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hello_vulkan.cpp
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hello_vulkan.cpp
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/*
* Copyright (c) 2014-2021, NVIDIA CORPORATION. All rights reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* SPDX-FileCopyrightText: Copyright (c) 2014-2021 NVIDIA CORPORATION
* SPDX-License-Identifier: Apache-2.0
*/
#include <sstream>
#define STB_IMAGE_IMPLEMENTATION
#include "obj_loader.h"
#include "stb_image.h"
#include "hello_vulkan.h"
#include "nvh/alignment.hpp"
#include "nvh/cameramanipulator.hpp"
#include "nvh/fileoperations.hpp"
#include "nvvk/commands_vk.hpp"
#include "nvvk/descriptorsets_vk.hpp"
#include "nvvk/images_vk.hpp"
#include "nvvk/pipeline_vk.hpp"
#include "nvvk/renderpasses_vk.hpp"
#include "nvvk/shaders_vk.hpp"
#include "nvvk/buffers_vk.hpp"
extern std::vector<std::string> defaultSearchPaths;
//--------------------------------------------------------------------------------------------------
// Keep the handle on the device
// Initialize the tool to do all our allocations: buffers, images
//
void HelloVulkan::setup(const VkInstance& instance, const VkDevice& device, const VkPhysicalDevice& physicalDevice, uint32_t queueFamily)
{
AppBaseVk::setup(instance, device, physicalDevice, queueFamily);
m_alloc.init(instance, device, physicalDevice);
m_debug.setup(m_device);
m_offscreenDepthFormat = nvvk::findDepthFormat(physicalDevice);
}
//--------------------------------------------------------------------------------------------------
// Called at each frame to update the camera matrix
//
void HelloVulkan::updateUniformBuffer(const VkCommandBuffer& cmdBuf)
{
// Prepare new UBO contents on host.
const float aspectRatio = m_size.width / static_cast<float>(m_size.height);
GlobalUniforms hostUBO = {};
const auto& view = CameraManip.getMatrix();
const auto& proj = nvmath::perspectiveVK(CameraManip.getFov(), aspectRatio, 0.1f, 1000.0f);
// proj[1][1] *= -1; // Inverting Y for Vulkan (not needed with perspectiveVK).
hostUBO.viewProj = proj * view;
hostUBO.viewInverse = nvmath::invert(view);
hostUBO.projInverse = nvmath::invert(proj);
// UBO on the device, and what stages access it.
VkBuffer deviceUBO = m_bGlobals.buffer;
auto uboUsageStages = VK_PIPELINE_STAGE_VERTEX_SHADER_BIT | VK_PIPELINE_STAGE_RAY_TRACING_SHADER_BIT_KHR;
// Ensure that the modified UBO is not visible to previous frames.
VkBufferMemoryBarrier beforeBarrier{VK_STRUCTURE_TYPE_BUFFER_MEMORY_BARRIER};
beforeBarrier.srcAccessMask = VK_ACCESS_SHADER_READ_BIT;
beforeBarrier.dstAccessMask = VK_ACCESS_TRANSFER_WRITE_BIT;
beforeBarrier.buffer = deviceUBO;
beforeBarrier.offset = 0;
beforeBarrier.size = sizeof(hostUBO);
vkCmdPipelineBarrier(cmdBuf, uboUsageStages, VK_PIPELINE_STAGE_TRANSFER_BIT, VK_DEPENDENCY_DEVICE_GROUP_BIT, 0,
nullptr, 1, &beforeBarrier, 0, nullptr);
// Schedule the host-to-device upload. (hostUBO is copied into the cmd
// buffer so it is okay to deallocate when the function returns).
vkCmdUpdateBuffer(cmdBuf, m_bGlobals.buffer, 0, sizeof(GlobalUniforms), &hostUBO);
// Making sure the updated UBO will be visible.
VkBufferMemoryBarrier afterBarrier{VK_STRUCTURE_TYPE_BUFFER_MEMORY_BARRIER};
afterBarrier.srcAccessMask = VK_ACCESS_TRANSFER_WRITE_BIT;
afterBarrier.dstAccessMask = VK_ACCESS_SHADER_READ_BIT;
afterBarrier.buffer = deviceUBO;
afterBarrier.offset = 0;
afterBarrier.size = sizeof(hostUBO);
vkCmdPipelineBarrier(cmdBuf, VK_PIPELINE_STAGE_TRANSFER_BIT, uboUsageStages, VK_DEPENDENCY_DEVICE_GROUP_BIT, 0,
nullptr, 1, &afterBarrier, 0, nullptr);
}
//--------------------------------------------------------------------------------------------------
// Describing the layout pushed when rendering
//
void HelloVulkan::createDescriptorSetLayout()
{
auto nbTxt = static_cast<uint32_t>(m_textures.size());
// Camera matrices
m_descSetLayoutBind.addBinding(SceneBindings::eGlobals, VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER, 1,
VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_RAYGEN_BIT_KHR);
// Obj descriptions
m_descSetLayoutBind.addBinding(SceneBindings::eObjDescs, VK_DESCRIPTOR_TYPE_STORAGE_BUFFER, 1,
VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT | VK_SHADER_STAGE_CLOSEST_HIT_BIT_KHR);
// Textures
m_descSetLayoutBind.addBinding(SceneBindings::eTextures, VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER, nbTxt,
VK_SHADER_STAGE_FRAGMENT_BIT | VK_SHADER_STAGE_CLOSEST_HIT_BIT_KHR);
m_descSetLayout = m_descSetLayoutBind.createLayout(m_device);
m_descPool = m_descSetLayoutBind.createPool(m_device, 1);
m_descSet = nvvk::allocateDescriptorSet(m_device, m_descPool, m_descSetLayout);
}
//--------------------------------------------------------------------------------------------------
// Setting up the buffers in the descriptor set
//
void HelloVulkan::updateDescriptorSet()
{
std::vector<VkWriteDescriptorSet> writes;
// Camera matrices and scene description
VkDescriptorBufferInfo dbiUnif{m_bGlobals.buffer, 0, VK_WHOLE_SIZE};
writes.emplace_back(m_descSetLayoutBind.makeWrite(m_descSet, SceneBindings::eGlobals, &dbiUnif));
VkDescriptorBufferInfo dbiSceneDesc{m_bObjDesc.buffer, 0, VK_WHOLE_SIZE};
writes.emplace_back(m_descSetLayoutBind.makeWrite(m_descSet, SceneBindings::eObjDescs, &dbiSceneDesc));
// All texture samplers
std::vector<VkDescriptorImageInfo> diit;
for(auto& texture : m_textures)
{
diit.emplace_back(texture.descriptor);
}
writes.emplace_back(m_descSetLayoutBind.makeWriteArray(m_descSet, SceneBindings::eTextures, diit.data()));
// Writing the information
vkUpdateDescriptorSets(m_device, static_cast<uint32_t>(writes.size()), writes.data(), 0, nullptr);
}
//--------------------------------------------------------------------------------------------------
// Creating the pipeline layout
//
void HelloVulkan::createGraphicsPipeline()
{
VkPushConstantRange pushConstantRanges = {VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT, 0, sizeof(PushConstantRaster)};
// Creating the Pipeline Layout
VkPipelineLayoutCreateInfo createInfo{VK_STRUCTURE_TYPE_PIPELINE_LAYOUT_CREATE_INFO};
createInfo.setLayoutCount = 1;
createInfo.pSetLayouts = &m_descSetLayout;
createInfo.pushConstantRangeCount = 1;
createInfo.pPushConstantRanges = &pushConstantRanges;
vkCreatePipelineLayout(m_device, &createInfo, nullptr, &m_pipelineLayout);
// Creating the Pipeline
std::vector<std::string> paths = defaultSearchPaths;
nvvk::GraphicsPipelineGeneratorCombined gpb(m_device, m_pipelineLayout, m_offscreenRenderPass);
gpb.depthStencilState.depthTestEnable = true;
gpb.addShader(nvh::loadFile("spv/vert_shader.vert.spv", true, paths, true), VK_SHADER_STAGE_VERTEX_BIT);
gpb.addShader(nvh::loadFile("spv/frag_shader.frag.spv", true, paths, true), VK_SHADER_STAGE_FRAGMENT_BIT);
gpb.addBindingDescription({0, sizeof(VertexObj)});
gpb.addAttributeDescriptions({
{0, 0, VK_FORMAT_R32G32B32_SFLOAT, static_cast<uint32_t>(offsetof(VertexObj, pos))},
{1, 0, VK_FORMAT_R32G32B32_SFLOAT, static_cast<uint32_t>(offsetof(VertexObj, nrm))},
{2, 0, VK_FORMAT_R32G32B32_SFLOAT, static_cast<uint32_t>(offsetof(VertexObj, color))},
{3, 0, VK_FORMAT_R32G32_SFLOAT, static_cast<uint32_t>(offsetof(VertexObj, texCoord))},
});
m_graphicsPipeline = gpb.createPipeline();
m_debug.setObjectName(m_graphicsPipeline, "Graphics");
}
//--------------------------------------------------------------------------------------------------
// Loading the OBJ file and setting up all buffers
//
void HelloVulkan::loadModel(const std::string& filename, nvmath::mat4f transform)
{
LOGI("Loading File: %s \n", filename.c_str());
ObjLoader loader;
loader.loadModel(filename);
// Converting from Srgb to linear
for(auto& m : loader.m_materials)
{
m.ambient = nvmath::pow(m.ambient, 2.2f);
m.diffuse = nvmath::pow(m.diffuse, 2.2f);
m.specular = nvmath::pow(m.specular, 2.2f);
}
ObjModel model;
model.nbIndices = static_cast<uint32_t>(loader.m_indices.size());
model.nbVertices = static_cast<uint32_t>(loader.m_vertices.size());
// Create the buffers on Device and copy vertices, indices and materials
nvvk::CommandPool cmdBufGet(m_device, m_graphicsQueueIndex);
VkCommandBuffer cmdBuf = cmdBufGet.createCommandBuffer();
VkBufferUsageFlags flag = VK_BUFFER_USAGE_SHADER_DEVICE_ADDRESS_BIT;
VkBufferUsageFlags rayTracingFlags = // used also for building acceleration structures
flag | VK_BUFFER_USAGE_ACCELERATION_STRUCTURE_BUILD_INPUT_READ_ONLY_BIT_KHR | VK_BUFFER_USAGE_STORAGE_BUFFER_BIT;
model.vertexBuffer = m_alloc.createBuffer(cmdBuf, loader.m_vertices, VK_BUFFER_USAGE_VERTEX_BUFFER_BIT | rayTracingFlags);
model.indexBuffer = m_alloc.createBuffer(cmdBuf, loader.m_indices, VK_BUFFER_USAGE_INDEX_BUFFER_BIT | rayTracingFlags);
model.matColorBuffer = m_alloc.createBuffer(cmdBuf, loader.m_materials, VK_BUFFER_USAGE_STORAGE_BUFFER_BIT | flag);
model.matIndexBuffer = m_alloc.createBuffer(cmdBuf, loader.m_matIndx, VK_BUFFER_USAGE_STORAGE_BUFFER_BIT | flag);
// Creates all textures found and find the offset for this model
auto txtOffset = static_cast<uint32_t>(m_textures.size());
createTextureImages(cmdBuf, loader.m_textures);
cmdBufGet.submitAndWait(cmdBuf);
m_alloc.finalizeAndReleaseStaging();
std::string objNb = std::to_string(m_objModel.size());
m_debug.setObjectName(model.vertexBuffer.buffer, (std::string("vertex_" + objNb)));
m_debug.setObjectName(model.indexBuffer.buffer, (std::string("index_" + objNb)));
m_debug.setObjectName(model.matColorBuffer.buffer, (std::string("mat_" + objNb)));
m_debug.setObjectName(model.matIndexBuffer.buffer, (std::string("matIdx_" + objNb)));
// Keeping transformation matrix of the instance
ObjInstance instance;
instance.transform = transform;
instance.objIndex = static_cast<uint32_t>(m_objModel.size());
m_instances.push_back(instance);
// Creating information for device access
ObjDesc desc;
desc.txtOffset = txtOffset;
desc.vertexAddress = nvvk::getBufferDeviceAddress(m_device, model.vertexBuffer.buffer);
desc.indexAddress = nvvk::getBufferDeviceAddress(m_device, model.indexBuffer.buffer);
desc.materialAddress = nvvk::getBufferDeviceAddress(m_device, model.matColorBuffer.buffer);
desc.materialIndexAddress = nvvk::getBufferDeviceAddress(m_device, model.matIndexBuffer.buffer);
// Keeping the obj host model and device description
m_objModel.emplace_back(model);
m_objDesc.emplace_back(desc);
}
//--------------------------------------------------------------------------------------------------
// Creating the uniform buffer holding the camera matrices
// - Buffer is host visible
//
void HelloVulkan::createUniformBuffer()
{
m_bGlobals = m_alloc.createBuffer(sizeof(GlobalUniforms), VK_BUFFER_USAGE_UNIFORM_BUFFER_BIT | VK_BUFFER_USAGE_TRANSFER_DST_BIT,
VK_MEMORY_PROPERTY_DEVICE_LOCAL_BIT);
m_debug.setObjectName(m_bGlobals.buffer, "Globals");
}
//--------------------------------------------------------------------------------------------------
// Create a storage buffer containing the description of the scene elements
// - Which geometry is used by which instance
// - Transformation
// - Offset for texture
//
void HelloVulkan::createObjDescriptionBuffer()
{
nvvk::CommandPool cmdGen(m_device, m_graphicsQueueIndex);
auto cmdBuf = cmdGen.createCommandBuffer();
m_bObjDesc = m_alloc.createBuffer(cmdBuf, m_objDesc, VK_BUFFER_USAGE_STORAGE_BUFFER_BIT);
cmdGen.submitAndWait(cmdBuf);
m_alloc.finalizeAndReleaseStaging();
m_debug.setObjectName(m_bObjDesc.buffer, "ObjDescs");
}
//--------------------------------------------------------------------------------------------------
// Creating all textures and samplers
//
void HelloVulkan::createTextureImages(const VkCommandBuffer& cmdBuf, const std::vector<std::string>& textures)
{
VkSamplerCreateInfo samplerCreateInfo{VK_STRUCTURE_TYPE_SAMPLER_CREATE_INFO};
samplerCreateInfo.minFilter = VK_FILTER_LINEAR;
samplerCreateInfo.magFilter = VK_FILTER_LINEAR;
samplerCreateInfo.mipmapMode = VK_SAMPLER_MIPMAP_MODE_LINEAR;
samplerCreateInfo.maxLod = FLT_MAX;
VkFormat format = VK_FORMAT_R8G8B8A8_SRGB;
// If no textures are present, create a dummy one to accommodate the pipeline layout
if(textures.empty() && m_textures.empty())
{
nvvk::Texture texture;
std::array<uint8_t, 4> color{255u, 255u, 255u, 255u};
VkDeviceSize bufferSize = sizeof(color);
auto imgSize = VkExtent2D{1, 1};
auto imageCreateInfo = nvvk::makeImage2DCreateInfo(imgSize, format);
// Creating the dummy texture
nvvk::Image image = m_alloc.createImage(cmdBuf, bufferSize, color.data(), imageCreateInfo);
VkImageViewCreateInfo ivInfo = nvvk::makeImageViewCreateInfo(image.image, imageCreateInfo);
texture = m_alloc.createTexture(image, ivInfo, samplerCreateInfo);
// The image format must be in VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL
nvvk::cmdBarrierImageLayout(cmdBuf, texture.image, VK_IMAGE_LAYOUT_UNDEFINED, VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL);
m_textures.push_back(texture);
}
else
{
// Uploading all images
for(const auto& texture : textures)
{
std::stringstream o;
int texWidth, texHeight, texChannels;
o << "media/textures/" << texture;
std::string txtFile = nvh::findFile(o.str(), defaultSearchPaths, true);
stbi_uc* stbi_pixels = stbi_load(txtFile.c_str(), &texWidth, &texHeight, &texChannels, STBI_rgb_alpha);
std::array<stbi_uc, 4> color{255u, 0u, 255u, 255u};
stbi_uc* pixels = stbi_pixels;
// Handle failure
if(!stbi_pixels)
{
texWidth = texHeight = 1;
texChannels = 4;
pixels = reinterpret_cast<stbi_uc*>(color.data());
}
VkDeviceSize bufferSize = static_cast<uint64_t>(texWidth) * texHeight * sizeof(uint8_t) * 4;
auto imgSize = VkExtent2D{(uint32_t)texWidth, (uint32_t)texHeight};
auto imageCreateInfo = nvvk::makeImage2DCreateInfo(imgSize, format, VK_IMAGE_USAGE_SAMPLED_BIT, true);
{
nvvk::Image image = m_alloc.createImage(cmdBuf, bufferSize, pixels, imageCreateInfo);
nvvk::cmdGenerateMipmaps(cmdBuf, image.image, format, imgSize, imageCreateInfo.mipLevels);
VkImageViewCreateInfo ivInfo = nvvk::makeImageViewCreateInfo(image.image, imageCreateInfo);
nvvk::Texture texture = m_alloc.createTexture(image, ivInfo, samplerCreateInfo);
m_textures.push_back(texture);
}
stbi_image_free(stbi_pixels);
}
}
}
//--------------------------------------------------------------------------------------------------
// Destroying all allocations
//
void HelloVulkan::destroyResources()
{
vkDestroyPipeline(m_device, m_graphicsPipeline, nullptr);
vkDestroyPipelineLayout(m_device, m_pipelineLayout, nullptr);
vkDestroyDescriptorPool(m_device, m_descPool, nullptr);
vkDestroyDescriptorSetLayout(m_device, m_descSetLayout, nullptr);
m_alloc.destroy(m_bGlobals);
m_alloc.destroy(m_bObjDesc);
for(auto& m : m_objModel)
{
m_alloc.destroy(m.vertexBuffer);
m_alloc.destroy(m.indexBuffer);
m_alloc.destroy(m.matColorBuffer);
m_alloc.destroy(m.matIndexBuffer);
}
for(auto& t : m_textures)
{
m_alloc.destroy(t);
}
//#Post
m_alloc.destroy(m_offscreenColor);
m_alloc.destroy(m_offscreenDepth);
vkDestroyPipeline(m_device, m_postPipeline, nullptr);
vkDestroyPipelineLayout(m_device, m_postPipelineLayout, nullptr);
vkDestroyDescriptorPool(m_device, m_postDescPool, nullptr);
vkDestroyDescriptorSetLayout(m_device, m_postDescSetLayout, nullptr);
vkDestroyRenderPass(m_device, m_offscreenRenderPass, nullptr);
vkDestroyFramebuffer(m_device, m_offscreenFramebuffer, nullptr);
// #VKRay
m_sbtWrapper.destroy();
m_rtBuilder.destroy();
vkDestroyPipeline(m_device, m_rtPipeline, nullptr);
vkDestroyPipelineLayout(m_device, m_rtPipelineLayout, nullptr);
vkDestroyDescriptorPool(m_device, m_rtDescPool, nullptr);
vkDestroyDescriptorSetLayout(m_device, m_rtDescSetLayout, nullptr);
m_alloc.deinit();
}
//--------------------------------------------------------------------------------------------------
// Drawing the scene in raster mode
//
void HelloVulkan::rasterize(const VkCommandBuffer& cmdBuf)
{
VkDeviceSize offset{0};
m_debug.beginLabel(cmdBuf, "Rasterize");
// Dynamic Viewport
setViewport(cmdBuf);
// Drawing all triangles
vkCmdBindPipeline(cmdBuf, VK_PIPELINE_BIND_POINT_GRAPHICS, m_graphicsPipeline);
vkCmdBindDescriptorSets(cmdBuf, VK_PIPELINE_BIND_POINT_GRAPHICS, m_pipelineLayout, 0, 1, &m_descSet, 0, nullptr);
for(const HelloVulkan::ObjInstance& inst : m_instances)
{
auto& model = m_objModel[inst.objIndex];
m_pcRaster.objIndex = inst.objIndex; // Telling which object is drawn
m_pcRaster.modelMatrix = inst.transform;
vkCmdPushConstants(cmdBuf, m_pipelineLayout, VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT, 0,
sizeof(PushConstantRaster), &m_pcRaster);
vkCmdBindVertexBuffers(cmdBuf, 0, 1, &model.vertexBuffer.buffer, &offset);
vkCmdBindIndexBuffer(cmdBuf, model.indexBuffer.buffer, 0, VK_INDEX_TYPE_UINT32);
vkCmdDrawIndexed(cmdBuf, model.nbIndices, 1, 0, 0, 0);
}
m_debug.endLabel(cmdBuf);
}
//--------------------------------------------------------------------------------------------------
// Handling resize of the window
//
void HelloVulkan::onResize(int /*w*/, int /*h*/)
{
createOffscreenRender();
updatePostDescriptorSet();
updateRtDescriptorSet();
}
//////////////////////////////////////////////////////////////////////////
// Post-processing
//////////////////////////////////////////////////////////////////////////
//--------------------------------------------------------------------------------------------------
// Creating an offscreen frame buffer and the associated render pass
//
void HelloVulkan::createOffscreenRender()
{
m_alloc.destroy(m_offscreenColor);
m_alloc.destroy(m_offscreenDepth);
// Creating the color image
{
auto colorCreateInfo = nvvk::makeImage2DCreateInfo(m_size, m_offscreenColorFormat,
VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT | VK_IMAGE_USAGE_SAMPLED_BIT
| VK_IMAGE_USAGE_STORAGE_BIT);
nvvk::Image image = m_alloc.createImage(colorCreateInfo);
VkImageViewCreateInfo ivInfo = nvvk::makeImageViewCreateInfo(image.image, colorCreateInfo);
VkSamplerCreateInfo sampler{VK_STRUCTURE_TYPE_SAMPLER_CREATE_INFO};
m_offscreenColor = m_alloc.createTexture(image, ivInfo, sampler);
m_offscreenColor.descriptor.imageLayout = VK_IMAGE_LAYOUT_GENERAL;
}
// Creating the depth buffer
auto depthCreateInfo = nvvk::makeImage2DCreateInfo(m_size, m_offscreenDepthFormat, VK_IMAGE_USAGE_DEPTH_STENCIL_ATTACHMENT_BIT);
{
nvvk::Image image = m_alloc.createImage(depthCreateInfo);
VkImageViewCreateInfo depthStencilView{VK_STRUCTURE_TYPE_IMAGE_VIEW_CREATE_INFO};
depthStencilView.viewType = VK_IMAGE_VIEW_TYPE_2D;
depthStencilView.format = m_offscreenDepthFormat;
depthStencilView.subresourceRange = {VK_IMAGE_ASPECT_DEPTH_BIT, 0, 1, 0, 1};
depthStencilView.image = image.image;
m_offscreenDepth = m_alloc.createTexture(image, depthStencilView);
}
// Setting the image layout for both color and depth
{
nvvk::CommandPool genCmdBuf(m_device, m_graphicsQueueIndex);
auto cmdBuf = genCmdBuf.createCommandBuffer();
nvvk::cmdBarrierImageLayout(cmdBuf, m_offscreenColor.image, VK_IMAGE_LAYOUT_UNDEFINED, VK_IMAGE_LAYOUT_GENERAL);
nvvk::cmdBarrierImageLayout(cmdBuf, m_offscreenDepth.image, VK_IMAGE_LAYOUT_UNDEFINED,
VK_IMAGE_LAYOUT_DEPTH_STENCIL_ATTACHMENT_OPTIMAL, VK_IMAGE_ASPECT_DEPTH_BIT);
genCmdBuf.submitAndWait(cmdBuf);
}
// Creating a renderpass for the offscreen
if(!m_offscreenRenderPass)
{
m_offscreenRenderPass = nvvk::createRenderPass(m_device, {m_offscreenColorFormat}, m_offscreenDepthFormat, 1, true,
true, VK_IMAGE_LAYOUT_GENERAL, VK_IMAGE_LAYOUT_GENERAL);
}
// Creating the frame buffer for offscreen
std::vector<VkImageView> attachments = {m_offscreenColor.descriptor.imageView, m_offscreenDepth.descriptor.imageView};
vkDestroyFramebuffer(m_device, m_offscreenFramebuffer, nullptr);
VkFramebufferCreateInfo info{VK_STRUCTURE_TYPE_FRAMEBUFFER_CREATE_INFO};
info.renderPass = m_offscreenRenderPass;
info.attachmentCount = 2;
info.pAttachments = attachments.data();
info.width = m_size.width;
info.height = m_size.height;
info.layers = 1;
vkCreateFramebuffer(m_device, &info, nullptr, &m_offscreenFramebuffer);
}
//--------------------------------------------------------------------------------------------------
// The pipeline is how things are rendered, which shaders, type of primitives, depth test and more
//
void HelloVulkan::createPostPipeline()
{
// Push constants in the fragment shader
VkPushConstantRange pushConstantRanges = {VK_SHADER_STAGE_FRAGMENT_BIT, 0, sizeof(float)};
// Creating the pipeline layout
VkPipelineLayoutCreateInfo createInfo{VK_STRUCTURE_TYPE_PIPELINE_LAYOUT_CREATE_INFO};
createInfo.setLayoutCount = 1;
createInfo.pSetLayouts = &m_postDescSetLayout;
createInfo.pushConstantRangeCount = 1;
createInfo.pPushConstantRanges = &pushConstantRanges;
vkCreatePipelineLayout(m_device, &createInfo, nullptr, &m_postPipelineLayout);
// Pipeline: completely generic, no vertices
nvvk::GraphicsPipelineGeneratorCombined pipelineGenerator(m_device, m_postPipelineLayout, m_renderPass);
pipelineGenerator.addShader(nvh::loadFile("spv/passthrough.vert.spv", true, defaultSearchPaths, true), VK_SHADER_STAGE_VERTEX_BIT);
pipelineGenerator.addShader(nvh::loadFile("spv/post.frag.spv", true, defaultSearchPaths, true), VK_SHADER_STAGE_FRAGMENT_BIT);
pipelineGenerator.rasterizationState.cullMode = VK_CULL_MODE_NONE;
m_postPipeline = pipelineGenerator.createPipeline();
m_debug.setObjectName(m_postPipeline, "post");
}
//--------------------------------------------------------------------------------------------------
// The descriptor layout is the description of the data that is passed to the vertex or the
// fragment program.
//
void HelloVulkan::createPostDescriptor()
{
m_postDescSetLayoutBind.addBinding(0, VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER, 1, VK_SHADER_STAGE_FRAGMENT_BIT);
m_postDescSetLayout = m_postDescSetLayoutBind.createLayout(m_device);
m_postDescPool = m_postDescSetLayoutBind.createPool(m_device);
m_postDescSet = nvvk::allocateDescriptorSet(m_device, m_postDescPool, m_postDescSetLayout);
}
//--------------------------------------------------------------------------------------------------
// Update the output
//
void HelloVulkan::updatePostDescriptorSet()
{
VkWriteDescriptorSet writeDescriptorSets = m_postDescSetLayoutBind.makeWrite(m_postDescSet, 0, &m_offscreenColor.descriptor);
vkUpdateDescriptorSets(m_device, 1, &writeDescriptorSets, 0, nullptr);
}
//--------------------------------------------------------------------------------------------------
// Draw a full screen quad with the attached image
//
void HelloVulkan::drawPost(VkCommandBuffer cmdBuf)
{
m_debug.beginLabel(cmdBuf, "Post");
setViewport(cmdBuf);
auto aspectRatio = static_cast<float>(m_size.width) / static_cast<float>(m_size.height);
vkCmdPushConstants(cmdBuf, m_postPipelineLayout, VK_SHADER_STAGE_FRAGMENT_BIT, 0, sizeof(float), &aspectRatio);
vkCmdBindPipeline(cmdBuf, VK_PIPELINE_BIND_POINT_GRAPHICS, m_postPipeline);
vkCmdBindDescriptorSets(cmdBuf, VK_PIPELINE_BIND_POINT_GRAPHICS, m_postPipelineLayout, 0, 1, &m_postDescSet, 0, nullptr);
vkCmdDraw(cmdBuf, 3, 1, 0, 0);
m_debug.endLabel(cmdBuf);
}
//////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////
//--------------------------------------------------------------------------------------------------
// Initialize Vulkan ray tracing
// #VKRay
void HelloVulkan::initRayTracing()
{
// Requesting ray tracing properties
VkPhysicalDeviceProperties2 prop2{VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_PROPERTIES_2};
prop2.pNext = &m_rtProperties;
vkGetPhysicalDeviceProperties2(m_physicalDevice, &prop2);
m_rtBuilder.setup(m_device, &m_alloc, m_graphicsQueueIndex);
m_sbtWrapper.setup(m_device, m_graphicsQueueIndex, &m_alloc, m_rtProperties);
}
//--------------------------------------------------------------------------------------------------
// Convert an OBJ model into the ray tracing geometry used to build the BLAS
//
auto HelloVulkan::objectToVkGeometryKHR(const ObjModel& model)
{
// BLAS builder requires raw device addresses.
VkDeviceAddress vertexAddress = nvvk::getBufferDeviceAddress(m_device, model.vertexBuffer.buffer);
VkDeviceAddress indexAddress = nvvk::getBufferDeviceAddress(m_device, model.indexBuffer.buffer);
uint32_t maxPrimitiveCount = model.nbIndices / 3;
// Describe buffer as array of VertexObj.
VkAccelerationStructureGeometryTrianglesDataKHR triangles{VK_STRUCTURE_TYPE_ACCELERATION_STRUCTURE_GEOMETRY_TRIANGLES_DATA_KHR};
triangles.vertexFormat = VK_FORMAT_R32G32B32_SFLOAT; // vec3 vertex position data.
triangles.vertexData.deviceAddress = vertexAddress;
triangles.vertexStride = sizeof(VertexObj);
// Describe index data (32-bit unsigned int)
triangles.indexType = VK_INDEX_TYPE_UINT32;
triangles.indexData.deviceAddress = indexAddress;
// Indicate identity transform by setting transformData to null device pointer.
//triangles.transformData = {};
triangles.maxVertex = model.nbVertices;
// Identify the above data as containing opaque triangles.
VkAccelerationStructureGeometryKHR asGeom{VK_STRUCTURE_TYPE_ACCELERATION_STRUCTURE_GEOMETRY_KHR};
asGeom.geometryType = VK_GEOMETRY_TYPE_TRIANGLES_KHR;
asGeom.flags = VK_GEOMETRY_OPAQUE_BIT_KHR;
asGeom.geometry.triangles = triangles;
// The entire array will be used to build the BLAS.
VkAccelerationStructureBuildRangeInfoKHR offset;
offset.firstVertex = 0;
offset.primitiveCount = maxPrimitiveCount;
offset.primitiveOffset = 0;
offset.transformOffset = 0;
// Our blas is made from only one geometry, but could be made of many geometries
nvvk::RaytracingBuilderKHR::BlasInput input;
input.asGeometry.emplace_back(asGeom);
input.asBuildOffsetInfo.emplace_back(offset);
return input;
}
//--------------------------------------------------------------------------------------------------
//
//
void HelloVulkan::createBottomLevelAS()
{
// BLAS - Storing each primitive in a geometry
std::vector<nvvk::RaytracingBuilderKHR::BlasInput> allBlas;
allBlas.reserve(m_objModel.size());
for(const auto& obj : m_objModel)
{
auto blas = objectToVkGeometryKHR(obj);
// We could add more geometry in each BLAS, but we add only one for now
allBlas.emplace_back(blas);
}
m_rtBuilder.buildBlas(allBlas, VK_BUILD_ACCELERATION_STRUCTURE_PREFER_FAST_TRACE_BIT_KHR);
}
//--------------------------------------------------------------------------------------------------
//
//
void HelloVulkan::createTopLevelAS()
{
std::vector<VkAccelerationStructureInstanceKHR> tlas;
tlas.reserve(m_instances.size());
for(const HelloVulkan::ObjInstance& inst : m_instances)
{
VkAccelerationStructureInstanceKHR rayInst{};
rayInst.transform = nvvk::toTransformMatrixKHR(inst.transform); // Position of the instance
rayInst.instanceCustomIndex = inst.objIndex; // gl_InstanceCustomIndexEXT
rayInst.accelerationStructureReference = m_rtBuilder.getBlasDeviceAddress(inst.objIndex);
rayInst.flags = VK_GEOMETRY_INSTANCE_TRIANGLE_FACING_CULL_DISABLE_BIT_KHR;
rayInst.mask = 0xFF; // Only be hit if rayMask & instance.mask != 0
rayInst.instanceShaderBindingTableRecordOffset = 0; // We will use the same hit group for all objects
tlas.emplace_back(rayInst);
}
m_rtBuilder.buildTlas(tlas, VK_BUILD_ACCELERATION_STRUCTURE_PREFER_FAST_TRACE_BIT_KHR);
}
//--------------------------------------------------------------------------------------------------
// This descriptor set holds the Acceleration structure and the output image
//
void HelloVulkan::createRtDescriptorSet()
{
// Top-level acceleration structure, usable by both the ray generation and the closest hit (to
// shoot shadow rays)
m_rtDescSetLayoutBind.addBinding(RtxBindings::eTlas, VK_DESCRIPTOR_TYPE_ACCELERATION_STRUCTURE_KHR, 1,
VK_SHADER_STAGE_RAYGEN_BIT_KHR | VK_SHADER_STAGE_CLOSEST_HIT_BIT_KHR); // TLAS
m_rtDescSetLayoutBind.addBinding(RtxBindings::eOutImage, VK_DESCRIPTOR_TYPE_STORAGE_IMAGE, 1,
VK_SHADER_STAGE_RAYGEN_BIT_KHR); // Output image
m_rtDescPool = m_rtDescSetLayoutBind.createPool(m_device);
m_rtDescSetLayout = m_rtDescSetLayoutBind.createLayout(m_device);
VkDescriptorSetAllocateInfo allocateInfo{VK_STRUCTURE_TYPE_DESCRIPTOR_SET_ALLOCATE_INFO};
allocateInfo.descriptorPool = m_rtDescPool;
allocateInfo.descriptorSetCount = 1;
allocateInfo.pSetLayouts = &m_rtDescSetLayout;
vkAllocateDescriptorSets(m_device, &allocateInfo, &m_rtDescSet);
VkAccelerationStructureKHR tlas = m_rtBuilder.getAccelerationStructure();
VkWriteDescriptorSetAccelerationStructureKHR descASInfo{VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET_ACCELERATION_STRUCTURE_KHR};
descASInfo.accelerationStructureCount = 1;
descASInfo.pAccelerationStructures = &tlas;
VkDescriptorImageInfo imageInfo{{}, m_offscreenColor.descriptor.imageView, VK_IMAGE_LAYOUT_GENERAL};
std::vector<VkWriteDescriptorSet> writes;
writes.emplace_back(m_rtDescSetLayoutBind.makeWrite(m_rtDescSet, RtxBindings::eTlas, &descASInfo));
writes.emplace_back(m_rtDescSetLayoutBind.makeWrite(m_rtDescSet, RtxBindings::eOutImage, &imageInfo));
vkUpdateDescriptorSets(m_device, static_cast<uint32_t>(writes.size()), writes.data(), 0, nullptr);
}
//--------------------------------------------------------------------------------------------------
// Writes the output image to the descriptor set
// - Required when changing resolution
//
void HelloVulkan::updateRtDescriptorSet()
{
// (1) Output buffer
VkDescriptorImageInfo imageInfo{{}, m_offscreenColor.descriptor.imageView, VK_IMAGE_LAYOUT_GENERAL};
VkWriteDescriptorSet wds = m_rtDescSetLayoutBind.makeWrite(m_rtDescSet, RtxBindings::eOutImage, &imageInfo);
vkUpdateDescriptorSets(m_device, 1, &wds, 0, nullptr);
}
//--------------------------------------------------------------------------------------------------
// Pipeline for the ray tracer: all shaders, raygen, chit, miss
//
void HelloVulkan::createRtPipeline()
{
enum StageIndices
{
eRaygen,
eMiss,
eMiss2,
eClosestHit,
eCall0,
eCall1,
eCall2,
eShaderGroupCount
};
// All stages
std::array<VkPipelineShaderStageCreateInfo, eShaderGroupCount> stages{};
VkPipelineShaderStageCreateInfo stage{VK_STRUCTURE_TYPE_PIPELINE_SHADER_STAGE_CREATE_INFO};
stage.pName = "main"; // All the same entry point
// Raygen
stage.module = nvvk::createShaderModule(m_device, nvh::loadFile("spv/raytrace.rgen.spv", true, defaultSearchPaths, true));
stage.stage = VK_SHADER_STAGE_RAYGEN_BIT_KHR;
stages[eRaygen] = stage;
// Miss
stage.module = nvvk::createShaderModule(m_device, nvh::loadFile("spv/raytrace.rmiss.spv", true, defaultSearchPaths, true));
stage.stage = VK_SHADER_STAGE_MISS_BIT_KHR;
stages[eMiss] = stage;
// The second miss shader is invoked when a shadow ray misses the geometry. It simply indicates that no occlusion has been found
stage.module =
nvvk::createShaderModule(m_device, nvh::loadFile("spv/raytraceShadow.rmiss.spv", true, defaultSearchPaths, true));
stage.stage = VK_SHADER_STAGE_MISS_BIT_KHR;
stages[eMiss2] = stage;
// Hit Group - Closest Hit
stage.module = nvvk::createShaderModule(m_device, nvh::loadFile("spv/raytrace.rchit.spv", true, defaultSearchPaths, true));
stage.stage = VK_SHADER_STAGE_CLOSEST_HIT_BIT_KHR;
stages[eClosestHit] = stage;
// Call0
stage.module = nvvk::createShaderModule(m_device, nvh::loadFile("spv/light_point.rcall.spv", true, defaultSearchPaths, true));
stage.stage = VK_SHADER_STAGE_CALLABLE_BIT_KHR;
stages[eCall0] = stage;
// Call1
stage.module = nvvk::createShaderModule(m_device, nvh::loadFile("spv/light_spot.rcall.spv", true, defaultSearchPaths, true));
stage.stage = VK_SHADER_STAGE_CALLABLE_BIT_KHR;
stages[eCall1] = stage;
// Call2
stage.module = nvvk::createShaderModule(m_device, nvh::loadFile("spv/light_inf.rcall.spv", true, defaultSearchPaths, true));
stage.stage = VK_SHADER_STAGE_CALLABLE_BIT_KHR;
stages[eCall2] = stage;
// Shader groups
VkRayTracingShaderGroupCreateInfoKHR group{VK_STRUCTURE_TYPE_RAY_TRACING_SHADER_GROUP_CREATE_INFO_KHR};
group.anyHitShader = VK_SHADER_UNUSED_KHR;
group.closestHitShader = VK_SHADER_UNUSED_KHR;
group.generalShader = VK_SHADER_UNUSED_KHR;
group.intersectionShader = VK_SHADER_UNUSED_KHR;
// Raygen
group.type = VK_RAY_TRACING_SHADER_GROUP_TYPE_GENERAL_KHR;
group.generalShader = eRaygen;
m_rtShaderGroups.push_back(group);
// Miss
group.type = VK_RAY_TRACING_SHADER_GROUP_TYPE_GENERAL_KHR;
group.generalShader = eMiss;
m_rtShaderGroups.push_back(group);
// Shadow Miss
group.type = VK_RAY_TRACING_SHADER_GROUP_TYPE_GENERAL_KHR;
group.generalShader = eMiss2;
m_rtShaderGroups.push_back(group);
// closest hit shader
group.type = VK_RAY_TRACING_SHADER_GROUP_TYPE_TRIANGLES_HIT_GROUP_KHR;
group.generalShader = VK_SHADER_UNUSED_KHR;
group.closestHitShader = eClosestHit;
m_rtShaderGroups.push_back(group);
// Callable shaders
group.type = VK_RAY_TRACING_SHADER_GROUP_TYPE_GENERAL_KHR;
group.closestHitShader = VK_SHADER_UNUSED_KHR;
group.generalShader = eCall0;
m_rtShaderGroups.push_back(group);
group.generalShader = eCall1;
m_rtShaderGroups.push_back(group);
group.generalShader = eCall2;
m_rtShaderGroups.push_back(group);
// Push constant: we want to be able to update constants used by the shaders
VkPushConstantRange pushConstant{VK_SHADER_STAGE_RAYGEN_BIT_KHR | VK_SHADER_STAGE_CLOSEST_HIT_BIT_KHR
| VK_SHADER_STAGE_MISS_BIT_KHR | VK_SHADER_STAGE_CALLABLE_BIT_KHR,
0, sizeof(PushConstantRay)};
VkPipelineLayoutCreateInfo pipelineLayoutCreateInfo{VK_STRUCTURE_TYPE_PIPELINE_LAYOUT_CREATE_INFO};
pipelineLayoutCreateInfo.pushConstantRangeCount = 1;
pipelineLayoutCreateInfo.pPushConstantRanges = &pushConstant;
// Descriptor sets: one specific to ray tracing, and one shared with the rasterization pipeline
std::vector<VkDescriptorSetLayout> rtDescSetLayouts = {m_rtDescSetLayout, m_descSetLayout};
pipelineLayoutCreateInfo.setLayoutCount = static_cast<uint32_t>(rtDescSetLayouts.size());
pipelineLayoutCreateInfo.pSetLayouts = rtDescSetLayouts.data();
vkCreatePipelineLayout(m_device, &pipelineLayoutCreateInfo, nullptr, &m_rtPipelineLayout);
// Assemble the shader stages and recursion depth info into the ray tracing pipeline
VkRayTracingPipelineCreateInfoKHR rayPipelineInfo{VK_STRUCTURE_TYPE_RAY_TRACING_PIPELINE_CREATE_INFO_KHR};
rayPipelineInfo.stageCount = static_cast<uint32_t>(stages.size()); // Stages are shaders
rayPipelineInfo.pStages = stages.data();
rayPipelineInfo.groupCount = static_cast<uint32_t>(m_rtShaderGroups.size());
rayPipelineInfo.pGroups = m_rtShaderGroups.data();
// The ray tracing process can shoot rays from the camera, and a shadow ray can be shot from the
// hit points of the camera rays, hence a recursion level of 2. This number should be kept as low
// as possible for performance reasons. Even recursive ray tracing should be flattened into a loop
// in the ray generation to avoid deep recursion.
rayPipelineInfo.maxPipelineRayRecursionDepth = 2; // Ray depth
rayPipelineInfo.layout = m_rtPipelineLayout;
vkCreateRayTracingPipelinesKHR(m_device, {}, {}, 1, &rayPipelineInfo, nullptr, &m_rtPipeline);
m_sbtWrapper.create(m_rtPipeline, rayPipelineInfo);
for(auto& s : stages)
vkDestroyShaderModule(m_device, s.module, nullptr);
}
//--------------------------------------------------------------------------------------------------
// Ray Tracing the scene
//
void HelloVulkan::raytrace(const VkCommandBuffer& cmdBuf, const nvmath::vec4f& clearColor)
{
m_debug.beginLabel(cmdBuf, "Ray trace");
// Initializing push constant values
m_pcRay.clearColor = clearColor;
m_pcRay.lightPosition = m_pcRaster.lightPosition;
m_pcRay.lightIntensity = m_pcRaster.lightIntensity;
m_pcRay.lightDirection = m_pcRaster.lightDirection;
m_pcRay.lightSpotCutoff = m_pcRaster.lightSpotCutoff;
m_pcRay.lightSpotOuterCutoff = m_pcRaster.lightSpotOuterCutoff;
m_pcRay.lightType = m_pcRaster.lightType;
std::vector<VkDescriptorSet> descSets{m_rtDescSet, m_descSet};
vkCmdBindPipeline(cmdBuf, VK_PIPELINE_BIND_POINT_RAY_TRACING_KHR, m_rtPipeline);
vkCmdBindDescriptorSets(cmdBuf, VK_PIPELINE_BIND_POINT_RAY_TRACING_KHR, m_rtPipelineLayout, 0,
(uint32_t)descSets.size(), descSets.data(), 0, nullptr);
vkCmdPushConstants(cmdBuf, m_rtPipelineLayout,
VK_SHADER_STAGE_RAYGEN_BIT_KHR | VK_SHADER_STAGE_CLOSEST_HIT_BIT_KHR | VK_SHADER_STAGE_MISS_BIT_KHR
| VK_SHADER_STAGE_CALLABLE_BIT_KHR,
0, sizeof(PushConstantRay), &m_pcRay);
auto& regions = m_sbtWrapper.getRegions();
vkCmdTraceRaysKHR(cmdBuf, ®ions[0], ®ions[1], ®ions[2], ®ions[3], m_size.width, m_size.height, 1);
m_debug.endLabel(cmdBuf);
}