Mercurial > games > semicongine
view tests/test_gltf.nim @ 1256:bfb75c934f4e
add: window focus handling, improve window api a bit
| author | sam <sam@basx.dev> |
|---|---|
| date | Sun, 28 Jul 2024 17:33:41 +0700 |
| parents | 2b5ca798f6d6 |
| children | e9b8d87b9883 |
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import std/os import std/sequtils import std/monotimes import std/times import std/options import std/random import ../semiconginev2 proc test_gltf(time: float32) = var renderdata = InitRenderData() type ObjectData = object transform: Mat4 materialId: int32 Camera = object viewPerspective: Mat4 Material = object color: Vec4f = NewVec4f(1, 1, 1, 1) # colorTexture: int32 = -1 metallic: float32 = 0 roughness: float32 = 0 # metallicRoughnessTexture: int32 = -1 # normalTexture: int32 = -1 # occlusionTexture: int32 = -1 emissive: Vec4f = NewVec4f(0, 0, 0, 0) # emissiveTexture: int32 = -1 MainDescriptors = object materials: array[32, GPUValue[Material, UniformBuffer]] camera: GPUValue[Camera, UniformBufferMapped] Shader = object objectData {.PushConstantAttribute.}: ObjectData position {.VertexAttribute.}: Vec3f color {.VertexAttribute.}: Vec4f normal {.VertexAttribute.}: Vec3f fragmentColor {.Pass.}: Vec4f fragmentNormal {.Pass.}: Vec3f outColor {.ShaderOutput.}: Vec4f descriptors {.DescriptorSets.}: (MainDescriptors, ) # code vertexCode: string = """ void main() { fragmentColor = color * materials[objectData.materialId].color; fragmentNormal = normal; gl_Position = vec4(position, 1) * (objectData.transform * camera.viewPerspective); }""" fragmentCode: string = """ const vec3 lightDir = normalize(vec3(1, -1, 1)); void main() { outColor = vec4(fragmentColor.rgb * (1 - abs(dot(fragmentNormal, lightDir))), fragmentColor.a); }""" Mesh = object position: GPUArray[Vec3f, VertexBuffer] color: GPUArray[Vec4f, VertexBuffer] normal: GPUArray[Vec3f, VertexBuffer] indices: GPUArray[uint32, IndexBuffer] material: int32 var gltfData = LoadMeshes[Mesh, Material]( "town.glb", MeshAttributeNames( POSITION: "position", COLOR: @["color"], NORMAL: "normal", indices: "indices", material: "material", ), MaterialAttributeNames( baseColorFactor: "color", baseColorTexture: "colorTexture", metallicFactor: "metallic", roughnessFactor: "roughness", metallicRoughnessTexture: "metallicRoughnessTexture", normalTexture: "normalTexture", occlusionTexture: "occlusionTexture", emissiveTexture: "emissiveTexture", emissiveFactor: "emissive", ) ) var descriptors = asDescriptorSet( MainDescriptors( camera: asGPUValue(Camera( viewPerspective: Unit4, ), UniformBufferMapped) ) ) for i in 0 ..< gltfData.materials.len: descriptors.data.materials[i] = asGPUValue(gltfData.materials[i], UniformBuffer) for mesh in mitems(gltfData.meshes): for primitive in mitems(mesh): primitive[0].color = asGPUArray(newSeqWith(primitive[0].position.data.len, NewVec4f(1, 1, 1, 1)), VertexBuffer) renderdata.AssignBuffers(primitive[0]) renderdata.AssignBuffers(descriptors) var pipeline = CreatePipeline[Shader](renderPass = vulkan.swapchain.renderPass) InitDescriptorSet(renderdata, pipeline.descriptorSetLayouts[0], descriptors) renderdata.FlushAllMemory() proc drawNode(commandbuffer: VkCommandBuffer, pipeline: Pipeline, nodeId: int, transform: Mat4) = let nodeTransform = gltfData.nodes[nodeId].transform * transform if gltfData.nodes[nodeId].mesh >= 0: for primitive in gltfData.meshes[gltfData.nodes[nodeId].mesh]: RenderWithPushConstant( commandbuffer = commandbuffer, pipeline = pipeline, mesh = primitive[0], pushConstant = ObjectData(transform: nodeTransform, materialId: primitive[0].material) ) for childNode in gltfData.nodes[nodeId].children: drawNode(commandbuffer = commandbuffer, pipeline = pipeline, nodeId = childNode, transform = nodeTransform) var camPos: Vec3f var camYaw: float32 var camPitch: float32 discard UpdateInputs() # clear inputs, otherwise MouseMove will have stuff var start = getMonoTime() var lastT = getMonoTime() while ((getMonoTime() - start).inMilliseconds().int / 1000) < time and UpdateInputs(): let dt = ((getMonoTime() - lastT).inNanoseconds().int / 1_000_000_000).float32 lastT = getMonoTime() camYaw -= MouseMove().x / 1000 camPitch -= MouseMove().y / 1000 var forward = 0'f32 sideward = 0'f32 if KeyIsDown(W): forward += 2 if KeyIsDown(S): forward -= 2 if KeyIsDown(A): sideward -= 2 if KeyIsDown(D): sideward += 2 let camDir = (Rotate(camYaw, Y) * Rotate(camPitch, X)) * Z let camDirSide = camDir.Cross(-Y).Normalized camPos += camDir * forward * dt camPos += camDirSide * sideward * dt descriptors.data.camera.data.viewPerspective = ( Perspective(PI/3, aspect = GetAspectRatio(), zNear = 0.1, zFar = 1) * Rotate(-camPitch, X) * Rotate(-camYaw, Y) * Translate(-camPos) ) UpdateGPUBuffer(descriptors.data.camera) WithNextFrame(framebuffer, commandbuffer): WithRenderPass(vulkan.swapchain.renderPass, framebuffer, commandbuffer, vulkan.swapchain.width, vulkan.swapchain.height, NewVec4f(0, 0, 0, 0)): WithPipeline(commandbuffer, pipeline): WithBind(commandbuffer, (descriptors, ), pipeline): for nodeId in gltfData.scenes[0]: drawNode( commandbuffer = commandbuffer, pipeline = pipeline, nodeId = nodeId, transform = Rotate(PI / 2, Z) ) # cleanup checkVkResult vkDeviceWaitIdle(vulkan.device) DestroyPipeline(pipeline) DestroyRenderData(renderdata) when isMainModule: var time = 1000'f32 InitVulkan() var renderpass = CreateDirectPresentationRenderPass(depthBuffer = true, samples = VK_SAMPLE_COUNT_4_BIT) SetupSwapchain(renderpass = renderpass) LockMouse(true) ShowSystemCursor(false) # tests a simple triangle with minimalistic shader and vertex format test_gltf(time) checkVkResult vkDeviceWaitIdle(vulkan.device) vkDestroyRenderPass(vulkan.device, renderpass.vk, nil) ClearSwapchain() DestroyVulkan()