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framework update 4/29/2020

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This commit is contained in:
Christoph Kubisch 2020-04-29 13:59:03 +02:00
parent 21fc655237
commit 60103dd1ce
62 changed files with 2931 additions and 2743 deletions
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286
ray_tracing_intersection/hello_vulkan.cpp
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@ -36,13 +36,14 @@ extern std::vector<std::string> defaultSearchPaths;
#include "hello_vulkan.h"
#include "nvh//cameramanipulator.hpp"
#include "nvvkpp/descriptorsets_vkpp.hpp"
#include "nvvkpp/pipeline_vkpp.hpp"
#include "nvvk/descriptorsets_vk.hpp"
#include "nvvk/pipeline_vk.hpp"
#include "nvh/fileoperations.hpp"
#include "nvvkpp/commands_vkpp.hpp"
#include "nvvkpp/renderpass_vkpp.hpp"
#include "nvvkpp/utilities_vkpp.hpp"
#include "nvvk/commands_vk.hpp"
#include "nvvk/renderpasses_vk.hpp"
#include "nvvk/shaders_vk.hpp"
#include <random>
// Holding the camera matrices
@ -59,11 +60,12 @@ struct CameraMatrices
// Keep the handle on the device
// Initialize the tool to do all our allocations: buffers, images
//
void HelloVulkan::setup(const vk::Device& device,
void HelloVulkan::setup(const vk::Instance& instance,
const vk::Device& device,
const vk::PhysicalDevice& physicalDevice,
uint32_t queueFamily)
{
AppBase::setup(device, physicalDevice, queueFamily);
AppBase::setup(instance, device, physicalDevice, queueFamily);
m_alloc.init(device, physicalDevice);
m_debug.setup(m_device);
}
@ -100,34 +102,34 @@ void HelloVulkan::createDescriptorSetLayout()
uint32_t nbObj = static_cast<uint32_t>(m_objModel.size());
// Camera matrices (binding = 0)
m_descSetLayoutBind.emplace_back(
m_descSetLayoutBind.addBinding(
vkDS(0, vkDT::eUniformBuffer, 1, vkSS::eVertex | vkSS::eRaygenKHR));
// Materials (binding = 1)
m_descSetLayoutBind.emplace_back(vkDS(1, vkDT::eStorageBuffer, nbObj + 1,
vkSS::eVertex | vkSS::eFragment | vkSS::eClosestHitKHR));
m_descSetLayoutBind.addBinding(vkDS(1, vkDT::eStorageBuffer, nbObj + 1,
vkSS::eVertex | vkSS::eFragment | vkSS::eClosestHitKHR));
// Scene description (binding = 2)
m_descSetLayoutBind.emplace_back( //
m_descSetLayoutBind.addBinding( //
vkDS(2, vkDT::eStorageBuffer, 1, vkSS::eVertex | vkSS::eFragment | vkSS::eClosestHitKHR));
// Textures (binding = 3)
m_descSetLayoutBind.emplace_back(
m_descSetLayoutBind.addBinding(
vkDS(3, vkDT::eCombinedImageSampler, nbTxt, vkSS::eFragment | vkSS::eClosestHitKHR));
// Materials Index (binding = 4)
m_descSetLayoutBind.emplace_back(
m_descSetLayoutBind.addBinding(
vkDS(4, vkDT::eStorageBuffer, nbObj + 1, vkSS::eFragment | vkSS::eClosestHitKHR));
// Storing vertices (binding = 5)
m_descSetLayoutBind.emplace_back( //
m_descSetLayoutBind.addBinding( //
vkDS(5, vkDT::eStorageBuffer, nbObj, vkSS::eClosestHitKHR));
// Storing indices (binding = 6)
m_descSetLayoutBind.emplace_back( //
m_descSetLayoutBind.addBinding( //
vkDS(6, vkDT::eStorageBuffer, nbObj, vkSS::eClosestHitKHR));
// Storing spheres (binding = 7)
m_descSetLayoutBind.emplace_back( //
m_descSetLayoutBind.addBinding( //
vkDS(7, vkDT::eStorageBuffer, 1, vkSS::eClosestHitKHR | vkSS::eIntersectionKHR));
m_descSetLayout = nvvkpp::util::createDescriptorSetLayout(m_device, m_descSetLayoutBind);
m_descPool = nvvkpp::util::createDescriptorPool(m_device, m_descSetLayoutBind, 1);
m_descSet = nvvkpp::util::createDescriptorSet(m_device, m_descPool, m_descSetLayout);
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);
}
//--------------------------------------------------------------------------------------------------
@ -139,9 +141,9 @@ void HelloVulkan::updateDescriptorSet()
// Camera matrices and scene description
vk::DescriptorBufferInfo dbiUnif{m_cameraMat.buffer, 0, VK_WHOLE_SIZE};
writes.emplace_back(nvvkpp::util::createWrite(m_descSet, m_descSetLayoutBind[0], &dbiUnif));
writes.emplace_back(m_descSetLayoutBind.makeWrite(m_descSet, 0, &dbiUnif));
vk::DescriptorBufferInfo dbiSceneDesc{m_sceneDesc.buffer, 0, VK_WHOLE_SIZE};
writes.emplace_back(nvvkpp::util::createWrite(m_descSet, m_descSetLayoutBind[2], &dbiSceneDesc));
writes.emplace_back(m_descSetLayoutBind.makeWrite(m_descSet, 2, &dbiSceneDesc));
// All material buffers, 1 buffer per OBJ
std::vector<vk::DescriptorBufferInfo> dbiMat;
@ -158,14 +160,13 @@ void HelloVulkan::updateDescriptorSet()
dbiMat.emplace_back(m_spheresMatColorBuffer.buffer, 0, VK_WHOLE_SIZE);
dbiMatIdx.emplace_back(m_spheresMatIndexBuffer.buffer, 0, VK_WHOLE_SIZE);
writes.emplace_back(nvvkpp::util::createWrite(m_descSet, m_descSetLayoutBind[1], dbiMat.data()));
writes.emplace_back(
nvvkpp::util::createWrite(m_descSet, m_descSetLayoutBind[4], dbiMatIdx.data()));
writes.emplace_back(nvvkpp::util::createWrite(m_descSet, m_descSetLayoutBind[5], dbiVert.data()));
writes.emplace_back(nvvkpp::util::createWrite(m_descSet, m_descSetLayoutBind[6], dbiIdx.data()));
writes.emplace_back(m_descSetLayoutBind.makeWriteArray(m_descSet, 1, dbiMat.data()));
writes.emplace_back(m_descSetLayoutBind.makeWriteArray(m_descSet, 4, dbiMatIdx.data()));
writes.emplace_back(m_descSetLayoutBind.makeWriteArray(m_descSet, 5, dbiVert.data()));
writes.emplace_back(m_descSetLayoutBind.makeWriteArray(m_descSet, 6, dbiIdx.data()));
vk::DescriptorBufferInfo dbiSpheres{m_spheresBuffer.buffer, 0, VK_WHOLE_SIZE};
writes.emplace_back(nvvkpp::util::createWrite(m_descSet, m_descSetLayoutBind[7], &dbiSpheres));
writes.emplace_back(m_descSetLayoutBind.makeWrite(m_descSet, 7, &dbiSpheres));
// All texture samplers
std::vector<vk::DescriptorImageInfo> diit;
@ -173,7 +174,7 @@ void HelloVulkan::updateDescriptorSet()
{
diit.push_back(texture.descriptor);
}
writes.emplace_back(nvvkpp::util::createWrite(m_descSet, m_descSetLayoutBind[3], diit.data()));
writes.emplace_back(m_descSetLayoutBind.makeWriteArray(m_descSet, 3, diit.data()));
// Writing the information
m_device.updateDescriptorSets(static_cast<uint32_t>(writes.size()), writes.data(), 0, nullptr);
@ -199,19 +200,18 @@ void HelloVulkan::createGraphicsPipeline()
m_pipelineLayout = m_device.createPipelineLayout(pipelineLayoutCreateInfo);
// Creating the Pipeline
std::vector<std::string> paths = defaultSearchPaths;
nvvkpp::GraphicsPipelineGenerator gpb(m_device, m_pipelineLayout, m_offscreenRenderPass);
gpb.depthStencilState = {true};
std::vector<std::string> paths = defaultSearchPaths;
nvvk::GraphicsPipelineGeneratorCombined gpb(m_device, m_pipelineLayout, m_offscreenRenderPass);
gpb.depthStencilState.depthTestEnable = true;
gpb.addShader(nvh::loadFile("shaders/vert_shader.vert.spv", true, paths), vkSS::eVertex);
gpb.addShader(nvh::loadFile("shaders/frag_shader.frag.spv", true, paths), vkSS::eFragment);
gpb.vertexInputState.bindingDescriptions = {{0, sizeof(VertexObj)}};
gpb.vertexInputState.attributeDescriptions = {
{0, 0, vk::Format::eR32G32B32Sfloat, offsetof(VertexObj, pos)},
{1, 0, vk::Format::eR32G32B32Sfloat, offsetof(VertexObj, nrm)},
{2, 0, vk::Format::eR32G32B32Sfloat, offsetof(VertexObj, color)},
{3, 0, vk::Format::eR32G32Sfloat, offsetof(VertexObj, texCoord)}};
gpb.addBindingDescription({0, sizeof(VertexObj)});
gpb.addAttributeDescriptions({{0, 0, vk::Format::eR32G32B32Sfloat, offsetof(VertexObj, pos)},
{1, 0, vk::Format::eR32G32B32Sfloat, offsetof(VertexObj, nrm)},
{2, 0, vk::Format::eR32G32B32Sfloat, offsetof(VertexObj, color)},
{3, 0, vk::Format::eR32G32Sfloat, offsetof(VertexObj, texCoord)}});
m_graphicsPipeline = gpb.create();
m_graphicsPipeline = gpb.createPipeline();
m_debug.setObjectName(m_graphicsPipeline, "Graphics");
}
@ -244,8 +244,8 @@ void HelloVulkan::loadModel(const std::string& filename, nvmath::mat4f transform
model.nbVertices = static_cast<uint32_t>(loader.m_vertices.size());
// Create the buffers on Device and copy vertices, indices and materials
nvvkpp::SingleCommandBuffer cmdBufGet(m_device, m_graphicsQueueIndex);
vk::CommandBuffer cmdBuf = cmdBufGet.createCommandBuffer();
nvvk::CommandPool cmdBufGet(m_device, m_graphicsQueueIndex);
vk::CommandBuffer cmdBuf = cmdBufGet.createCommandBuffer();
model.vertexBuffer =
m_alloc.createBuffer(cmdBuf, loader.m_vertices,
vkBU::eVertexBuffer | vkBU::eStorageBuffer | vkBU::eShaderDeviceAddress);
@ -256,8 +256,8 @@ void HelloVulkan::loadModel(const std::string& filename, nvmath::mat4f transform
model.matIndexBuffer = m_alloc.createBuffer(cmdBuf, loader.m_matIndx, vkBU::eStorageBuffer);
// Creates all textures found
createTextureImages(cmdBuf, loader.m_textures);
cmdBufGet.flushCommandBuffer(cmdBuf);
m_alloc.flushStaging();
cmdBufGet.submitAndWait(cmdBuf);
m_alloc.finalizeAndReleaseStaging();
std::string objNb = std::to_string(instance.objIndex);
m_debug.setObjectName(model.vertexBuffer.buffer, (std::string("vertex_" + objNb).c_str()));
@ -292,12 +292,12 @@ void HelloVulkan::createUniformBuffer()
void HelloVulkan::createSceneDescriptionBuffer()
{
using vkBU = vk::BufferUsageFlagBits;
nvvkpp::SingleCommandBuffer cmdGen(m_device, m_graphicsQueueIndex);
nvvk::CommandPool cmdGen(m_device, m_graphicsQueueIndex);
auto cmdBuf = cmdGen.createCommandBuffer();
m_sceneDesc = m_alloc.createBuffer(cmdBuf, m_objInstance, vkBU::eStorageBuffer);
cmdGen.flushCommandBuffer(cmdBuf);
m_alloc.flushStaging();
cmdGen.submitAndWait(cmdBuf);
m_alloc.finalizeAndReleaseStaging();
m_debug.setObjectName(m_sceneDesc.buffer, "sceneDesc");
}
@ -317,21 +317,21 @@ void HelloVulkan::createTextureImages(const vk::CommandBuffer& cmdBuf,
// If no textures are present, create a dummy one to accommodate the pipeline layout
if(textures.empty() && m_textures.empty())
{
nvvkTexture texture;
nvvk::Texture texture;
std::array<uint8_t, 4> color{255u, 255u, 255u, 255u};
vk::DeviceSize bufferSize = sizeof(color);
auto imgSize = vk::Extent2D(1, 1);
auto imageCreateInfo = nvvkpp::image::create2DInfo(imgSize, format);
auto imageCreateInfo = nvvk::makeImage2DCreateInfo(imgSize, format);
// Creating the dummy texure
nvvk::Image image = m_alloc.createImage(cmdBuf, bufferSize, color.data(), imageCreateInfo);
vk::ImageViewCreateInfo ivInfo = nvvk::makeImageViewCreateInfo(image.image, imageCreateInfo);
texture = m_alloc.createTexture(image, ivInfo, samplerCreateInfo);
// Creating the VKImage
texture = m_alloc.createImage(cmdBuf, bufferSize, color.data(), imageCreateInfo);
// Setting up the descriptor used by the shader
texture.descriptor =
nvvkpp::image::create2DDescriptor(m_device, texture.image, samplerCreateInfo, format);
// The image format must be in VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL
nvvkpp::image::setImageLayout(cmdBuf, texture.image, vk::ImageLayout::eUndefined,
vk::ImageLayout::eShaderReadOnlyOptimal);
nvvk::cmdBarrierImageLayout(cmdBuf, texture.image, vk::ImageLayout::eUndefined,
vk::ImageLayout::eShaderReadOnlyOptimal);
m_textures.push_back(texture);
}
else
@ -358,16 +358,16 @@ void HelloVulkan::createTextureImages(const vk::CommandBuffer& cmdBuf,
vk::DeviceSize bufferSize = static_cast<uint64_t>(texWidth) * texHeight * sizeof(uint8_t) * 4;
auto imgSize = vk::Extent2D(texWidth, texHeight);
auto imageCreateInfo = nvvkpp::image::create2DInfo(imgSize, format, vkIU::eSampled, true);
auto imageCreateInfo = nvvk::makeImage2DCreateInfo(imgSize, format, vkIU::eSampled, true);
{
nvvkTexture texture;
texture = m_alloc.createImage(cmdBuf, bufferSize, pixels, imageCreateInfo);
nvvk::ImageDedicated image =
m_alloc.createImage(cmdBuf, bufferSize, pixels, imageCreateInfo);
nvvk::cmdGenerateMipmaps(cmdBuf, image.image, format, imgSize, imageCreateInfo.mipLevels);
vk::ImageViewCreateInfo ivInfo =
nvvk::makeImageViewCreateInfo(image.image, imageCreateInfo);
nvvk::Texture texture = m_alloc.createTexture(image, ivInfo, samplerCreateInfo);
nvvkpp::image::generateMipmaps(cmdBuf, texture.image, format, imgSize,
imageCreateInfo.mipLevels);
texture.descriptor =
nvvkpp::image::create2DDescriptor(m_device, texture.image, samplerCreateInfo, format);
m_textures.push_back(texture);
}
}
@ -449,7 +449,7 @@ void HelloVulkan::rasterize(const vk::CommandBuffer& cmdBuf)
cmdBuf.pushConstants<ObjPushConstant>(m_pipelineLayout, vkSS::eVertex | vkSS::eFragment, 0,
m_pushConstant);
cmdBuf.bindVertexBuffers(0, 1, &model.vertexBuffer.buffer, &offset);
cmdBuf.bindVertexBuffers(0, {model.vertexBuffer.buffer}, {offset});
cmdBuf.bindIndexBuffer(model.indexBuffer.buffer, 0, vk::IndexType::eUint32);
cmdBuf.drawIndexed(model.nbIndices, 1, 0, 0, 0);
}
@ -479,49 +479,54 @@ void HelloVulkan::createOffscreenRender()
m_alloc.destroy(m_offscreenDepth);
// Creating the color image
auto colorCreateInfo = nvvkpp::image::create2DInfo(m_size, m_offscreenColorFormat,
vk::ImageUsageFlagBits::eColorAttachment
| vk::ImageUsageFlagBits::eSampled
| vk::ImageUsageFlagBits::eStorage);
m_offscreenColor = m_alloc.createImage(colorCreateInfo);
{
auto colorCreateInfo = nvvk::makeImage2DCreateInfo(m_size, m_offscreenColorFormat,
vk::ImageUsageFlagBits::eColorAttachment
| vk::ImageUsageFlagBits::eSampled
| vk::ImageUsageFlagBits::eStorage);
m_offscreenColor.descriptor =
nvvkpp::image::create2DDescriptor(m_device, m_offscreenColor.image, vk::SamplerCreateInfo{},
m_offscreenColorFormat, vk::ImageLayout::eGeneral);
nvvk::Image image = m_alloc.createImage(colorCreateInfo);
vk::ImageViewCreateInfo ivInfo = nvvk::makeImageViewCreateInfo(image.image, colorCreateInfo);
m_offscreenColor = m_alloc.createTexture(image, ivInfo, vk::SamplerCreateInfo());
m_offscreenColor.descriptor.imageLayout = VK_IMAGE_LAYOUT_GENERAL;
}
// Creating the depth buffer
auto depthCreateInfo =
nvvkpp::image::create2DInfo(m_size, m_offscreenDepthFormat,
nvvk::makeImage2DCreateInfo(m_size, m_offscreenDepthFormat,
vk::ImageUsageFlagBits::eDepthStencilAttachment);
m_offscreenDepth = m_alloc.createImage(depthCreateInfo);
{
nvvk::Image image = m_alloc.createImage(depthCreateInfo);
vk::ImageViewCreateInfo depthStencilView;
depthStencilView.setViewType(vk::ImageViewType::e2D);
depthStencilView.setFormat(m_offscreenDepthFormat);
depthStencilView.setSubresourceRange({vk::ImageAspectFlagBits::eDepth, 0, 1, 0, 1});
depthStencilView.setImage(m_offscreenDepth.image);
m_offscreenDepth.descriptor.imageView = m_device.createImageView(depthStencilView);
vk::ImageViewCreateInfo depthStencilView;
depthStencilView.setViewType(vk::ImageViewType::e2D);
depthStencilView.setFormat(m_offscreenDepthFormat);
depthStencilView.setSubresourceRange({vk::ImageAspectFlagBits::eDepth, 0, 1, 0, 1});
depthStencilView.setImage(image.image);
m_offscreenDepth = m_alloc.createTexture(image, depthStencilView);
}
// Setting the image layout for both color and depth
{
nvvkpp::SingleCommandBuffer genCmdBuf(m_device, m_graphicsQueueIndex);
auto cmdBuf = genCmdBuf.createCommandBuffer();
nvvkpp::image::setImageLayout(cmdBuf, m_offscreenColor.image, vk::ImageLayout::eUndefined,
vk::ImageLayout::eGeneral);
nvvkpp::image::setImageLayout(cmdBuf, m_offscreenDepth.image, vk::ImageAspectFlagBits::eDepth,
vk::ImageLayout::eUndefined,
vk::ImageLayout::eDepthStencilAttachmentOptimal);
nvvk::CommandPool genCmdBuf(m_device, m_graphicsQueueIndex);
auto cmdBuf = genCmdBuf.createCommandBuffer();
nvvk::cmdBarrierImageLayout(cmdBuf, m_offscreenColor.image, vk::ImageLayout::eUndefined,
vk::ImageLayout::eGeneral);
nvvk::cmdBarrierImageLayout(cmdBuf, m_offscreenDepth.image, vk::ImageLayout::eUndefined,
vk::ImageLayout::eDepthStencilAttachmentOptimal,
vk::ImageAspectFlagBits::eDepth);
genCmdBuf.flushCommandBuffer(cmdBuf);
genCmdBuf.submitAndWait(cmdBuf);
}
// Creating a renderpass for the offscreen
if(!m_offscreenRenderPass)
{
m_offscreenRenderPass =
nvvkpp::util::createRenderPass(m_device, {m_offscreenColorFormat}, m_offscreenDepthFormat,
1, true, true, vk::ImageLayout::eGeneral,
vk::ImageLayout::eGeneral);
nvvk::createRenderPass(m_device, {m_offscreenColorFormat}, m_offscreenDepthFormat, 1, true,
true, vk::ImageLayout::eGeneral, vk::ImageLayout::eGeneral);
}
// Creating the frame buffer for offscreen
@ -558,13 +563,14 @@ void HelloVulkan::createPostPipeline()
// Pipeline: completely generic, no vertices
std::vector<std::string> paths = defaultSearchPaths;
nvvkpp::GraphicsPipelineGenerator pipelineGenerator(m_device, m_postPipelineLayout, m_renderPass);
nvvk::GraphicsPipelineGeneratorCombined pipelineGenerator(m_device, m_postPipelineLayout,
m_renderPass);
pipelineGenerator.addShader(nvh::loadFile("shaders/passthrough.vert.spv", true, paths),
vk::ShaderStageFlagBits::eVertex);
pipelineGenerator.addShader(nvh::loadFile("shaders/post.frag.spv", true, paths),
vk::ShaderStageFlagBits::eFragment);
pipelineGenerator.rasterizationState.setCullMode(vk::CullModeFlagBits::eNone);
m_postPipeline = pipelineGenerator.create();
m_postPipeline = pipelineGenerator.createPipeline();
m_debug.setObjectName(m_postPipeline, "post");
}
@ -578,10 +584,10 @@ void HelloVulkan::createPostDescriptor()
using vkDT = vk::DescriptorType;
using vkSS = vk::ShaderStageFlagBits;
m_postDescSetLayoutBind.emplace_back(vkDS(0, vkDT::eCombinedImageSampler, 1, vkSS::eFragment));
m_postDescSetLayout = nvvkpp::util::createDescriptorSetLayout(m_device, m_postDescSetLayoutBind);
m_postDescPool = nvvkpp::util::createDescriptorPool(m_device, m_postDescSetLayoutBind);
m_postDescSet = nvvkpp::util::createDescriptorSet(m_device, m_postDescPool, m_postDescSetLayout);
m_postDescSetLayoutBind.addBinding(vkDS(0, vkDT::eCombinedImageSampler, 1, vkSS::eFragment));
m_postDescSetLayout = m_postDescSetLayoutBind.createLayout(m_device);
m_postDescPool = m_postDescSetLayoutBind.createPool(m_device);
m_postDescSet = nvvk::allocateDescriptorSet(m_device, m_postDescPool, m_postDescSetLayout);
}
//--------------------------------------------------------------------------------------------------
@ -590,8 +596,7 @@ void HelloVulkan::createPostDescriptor()
void HelloVulkan::updatePostDescriptorSet()
{
vk::WriteDescriptorSet writeDescriptorSets =
nvvkpp::util::createWrite(m_postDescSet, m_postDescSetLayoutBind[0],
&m_offscreenColor.descriptor);
m_postDescSetLayoutBind.makeWrite(m_postDescSet, 0, &m_offscreenColor.descriptor);
m_device.updateDescriptorSets(writeDescriptorSets, nullptr);
}
@ -629,13 +634,13 @@ void HelloVulkan::initRayTracing()
auto properties = m_physicalDevice.getProperties2<vk::PhysicalDeviceProperties2,
vk::PhysicalDeviceRayTracingPropertiesKHR>();
m_rtProperties = properties.get<vk::PhysicalDeviceRayTracingPropertiesKHR>();
m_rtBuilder.setup(m_device, m_physicalDevice, m_graphicsQueueIndex);
m_rtBuilder.setup(m_device, &m_alloc, m_graphicsQueueIndex);
}
//--------------------------------------------------------------------------------------------------
// Converting a OBJ primitive to the ray tracing geometry used for the BLAS
//
nvvkpp::RaytracingBuilderKHR::Blas HelloVulkan::objectToVkGeometryKHR(const ObjModel& model)
nvvk::RaytracingBuilderKHR::Blas HelloVulkan::objectToVkGeometryKHR(const ObjModel& model)
{
vk::AccelerationStructureCreateGeometryTypeInfoKHR asCreate;
asCreate.setGeometryType(vk::GeometryTypeKHR::eTriangles);
@ -667,7 +672,7 @@ nvvkpp::RaytracingBuilderKHR::Blas HelloVulkan::objectToVkGeometryKHR(const ObjM
offset.setPrimitiveOffset(0);
offset.setTransformOffset(0);
nvvkpp::RaytracingBuilderKHR::Blas blas;
nvvk::RaytracingBuilderKHR::Blas blas;
blas.asGeometry.emplace_back(asGeom);
blas.asCreateGeometryInfo.emplace_back(asCreate);
blas.asBuildOffsetInfo.emplace_back(offset);
@ -677,7 +682,7 @@ nvvkpp::RaytracingBuilderKHR::Blas HelloVulkan::objectToVkGeometryKHR(const ObjM
//--------------------------------------------------------------------------------------------------
// Returning the ray tracing geometry used for the BLAS, containing all spheres
//
nvvkpp::RaytracingBuilderKHR::Blas HelloVulkan::sphereToVkGeometryKHR()
nvvk::RaytracingBuilderKHR::Blas HelloVulkan::sphereToVkGeometryKHR()
{
vk::AccelerationStructureCreateGeometryTypeInfoKHR asCreate;
asCreate.setGeometryType(vk::GeometryTypeKHR::eAabbs);
@ -705,7 +710,7 @@ nvvkpp::RaytracingBuilderKHR::Blas HelloVulkan::sphereToVkGeometryKHR()
offset.setPrimitiveOffset(0);
offset.setTransformOffset(0);
nvvkpp::RaytracingBuilderKHR::Blas blas;
nvvk::RaytracingBuilderKHR::Blas blas;
blas.asGeometry.emplace_back(asGeom);
blas.asCreateGeometryInfo.emplace_back(asCreate);
blas.asBuildOffsetInfo.emplace_back(offset);
@ -759,13 +764,13 @@ void HelloVulkan::createSpheres()
// Creating all buffers
using vkBU = vk::BufferUsageFlagBits;
nvvkpp::SingleCommandBuffer genCmdBuf(m_device, m_graphicsQueueIndex);
auto cmdBuf = genCmdBuf.createCommandBuffer();
m_spheresBuffer = m_alloc.createBuffer(cmdBuf, m_spheres, vkBU::eStorageBuffer);
m_spheresAabbBuffer = m_alloc.createBuffer(cmdBuf, aabbs, vkBU::eShaderDeviceAddress);
m_spheresMatIndexBuffer = m_alloc.createBuffer(cmdBuf, matIdx, vkBU::eStorageBuffer);
m_spheresMatColorBuffer = m_alloc.createBuffer(cmdBuf, materials, vkBU::eStorageBuffer);
genCmdBuf.flushCommandBuffer(cmdBuf);
nvvk::CommandPool genCmdBuf(m_device, m_graphicsQueueIndex);
auto cmdBuf = genCmdBuf.createCommandBuffer();
m_spheresBuffer = m_alloc.createBuffer(cmdBuf, m_spheres, vkBU::eStorageBuffer);
m_spheresAabbBuffer = m_alloc.createBuffer(cmdBuf, aabbs, vkBU::eShaderDeviceAddress);
m_spheresMatIndexBuffer = m_alloc.createBuffer(cmdBuf, matIdx, vkBU::eStorageBuffer);
m_spheresMatColorBuffer = m_alloc.createBuffer(cmdBuf, materials, vkBU::eStorageBuffer);
genCmdBuf.submitAndWait(cmdBuf);
// Debug information
m_debug.setObjectName(m_spheresBuffer.buffer, "spheres");
@ -777,7 +782,7 @@ void HelloVulkan::createSpheres()
void HelloVulkan::createBottomLevelAS()
{
// BLAS - Storing each primitive in a geometry
std::vector<nvvkpp::RaytracingBuilderKHR::Blas> allBlas;
std::vector<nvvk::RaytracingBuilderKHR::Blas> allBlas;
allBlas.reserve(m_objModel.size());
for(const auto& obj : m_objModel)
{
@ -798,27 +803,27 @@ void HelloVulkan::createBottomLevelAS()
void HelloVulkan::createTopLevelAS()
{
std::vector<nvvkpp::RaytracingBuilderKHR::Instance> tlas;
std::vector<nvvk::RaytracingBuilderKHR::Instance> tlas;
tlas.reserve(m_objInstance.size());
for(int i = 0; i < static_cast<int>(m_objInstance.size()); i++)
{
nvvkpp::RaytracingBuilderKHR::Instance rayInst;
nvvk::RaytracingBuilderKHR::Instance rayInst;
rayInst.transform = m_objInstance[i].transform; // Position of the instance
rayInst.instanceId = i; // gl_InstanceID
rayInst.blasId = m_objInstance[i].objIndex;
rayInst.hitGroupId = 0; // We will use the same hit group for all objects
rayInst.flags = vk::GeometryInstanceFlagBitsKHR::eTriangleCullDisable;
rayInst.flags = VK_GEOMETRY_INSTANCE_TRIANGLE_FACING_CULL_DISABLE_BIT_KHR;
tlas.emplace_back(rayInst);
}
// Add the blas containing all spheres
{
nvvkpp::RaytracingBuilderKHR::Instance rayInst;
nvvk::RaytracingBuilderKHR::Instance rayInst;
rayInst.transform = m_objInstance[0].transform; // Position of the instance
rayInst.instanceId = static_cast<uint32_t>(tlas.size()); // gl_InstanceID
rayInst.blasId = static_cast<uint32_t>(m_objModel.size());
rayInst.hitGroupId = 1; // We will use the same hit group for all objects
rayInst.flags = vk::GeometryInstanceFlagBitsKHR::eTriangleCullDisable;
rayInst.flags = VK_GEOMETRY_INSTANCE_TRIANGLE_FACING_CULL_DISABLE_BIT_KHR;
tlas.emplace_back(rayInst);
}
@ -834,25 +839,25 @@ void HelloVulkan::createRtDescriptorSet()
using vkSS = vk::ShaderStageFlagBits;
using vkDSLB = vk::DescriptorSetLayoutBinding;
m_rtDescSetLayoutBind.emplace_back(vkDSLB(0, vkDT::eAccelerationStructureKHR, 1,
vkSS::eRaygenKHR | vkSS::eClosestHitKHR)); // TLAS
m_rtDescSetLayoutBind.emplace_back(
m_rtDescSetLayoutBind.addBinding(vkDSLB(0, vkDT::eAccelerationStructureKHR, 1,
vkSS::eRaygenKHR | vkSS::eClosestHitKHR)); // TLAS
m_rtDescSetLayoutBind.addBinding(
vkDSLB(1, vkDT::eStorageImage, 1, vkSS::eRaygenKHR)); // Output image
m_rtDescPool = nvvkpp::util::createDescriptorPool(m_device, m_rtDescSetLayoutBind);
m_rtDescSetLayout = nvvkpp::util::createDescriptorSetLayout(m_device, m_rtDescSetLayoutBind);
m_rtDescPool = m_rtDescSetLayoutBind.createPool(m_device);
m_rtDescSetLayout = m_rtDescSetLayoutBind.createLayout(m_device);
m_rtDescSet = m_device.allocateDescriptorSets({m_rtDescPool, 1, &m_rtDescSetLayout})[0];
vk::AccelerationStructureKHR tlas = m_rtBuilder.getAccelerationStructure();
vk::WriteDescriptorSetAccelerationStructureKHR descASInfo;
descASInfo.setAccelerationStructureCount(1);
descASInfo.setPAccelerationStructures(&m_rtBuilder.getAccelerationStructure());
descASInfo.setPAccelerationStructures(&tlas);
vk::DescriptorImageInfo imageInfo{
{}, m_offscreenColor.descriptor.imageView, vk::ImageLayout::eGeneral};
std::vector<vk::WriteDescriptorSet> writes;
writes.emplace_back(
nvvkpp::util::createWrite(m_rtDescSet, m_rtDescSetLayoutBind[0], &descASInfo));
writes.emplace_back(nvvkpp::util::createWrite(m_rtDescSet, m_rtDescSetLayoutBind[1], &imageInfo));
writes.emplace_back(m_rtDescSetLayoutBind.makeWrite(m_rtDescSet, 0, &descASInfo));
writes.emplace_back(m_rtDescSetLayoutBind.makeWrite(m_rtDescSet, 1, &imageInfo));
m_device.updateDescriptorSets(static_cast<uint32_t>(writes.size()), writes.data(), 0, nullptr);
}
@ -881,16 +886,17 @@ void HelloVulkan::createRtPipeline()
std::vector<std::string> paths = defaultSearchPaths;
vk::ShaderModule raygenSM =
nvvkpp::util::createShaderModule(m_device, //
nvh::loadFile("shaders/raytrace.rgen.spv", true, paths));
nvvk::createShaderModule(m_device, //
nvh::loadFile("shaders/raytrace.rgen.spv", true, paths));
vk::ShaderModule missSM =
nvvkpp::util::createShaderModule(m_device, //
nvh::loadFile("shaders/raytrace.rmiss.spv", true, paths));
nvvk::createShaderModule(m_device, //
nvh::loadFile("shaders/raytrace.rmiss.spv", true, paths));
// The second miss shader is invoked when a shadow ray misses the geometry. It
// simply indicates that no occlusion has been found
vk::ShaderModule shadowmissSM = nvvkpp::util::createShaderModule(
m_device, nvh::loadFile("shaders/raytraceShadow.rmiss.spv", true, paths));
vk::ShaderModule shadowmissSM =
nvvk::createShaderModule(m_device,
nvh::loadFile("shaders/raytraceShadow.rmiss.spv", true, paths));
std::vector<vk::PipelineShaderStageCreateInfo> stages;
@ -916,8 +922,8 @@ void HelloVulkan::createRtPipeline()
// Hit Group0 - Closest Hit
vk::ShaderModule chitSM =
nvvkpp::util::createShaderModule(m_device, //
nvh::loadFile("shaders/raytrace.rchit.spv", true, paths));
nvvk::createShaderModule(m_device, //
nvh::loadFile("shaders/raytrace.rchit.spv", true, paths));
{
vk::RayTracingShaderGroupCreateInfoKHR hg{vk::RayTracingShaderGroupTypeKHR::eTrianglesHitGroup,
@ -930,11 +936,11 @@ void HelloVulkan::createRtPipeline()
// Hit Group1 - Closest Hit + Intersection (procedural)
vk::ShaderModule chit2SM =
nvvkpp::util::createShaderModule(m_device, //
nvh::loadFile("shaders/raytrace2.rchit.spv", true, paths));
nvvk::createShaderModule(m_device, //
nvh::loadFile("shaders/raytrace2.rchit.spv", true, paths));
vk::ShaderModule rintSM =
nvvkpp::util::createShaderModule(m_device, //
nvh::loadFile("shaders/raytrace.rint.spv", true, paths));
nvvk::createShaderModule(m_device, //
nvh::loadFile("shaders/raytrace.rint.spv", true, paths));
{
vk::RayTracingShaderGroupCreateInfoKHR hg{vk::RayTracingShaderGroupTypeKHR::eProceduralHitGroup,
VK_SHADER_UNUSED_KHR, VK_SHADER_UNUSED_KHR,
@ -1003,17 +1009,17 @@ void HelloVulkan::createRtShaderBindingTable()
m_device.getRayTracingShaderGroupHandlesKHR(m_rtPipeline, 0, groupCount, sbtSize,
shaderHandleStorage.data());
// Write the handles in the SBT
nvvkpp::SingleCommandBuffer genCmdBuf(m_device, m_graphicsQueueIndex);
vk::CommandBuffer cmdBuf = genCmdBuf.createCommandBuffer();
nvvk::CommandPool genCmdBuf(m_device, m_graphicsQueueIndex);
vk::CommandBuffer cmdBuf = genCmdBuf.createCommandBuffer();
m_rtSBTBuffer =
m_alloc.createBuffer(cmdBuf, shaderHandleStorage, vk::BufferUsageFlagBits::eRayTracingKHR);
m_debug.setObjectName(m_rtSBTBuffer.buffer, "SBT");
genCmdBuf.flushCommandBuffer(cmdBuf);
genCmdBuf.submitAndWait(cmdBuf);
m_alloc.flushStaging();
m_alloc.finalizeAndReleaseStaging();
}
//--------------------------------------------------------------------------------------------------

109
ray_tracing_intersection/hello_vulkan.h
View file

@ -26,16 +26,14 @@
*/
#pragma once
#include "nvvkpp/allocator_dedicated_vkpp.hpp"
#include "nvvkpp/appbase_vkpp.hpp"
#include "nvvkpp/debug_util_vkpp.hpp"
#define NVVK_ALLOC_DEDICATED
#include "nvvk/allocator_vk.hpp"
#include "nvvk/appbase_vkpp.hpp"
#include "nvvk/debug_util_vk.hpp"
#include "nvvk/descriptorsets_vk.hpp"
// #VKRay
#define ALLOC_DEDICATED
#include "nvvkpp/raytraceKHR_vkpp.hpp"
using nvvkBuffer = nvvkpp::BufferDedicated;
using nvvkTexture = nvvkpp::TextureDedicated;
#include "nvvk/raytraceKHR_vk.hpp"
//--------------------------------------------------------------------------------------------------
// Simple rasterizer of OBJ objects
@ -44,10 +42,11 @@ using nvvkTexture = nvvkpp::TextureDedicated;
// - Rendering is done in an offscreen framebuffer
// - The image of the framebuffer is displayed in post-process in a full-screen quad
//
class HelloVulkan : public nvvkpp::AppBase
class HelloVulkan : public nvvk::AppBase
{
public:
void setup(const vk::Device& device,
void setup(const vk::Instance& instance,
const vk::Device& device,
const vk::PhysicalDevice& physicalDevice,
uint32_t queueFamily) override;
void createDescriptorSetLayout();
@ -66,12 +65,12 @@ public:
// The OBJ model
struct ObjModel
{
uint32_t nbIndices{0};
uint32_t nbVertices{0};
nvvkBuffer vertexBuffer; // Device buffer of all 'Vertex'
nvvkBuffer indexBuffer; // Device buffer of the indices forming triangles
nvvkBuffer matColorBuffer; // Device buffer of array of 'Wavefront material'
nvvkBuffer matIndexBuffer; // Device buffer of array of 'Wavefront material'
uint32_t nbIndices{0};
uint32_t nbVertices{0};
nvvk::Buffer vertexBuffer; // Device buffer of all 'Vertex'
nvvk::Buffer indexBuffer; // Device buffer of the indices forming triangles
nvvk::Buffer matColorBuffer; // Device buffer of array of 'Wavefront material'
nvvk::Buffer matIndexBuffer; // Device buffer of array of 'Wavefront material'
};
// Instance of the OBJ
@ -98,19 +97,19 @@ public:
std::vector<ObjInstance> m_objInstance;
// Graphic pipeline
vk::PipelineLayout m_pipelineLayout;
vk::Pipeline m_graphicsPipeline;
std::vector<vk::DescriptorSetLayoutBinding> m_descSetLayoutBind;
vk::DescriptorPool m_descPool;
vk::DescriptorSetLayout m_descSetLayout;
vk::DescriptorSet m_descSet;
vk::PipelineLayout m_pipelineLayout;
vk::Pipeline m_graphicsPipeline;
nvvk::DescriptorSetBindings m_descSetLayoutBind;
vk::DescriptorPool m_descPool;
vk::DescriptorSetLayout m_descSetLayout;
vk::DescriptorSet m_descSet;
nvvkBuffer m_cameraMat; // Device-Host of the camera matrices
nvvkBuffer m_sceneDesc; // Device buffer of the OBJ instances
std::vector<nvvkTexture> m_textures; // vector of all textures of the scene
nvvk::Buffer m_cameraMat; // Device-Host of the camera matrices
nvvk::Buffer m_sceneDesc; // Device buffer of the OBJ instances
std::vector<nvvk::Texture> m_textures; // vector of all textures of the scene
nvvkpp::AllocatorDedicated m_alloc; // Allocator for buffer, images, acceleration structures
nvvkpp::DebugUtil m_debug; // Utility to name objects
nvvk::AllocatorDedicated m_alloc; // Allocator for buffer, images, acceleration structures
nvvk::DebugUtil m_debug; // Utility to name objects
// #Post
void createOffscreenRender();
@ -119,41 +118,41 @@ public:
void updatePostDescriptorSet();
void drawPost(vk::CommandBuffer cmdBuf);
std::vector<vk::DescriptorSetLayoutBinding> m_postDescSetLayoutBind;
vk::DescriptorPool m_postDescPool;
vk::DescriptorSetLayout m_postDescSetLayout;
vk::DescriptorSet m_postDescSet;
vk::Pipeline m_postPipeline;
vk::PipelineLayout m_postPipelineLayout;
vk::RenderPass m_offscreenRenderPass;
vk::Framebuffer m_offscreenFramebuffer;
nvvkTexture m_offscreenColor;
vk::Format m_offscreenColorFormat{vk::Format::eR32G32B32A32Sfloat};
nvvkTexture m_offscreenDepth;
vk::Format m_offscreenDepthFormat{vk::Format::eD32Sfloat};
nvvk::DescriptorSetBindings m_postDescSetLayoutBind;
vk::DescriptorPool m_postDescPool;
vk::DescriptorSetLayout m_postDescSetLayout;
vk::DescriptorSet m_postDescSet;
vk::Pipeline m_postPipeline;
vk::PipelineLayout m_postPipelineLayout;
vk::RenderPass m_offscreenRenderPass;
vk::Framebuffer m_offscreenFramebuffer;
nvvk::Texture m_offscreenColor;
vk::Format m_offscreenColorFormat{vk::Format::eR32G32B32A32Sfloat};
nvvk::Texture m_offscreenDepth;
vk::Format m_offscreenDepthFormat{vk::Format::eD32Sfloat};
// #VKRay
void initRayTracing();
nvvkpp::RaytracingBuilderKHR::Blas objectToVkGeometryKHR(const ObjModel& model);
void createBottomLevelAS();
void createTopLevelAS();
void createRtDescriptorSet();
void updateRtDescriptorSet();
void createRtPipeline();
void createRtShaderBindingTable();
void initRayTracing();
nvvk::RaytracingBuilderKHR::Blas objectToVkGeometryKHR(const ObjModel& model);
void createBottomLevelAS();
void createTopLevelAS();
void createRtDescriptorSet();
void updateRtDescriptorSet();
void createRtPipeline();
void createRtShaderBindingTable();
void raytrace(const vk::CommandBuffer& cmdBuf, const nvmath::vec4f& clearColor);
vk::PhysicalDeviceRayTracingPropertiesKHR m_rtProperties;
nvvkpp::RaytracingBuilderKHR m_rtBuilder;
std::vector<vk::DescriptorSetLayoutBinding> m_rtDescSetLayoutBind;
nvvk::RaytracingBuilderKHR m_rtBuilder;
nvvk::DescriptorSetBindings m_rtDescSetLayoutBind;
vk::DescriptorPool m_rtDescPool;
vk::DescriptorSetLayout m_rtDescSetLayout;
vk::DescriptorSet m_rtDescSet;
std::vector<vk::RayTracingShaderGroupCreateInfoKHR> m_rtShaderGroups;
vk::PipelineLayout m_rtPipelineLayout;
vk::Pipeline m_rtPipeline;
nvvkBuffer m_rtSBTBuffer;
nvvk::Buffer m_rtSBTBuffer;
struct RtPushConstant
{
@ -176,12 +175,12 @@ public:
nvmath::vec3f maximum;
};
nvvkpp::RaytracingBuilderKHR::Blas sphereToVkGeometryKHR();
nvvk::RaytracingBuilderKHR::Blas sphereToVkGeometryKHR();
std::vector<Sphere> m_spheres; // All spheres
nvvkBuffer m_spheresBuffer; // Buffer holding the spheres
nvvkBuffer m_spheresAabbBuffer; // Buffer of all Aabb
nvvkBuffer m_spheresMatColorBuffer; // Multiple materials
nvvkBuffer m_spheresMatIndexBuffer; // Define which sphere uses which material
nvvk::Buffer m_spheresBuffer; // Buffer holding the spheres
nvvk::Buffer m_spheresAabbBuffer; // Buffer of all Aabb
nvvk::Buffer m_spheresMatColorBuffer; // Multiple materials
nvvk::Buffer m_spheresMatIndexBuffer; // Define which sphere uses which material
void createSpheres();
};

20
ray_tracing_intersection/main.cpp
View file

@ -31,6 +31,7 @@
#include <array>
#include <vulkan/vulkan.hpp>
VULKAN_HPP_DEFAULT_DISPATCH_LOADER_DYNAMIC_STORAGE
#include "imgui.h"
#include "imgui_impl_glfw.h"
@ -39,10 +40,10 @@
#include "nvh/cameramanipulator.hpp"
#include "nvh/fileoperations.hpp"
#include "nvpsystem.hpp"
#include "nvvkpp/appbase_vkpp.hpp"
#include "nvvkpp/commands_vkpp.hpp"
#include "nvvkpp/context_vkpp.hpp"
#include "nvvkpp/utilities_vkpp.hpp"
#include "nvvk/appbase_vkpp.hpp"
#include "nvvk/commands_vk.hpp"
#include "nvvk/context_vk.hpp"
//////////////////////////////////////////////////////////////////////////
#define UNUSED(x) (void)(x)
@ -124,7 +125,7 @@ int main(int argc, char** argv)
vk::PhysicalDeviceRayTracingFeaturesKHR raytracingFeature;
// Requesting Vulkan extensions and layers
nvvkpp::ContextCreateInfo contextInfo(true);
nvvk::ContextCreateInfo contextInfo(true);
contextInfo.setVersion(1, 2);
contextInfo.addInstanceLayer("VK_LAYER_LUNARG_monitor", true);
contextInfo.addInstanceExtension(VK_KHR_SURFACE_EXTENSION_NAME);
@ -148,7 +149,7 @@ int main(int argc, char** argv)
contextInfo.addDeviceExtension(VK_KHR_BUFFER_DEVICE_ADDRESS_EXTENSION_NAME);
// Creating Vulkan base application
nvvkpp::Context vkctx{};
nvvk::Context vkctx{};
vkctx.initInstance(contextInfo);
// Find all compatible devices
auto compatibleDevices = vkctx.getCompatibleDevices(contextInfo);
@ -163,7 +164,8 @@ int main(int argc, char** argv)
const vk::SurfaceKHR surface = helloVk.getVkSurface(vkctx.m_instance, window);
vkctx.setGCTQueueWithPresent(surface);
helloVk.setup(vkctx.m_device, vkctx.m_physicalDevice, vkctx.m_queueGCT.familyIndex);
helloVk.setup(vkctx.m_instance, vkctx.m_device, vkctx.m_physicalDevice,
vkctx.m_queueGCT.familyIndex);
helloVk.createSurface(surface, SAMPLE_WIDTH, SAMPLE_HEIGHT);
helloVk.createDepthBuffer();
helloVk.createRenderPass();
@ -241,7 +243,8 @@ int main(int argc, char** argv)
// Clearing screen
vk::ClearValue clearValues[2];
clearValues[0].setColor(nvvkpp::util::clearColor(clearColor));
clearValues[0].setColor(
std::array<float, 4>({clearColor[0], clearColor[1], clearColor[2], clearColor[3]}));
clearValues[1].setDepthStencil({1.0f, 0});
// Offscreen render pass
@ -293,7 +296,6 @@ int main(int argc, char** argv)
helloVk.destroyResources();
helloVk.destroy();
vkctx.m_instance.destroySurfaceKHR(surface);
vkctx.deinit();
glfwDestroyWindow(window);

2
ray_tracing_intersection/shaders/raytrace.rchit
View file

@ -6,7 +6,7 @@
#include "raycommon.glsl"
#include "wavefront.glsl"
hitAttributeEXT vec3 attribs;
hitAttributeEXT vec2 attribs;
// clang-format off
layout(location = 0) rayPayloadInEXT hitPayload prd;

2
ray_tracing_intersection/shaders/raytrace2.rchit
View file

@ -6,7 +6,7 @@
#include "raycommon.glsl"
#include "wavefront.glsl"
hitAttributeEXT vec3 attribs;
hitAttributeEXT vec2 attribs;
// clang-format off
layout(location = 0) rayPayloadInEXT hitPayload prd;