public AmtSampler(IMTLDevice mDevice, MgSamplerCreateInfo pCreateInfo) { if (pCreateInfo == null) { throw new ArgumentNullException(nameof(pCreateInfo)); } var descriptor = new MTLSamplerDescriptor { SAddressMode = TranslateAddressMode(pCreateInfo.AddressModeU), TAddressMode = TranslateAddressMode(pCreateInfo.AddressModeV), RAddressMode = TranslateAddressMode(pCreateInfo.AddressModeW), MinFilter = TranslateMinFilter(pCreateInfo.MinFilter), MagFilter = TranslateMagFilter(pCreateInfo.MagFilter), MipFilter = TranslateMipFilter(pCreateInfo.MipmapMode), LodMinClamp = pCreateInfo.MinLod, LodMaxClamp = pCreateInfo.MaxLod, MaxAnisotropy = (nuint)pCreateInfo.MaxAnisotropy, CompareFunction = TranslateCompareFunction(pCreateInfo.CompareOp), NormalizedCoordinates = !pCreateInfo.UnnormalizedCoordinates, }; Sampler = mDevice.CreateSamplerState(descriptor); }
public override void ViewDidLoad() { base.ViewDidLoad(); // Set the view to use the default device device = MTLDevice.SystemDefault; if (device == null) { Console.WriteLine("Metal is not supported on this device"); View = new NSView(View.Frame); } // Create a new command queue commandQueue = device.CreateCommandQueue(); // Load all the shader files with a metal file extension in the project defaultLibrary = device.CreateDefaultLibrary(); // Setup view view = (MTKView)View; view.Delegate = this; view.Device = device; view.SampleCount = 1; view.DepthStencilPixelFormat = MTLPixelFormat.Depth32Float_Stencil8; view.ColorPixelFormat = MTLPixelFormat.BGRA8Unorm; view.PreferredFramesPerSecond = 60; view.ClearColor = new MTLClearColor(0.5f, 0.5f, 0.5f, 1.0f); // Load the vertex program into the library IMTLFunction vertexProgram = defaultLibrary.CreateFunction("quad_vertex"); // Load the fragment program into the library IMTLFunction fragmentProgram = defaultLibrary.CreateFunction("quad_fragment"); // Create a vertex descriptor from the MTKMesh MTLVertexDescriptor vertexDescriptor = new MTLVertexDescriptor(); vertexDescriptor.Attributes[0].Format = MTLVertexFormat.Float4; vertexDescriptor.Attributes[0].BufferIndex = 0; vertexDescriptor.Attributes[0].Offset = 0; vertexDescriptor.Attributes[1].Format = MTLVertexFormat.Float2; vertexDescriptor.Attributes[1].BufferIndex = 0; vertexDescriptor.Attributes[1].Offset = 4 * sizeof(float); vertexDescriptor.Layouts[0].Stride = 6 * sizeof(float); vertexDescriptor.Layouts[0].StepRate = 1; vertexDescriptor.Layouts[0].StepFunction = MTLVertexStepFunction.PerVertex; this.vertexBuffer = device.CreateBuffer(vertexData, MTLResourceOptions.CpuCacheModeDefault);// (MTLResourceOptions)0); this.mipmapping = 0; this.constantBuffer = device.CreateBuffer(sizeof(float), MTLResourceOptions.CpuCacheModeDefault); SetConstantBuffer(this.mipmapping, constantBuffer); // Create a reusable pipeline state var pipelineStateDescriptor = new MTLRenderPipelineDescriptor { SampleCount = view.SampleCount, VertexFunction = vertexProgram, FragmentFunction = fragmentProgram, VertexDescriptor = vertexDescriptor, DepthAttachmentPixelFormat = view.DepthStencilPixelFormat, StencilAttachmentPixelFormat = view.DepthStencilPixelFormat }; pipelineStateDescriptor.ColorAttachments[0].PixelFormat = view.ColorPixelFormat; NSError error; pipelineState = device.CreateRenderPipelineState(pipelineStateDescriptor, out error); if (pipelineState == null) { Console.WriteLine("Failed to created pipeline state, error {0}", error); } var depthStateDesc = new MTLDepthStencilDescriptor { DepthCompareFunction = MTLCompareFunction.Less, DepthWriteEnabled = true }; depthState = device.CreateDepthStencilState(depthStateDesc); // Texture KTX NSUrl url = NSBundle.MainBundle.GetUrlForResource("crate", "ktx"); MTKTextureLoader mTKTextureLoader = new MTKTextureLoader(device); this.texture = mTKTextureLoader.FromUrl(url, new MTKTextureLoaderOptions(), out error); Console.WriteLine("Failed to created pipeline state, error {0}", error); MTLSamplerDescriptor samplerDescriptor = new MTLSamplerDescriptor() { MinFilter = MTLSamplerMinMagFilter.Linear, MagFilter = MTLSamplerMinMagFilter.Linear, MipFilter = MTLSamplerMipFilter.Linear, SAddressMode = MTLSamplerAddressMode.ClampToEdge, TAddressMode = MTLSamplerAddressMode.ClampToEdge, }; this.sampler = device.CreateSamplerState(samplerDescriptor); this.clock = new System.Diagnostics.Stopwatch(); this.clock.Start(); this.time = 0; }
public override void ViewDidLoad() { base.ViewDidLoad(); // Set the view to use the default device device = MTLDevice.SystemDefault; if (device == null) { Console.WriteLine("Metal is not supported on this device"); View = new NSView(View.Frame); } // Create a new command queue commandQueue = device.CreateCommandQueue(); // Load all the shader files with a metal file extension in the project defaultLibrary = device.CreateDefaultLibrary(); // Setup view mtkView = (MTKView)View; mtkView.Delegate = this; mtkView.Device = device; mtkView.SampleCount = 1; mtkView.DepthStencilPixelFormat = MTLPixelFormat.Depth32Float_Stencil8; mtkView.ColorPixelFormat = MTLPixelFormat.BGRA8Unorm; mtkView.PreferredFramesPerSecond = 60; mtkView.ClearColor = new MTLClearColor(0.5f, 0.5f, 0.5f, 1.0f); // Load the vertex program into the library IMTLFunction triangleVertexProgram = defaultLibrary.CreateFunction("triangle_vertex"); IMTLFunction cubeVertexProgram = defaultLibrary.CreateFunction("cube_vertex"); // Load the fragment program into the library IMTLFunction triangleFragmentProgram = defaultLibrary.CreateFunction("triangle_fragment"); IMTLFunction cubeFragmentProgram = defaultLibrary.CreateFunction("cube_fragment"); // Triangle vertex descriptor MTLVertexDescriptor triangleVertexDescriptor = new MTLVertexDescriptor(); triangleVertexDescriptor.Attributes[0].Format = MTLVertexFormat.Float4; triangleVertexDescriptor.Attributes[0].BufferIndex = 0; triangleVertexDescriptor.Attributes[0].Offset = 0; triangleVertexDescriptor.Attributes[1].Format = MTLVertexFormat.Float4; triangleVertexDescriptor.Attributes[1].BufferIndex = 0; triangleVertexDescriptor.Attributes[1].Offset = 4 * sizeof(float); triangleVertexDescriptor.Layouts[0].Stride = 8 * sizeof(float); triangleVertexDescriptor.Layouts[0].StepRate = 1; triangleVertexDescriptor.Layouts[0].StepFunction = MTLVertexStepFunction.PerVertex; // Cube vertex descriptor MTLVertexDescriptor cubeVertexDescriptor = new MTLVertexDescriptor(); cubeVertexDescriptor.Attributes[0].Format = MTLVertexFormat.Float4; cubeVertexDescriptor.Attributes[0].BufferIndex = 0; cubeVertexDescriptor.Attributes[0].Offset = 0; cubeVertexDescriptor.Attributes[1].Format = MTLVertexFormat.Float2; cubeVertexDescriptor.Attributes[1].BufferIndex = 0; cubeVertexDescriptor.Attributes[1].Offset = 4 * sizeof(float); cubeVertexDescriptor.Layouts[0].Stride = 6 * sizeof(float); cubeVertexDescriptor.Layouts[0].StepRate = 1; cubeVertexDescriptor.Layouts[0].StepFunction = MTLVertexStepFunction.PerVertex; // Create buffers triangleVertexBuffer = device.CreateBuffer(triangleVertexData, MTLResourceOptions.CpuCacheModeDefault); cubeVertexBuffer = device.CreateBuffer(cubeVertexData, MTLResourceOptions.CpuCacheModeDefault); this.clock = new System.Diagnostics.Stopwatch(); clock.Start(); this.view = CreateLookAt(new Vector3(0, 0, 5), new Vector3(0, 0, 0), Vector3.UnitY); var aspect = (float)(View.Bounds.Size.Width / View.Bounds.Size.Height); this.proj = Matrix4.CreatePerspectiveFieldOfView((float)Math.PI / 4, aspect, 0.1f, 100); this.cubeParameters.WorldViewProjection = Matrix4.Identity; cubeConstantBuffer = device.CreateBuffer((uint)Marshal.SizeOf(this.cubeParameters), MTLResourceOptions.CpuCacheModeDefault); // Create Pipeline Descriptor var trianglePipelineStateDescriptor = new MTLRenderPipelineDescriptor { SampleCount = mtkView.SampleCount, VertexFunction = triangleVertexProgram, FragmentFunction = triangleFragmentProgram, VertexDescriptor = triangleVertexDescriptor, DepthAttachmentPixelFormat = mtkView.DepthStencilPixelFormat, StencilAttachmentPixelFormat = mtkView.DepthStencilPixelFormat, }; var cubePipelineStateDescriptor = new MTLRenderPipelineDescriptor { SampleCount = mtkView.SampleCount, VertexFunction = cubeVertexProgram, FragmentFunction = cubeFragmentProgram, VertexDescriptor = cubeVertexDescriptor, DepthAttachmentPixelFormat = mtkView.DepthStencilPixelFormat, StencilAttachmentPixelFormat = mtkView.DepthStencilPixelFormat, }; MTLRenderPipelineColorAttachmentDescriptor triangleRenderBufferAttachment = trianglePipelineStateDescriptor.ColorAttachments[0]; triangleRenderBufferAttachment.PixelFormat = mtkView.ColorPixelFormat; MTLRenderPipelineColorAttachmentDescriptor cubeRenderBufferAttachment = cubePipelineStateDescriptor.ColorAttachments[0]; cubeRenderBufferAttachment.PixelFormat = mtkView.ColorPixelFormat; NSError error; trianglePipelineState = device.CreateRenderPipelineState(trianglePipelineStateDescriptor, out error); if (trianglePipelineState == null) { Console.WriteLine("Failed to created pipeline state, error {0}", error); } cubePipelineState = device.CreateRenderPipelineState(cubePipelineStateDescriptor, out error); if (cubePipelineState == null) { Console.WriteLine("Failed to created pipeline state, error {0}", error); } var depthStencilDescriptor = new MTLDepthStencilDescriptor { DepthCompareFunction = MTLCompareFunction.Less, DepthWriteEnabled = true }; depthStencilState = device.CreateDepthStencilState(depthStencilDescriptor); // Texture NSImage image = NSImage.ImageNamed("crate.png"); MTKTextureLoader mTKTextureLoader = new MTKTextureLoader(device); this.cubeTexture = mTKTextureLoader.FromCGImage(image.CGImage, new MTKTextureLoaderOptions(), out error); MTLSamplerDescriptor samplerDescriptor = new MTLSamplerDescriptor() { MinFilter = MTLSamplerMinMagFilter.Linear, MagFilter = MTLSamplerMinMagFilter.Linear, SAddressMode = MTLSamplerAddressMode.Repeat, TAddressMode = MTLSamplerAddressMode.Repeat, }; this.sampler = device.CreateSamplerState(samplerDescriptor); // Create FrameBuffer texture IMTLTexture drawableTexture = mtkView.CurrentDrawable.Texture; MTLTextureDescriptor textureDescriptor = new MTLTextureDescriptor() { Width = drawableTexture.Width, Height = drawableTexture.Height, PixelFormat = drawableTexture.PixelFormat, TextureType = drawableTexture.TextureType, MipmapLevelCount = drawableTexture.MipmapLevelCount, ArrayLength = drawableTexture.ArrayLength, SampleCount = drawableTexture.SampleCount, Depth = drawableTexture.Depth, CpuCacheMode = drawableTexture.CpuCacheMode, Usage = MTLTextureUsage.RenderTarget, StorageMode = MTLStorageMode.Managed, }; this.colorFrameBufferTexture = device.CreateTexture(textureDescriptor); }
public override void ViewDidLoad() { base.ViewDidLoad(); // Set the view to use the default device device = MTLDevice.SystemDefault; if (device == null) { Console.WriteLine("Metal is not supported on this device"); View = new NSView(View.Frame); } // Create a new command queue commandQueue = device.CreateCommandQueue(); // Load all the shader files with a metal file extension in the project defaultLibrary = device.CreateDefaultLibrary(); // Setup view mtkView = (MTKView)View; mtkView.Delegate = this; mtkView.Device = device; mtkView.SampleCount = 1; mtkView.DepthStencilPixelFormat = MTLPixelFormat.Depth32Float_Stencil8; mtkView.ColorPixelFormat = MTLPixelFormat.BGRA8Unorm; mtkView.PreferredFramesPerSecond = 60; mtkView.ClearColor = new MTLClearColor(0.5f, 0.5f, 0.5f, 1.0f); // Load the vertex program into the library IMTLFunction vertexProgram = defaultLibrary.CreateFunction("cube_vertex"); // Load the fragment program into the library IMTLFunction fragmentProgram = defaultLibrary.CreateFunction("cube_fragment"); // Create a vertex descriptor from the MTKMesh MTLVertexDescriptor vertexDescriptor = new MTLVertexDescriptor(); vertexDescriptor.Attributes[0].Format = MTLVertexFormat.Float4; vertexDescriptor.Attributes[0].BufferIndex = 0; vertexDescriptor.Attributes[0].Offset = 0; vertexDescriptor.Attributes[1].Format = MTLVertexFormat.Float3; vertexDescriptor.Attributes[1].BufferIndex = 0; vertexDescriptor.Attributes[1].Offset = 4 * sizeof(float); vertexDescriptor.Attributes[2].Format = MTLVertexFormat.Float2; vertexDescriptor.Attributes[2].BufferIndex = 0; vertexDescriptor.Attributes[2].Offset = 7 * sizeof(float); vertexDescriptor.Layouts[0].Stride = 9 * sizeof(float); vertexDescriptor.Layouts[0].StepRate = 1; vertexDescriptor.Layouts[0].StepFunction = MTLVertexStepFunction.PerVertex; // Primitive Torus(1.0f, 0.3f, 28, out List <PositionNormalTexture> vertexData, out List <ushort> indexData); vertexBuffer = device.CreateBuffer(vertexData.ToArray(), MTLResourceOptions.CpuCacheModeDefault);// (MTLResourceOptions)0); indexDataArray = indexData.ToArray(); indexBuffer = device.CreateBuffer(indexDataArray, MTLResourceOptions.CpuCacheModeDefault); // Use clock this.clock = new System.Diagnostics.Stopwatch(); clock.Start(); Vector3 cameraPosition = new Vector3(0, 0, 1.5f); this.view = CreateLookAt(cameraPosition, new Vector3(0, 0, 0), Vector3.UnitY); var aspect = (float)(View.Bounds.Size.Width / View.Bounds.Size.Height); proj = Matrix4.CreatePerspectiveFieldOfView((float)Math.PI / 4, aspect, 0.1f, 100); // Constant Buffer this.param = new Parameters() { CameraPosition = cameraPosition, WorldViewProjection = Matrix4.Identity, World = Matrix4.Identity, WorldInverseTranspose = Matrix4.Identity, }; this.constantBuffer = device.CreateBuffer((uint)Marshal.SizeOf(this.param), MTLResourceOptions.CpuCacheModeDefault); // Create a reusable pipeline state var pipelineStateDescriptor = new MTLRenderPipelineDescriptor { SampleCount = mtkView.SampleCount, VertexFunction = vertexProgram, FragmentFunction = fragmentProgram, VertexDescriptor = vertexDescriptor, DepthAttachmentPixelFormat = mtkView.DepthStencilPixelFormat, StencilAttachmentPixelFormat = mtkView.DepthStencilPixelFormat, }; MTLRenderPipelineColorAttachmentDescriptor renderBufferAttachment = pipelineStateDescriptor.ColorAttachments[0]; renderBufferAttachment.PixelFormat = mtkView.ColorPixelFormat; NSError error; pipelineState = device.CreateRenderPipelineState(pipelineStateDescriptor, out error); if (pipelineState == null) { Console.WriteLine("Failed to created pipeline state, error {0}", error); } var depthStateDesc = new MTLDepthStencilDescriptor { DepthCompareFunction = MTLCompareFunction.Less, DepthWriteEnabled = true }; depthState = device.CreateDepthStencilState(depthStateDesc); MTKTextureLoader mTKTextureLoader = new MTKTextureLoader(device); // Texture NSUrl url = NSBundle.MainBundle.GetUrlForResource("cubemap2", "ktx"); this.texture = mTKTextureLoader.FromUrl(url, new MTKTextureLoaderOptions(), out error); Console.WriteLine("Failed to created pipeline state, error {0}", error); MTLSamplerDescriptor samplerDescriptor = new MTLSamplerDescriptor() { MinFilter = MTLSamplerMinMagFilter.Linear, MagFilter = MTLSamplerMinMagFilter.Linear, MipFilter = MTLSamplerMipFilter.Linear, SAddressMode = MTLSamplerAddressMode.ClampToEdge, TAddressMode = MTLSamplerAddressMode.ClampToEdge, }; this.sampler = device.CreateSamplerState(samplerDescriptor); }
public override void ViewDidLoad() { base.ViewDidLoad(); // Set the view to use the default device device = MTLDevice.SystemDefault; if (device == null) { Console.WriteLine("Metal is not supported on this device"); View = new NSView(View.Frame); } // Create a new command queue commandQueue = device.CreateCommandQueue(); // Load all the shader files with a metal file extension in the project defaultLibrary = device.CreateDefaultLibrary(); // Setup view mtkView = (MTKView)View; mtkView.Delegate = this; mtkView.Device = device; mtkView.SampleCount = 1; mtkView.DepthStencilPixelFormat = MTLPixelFormat.Depth32Float_Stencil8; mtkView.ColorPixelFormat = MTLPixelFormat.BGRA8Unorm; mtkView.PreferredFramesPerSecond = 60; mtkView.ClearColor = new MTLClearColor(0.5f, 0.5f, 0.5f, 1.0f); // Load the vertex program into the library IMTLFunction vertexProgram = defaultLibrary.CreateFunction("mesh_vertex"); // Load the fragment program into the library IMTLFunction fragmentProgram = defaultLibrary.CreateFunction("mesh_fragment"); // Generate meshes MTKMeshBufferAllocator mtkBufferAllocator = new MTKMeshBufferAllocator(device); NSUrl url = NSBundle.MainBundle.GetUrlForResource("Fighter", "obj"); MDLAsset mdlAsset = new MDLAsset(url, new MDLVertexDescriptor(), mtkBufferAllocator); MDLObject mdlObject = mdlAsset.GetObject(0); MDLMesh mdlMesh = mdlObject as MDLMesh; NSError error; objMesh = new MTKMesh(mdlMesh, device, out error); // Create a vertex descriptor from the MTKMesh MTLVertexDescriptor vertexDescriptor = MTLVertexDescriptor.FromModelIO(objMesh.VertexDescriptor); vertexDescriptor.Layouts[0].StepRate = 1; vertexDescriptor.Layouts[0].StepFunction = MTLVertexStepFunction.PerVertex; this.clock = new System.Diagnostics.Stopwatch(); clock.Start(); this.view = CreateLookAt(new Vector3(0, 1, 2), new Vector3(0, 0, 0), Vector3.UnitY); var aspect = (float)(View.Bounds.Size.Width / View.Bounds.Size.Height); this.proj = Matrix4.CreatePerspectiveFieldOfView((float)Math.PI / 4, aspect, 0.1f, 100); this.constantBuffer = device.CreateBuffer((uint)Marshal.SizeOf(this.param), MTLResourceOptions.CpuCacheModeDefault); // Create a reusable pipeline state var pipelineStateDescriptor = new MTLRenderPipelineDescriptor { SampleCount = mtkView.SampleCount, VertexFunction = vertexProgram, FragmentFunction = fragmentProgram, VertexDescriptor = vertexDescriptor, DepthAttachmentPixelFormat = mtkView.DepthStencilPixelFormat, StencilAttachmentPixelFormat = mtkView.DepthStencilPixelFormat }; pipelineStateDescriptor.ColorAttachments[0].PixelFormat = mtkView.ColorPixelFormat; pipelineState = device.CreateRenderPipelineState(pipelineStateDescriptor, out error); if (pipelineState == null) { Console.WriteLine("Failed to created pipeline state, error {0}", error); } var depthStateDesc = new MTLDepthStencilDescriptor { DepthCompareFunction = MTLCompareFunction.Less, DepthWriteEnabled = true }; depthState = device.CreateDepthStencilState(depthStateDesc); NSImage image = NSImage.ImageNamed("Fighter_Diffuse.jpg"); MTKTextureLoader mTKTextureLoader = new MTKTextureLoader(device); this.texture = mTKTextureLoader.FromCGImage(image.CGImage, new MTKTextureLoaderOptions(), out error); MTLSamplerDescriptor samplerDescriptor = new MTLSamplerDescriptor() { MinFilter = MTLSamplerMinMagFilter.Linear, MagFilter = MTLSamplerMinMagFilter.Linear, SAddressMode = MTLSamplerAddressMode.ClampToEdge, TAddressMode = MTLSamplerAddressMode.ClampToEdge, }; this.sampler = device.CreateSamplerState(samplerDescriptor); }
public override void ViewDidLoad() { base.ViewDidLoad(); // Set the view to use the default device device = MTLDevice.SystemDefault; if (device == null) { Console.WriteLine("Metal is not supported on this device"); View = new NSView(View.Frame); } // Create a new command queue commandQueue = device.CreateCommandQueue(); // Load all the shader files with a metal file extension in the project defaultLibrary = device.CreateDefaultLibrary(); // Setup view mtkView = (MTKView)View; mtkView.Delegate = this; mtkView.Device = device; mtkView.SampleCount = 1; mtkView.DepthStencilPixelFormat = MTLPixelFormat.Depth32Float_Stencil8; mtkView.ColorPixelFormat = MTLPixelFormat.BGRA8Unorm; mtkView.PreferredFramesPerSecond = 60; mtkView.ClearColor = new MTLClearColor(0.5f, 0.5f, 0.5f, 1.0f); // Load the vertex program into the library IMTLFunction vertexProgram = defaultLibrary.CreateFunction("cube_vertex"); // Load the fragment program into the library IMTLFunction fragmentProgram = defaultLibrary.CreateFunction("cube_fragment"); // Create a vertex descriptor from the MTKMesh MTLVertexDescriptor vertexDescriptor = new MTLVertexDescriptor(); vertexDescriptor.Attributes[0].Format = MTLVertexFormat.Float4; vertexDescriptor.Attributes[0].BufferIndex = 0; vertexDescriptor.Attributes[0].Offset = 0; vertexDescriptor.Attributes[1].Format = MTLVertexFormat.Float4; vertexDescriptor.Attributes[1].BufferIndex = 0; vertexDescriptor.Attributes[1].Offset = 4 * sizeof(float); vertexDescriptor.Attributes[2].Format = MTLVertexFormat.Float2; vertexDescriptor.Attributes[2].BufferIndex = 0; vertexDescriptor.Attributes[2].Offset = 8 * sizeof(float); vertexDescriptor.Layouts[0].Stride = 10 * sizeof(float); vertexDescriptor.Layouts[0].StepRate = 1; vertexDescriptor.Layouts[0].StepFunction = MTLVertexStepFunction.PerVertex; vertexBuffer = device.CreateBuffer(vertexData, MTLResourceOptions.CpuCacheModeDefault);// (MTLResourceOptions)0); this.clock = new System.Diagnostics.Stopwatch(); clock.Start(); this.view = CreateLookAt(new Vector3(0, 0, 5), new Vector3(0, 0, 0), Vector3.UnitY); var aspect = (float)(View.Bounds.Size.Width / View.Bounds.Size.Height); proj = Matrix4.CreatePerspectiveFieldOfView((float)Math.PI / 4, aspect, 0.1f, 100); constantBuffer = device.CreateBuffer(64, MTLResourceOptions.CpuCacheModeDefault); // Create a reusable pipeline state var pipelineStateDescriptor = new MTLRenderPipelineDescriptor { SampleCount = mtkView.SampleCount, VertexFunction = vertexProgram, FragmentFunction = fragmentProgram, VertexDescriptor = vertexDescriptor, DepthAttachmentPixelFormat = mtkView.DepthStencilPixelFormat, StencilAttachmentPixelFormat = mtkView.DepthStencilPixelFormat, }; MTLRenderPipelineColorAttachmentDescriptor renderBufferAttachment = pipelineStateDescriptor.ColorAttachments[0]; renderBufferAttachment.PixelFormat = mtkView.ColorPixelFormat; NSError error; pipelineState = device.CreateRenderPipelineState(pipelineStateDescriptor, out error); if (pipelineState == null) { Console.WriteLine("Failed to created pipeline state, error {0}", error); } var depthStateDesc = new MTLDepthStencilDescriptor { DepthCompareFunction = MTLCompareFunction.Less, DepthWriteEnabled = true }; depthState = device.CreateDepthStencilState(depthStateDesc); // Texture NSImage image = NSImage.ImageNamed("crate.png"); MTKTextureLoader mTKTextureLoader = new MTKTextureLoader(device); this.texture = mTKTextureLoader.FromCGImage(image.CGImage, new MTKTextureLoaderOptions(), out error); MTLSamplerDescriptor samplerDescriptor = new MTLSamplerDescriptor() { MinFilter = MTLSamplerMinMagFilter.Linear, MagFilter = MTLSamplerMinMagFilter.Linear, SAddressMode = MTLSamplerAddressMode.Repeat, TAddressMode = MTLSamplerAddressMode.Repeat, }; this.sampler = device.CreateSamplerState(samplerDescriptor); }