glGetUniformLocation(useShadowMapInstancingShader, "ModelViewMatrix"); useShadow_lightSpecularIntensity = glGetUniformLocation(useShadowMapInstancingShader, "lightSpecularIntensityIn"); useShadow_materialSpecularColor = glGetUniformLocation(useShadowMapInstancingShader, "materialSpecularColorIn"); useShadow_MVP = glGetUniformLocation(useShadowMapInstancingShader, "MVP"); useShadow_ProjectionMatrix = glGetUniformLocation(useShadowMapInstancingShader, "ProjectionMatrix"); useShadow_DepthBiasModelViewMatrix = glGetUniformLocation(useShadowMapInstancingShader, "DepthBiasModelViewProjectionMatrix"); useShadow_uniform_texture_diffuse = glGetUniformLocation(useShadowMapInstancingShader, "Diffuse"); useShadow_shadowMap = glGetUniformLocation(useShadowMapInstancingShader,"shadowMap"); useShadow_lightPosIn = glGetUniformLocation(useShadowMapInstancingShader,"lightPosIn"); useShadow_cameraPositionIn = glGetUniformLocation(useShadowMapInstancingShader,"cameraPositionIn"); useShadow_materialShininessIn = glGetUniformLocation(useShadowMapInstancingShader,"materialShininessIn"); createShadowMapInstancingShader = gltLoadShaderPair(createShadowMapInstancingVertexShader,createShadowMapInstancingFragmentShader); glLinkProgram(createShadowMapInstancingShader); glUseProgram(createShadowMapInstancingShader); createShadow_depthMVP = glGetUniformLocation(createShadowMapInstancingShader, "depthMVP"); glUseProgram(0); instancingShader = gltLoadShaderPair(instancingVertexShader,instancingFragmentShader); glLinkProgram(instancingShader); glUseProgram(instancingShader); ModelViewMatrix = glGetUniformLocation(instancingShader, "ModelViewMatrix"); ProjectionMatrix = glGetUniformLocation(instancingShader, "ProjectionMatrix"); uniform_texture_diffuse = glGetUniformLocation(instancingShader, "Diffuse"); regularLightDirIn = glGetUniformLocation(instancingShader,"lightDirIn"); glUseProgram(0); instancingShaderPointSprite = gltLoadShaderPair(pointSpriteVertexShader,pointSpriteFragmentShader); glUseProgram(instancingShaderPointSprite); ModelViewMatrixPointSprite = glGetUniformLocation(instancingShaderPointSprite, "ModelViewMatrix"); ProjectionMatrixPointSprite = glGetUniformLocation(instancingShaderPointSprite, "ProjectionMatrix"); screenWidthPointSprite = glGetUniformLocation(instancingShaderPointSprite, "screenWidth"); glUseProgram(0); //GLuint offset = 0; glGenBuffers(1, &m_data->m_vbo); checkError("glGenBuffers"); glBindBuffer(GL_ARRAY_BUFFER, m_data->m_vbo); int size = m_data->m_maxShapeCapacityInBytes + POSITION_BUFFER_SIZE+ORIENTATION_BUFFER_SIZE+COLOR_BUFFER_SIZE+SCALE_BUFFER_SIZE; m_data->m_vboSize = size; glBufferData(GL_ARRAY_BUFFER, size, 0, GL_DYNAMIC_DRAW);//GL_STATIC_DRAW); glBindBuffer(GL_ARRAY_BUFFER,0); glBindVertexArray(0); glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0); } void GLInstancingRenderer::init() { b3Assert(glGetError() ==GL_NO_ERROR); glEnable(GL_DEPTH_TEST); glDepthFunc(GL_LESS); b3Assert(glGetError() ==GL_NO_ERROR); // glClearColor(float(0.),float(0.),float(0.4),float(0)); b3Assert(glGetError() ==GL_NO_ERROR); b3Assert(glGetError() ==GL_NO_ERROR); { B3_PROFILE("texture"); if(m_textureenabled) { if(!m_textureinitialized) { glActiveTexture(GL_TEXTURE0); GLubyte* image=new GLubyte[256*256*3]; for(int y=0;y<256;++y) { // const int t=y>>5; GLubyte* pi=image+y*256*3; for(int x=0;x<256;++x) { if (x<2||y<2||x>253||y>253) { pi[0]=255;//0; pi[1]=255;//0; pi[2]=255;//0; } else { pi[0]=255; pi[1]=255; pi[2]=255; } /* const int s=x>>5; const GLubyte b=180; GLubyte c=b+((s+t&1)&1)*(255-b); pi[0]=c; pi[1]=c; pi[2]=c; */ pi+=3; } } glGenTextures(1,(GLuint*)&m_data->m_defaultTexturehandle); glBindTexture(GL_TEXTURE_2D,m_data->m_defaultTexturehandle); b3Assert(glGetError() ==GL_NO_ERROR); glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB, 256,256,0,GL_RGB,GL_UNSIGNED_BYTE,image); glGenerateMipmap(GL_TEXTURE_2D); b3Assert(glGetError() ==GL_NO_ERROR); delete[] image; m_textureinitialized=true; } b3Assert(glGetError() ==GL_NO_ERROR); glBindTexture(GL_TEXTURE_2D,m_data->m_defaultTexturehandle); b3Assert(glGetError() ==GL_NO_ERROR); } else { glDisable(GL_TEXTURE_2D); b3Assert(glGetError() ==GL_NO_ERROR); } } //glEnable(GL_COLOR_MATERIAL); b3Assert(glGetError() ==GL_NO_ERROR); // glEnable(GL_CULL_FACE); // glCullFace(GL_BACK); } void GLInstancingRenderer::resize(int width, int height) { m_screenWidth = width; m_screenHeight = height; } const CommonCameraInterface* GLInstancingRenderer::getActiveCamera() const { return m_data->m_activeCamera; } CommonCameraInterface* GLInstancingRenderer::getActiveCamera() { return m_data->m_activeCamera; } void GLInstancingRenderer::setActiveCamera(CommonCameraInterface* cam) { m_data->m_activeCamera = cam; } void GLInstancingRenderer::setLightSpecularIntensity(const float lightSpecularIntensity[3]) { m_data->m_lightSpecularIntensity[0] = lightSpecularIntensity[0]; m_data->m_lightSpecularIntensity[1] = lightSpecularIntensity[1]; m_data->m_lightSpecularIntensity[2] = lightSpecularIntensity[2]; } void GLInstancingRenderer::setLightPosition(const float lightPos[3]) { m_data->m_lightPos[0] = lightPos[0]; m_data->m_lightPos[1] = lightPos[1]; m_data->m_lightPos[2] = lightPos[2]; } void GLInstancingRenderer::setLightPosition(const double lightPos[3]) { m_data->m_lightPos[0] = lightPos[0]; m_data->m_lightPos[1] = lightPos[1]; m_data->m_lightPos[2] = lightPos[2]; } void GLInstancingRenderer::updateCamera(int upAxis) { b3Assert(glGetError() ==GL_NO_ERROR); m_upAxis = upAxis; m_data->m_activeCamera->setCameraUpAxis(upAxis); m_data->m_activeCamera->setAspectRatio((float)m_screenWidth/(float)m_screenHeight); m_data->m_defaultCamera1.update(); m_data->m_activeCamera->getCameraProjectionMatrix(m_data->m_projectionMatrix); m_data->m_activeCamera->getCameraViewMatrix(m_data->m_viewMatrix); b3Scalar viewMat[16]; b3Scalar viewMatInverse[16]; for (int i=0;i<16;i++) { viewMat[i] = m_data->m_viewMatrix[i]; } b3Transform tr; tr.setFromOpenGLMatrix(viewMat); tr = tr.inverse(); tr.getOpenGLMatrix(viewMatInverse); for (int i=0;i<16;i++) { m_data->m_viewMatrixInverse[i]=viewMatInverse[i]; } } //#define STB_IMAGE_WRITE_IMPLEMENTATION #include "stb_image/stb_image_write.h" void writeTextureToPng(int textureWidth, int textureHeight, const char* fileName, int numComponents) { b3Assert(glGetError() ==GL_NO_ERROR); glPixelStorei(GL_PACK_ALIGNMENT,4); glReadBuffer(GL_NONE); float* orgPixels = (float*)malloc(textureWidth*textureHeight*numComponents*4); char* pixels = (char*)malloc(textureWidth*textureHeight*numComponents*4); glReadPixels(0,0,textureWidth, textureHeight, GL_DEPTH_COMPONENT, GL_FLOAT, orgPixels); b3Assert(glGetError() ==GL_NO_ERROR); for (int j=0;jm_projectionMatrix,m_data->m_viewMatrix,viewProjection); float MVP[16]; b3Matrix4x4Mul16(viewProjection,modelMat,MVP); glUniformMatrix4fv(triangle_mvp_location, 1, GL_FALSE, (const GLfloat*) MVP); checkError("glUniformMatrix4fv"); glUniform3f(triangle_vcol_location,colorRGBA[0],colorRGBA[1],colorRGBA[2]); checkError("glUniform3f"); glBindVertexArray(triangleVertexArrayObject); checkError("glBindVertexArray"); glBindBuffer(GL_ARRAY_BUFFER, triangleVertexBufferObject); checkError("glBindBuffer"); glBufferData(GL_ARRAY_BUFFER, sizeof(GfxVertexFormat0)*numvertices, 0, GL_DYNAMIC_DRAW); glBufferSubData(GL_ARRAY_BUFFER, 0, sizeof(GfxVertexFormat0)*numvertices, vertices); PointerCaster posCast; posCast.m_baseIndex = 0; PointerCaster uvCast; uvCast.m_baseIndex = 8*sizeof(float); glVertexAttribPointer(0, 3, GL_FLOAT, GL_FALSE, sizeof(GfxVertexFormat0), posCast.m_pointer); glVertexAttribPointer(1, 2, GL_FLOAT, GL_FALSE, sizeof(GfxVertexFormat0), uvCast.m_pointer); checkError("glVertexAttribPointer"); glEnableVertexAttribArray(0); glEnableVertexAttribArray(1); glVertexAttribDivisor(0,0); glVertexAttribDivisor(1,0); checkError("glVertexAttribDivisor"); glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, triangleIndexVbo); int indexBufferSizeInBytes = numIndices*sizeof(int); glBufferData(GL_ELEMENT_ARRAY_BUFFER, numIndices*sizeof(int), NULL, GL_DYNAMIC_DRAW); glBufferSubData(GL_ELEMENT_ARRAY_BUFFER, 0, numIndices*sizeof(int), indices); glDrawElements(GL_TRIANGLES, numIndices, GL_UNSIGNED_INT, 0); //glDrawElements(GL_TRIANGLES, numIndices, GL_UNSIGNED_INT,indices); checkError("glDrawElements"); glActiveTexture(GL_TEXTURE0); glBindTexture(GL_TEXTURE_2D,0); glUseProgram(0); glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0); glBindBuffer(GL_ARRAY_BUFFER,0); glBindVertexArray(0); checkError("glBindVertexArray"); } void GLInstancingRenderer::drawPoint(const double* position, const double color[4], double pointDrawSize) { float pos[4]={(float)position[0],(float)position[1],(float)position[2],0}; float clr[4] = {(float)color[0],(float)color[1],(float)color[2],(float)color[3]}; drawPoints(pos,clr,1,3*sizeof(float),float(pointDrawSize)); } void GLInstancingRenderer::drawPoint(const float* positions, const float color[4], float pointDrawSize) { drawPoints(positions,color,1,3*sizeof(float),pointDrawSize); } void GLInstancingRenderer::drawPoints(const float* positions, const float color[4], int numPoints, int pointStrideInBytes, float pointDrawSize) { glActiveTexture(GL_TEXTURE0); glBindTexture(GL_TEXTURE_2D,0); b3Assert(glGetError() ==GL_NO_ERROR); glUseProgram(linesShader); glUniformMatrix4fv(lines_ProjectionMatrix, 1, false, &m_data->m_projectionMatrix[0]); glUniformMatrix4fv(lines_ModelViewMatrix, 1, false, &m_data->m_viewMatrix[0]); glUniform4f(lines_colour,color[0],color[1],color[2],color[3]); glPointSize(pointDrawSize); glBindVertexArray(lineVertexArrayObject); glBindBuffer(GL_ARRAY_BUFFER, lineVertexBufferObject); int maxPointsInBatch = MAX_POINTS_IN_BATCH; int remainingPoints = numPoints; int offsetNumPoints= 0; while (1) { int curPointsInBatch = b3Min(maxPointsInBatch, remainingPoints); if (curPointsInBatch) { glBufferSubData(GL_ARRAY_BUFFER, 0, curPointsInBatch*pointStrideInBytes, positions + offsetNumPoints*(pointStrideInBytes / sizeof(float))); glEnableVertexAttribArray(0); int numFloats = 3;// pointStrideInBytes / sizeof(float); glVertexAttribPointer(0, numFloats, GL_FLOAT, GL_FALSE, pointStrideInBytes, 0); glDrawArrays(GL_POINTS, 0, curPointsInBatch); remainingPoints -= curPointsInBatch; offsetNumPoints += curPointsInBatch; } else { break; } } glBindVertexArray(0); glPointSize(1); glUseProgram(0); } void GLInstancingRenderer::drawLines(const float* positions, const float color[4], int numPoints, int pointStrideInBytes, const unsigned int* indices, int numIndices, float lineWidthIn) { glActiveTexture(GL_TEXTURE0); glBindTexture(GL_TEXTURE_2D,0); float lineWidth = lineWidthIn; b3Clamp(lineWidth,(float)lineWidthRange[0],(float)lineWidthRange[1]); glLineWidth(lineWidth); glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0); glActiveTexture(GL_TEXTURE0); glBindTexture(GL_TEXTURE_2D,0); b3Assert(glGetError() ==GL_NO_ERROR); glUseProgram(linesShader); glUniformMatrix4fv(lines_ProjectionMatrix, 1, false, &m_data->m_projectionMatrix[0]); glUniformMatrix4fv(lines_ModelViewMatrix, 1, false, &m_data->m_viewMatrix[0]); glUniform4f(lines_colour,color[0],color[1],color[2],color[3]); // glPointSize(pointDrawSize); glBindVertexArray(linesVertexArrayObject); b3Assert(glGetError() ==GL_NO_ERROR); glBindBuffer(GL_ARRAY_BUFFER, linesVertexBufferObject); { glBufferData(GL_ARRAY_BUFFER, numPoints*pointStrideInBytes, 0,GL_DYNAMIC_DRAW); glBufferSubData(GL_ARRAY_BUFFER, 0, numPoints*pointStrideInBytes, positions); b3Assert(glGetError() ==GL_NO_ERROR); glBindBuffer(GL_ARRAY_BUFFER, 0); glBindBuffer(GL_ARRAY_BUFFER, linesVertexBufferObject); glEnableVertexAttribArray(0); b3Assert(glGetError() ==GL_NO_ERROR); int numFloats = 3; glVertexAttribPointer(0, numFloats, GL_FLOAT, GL_FALSE, pointStrideInBytes, 0); b3Assert(glGetError() ==GL_NO_ERROR); glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, linesIndexVbo); int indexBufferSizeInBytes = numIndices*sizeof(int); glBufferData(GL_ELEMENT_ARRAY_BUFFER, indexBufferSizeInBytes, NULL, GL_DYNAMIC_DRAW); glBufferSubData(GL_ELEMENT_ARRAY_BUFFER, 0, indexBufferSizeInBytes, indices); glDrawElements(GL_LINES, numIndices, GL_UNSIGNED_INT, 0); } glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0); glBindBuffer(GL_ARRAY_BUFFER, 0); // for (int i=0;im_projectionMatrix[0]); glUniformMatrix4fv(lines_ModelViewMatrix, 1, false, &m_data->m_viewMatrix[0]); glUniform4f(lines_colour,color[0],color[1],color[2],color[3]); b3Assert(glGetError() ==GL_NO_ERROR); const float vertexPositions[] = { from[0],from[1],from[2],1, to[0],to[1],to[2],1 }; int sz = sizeof(vertexPositions); b3Assert(glGetError() ==GL_NO_ERROR); b3Clamp(lineWidth,(float)lineWidthRange[0],(float)lineWidthRange[1]); glLineWidth(lineWidth); b3Assert(glGetError() ==GL_NO_ERROR); glBindVertexArray(lineVertexArrayObject); b3Assert(glGetError() ==GL_NO_ERROR); glBindBuffer(GL_ARRAY_BUFFER, lineVertexBufferObject); b3Assert(glGetError() ==GL_NO_ERROR); { glBufferSubData(GL_ARRAY_BUFFER, 0,sz, vertexPositions); } b3Assert(glGetError() ==GL_NO_ERROR); glBindBuffer(GL_ARRAY_BUFFER, 0); glBindBuffer(GL_ARRAY_BUFFER, lineVertexBufferObject); b3Assert(glGetError() ==GL_NO_ERROR); glEnableVertexAttribArray(0); glVertexAttribPointer(0, 4, GL_FLOAT, GL_FALSE, 0, 0); b3Assert(glGetError() ==GL_NO_ERROR); glDrawArrays(GL_LINES, 0, 2); b3Assert(glGetError() ==GL_NO_ERROR); glBindVertexArray(0); glLineWidth(1); b3Assert(glGetError() ==GL_NO_ERROR); glUseProgram(0); } struct SortableTransparentInstance { int m_shapeIndex; int m_instanceId; b3Vector3 m_centerPosition; }; struct TransparentDistanceSortPredicate { b3Vector3 m_camForwardVec; inline bool operator() (const SortableTransparentInstance& a, const SortableTransparentInstance& b) const { b3Scalar projA = a.m_centerPosition.dot(m_camForwardVec); b3Scalar projB = b.m_centerPosition.dot(m_camForwardVec); return (projA > projB); } }; void GLInstancingRenderer::renderSceneInternal(int orgRenderMode) { int renderMode=orgRenderMode; bool reflectionPass = false; if (orgRenderMode==B3_USE_SHADOWMAP_RENDERMODE_REFLECTION) { reflectionPass = true; renderMode = B3_USE_SHADOWMAP_RENDERMODE; } if (!useShadowMap) { renderMode = B3_DEFAULT_RENDERMODE; } // glEnable(GL_DEPTH_TEST); GLint dims[4]; glGetIntegerv(GL_VIEWPORT, dims); //we need to get the viewport dims, because on Apple Retina the viewport dimension is different from screenWidth //printf("dims=%d,%d,%d,%d\n",dims[0],dims[1],dims[2],dims[3]); // Accept fragment if it closer to the camera than the former one //glDepthFunc(GL_LESS); // Cull triangles which normal is not towards the camera glEnable(GL_CULL_FACE); B3_PROFILE("GLInstancingRenderer::RenderScene"); { B3_PROFILE("init"); init(); } b3Assert(glGetError() ==GL_NO_ERROR); float depthProjectionMatrix[4][4]; GLfloat depthModelViewMatrix[4][4]; //GLfloat depthModelViewMatrix2[4][4]; // Compute the MVP matrix from the light's point of view if (renderMode==B3_CREATE_SHADOWMAP_RENDERMODE) { glEnable(GL_CULL_FACE); glCullFace(GL_FRONT); if (!m_data->m_shadowMap) { glActiveTexture(GL_TEXTURE0); glGenTextures(1,&m_data->m_shadowTexture); glBindTexture(GL_TEXTURE_2D,m_data->m_shadowTexture); //glTexImage2D(GL_TEXTURE_2D,0,GL_DEPTH_COMPONENT16,m_screenWidth,m_screenHeight,0,GL_DEPTH_COMPONENT,GL_FLOAT,0); //glTexImage2D(GL_TEXTURE_2D,0,GL_DEPTH_COMPONENT32,m_screenWidth,m_screenHeight,0,GL_DEPTH_COMPONENT,GL_FLOAT,0); #ifdef OLD_SHADOWMAP_INIT glTexImage2D(GL_TEXTURE_2D, 0,GL_DEPTH_COMPONENT16, shadowMapWidth, shadowMapHeight, 0,GL_DEPTH_COMPONENT, GL_FLOAT, 0); #else//OLD_SHADOWMAP_INIT //Reduce size of shadowMap if glTexImage2D call fails as may happen in some cases //https://github.com/bulletphysics/bullet3/issues/40 int size; glGetIntegerv(GL_MAX_TEXTURE_SIZE, &size); if (size < shadowMapWidth){ shadowMapWidth = size; } if (size < shadowMapHeight){ shadowMapHeight = size; } GLuint err; do { glTexImage2D(GL_TEXTURE_2D, 0, GL_DEPTH_COMPONENT16, shadowMapWidth, shadowMapHeight, 0, GL_DEPTH_COMPONENT, GL_FLOAT, 0); err = glGetError(); if (err!=GL_NO_ERROR){ shadowMapHeight >>= 1; shadowMapWidth >>= 1; } } while (err != GL_NO_ERROR && shadowMapWidth > 0); #endif//OLD_SHADOWMAP_INIT glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR); float l_ClampColor[] = {1.0, 1.0, 1.0, 1.0}; glTexParameterfv(GL_TEXTURE_2D, GL_TEXTURE_BORDER_COLOR, l_ClampColor); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_BORDER); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_BORDER); // glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE); // glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_COMPARE_FUNC, GL_LEQUAL); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_COMPARE_MODE, GL_COMPARE_REF_TO_TEXTURE); m_data->m_shadowMap=new GLRenderToTexture(); m_data->m_shadowMap->init(shadowMapWidth, shadowMapHeight,m_data->m_shadowTexture,RENDERTEXTURE_DEPTH); } m_data->m_shadowMap->enable(); glViewport(0,0,shadowMapWidth,shadowMapHeight); //glClearColor(1,1,1,1); glClear(GL_DEPTH_BUFFER_BIT); //glClearColor(0.3,0.3,0.3,1); // m_data->m_shadowMap->disable(); // return; glEnable(GL_CULL_FACE); glCullFace(GL_FRONT); // Cull back-facing triangles -> draw only front-facing triangles b3Assert(glGetError() ==GL_NO_ERROR); } else { glEnable(GL_CULL_FACE); glCullFace(GL_BACK); } b3CreateOrtho(-shadowMapWorldSize,shadowMapWorldSize,-shadowMapWorldSize,shadowMapWorldSize,1,300,depthProjectionMatrix);//-14,14,-14,14,1,200, depthProjectionMatrix); float depthViewMatrix[4][4]; b3Vector3 center = b3MakeVector3(0,0,0); //float upf[3]; //m_data->m_activeCamera->getCameraUpVector(upf); b3Vector3 up, lightFwd; b3Vector3 lightDir = m_data->m_lightPos.normalized(); b3PlaneSpace1(lightDir,up,lightFwd); // b3Vector3 up = b3MakeVector3(upf[0],upf[1],upf[2]); b3CreateLookAt(m_data->m_lightPos,center,up,&depthViewMatrix[0][0]); //b3CreateLookAt(lightPos,m_data->m_cameraTargetPosition,b3Vector3(0,1,0),(float*)depthModelViewMatrix2); GLfloat depthModelMatrix[4][4]; b3CreateDiagonalMatrix(1.f,depthModelMatrix); b3Matrix4x4Mul(depthViewMatrix, depthModelMatrix, depthModelViewMatrix); GLfloat depthMVP[4][4]; b3Matrix4x4Mul(depthProjectionMatrix,depthModelViewMatrix,depthMVP); GLfloat biasMatrix[4][4]={ { 0.5, 0.0, 0.0, 0.0 }, { 0.0, 0.5, 0.0, 0.0 }, { 0.0, 0.0, 0.5, 0.0 }, { 0.5, 0.5, 0.5, 1.0 } }; GLfloat depthBiasMVP[4][4]; b3Matrix4x4Mul(biasMatrix,depthMVP,depthBiasMVP); //float m_frustumZNear=0.1; //float m_frustumZFar=100.f; //b3CreateFrustum(-m_frustumZNear, m_frustumZNear, -m_frustumZNear, m_frustumZNear, m_frustumZNear, m_frustumZFar,(float*)depthProjectionMatrix); //b3CreateLookAt(lightPos,m_data->m_cameraTargetPosition,b3Vector3(0,0,1),(float*)depthModelViewMatrix); { B3_PROFILE("updateCamera"); // updateCamera(); m_data->m_activeCamera->getCameraProjectionMatrix(m_data->m_projectionMatrix); m_data->m_activeCamera->getCameraViewMatrix(m_data->m_viewMatrix); } b3Assert(glGetError() ==GL_NO_ERROR); // glBindBuffer(GL_ARRAY_BUFFER, 0); { B3_PROFILE("glFlush2"); glBindBuffer(GL_ARRAY_BUFFER, m_data->m_vbo); //glFlush(); } b3Assert(glGetError() ==GL_NO_ERROR); int totalNumInstances = 0; for (int i=0;im_numGraphicsInstances; } b3AlignedObjectArray transparentInstances; { int curOffset = 0; //GLuint lastBindTexture = 0; transparentInstances.reserve(totalNumInstances); for (int obj=0;objm_numGraphicsInstances) { SortableTransparentInstance inst; inst.m_shapeIndex = obj; if ((gfxObj->m_flags&eGfxTransparency)==0) { inst.m_instanceId = curOffset; inst.m_centerPosition.setValue(m_data->m_instance_positions_ptr[inst.m_instanceId*4+0], m_data->m_instance_positions_ptr[inst.m_instanceId*4+1], m_data->m_instance_positions_ptr[inst.m_instanceId*4+2]); inst.m_centerPosition *= -1;//reverse sort opaque instances transparentInstances.push_back(inst); } else { for (int i=0;im_numGraphicsInstances;i++) { inst.m_instanceId = curOffset+i; inst.m_centerPosition.setValue(m_data->m_instance_positions_ptr[inst.m_instanceId*4+0], m_data->m_instance_positions_ptr[inst.m_instanceId*4+1], m_data->m_instance_positions_ptr[inst.m_instanceId*4+2]); transparentInstances.push_back(inst); } } curOffset+=gfxObj->m_numGraphicsInstances; } } TransparentDistanceSortPredicate sorter; float fwd[3]; m_data->m_activeCamera->getCameraForwardVector(fwd); sorter.m_camForwardVec.setValue(fwd[0],fwd[1],fwd[2]); transparentInstances.quickSort(sorter); } //two passes: first for opaque instances, second for transparent ones. for (int pass = 0; pass<2;pass++) { for (int i=0;im_flags&eGfxTransparency)==0); //transparent objects don't cast shadows (to simplify things) if (gfxObj->m_flags&eGfxTransparency) { if (renderMode==B3_CREATE_SHADOWMAP_RENDERMODE) drawThisPass = 0; } if (drawThisPass && gfxObj->m_numGraphicsInstances) { glActiveTexture(GL_TEXTURE0); GLuint curBindTexture = 0; if (gfxObj->m_flags & eGfxHasTexture) { curBindTexture = m_data->m_textureHandles[gfxObj->m_textureIndex].m_glTexture; glTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_BASE_LEVEL,0); if (m_data->m_textureHandles[gfxObj->m_textureIndex].m_enableFiltering) { glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR); } else { glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST); } } else { curBindTexture = m_data->m_defaultTexturehandle; } //disable lazy evaluation, it just leads to bugs //if (lastBindTexture != curBindTexture) { glBindTexture(GL_TEXTURE_2D,curBindTexture); } //lastBindTexture = curBindTexture; b3Assert(glGetError() ==GL_NO_ERROR); // int myOffset = gfxObj->m_instanceOffset*4*sizeof(float); int POSITION_BUFFER_SIZE = (totalNumInstances*sizeof(float)*4); int ORIENTATION_BUFFER_SIZE = (totalNumInstances*sizeof(float)*4); int COLOR_BUFFER_SIZE = (totalNumInstances*sizeof(float)*4); // int SCALE_BUFFER_SIZE = (totalNumInstances*sizeof(float)*3); glBindVertexArray(gfxObj->m_cube_vao); int vertexStride = 9*sizeof(float); PointerCaster vertex; vertex.m_baseIndex = gfxObj->m_vertexArrayOffset*vertexStride; glVertexAttribPointer(0, 4, GL_FLOAT, GL_FALSE, 9*sizeof(float), vertex.m_pointer); glVertexAttribPointer(1, 4, GL_FLOAT, GL_FALSE, 0, (GLvoid *)(transparentInstances[i].m_instanceId*4*sizeof(float)+m_data->m_maxShapeCapacityInBytes)); glVertexAttribPointer(2, 4, GL_FLOAT, GL_FALSE, 0, (GLvoid *)(transparentInstances[i].m_instanceId*4*sizeof(float)+m_data->m_maxShapeCapacityInBytes+POSITION_BUFFER_SIZE)); PointerCaster uv; uv.m_baseIndex = 7*sizeof(float)+vertex.m_baseIndex; PointerCaster normal; normal.m_baseIndex = 4*sizeof(float)+vertex.m_baseIndex; glVertexAttribPointer(3, 2, GL_FLOAT, GL_FALSE, 9*sizeof(float), uv.m_pointer); glVertexAttribPointer(4, 3, GL_FLOAT, GL_FALSE, 9*sizeof(float), normal.m_pointer); glVertexAttribPointer(5, 4, GL_FLOAT, GL_FALSE, 0, (GLvoid *)(transparentInstances[i].m_instanceId*4*sizeof(float)+m_data->m_maxShapeCapacityInBytes+POSITION_BUFFER_SIZE+ORIENTATION_BUFFER_SIZE)); glVertexAttribPointer(6, 3, GL_FLOAT, GL_FALSE, 0, (GLvoid *)(transparentInstances[i].m_instanceId*3*sizeof(float)+m_data->m_maxShapeCapacityInBytes+POSITION_BUFFER_SIZE+ORIENTATION_BUFFER_SIZE+COLOR_BUFFER_SIZE)); glEnableVertexAttribArray(0); glEnableVertexAttribArray(1); glEnableVertexAttribArray(2); glEnableVertexAttribArray(3); glEnableVertexAttribArray(4); glEnableVertexAttribArray(5); glEnableVertexAttribArray(6); glVertexAttribDivisor(0, 0); glVertexAttribDivisor(1, 1); glVertexAttribDivisor(2, 1); glVertexAttribDivisor(3, 0); glVertexAttribDivisor(4, 0); glVertexAttribDivisor(5, 1); glVertexAttribDivisor(6, 1); int indexCount = gfxObj->m_numIndices; GLvoid* indexOffset = 0; glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, gfxObj->m_index_vbo); { B3_PROFILE("glDrawElementsInstanced"); if (gfxObj->m_primitiveType==B3_GL_POINTS) { glUseProgram(instancingShaderPointSprite); glUniformMatrix4fv(ProjectionMatrixPointSprite, 1, false, &m_data->m_projectionMatrix[0]); glUniformMatrix4fv(ModelViewMatrixPointSprite, 1, false, &m_data->m_viewMatrix[0]); glUniform1f(screenWidthPointSprite,float(m_screenWidth)); //glUniform1i(uniform_texture_diffusePointSprite, 0); b3Assert(glGetError() ==GL_NO_ERROR); glPointSize(20); #ifndef __APPLE__ glEnable(GL_POINT_SPRITE_ARB); // glTexEnvi(GL_POINT_SPRITE_ARB, GL_COORD_REPLACE_ARB, GL_TRUE); #endif glEnable(GL_VERTEX_PROGRAM_POINT_SIZE); glDrawElementsInstanced(GL_POINTS, indexCount, GL_UNSIGNED_INT, indexOffset, gfxObj->m_numGraphicsInstances); } else { switch (renderMode) { case B3_DEFAULT_RENDERMODE: { if ( gfxObj->m_flags&eGfxTransparency) { glDepthMask(false); glEnable (GL_BLEND); glBlendFunc (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); } glUseProgram(instancingShader); glUniformMatrix4fv(ProjectionMatrix, 1, false, &m_data->m_projectionMatrix[0]); glUniformMatrix4fv(ModelViewMatrix, 1, false, &m_data->m_viewMatrix[0]); b3Vector3 gLightDir = m_data->m_lightPos; gLightDir.normalize(); glUniform3f(regularLightDirIn,gLightDir[0],gLightDir[1],gLightDir[2]); glUniform1i(uniform_texture_diffuse, 0); if ( gfxObj->m_flags&eGfxTransparency) { int instanceId = transparentInstances[i].m_instanceId; glVertexAttribPointer(1, 4, GL_FLOAT, GL_FALSE, 0, (GLvoid *)((instanceId)*4*sizeof(float)+m_data->m_maxShapeCapacityInBytes)); glVertexAttribPointer(2, 4, GL_FLOAT, GL_FALSE, 0, (GLvoid *)((instanceId)*4*sizeof(float)+m_data->m_maxShapeCapacityInBytes+POSITION_BUFFER_SIZE)); glVertexAttribPointer(5, 4, GL_FLOAT, GL_FALSE, 0, (GLvoid *)((instanceId)*4*sizeof(float)+m_data->m_maxShapeCapacityInBytes+POSITION_BUFFER_SIZE+ORIENTATION_BUFFER_SIZE)); glVertexAttribPointer(6, 3, GL_FLOAT, GL_FALSE, 0, (GLvoid *)((instanceId)*3*sizeof(float)+m_data->m_maxShapeCapacityInBytes+POSITION_BUFFER_SIZE+ORIENTATION_BUFFER_SIZE+COLOR_BUFFER_SIZE)); glDrawElements(GL_TRIANGLES, indexCount, GL_UNSIGNED_INT, 0); } else { glDrawElementsInstanced(GL_TRIANGLES, indexCount, GL_UNSIGNED_INT, indexOffset, gfxObj->m_numGraphicsInstances); } if ( gfxObj->m_flags&eGfxTransparency) { glDisable (GL_BLEND); glDepthMask(true); } break; } case B3_CREATE_SHADOWMAP_RENDERMODE: { glUseProgram(createShadowMapInstancingShader); glUniformMatrix4fv(createShadow_depthMVP, 1, false, &depthMVP[0][0]); glDrawElementsInstanced(GL_TRIANGLES, indexCount, GL_UNSIGNED_INT, indexOffset, gfxObj->m_numGraphicsInstances); break; } case B3_USE_SHADOWMAP_RENDERMODE: { if ( gfxObj->m_flags&eGfxTransparency) { glDepthMask(false); glEnable (GL_BLEND); glBlendFunc (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); } glUseProgram(useShadowMapInstancingShader); glUniformMatrix4fv(useShadow_ProjectionMatrix, 1, false, &m_data->m_projectionMatrix[0]); //glUniformMatrix4fv(useShadow_ModelViewMatrix, 1, false, &m_data->m_viewMatrix[0]); //glUniformMatrix4fv(useShadow_ViewMatrixInverse, 1, false, &m_data->m_viewMatrix[0]); //glUniformMatrix4fv(useShadow_ViewMatrixInverse, 1, false, &m_data->m_viewMatrixInverse[0]); //glUniformMatrix4fv(useShadow_ModelViewMatrix, 1, false, &m_data->m_viewMatrix[0]); glUniform3f(useShadow_lightSpecularIntensity, m_data->m_lightSpecularIntensity[0],m_data->m_lightSpecularIntensity[1],m_data->m_lightSpecularIntensity[2]); glUniform3f(useShadow_materialSpecularColor, gfxObj->m_materialSpecularColor[0],gfxObj->m_materialSpecularColor[1],gfxObj->m_materialSpecularColor[2]); float MVP[16]; if (reflectionPass) { float tmp[16]; float reflectionMatrix[16] = {1,0,0,0, 0,1,0,0, 0,0,-1,0, 0,0,0,1}; glCullFace(GL_FRONT); b3Matrix4x4Mul16(m_data->m_viewMatrix,reflectionMatrix,tmp); b3Matrix4x4Mul16(m_data->m_projectionMatrix,tmp,MVP); } else { b3Matrix4x4Mul16(m_data->m_projectionMatrix,m_data->m_viewMatrix,MVP); glCullFace(GL_BACK); } glUniformMatrix4fv(useShadow_MVP, 1, false, &MVP[0]); //gLightDir.normalize(); glUniform3f(useShadow_lightPosIn,m_data->m_lightPos[0],m_data->m_lightPos[1],m_data->m_lightPos[2]); float camPos[3]; m_data->m_activeCamera->getCameraPosition(camPos); glUniform3f(useShadow_cameraPositionIn,camPos[0],camPos[1],camPos[2]); glUniform1f(useShadow_materialShininessIn,gfxObj->m_materialShinyNess); glUniformMatrix4fv(useShadow_DepthBiasModelViewMatrix, 1, false, &depthBiasMVP[0][0]); glActiveTexture(GL_TEXTURE1); glBindTexture(GL_TEXTURE_2D, m_data->m_shadowTexture); glUniform1i(useShadow_shadowMap,1); //sort transparent objects //gfxObj->m_instanceOffset if ( gfxObj->m_flags&eGfxTransparency) { int instanceId = transparentInstances[i].m_instanceId; glVertexAttribPointer(1, 4, GL_FLOAT, GL_FALSE, 0, (GLvoid *)((instanceId)*4*sizeof(float)+m_data->m_maxShapeCapacityInBytes)); glVertexAttribPointer(2, 4, GL_FLOAT, GL_FALSE, 0, (GLvoid *)((instanceId)*4*sizeof(float)+m_data->m_maxShapeCapacityInBytes+POSITION_BUFFER_SIZE)); glVertexAttribPointer(5, 4, GL_FLOAT, GL_FALSE, 0, (GLvoid *)((instanceId)*4*sizeof(float)+m_data->m_maxShapeCapacityInBytes+POSITION_BUFFER_SIZE+ORIENTATION_BUFFER_SIZE)); glVertexAttribPointer(6, 3, GL_FLOAT, GL_FALSE, 0, (GLvoid *)((instanceId)*3*sizeof(float)+m_data->m_maxShapeCapacityInBytes+POSITION_BUFFER_SIZE+ORIENTATION_BUFFER_SIZE+COLOR_BUFFER_SIZE)); glDrawElements(GL_TRIANGLES, indexCount, GL_UNSIGNED_INT, 0); } else { glDrawElementsInstanced(GL_TRIANGLES, indexCount, GL_UNSIGNED_INT, indexOffset, gfxObj->m_numGraphicsInstances); } if ( gfxObj->m_flags&eGfxTransparency) { glDisable (GL_BLEND); glDepthMask(true); } glActiveTexture(GL_TEXTURE1); glBindTexture(GL_TEXTURE_2D,0); glActiveTexture(GL_TEXTURE0); glBindTexture(GL_TEXTURE_2D,0); break; } default: { // b3Assert(0); } }; } //glDrawElementsInstanced(GL_LINE_LOOP, indexCount, GL_UNSIGNED_INT, (void*)indexOffset, gfxObj->m_numGraphicsInstances); } } } } { B3_PROFILE("glFlush"); //glFlush(); } if (renderMode==B3_CREATE_SHADOWMAP_RENDERMODE) { // writeTextureToPng(shadowMapWidth,shadowMapHeight,"shadowmap.png",4); m_data->m_shadowMap->disable(); glBindFramebuffer( GL_FRAMEBUFFER, m_data->m_renderFrameBuffer); glViewport(dims[0],dims[1],dims[2],dims[3]); } b3Assert(glGetError() ==GL_NO_ERROR); { B3_PROFILE("glUseProgram(0);"); glUseProgram(0); glBindBuffer(GL_ARRAY_BUFFER,0); glBindVertexArray(0); } glDisable(GL_CULL_FACE); b3Assert(glGetError() ==GL_NO_ERROR); } void GLInstancingRenderer::CleanupShaders() { } void GLInstancingRenderer::enableShadowMap() { glActiveTexture(GL_TEXTURE0); //glEnable(GL_TEXTURE_2D); glBindTexture(GL_TEXTURE_2D, m_data->m_shadowTexture); //glBindTexture(GL_TEXTURE_2D, m_data->m_defaultTexturehandle); } void GLInstancingRenderer::clearZBuffer() { glClear(GL_DEPTH_BUFFER_BIT); } int GLInstancingRenderer::getMaxShapeCapacity() const { return m_data->m_maxShapeCapacityInBytes; } int GLInstancingRenderer::getInstanceCapacity() const { return m_data->m_maxNumObjectCapacity; } void GLInstancingRenderer::setRenderFrameBuffer(unsigned int renderFrameBuffer) { m_data->m_renderFrameBuffer = (GLuint) renderFrameBuffer; } int GLInstancingRenderer::getTotalNumInstances() const { return m_data->m_totalNumInstances; } #endif //NO_OPENGL3