/* * Copyright 2011-2014 Branimir Karadzic. All rights reserved. * License: http://www.opensource.org/licenses/BSD-2-Clause */ #include "common.h" #include "bgfx_utils.h" #include "imgui/imgui.h" #include "camera.h" #include "bounds.h" #define RENDER_PASS_GEOMETRY_ID 0 #define RENDER_PASS_GEOMETRY_BIT (1< caps->maxFBAttachments) { // When multiple render targets (MRT) is not supported by GPU, // implement alternative code path that doesn't use MRT. bool blink = uint32_t(time*3.0f)&1; bgfx::dbgTextPrintf(0, 5, blink ? 0x1f : 0x01, " MRT not supported by GPU. "); // Set view 0 default viewport. bgfx::setViewRect(0, 0, 0, width, height); // This dummy draw call is here to make sure that view 0 is cleared // if no other draw calls are submitted to view 0. bgfx::submit(0); } else { if (oldWidth != width || oldHeight != height || oldReset != reset || !bgfx::isValid(gbuffer) ) { // Recreate variable size render targets when resolution changes. oldWidth = width; oldHeight = height; oldReset = reset; if (bgfx::isValid(gbuffer) ) { bgfx::destroyFrameBuffer(gbuffer); } const uint32_t samplerFlags = 0 | BGFX_TEXTURE_RT | BGFX_TEXTURE_MIN_POINT | BGFX_TEXTURE_MAG_POINT | BGFX_TEXTURE_MIP_POINT | BGFX_TEXTURE_U_CLAMP | BGFX_TEXTURE_V_CLAMP ; gbufferTex[0] = bgfx::createTexture2D(width, height, 1, bgfx::TextureFormat::BGRA8, samplerFlags); gbufferTex[1] = bgfx::createTexture2D(width, height, 1, bgfx::TextureFormat::BGRA8, samplerFlags); gbufferTex[2] = bgfx::createTexture2D(width, height, 1, bgfx::TextureFormat::D24, samplerFlags); gbuffer = bgfx::createFrameBuffer(BX_COUNTOF(gbufferTex), gbufferTex, true); if (bgfx::isValid(lightBuffer) ) { bgfx::destroyFrameBuffer(lightBuffer); } lightBuffer = bgfx::createFrameBuffer(width, height, bgfx::TextureFormat::BGRA8, samplerFlags); } imguiBeginFrame(mouseState.m_mx , mouseState.m_my , (mouseState.m_buttons[entry::MouseButton::Left ] ? IMGUI_MBUT_LEFT : 0) | (mouseState.m_buttons[entry::MouseButton::Right ] ? IMGUI_MBUT_RIGHT : 0) , 0 , width , height ); imguiBeginScrollArea("Settings", width - width / 5 - 10, 10, width / 5, height / 3, &scrollArea); imguiSeparatorLine(); imguiSlider("Num lights", numLights, 1, 2048); if (imguiCheck("Show G-Buffer.", showGBuffer) ) { showGBuffer = !showGBuffer; } if (imguiCheck("Show light scissor.", showScissorRects) ) { showScissorRects = !showScissorRects; } if (imguiCheck("Animate mesh.", animateMesh) ) { animateMesh = !animateMesh; } imguiSlider("Lights animation speed", lightAnimationSpeed, 0.0f, 0.4f, 0.01f); imguiEndScrollArea(); imguiEndFrame(); // Update camera. cameraUpdate(deltaTime, mouseState.m_mx, mouseState.m_my, !!mouseState.m_buttons[entry::MouseButton::Right]); cameraGetViewMtx(view); // Setup views float vp[16]; float invvp[16]; { bgfx::setViewRectMask(0 | RENDER_PASS_GEOMETRY_BIT | RENDER_PASS_LIGHT_BIT | RENDER_PASS_COMBINE_BIT | RENDER_PASS_DEBUG_LIGHTS_BIT | RENDER_PASS_DEBUG_GBUFFER_BIT , 0, 0, width, height ); bgfx::setViewFrameBuffer(RENDER_PASS_LIGHT_ID, lightBuffer); float proj[16]; bx::mtxProj(proj, 60.0f, float(width)/float(height), 0.1f, 100.0f); bgfx::setViewFrameBuffer(RENDER_PASS_GEOMETRY_ID, gbuffer); bgfx::setViewTransform(RENDER_PASS_GEOMETRY_ID, view, proj); bx::mtxMul(vp, view, proj); bx::mtxInverse(invvp, vp); bx::mtxOrtho(proj, 0.0f, 1.0f, 1.0f, 0.0f, 0.0f, 100.0f); bgfx::setViewTransformMask(0 | RENDER_PASS_LIGHT_BIT | RENDER_PASS_COMBINE_BIT , NULL, proj ); const float aspectRatio = float(height)/float(width); const float size = 10.0f; bx::mtxOrtho(proj, -size, size, size*aspectRatio, -size*aspectRatio, 0.0f, 1000.0f); bgfx::setViewTransform(RENDER_PASS_DEBUG_GBUFFER_ID, NULL, proj); bx::mtxOrtho(proj, 0.0f, (float)width, 0.0f, (float)height, 0.0f, 1000.0f); bgfx::setViewTransform(RENDER_PASS_DEBUG_LIGHTS_ID, NULL, proj); } const uint32_t dim = 11; const float offset = (float(dim-1) * 3.0f) * 0.5f; // Draw into geometry pass. for (uint32_t yy = 0; yy < dim; ++yy) { for (uint32_t xx = 0; xx < dim; ++xx) { float mtx[16]; if (animateMesh) { bx::mtxRotateXY(mtx, time*1.023f + xx*0.21f, time*0.03f + yy*0.37f); } else { bx::mtxIdentity(mtx); } mtx[12] = -offset + float(xx)*3.0f; mtx[13] = -offset + float(yy)*3.0f; mtx[14] = 0.0f; // Set transform for draw call. bgfx::setTransform(mtx); // Set vertex and fragment shaders. bgfx::setProgram(geomProgram); // Set vertex and index buffer. bgfx::setVertexBuffer(vbh); bgfx::setIndexBuffer(ibh); // Bind textures. bgfx::setTexture(0, s_texColor, textureColor); bgfx::setTexture(1, s_texNormal, textureNormal); // Set render states. bgfx::setState(0 | BGFX_STATE_RGB_WRITE | BGFX_STATE_ALPHA_WRITE | BGFX_STATE_DEPTH_WRITE | BGFX_STATE_DEPTH_TEST_LESS | BGFX_STATE_MSAA ); // Submit primitive for rendering to view 0. bgfx::submit(RENDER_PASS_GEOMETRY_ID); } } // Draw lights into light buffer. for (int32_t light = 0; light < numLights; ++light) { Sphere lightPosRadius; float lightTime = time * lightAnimationSpeed * (sin(light/float(numLights) * float(M_PI_2) ) * 0.5f + 0.5f); lightPosRadius.m_center[0] = sin( ( (lightTime + light*0.47f) + float(M_PI_2)*1.37f ) )*offset; lightPosRadius.m_center[1] = cos( ( (lightTime + light*0.69f) + float(M_PI_2)*1.49f ) )*offset; lightPosRadius.m_center[2] = sin( ( (lightTime + light*0.37f) + float(M_PI_2)*1.57f ) )*2.0f; lightPosRadius.m_radius = 2.0f; Aabb aabb; sphereToAabb(aabb, lightPosRadius); float box[8][3] = { { aabb.m_min[0], aabb.m_min[1], aabb.m_min[2] }, { aabb.m_min[0], aabb.m_min[1], aabb.m_max[2] }, { aabb.m_min[0], aabb.m_max[1], aabb.m_min[2] }, { aabb.m_min[0], aabb.m_max[1], aabb.m_max[2] }, { aabb.m_max[0], aabb.m_min[1], aabb.m_min[2] }, { aabb.m_max[0], aabb.m_min[1], aabb.m_max[2] }, { aabb.m_max[0], aabb.m_max[1], aabb.m_min[2] }, { aabb.m_max[0], aabb.m_max[1], aabb.m_max[2] }, }; float xyz[3]; bx::vec3MulMtxH(xyz, box[0], vp); float minx = xyz[0]; float miny = xyz[1]; float maxx = xyz[0]; float maxy = xyz[1]; float maxz = xyz[2]; for (uint32_t ii = 1; ii < 8; ++ii) { bx::vec3MulMtxH(xyz, box[ii], vp); minx = bx::fmin(minx, xyz[0]); miny = bx::fmin(miny, xyz[1]); maxx = bx::fmax(maxx, xyz[0]); maxy = bx::fmax(maxy, xyz[1]); maxz = bx::fmax(maxz, xyz[2]); } // Cull light if it's fully behind camera. if (maxz >= 0.0f) { float x0 = bx::fclamp( (minx * 0.5f + 0.5f) * width, 0.0f, (float)width); float y0 = bx::fclamp( (miny * 0.5f + 0.5f) * height, 0.0f, (float)height); float x1 = bx::fclamp( (maxx * 0.5f + 0.5f) * width, 0.0f, (float)width); float y1 = bx::fclamp( (maxy * 0.5f + 0.5f) * height, 0.0f, (float)height); if (showScissorRects) { bgfx::TransientVertexBuffer tvb; bgfx::TransientIndexBuffer tib; if (bgfx::allocTransientBuffers(&tvb, DebugVertex::ms_decl, 4, &tib, 8) ) { uint32_t abgr = 0x8000ff00; DebugVertex* vertex = (DebugVertex*)tvb.data; vertex->m_x = x0; vertex->m_y = y0; vertex->m_z = 0.0f; vertex->m_abgr = abgr; ++vertex; vertex->m_x = x1; vertex->m_y = y0; vertex->m_z = 0.0f; vertex->m_abgr = abgr; ++vertex; vertex->m_x = x1; vertex->m_y = y1; vertex->m_z = 0.0f; vertex->m_abgr = abgr; ++vertex; vertex->m_x = x0; vertex->m_y = y1; vertex->m_z = 0.0f; vertex->m_abgr = abgr; uint16_t* indices = (uint16_t*)tib.data; *indices++ = 0; *indices++ = 1; *indices++ = 1; *indices++ = 2; *indices++ = 2; *indices++ = 3; *indices++ = 3; *indices++ = 0; bgfx::setProgram(lineProgram); bgfx::setVertexBuffer(&tvb); bgfx::setIndexBuffer(&tib); bgfx::setState(0 | BGFX_STATE_RGB_WRITE | BGFX_STATE_PT_LINES | BGFX_STATE_BLEND_ALPHA ); bgfx::submit(RENDER_PASS_DEBUG_LIGHTS_ID); } } uint8_t val = light&7; float lightRgbInnerR[4] = { val & 0x1 ? 1.0f : 0.25f, val & 0x2 ? 1.0f : 0.25f, val & 0x4 ? 1.0f : 0.25f, 0.8f, }; // Draw light. bgfx::setUniform(u_lightPosRadius, &lightPosRadius); bgfx::setUniform(u_lightRgbInnerR, lightRgbInnerR); bgfx::setUniform(u_mtx, invvp); const uint16_t scissorHeight = uint16_t(y1-y0); bgfx::setScissor(uint16_t(x0), height-scissorHeight-uint16_t(y0), uint16_t(x1-x0), scissorHeight); bgfx::setTexture(0, s_normal, gbuffer, 1); bgfx::setTexture(1, s_depth, gbuffer, 2); bgfx::setProgram(lightProgram); bgfx::setState(0 | BGFX_STATE_RGB_WRITE | BGFX_STATE_ALPHA_WRITE | BGFX_STATE_BLEND_ADD ); screenSpaceQuad( (float)width, (float)height, texelHalf, originBottomLeft); bgfx::submit(RENDER_PASS_LIGHT_ID); } } // Combine color and light buffers. bgfx::setTexture(0, s_albedo, gbuffer, 0); bgfx::setTexture(1, s_light, lightBuffer, 0); bgfx::setProgram(combineProgram); bgfx::setState(0 | BGFX_STATE_RGB_WRITE | BGFX_STATE_ALPHA_WRITE ); screenSpaceQuad( (float)width, (float)height, texelHalf, originBottomLeft); bgfx::submit(RENDER_PASS_COMBINE_ID); if (showGBuffer) { const float aspectRatio = float(width)/float(height); // Draw debug GBuffer. for (uint32_t ii = 0; ii < BX_COUNTOF(gbufferTex); ++ii) { float mtx[16]; bx::mtxSRT(mtx , aspectRatio, 1.0f, 1.0f , 0.0f, 0.0f, 0.0f , -7.9f - BX_COUNTOF(gbufferTex)*0.1f*0.5f + ii*2.1f*aspectRatio, 4.0f, 0.0f ); bgfx::setTransform(mtx); bgfx::setProgram(debugProgram); bgfx::setVertexBuffer(vbh); bgfx::setIndexBuffer(ibh, 0, 6); bgfx::setTexture(0, s_texColor, gbufferTex[ii]); bgfx::setState(BGFX_STATE_RGB_WRITE); bgfx::submit(RENDER_PASS_DEBUG_GBUFFER_ID); } } } // Advance to next frame. Rendering thread will be kicked to // process submitted rendering primitives. bgfx::frame(); } // Cleanup. cameraDestroy(); imguiDestroy(); if (bgfx::isValid(gbuffer) ) { bgfx::destroyFrameBuffer(gbuffer); bgfx::destroyFrameBuffer(lightBuffer); } bgfx::destroyIndexBuffer(ibh); bgfx::destroyVertexBuffer(vbh); bgfx::destroyProgram(geomProgram); bgfx::destroyProgram(lightProgram); bgfx::destroyProgram(combineProgram); bgfx::destroyProgram(debugProgram); bgfx::destroyProgram(lineProgram); bgfx::destroyTexture(textureColor); bgfx::destroyTexture(textureNormal); bgfx::destroyUniform(s_texColor); bgfx::destroyUniform(s_texNormal); bgfx::destroyUniform(s_albedo); bgfx::destroyUniform(s_normal); bgfx::destroyUniform(s_depth); bgfx::destroyUniform(s_light); bgfx::destroyUniform(u_lightPosRadius); bgfx::destroyUniform(u_lightRgbInnerR); bgfx::destroyUniform(u_mtx); // Shutdown bgfx. bgfx::shutdown(); return 0; }