/// <summary> /// CreateResources is called when the VirtualRealityProvider is initialized and should create the DirectX resources. /// </summary> /// <remarks> /// <para> /// <b>CreateResources</b> is called when the VirtualRealityProvider is initialized and should create the DirectX resources. /// </para> /// <para> /// This method is called after this virtual reality provider is registered with calling the <see cref="DXScene.InitializeVirtualRealityRendering"/> method. /// This method then calls the <see cref="DXSceneResource.InitializeResources"/> and the <see cref="VirtualRealityProviderBase.OnInitializeResources"/>. /// OnInitializeResources calls the this CreateResources method and then <see cref="VirtualRealityProviderBase.InitializeRenderingSteps"/> method. /// </para> /// <para> /// This method usually creates pixel shaders and constant buffers. /// Other resources (back buffers and views) are usually created in <see cref="VirtualRealityProviderBase.UpdateRenderingContext"/> where the size of the current back buffer is compared with the size of back buffers for virtual reality. /// </para> /// </remarks> /// <param name="dxScene">parent DXScene</param> protected override void CreateResources(DXScene dxScene) { if (_eyeTextureSwapChains != null) { if (_eyeTextureSwapChains[0] != null) { _eyeTextureSwapChains[0].Dispose(); } if (_eyeTextureSwapChains[1] != null) { _eyeTextureSwapChains[1].Dispose(); } } else { _eyeTextureSwapChains = new OculusTextureSwapChain[2]; } _eyeTextureSwapChains[0] = new OculusTextureSwapChain(_ovr, _sessionPtr, dxScene.Device, EyeType.Left, Format.B8G8R8A8_UNorm_SRgb, _ovr.GetFovTextureSize(_sessionPtr, EyeType.Left, _hmdDesc.DefaultEyeFov[0], 1.0f), createDepthStencilView: true, isDebugDevice: dxScene.DXDevice.IsDebugDevice); _eyeTextureSwapChains[1] = new OculusTextureSwapChain(_ovr, _sessionPtr, dxScene.Device, EyeType.Left, Format.B8G8R8A8_UNorm_SRgb, _ovr.GetFovTextureSize(_sessionPtr, EyeType.Right, _hmdDesc.DefaultEyeFov[1], 1.0f), createDepthStencilView: true, isDebugDevice: dxScene.DXDevice.IsDebugDevice); _layerShared = new LayerEyeFov(); _layerShared.Header = new LayerHeader() { Type = LayerType.EyeFov, Flags = LayerFlags.HighQuality }; // Specify the texture to show on the HMD. _layerShared.ColorTextureLeft = _eyeTextureSwapChains[0].TextureSwapChainPtr; _layerShared.ColorTextureRight = _eyeTextureSwapChains[1].TextureSwapChainPtr; _layerShared.ViewportLeft.Position = new Vector2i(0, 0); _layerShared.ViewportLeft.Size = _eyeTextureSwapChains[0].Size; _layerShared.ViewportRight.Position = new Vector2i(0, 0); _layerShared.ViewportRight.Size = _eyeTextureSwapChains[1].Size; _layerShared.FovLeft = _hmdDesc.DefaultEyeFov[0]; _layerShared.FovRight = _hmdDesc.DefaultEyeFov[1]; _eyeRenderDesc[0] = _ovr.GetRenderDesc(_sessionPtr, EyeType.Left, _hmdDesc.DefaultEyeFov[0]); _hmdToEyeOffset[1] = _eyeRenderDesc[1].HmdToEyePose.Position; _eyeRenderDesc[1] = _ovr.GetRenderDesc(_sessionPtr, EyeType.Right, _hmdDesc.DefaultEyeFov[1]); _hmdToEyeOffset[1] = _eyeRenderDesc[1].HmdToEyePose.Position; // Create MSAA back buffer if needed UpdateMsaaBackBuffer(_eyeTextureSwapChains[0].Size.Width, _eyeTextureSwapChains[0].Size.Height, _multisamplingCount); _mirrorTextureDesc = new MirrorTextureDesc() { Format = SharpDXHelpers.GetTextureFormat(dxScene.BackBufferDescription.Format), Height = dxScene.BackBufferDescription.Height, MiscFlags = dxScene.BackBufferDescription.MipLevels != 1 ? TextureMiscFlags.AllowGenerateMips : TextureMiscFlags.None, Width = dxScene.BackBufferDescription.Width }; // FloorLevel will give tracking poses where the floor height is 0 _ovr.SetTrackingOriginType(_sessionPtr, TrackingOrigin.EyeLevel); IntPtr mirrorTexturePtr; var result = _ovr.CreateMirrorTextureDX(_sessionPtr, dxScene.Device.NativePointer, ref _mirrorTextureDesc, out mirrorTexturePtr); if (result < Ab3d.OculusWrap.Result.Success) { var lastError = _ovr.GetLastErrorInfo(); throw new OvrException("Failed to create Oculus mirror texture: " + lastError.ErrorString, lastError.Result); } _mirrorTexture = new OculusMirrorTexture(_ovr, _sessionPtr, mirrorTexturePtr); // Retrieve the Direct3D texture contained in the Oculus MirrorTexture. IntPtr mirrorTextureComPtr; result = _mirrorTexture.GetBufferDX(typeof(Texture2D).GUID, out mirrorTextureComPtr); if (result < Ab3d.OculusWrap.Result.Success) { var lastError = _ovr.GetLastErrorInfo(); throw new OvrException("Failed to retrieve the texture from the created mirror texture buffer: " + lastError.ErrorString, lastError.Result); } // Create a managed Texture2D, based on the unmanaged texture pointer. _mirrorTextureDX = new Texture2D(mirrorTextureComPtr); if (dxScene.DXDevice.IsDebugDevice) { _mirrorTextureDX.DebugName = "OculusMirrorTexture"; } // To prevent DirectX from rendering more then one frame in the background, // we need to set the MaximumFrameLatency to 1. // This prevents occasional dropped frames in Oculus Rift. var dxgiDevice = dxScene.Device.QueryInterface <SharpDX.DXGI.Device1>(); if (dxgiDevice != null) { dxgiDevice.MaximumFrameLatency = 1; dxgiDevice.Dispose(); } _frameIndex = 0; _matrixCamera = new MatrixCamera(); }
private static void Main() { RenderForm form = new RenderForm("OculusWrap SharpDX demo"); IntPtr sessionPtr; InputLayout inputLayout = null; Buffer contantBuffer = null; Buffer vertexBuffer = null; ShaderSignature shaderSignature = null; PixelShader pixelShader = null; ShaderBytecode pixelShaderByteCode = null; VertexShader vertexShader = null; ShaderBytecode vertexShaderByteCode = null; Texture2D mirrorTextureD3D = null; EyeTexture[] eyeTextures = null; DeviceContext immediateContext = null; DepthStencilState depthStencilState = null; DepthStencilView depthStencilView = null; Texture2D depthBuffer = null; RenderTargetView backBufferRenderTargetView = null; Texture2D backBuffer = null; SharpDX.DXGI.SwapChain swapChain = null; Factory factory = null; MirrorTexture mirrorTexture = null; Guid textureInterfaceId = new Guid("6f15aaf2-d208-4e89-9ab4-489535d34f9c"); // Interface ID of the Direct3D Texture2D interface. Result result; OvrWrap OVR = OvrWrap.Create(); // Define initialization parameters with debug flag. InitParams initializationParameters = new InitParams(); initializationParameters.Flags = InitFlags.Debug | InitFlags.RequestVersion; initializationParameters.RequestedMinorVersion = 17; // Initialize the Oculus runtime. string errorReason = null; try { result = OVR.Initialize(initializationParameters); if (result < Result.Success) { errorReason = result.ToString(); } } catch (Exception ex) { errorReason = ex.Message; } if (errorReason != null) { MessageBox.Show("Failed to initialize the Oculus runtime library:\r\n" + errorReason, "Error", MessageBoxButtons.OK, MessageBoxIcon.Error); return; } // Use the head mounted display. sessionPtr = IntPtr.Zero; var graphicsLuid = new GraphicsLuid(); result = OVR.Create(ref sessionPtr, ref graphicsLuid); if (result < Result.Success) { MessageBox.Show("The HMD is not enabled: " + result.ToString(), "Error", MessageBoxButtons.OK, MessageBoxIcon.Error); return; } var hmdDesc = OVR.GetHmdDesc(sessionPtr); try { // Create a set of layers to submit. eyeTextures = new EyeTexture[2]; // Create DirectX drawing device. SharpDX.Direct3D11.Device device = new Device(SharpDX.Direct3D.DriverType.Hardware, DeviceCreationFlags.Debug); // Create DirectX Graphics Interface factory, used to create the swap chain. factory = new SharpDX.DXGI.Factory4(); immediateContext = device.ImmediateContext; // Define the properties of the swap chain. SwapChainDescription swapChainDescription = new SwapChainDescription(); swapChainDescription.BufferCount = 1; swapChainDescription.IsWindowed = true; swapChainDescription.OutputHandle = form.Handle; swapChainDescription.SampleDescription = new SampleDescription(1, 0); swapChainDescription.Usage = Usage.RenderTargetOutput | Usage.ShaderInput; swapChainDescription.SwapEffect = SwapEffect.Sequential; swapChainDescription.Flags = SwapChainFlags.AllowModeSwitch; swapChainDescription.ModeDescription.Width = form.Width; swapChainDescription.ModeDescription.Height = form.Height; swapChainDescription.ModeDescription.Format = Format.R8G8B8A8_UNorm; swapChainDescription.ModeDescription.RefreshRate.Numerator = 0; swapChainDescription.ModeDescription.RefreshRate.Denominator = 1; // Create the swap chain. swapChain = new SwapChain(factory, device, swapChainDescription); // Retrieve the back buffer of the swap chain. backBuffer = swapChain.GetBackBuffer <Texture2D>(0); backBufferRenderTargetView = new RenderTargetView(device, backBuffer); // Create a depth buffer, using the same width and height as the back buffer. Texture2DDescription depthBufferDescription = new Texture2DDescription(); depthBufferDescription.Format = Format.D32_Float; depthBufferDescription.ArraySize = 1; depthBufferDescription.MipLevels = 1; depthBufferDescription.Width = form.Width; depthBufferDescription.Height = form.Height; depthBufferDescription.SampleDescription = new SampleDescription(1, 0); depthBufferDescription.Usage = ResourceUsage.Default; depthBufferDescription.BindFlags = BindFlags.DepthStencil; depthBufferDescription.CpuAccessFlags = CpuAccessFlags.None; depthBufferDescription.OptionFlags = ResourceOptionFlags.None; // Define how the depth buffer will be used to filter out objects, based on their distance from the viewer. DepthStencilStateDescription depthStencilStateDescription = new DepthStencilStateDescription(); depthStencilStateDescription.IsDepthEnabled = true; depthStencilStateDescription.DepthComparison = Comparison.Less; depthStencilStateDescription.DepthWriteMask = DepthWriteMask.Zero; // Create the depth buffer. depthBuffer = new Texture2D(device, depthBufferDescription); depthStencilView = new DepthStencilView(device, depthBuffer); depthStencilState = new DepthStencilState(device, depthStencilStateDescription); var viewport = new Viewport(0, 0, hmdDesc.Resolution.Width, hmdDesc.Resolution.Height, 0.0f, 1.0f); immediateContext.OutputMerger.SetDepthStencilState(depthStencilState); immediateContext.OutputMerger.SetRenderTargets(depthStencilView, backBufferRenderTargetView); immediateContext.Rasterizer.SetViewport(viewport); // Retrieve the DXGI device, in order to set the maximum frame latency. using (SharpDX.DXGI.Device1 dxgiDevice = device.QueryInterface <SharpDX.DXGI.Device1>()) { dxgiDevice.MaximumFrameLatency = 1; } var layerEyeFov = new LayerEyeFov(); layerEyeFov.Header.Type = LayerType.EyeFov; layerEyeFov.Header.Flags = LayerFlags.None; for (int eyeIndex = 0; eyeIndex < 2; eyeIndex++) { EyeType eye = (EyeType)eyeIndex; var eyeTexture = new EyeTexture(); eyeTextures[eyeIndex] = eyeTexture; // Retrieve size and position of the texture for the current eye. eyeTexture.FieldOfView = hmdDesc.DefaultEyeFov[eyeIndex]; eyeTexture.TextureSize = OVR.GetFovTextureSize(sessionPtr, eye, hmdDesc.DefaultEyeFov[eyeIndex], 1.0f); eyeTexture.RenderDescription = OVR.GetRenderDesc(sessionPtr, eye, hmdDesc.DefaultEyeFov[eyeIndex]); eyeTexture.HmdToEyeViewOffset = eyeTexture.RenderDescription.HmdToEyePose.Position; eyeTexture.ViewportSize.Position = new Vector2i(0, 0); eyeTexture.ViewportSize.Size = eyeTexture.TextureSize; eyeTexture.Viewport = new Viewport(0, 0, eyeTexture.TextureSize.Width, eyeTexture.TextureSize.Height, 0.0f, 1.0f); // Define a texture at the size recommended for the eye texture. eyeTexture.Texture2DDescription = new Texture2DDescription(); eyeTexture.Texture2DDescription.Width = eyeTexture.TextureSize.Width; eyeTexture.Texture2DDescription.Height = eyeTexture.TextureSize.Height; eyeTexture.Texture2DDescription.ArraySize = 1; eyeTexture.Texture2DDescription.MipLevels = 1; eyeTexture.Texture2DDescription.Format = Format.R8G8B8A8_UNorm; eyeTexture.Texture2DDescription.SampleDescription = new SampleDescription(1, 0); eyeTexture.Texture2DDescription.Usage = ResourceUsage.Default; eyeTexture.Texture2DDescription.CpuAccessFlags = CpuAccessFlags.None; eyeTexture.Texture2DDescription.BindFlags = BindFlags.ShaderResource | BindFlags.RenderTarget; // Convert the SharpDX texture description to the Oculus texture swap chain description. TextureSwapChainDesc textureSwapChainDesc = SharpDXHelpers.CreateTextureSwapChainDescription(eyeTexture.Texture2DDescription); // Create a texture swap chain, which will contain the textures to render to, for the current eye. IntPtr textureSwapChainPtr; result = OVR.CreateTextureSwapChainDX(sessionPtr, device.NativePointer, ref textureSwapChainDesc, out textureSwapChainPtr); WriteErrorDetails(OVR, result, "Failed to create swap chain."); eyeTexture.SwapTextureSet = new TextureSwapChain(OVR, sessionPtr, textureSwapChainPtr); // Retrieve the number of buffers of the created swap chain. int textureSwapChainBufferCount; result = eyeTexture.SwapTextureSet.GetLength(out textureSwapChainBufferCount); WriteErrorDetails(OVR, result, "Failed to retrieve the number of buffers of the created swap chain."); // Create room for each DirectX texture in the SwapTextureSet. eyeTexture.Textures = new Texture2D[textureSwapChainBufferCount]; eyeTexture.RenderTargetViews = new RenderTargetView[textureSwapChainBufferCount]; // Create a texture 2D and a render target view, for each unmanaged texture contained in the SwapTextureSet. for (int textureIndex = 0; textureIndex < textureSwapChainBufferCount; textureIndex++) { // Retrieve the Direct3D texture contained in the Oculus TextureSwapChainBuffer. IntPtr swapChainTextureComPtr = IntPtr.Zero; result = eyeTexture.SwapTextureSet.GetBufferDX(textureIndex, textureInterfaceId, out swapChainTextureComPtr); WriteErrorDetails(OVR, result, "Failed to retrieve a texture from the created swap chain."); // Create a managed Texture2D, based on the unmanaged texture pointer. eyeTexture.Textures[textureIndex] = new Texture2D(swapChainTextureComPtr); // Create a render target view for the current Texture2D. eyeTexture.RenderTargetViews[textureIndex] = new RenderTargetView(device, eyeTexture.Textures[textureIndex]); } // Define the depth buffer, at the size recommended for the eye texture. eyeTexture.DepthBufferDescription = new Texture2DDescription(); eyeTexture.DepthBufferDescription.Format = Format.D32_Float; eyeTexture.DepthBufferDescription.Width = eyeTexture.TextureSize.Width; eyeTexture.DepthBufferDescription.Height = eyeTexture.TextureSize.Height; eyeTexture.DepthBufferDescription.ArraySize = 1; eyeTexture.DepthBufferDescription.MipLevels = 1; eyeTexture.DepthBufferDescription.SampleDescription = new SampleDescription(1, 0); eyeTexture.DepthBufferDescription.Usage = ResourceUsage.Default; eyeTexture.DepthBufferDescription.BindFlags = BindFlags.DepthStencil; eyeTexture.DepthBufferDescription.CpuAccessFlags = CpuAccessFlags.None; eyeTexture.DepthBufferDescription.OptionFlags = ResourceOptionFlags.None; // Create the depth buffer. eyeTexture.DepthBuffer = new Texture2D(device, eyeTexture.DepthBufferDescription); eyeTexture.DepthStencilView = new DepthStencilView(device, eyeTexture.DepthBuffer); // Specify the texture to show on the HMD. if (eyeIndex == 0) { layerEyeFov.ColorTextureLeft = eyeTexture.SwapTextureSet.TextureSwapChainPtr; layerEyeFov.ViewportLeft.Position = new Vector2i(0, 0); layerEyeFov.ViewportLeft.Size = eyeTexture.TextureSize; layerEyeFov.FovLeft = eyeTexture.FieldOfView; } else { layerEyeFov.ColorTextureRight = eyeTexture.SwapTextureSet.TextureSwapChainPtr; layerEyeFov.ViewportRight.Position = new Vector2i(0, 0); layerEyeFov.ViewportRight.Size = eyeTexture.TextureSize; layerEyeFov.FovRight = eyeTexture.FieldOfView; } } MirrorTextureDesc mirrorTextureDescription = new MirrorTextureDesc(); mirrorTextureDescription.Format = TextureFormat.R8G8B8A8_UNorm_SRgb; mirrorTextureDescription.Width = form.Width; mirrorTextureDescription.Height = form.Height; mirrorTextureDescription.MiscFlags = TextureMiscFlags.None; // Create the texture used to display the rendered result on the computer monitor. IntPtr mirrorTexturePtr; result = OVR.CreateMirrorTextureDX(sessionPtr, device.NativePointer, ref mirrorTextureDescription, out mirrorTexturePtr); WriteErrorDetails(OVR, result, "Failed to create mirror texture."); mirrorTexture = new MirrorTexture(OVR, sessionPtr, mirrorTexturePtr); // Retrieve the Direct3D texture contained in the Oculus MirrorTexture. IntPtr mirrorTextureComPtr = IntPtr.Zero; result = mirrorTexture.GetBufferDX(textureInterfaceId, out mirrorTextureComPtr); WriteErrorDetails(OVR, result, "Failed to retrieve the texture from the created mirror texture buffer."); // Create a managed Texture2D, based on the unmanaged texture pointer. mirrorTextureD3D = new Texture2D(mirrorTextureComPtr); #region Vertex and pixel shader // Create vertex shader. vertexShaderByteCode = ShaderBytecode.CompileFromFile("Shaders.fx", "VertexShaderPositionColor", "vs_4_0"); vertexShader = new VertexShader(device, vertexShaderByteCode); // Create pixel shader. pixelShaderByteCode = ShaderBytecode.CompileFromFile("Shaders.fx", "PixelShaderPositionColor", "ps_4_0"); pixelShader = new PixelShader(device, pixelShaderByteCode); shaderSignature = ShaderSignature.GetInputSignature(vertexShaderByteCode); // Specify that each vertex consists of a single vertex position and color. InputElement[] inputElements = new InputElement[] { new InputElement("POSITION", 0, Format.R32G32B32A32_Float, 0, 0), new InputElement("COLOR", 0, Format.R32G32B32A32_Float, 16, 0) }; // Define an input layout to be passed to the vertex shader. inputLayout = new InputLayout(device, shaderSignature, inputElements); // Create a vertex buffer, containing our 3D model. vertexBuffer = Buffer.Create(device, BindFlags.VertexBuffer, m_vertices); // Create a constant buffer, to contain our WorldViewProjection matrix, that will be passed to the vertex shader. contantBuffer = new Buffer(device, Utilities.SizeOf <Matrix>(), ResourceUsage.Default, BindFlags.ConstantBuffer, CpuAccessFlags.None, ResourceOptionFlags.None, 0); // Setup the immediate context to use the shaders and model we defined. immediateContext.InputAssembler.InputLayout = inputLayout; immediateContext.InputAssembler.PrimitiveTopology = PrimitiveTopology.TriangleList; immediateContext.InputAssembler.SetVertexBuffers(0, new VertexBufferBinding(vertexBuffer, sizeof(float) * 4 * 2, 0)); immediateContext.VertexShader.SetConstantBuffer(0, contantBuffer); immediateContext.VertexShader.Set(vertexShader); immediateContext.PixelShader.Set(pixelShader); #endregion DateTime startTime = DateTime.Now; Vector3 position = new Vector3(0, 0, -1); #region Render loop RenderLoop.Run(form, () => { Vector3f[] hmdToEyeViewOffsets = { eyeTextures[0].HmdToEyeViewOffset, eyeTextures[1].HmdToEyeViewOffset }; double displayMidpoint = OVR.GetPredictedDisplayTime(sessionPtr, 0); TrackingState trackingState = OVR.GetTrackingState(sessionPtr, displayMidpoint, true); Posef[] eyePoses = new Posef[2]; // Calculate the position and orientation of each eye. OVR.CalcEyePoses(trackingState.HeadPose.ThePose, hmdToEyeViewOffsets, ref eyePoses); float timeSinceStart = (float)(DateTime.Now - startTime).TotalSeconds; for (int eyeIndex = 0; eyeIndex < 2; eyeIndex++) { EyeType eye = (EyeType)eyeIndex; EyeTexture eyeTexture = eyeTextures[eyeIndex]; if (eyeIndex == 0) { layerEyeFov.RenderPoseLeft = eyePoses[0]; } else { layerEyeFov.RenderPoseRight = eyePoses[1]; } // Update the render description at each frame, as the HmdToEyeOffset can change at runtime. eyeTexture.RenderDescription = OVR.GetRenderDesc(sessionPtr, eye, hmdDesc.DefaultEyeFov[eyeIndex]); // Retrieve the index of the active texture int textureIndex; result = eyeTexture.SwapTextureSet.GetCurrentIndex(out textureIndex); WriteErrorDetails(OVR, result, "Failed to retrieve texture swap chain current index."); immediateContext.OutputMerger.SetRenderTargets(eyeTexture.DepthStencilView, eyeTexture.RenderTargetViews[textureIndex]); immediateContext.ClearRenderTargetView(eyeTexture.RenderTargetViews[textureIndex], Color.Black); immediateContext.ClearDepthStencilView(eyeTexture.DepthStencilView, DepthStencilClearFlags.Depth | DepthStencilClearFlags.Stencil, 1.0f, 0); immediateContext.Rasterizer.SetViewport(eyeTexture.Viewport); // Retrieve the eye rotation quaternion and use it to calculate the LookAt direction and the LookUp direction. Quaternion rotationQuaternion = SharpDXHelpers.ToQuaternion(eyePoses[eyeIndex].Orientation); Matrix rotationMatrix = Matrix.RotationQuaternion(rotationQuaternion); Vector3 lookUp = Vector3.Transform(new Vector3(0, -1, 0), rotationMatrix).ToVector3(); Vector3 lookAt = Vector3.Transform(new Vector3(0, 0, 1), rotationMatrix).ToVector3(); Vector3 viewPosition = position - eyePoses[eyeIndex].Position.ToVector3(); Matrix world = Matrix.Scaling(0.1f) * Matrix.RotationX(timeSinceStart / 10f) * Matrix.RotationY(timeSinceStart * 2 / 10f) * Matrix.RotationZ(timeSinceStart * 3 / 10f); Matrix viewMatrix = Matrix.LookAtLH(viewPosition, viewPosition + lookAt, lookUp); Matrix projectionMatrix = OVR.Matrix4f_Projection(eyeTexture.FieldOfView, 0.1f, 100.0f, ProjectionModifier.LeftHanded).ToMatrix(); projectionMatrix.Transpose(); Matrix worldViewProjection = world * viewMatrix * projectionMatrix; worldViewProjection.Transpose(); // Update the transformation matrix. immediateContext.UpdateSubresource(ref worldViewProjection, contantBuffer); // Draw the cube immediateContext.Draw(m_vertices.Length / 2, 0); // Commits any pending changes to the TextureSwapChain, and advances its current index result = eyeTexture.SwapTextureSet.Commit(); WriteErrorDetails(OVR, result, "Failed to commit the swap chain texture."); } result = OVR.SubmitFrame(sessionPtr, 0L, IntPtr.Zero, ref layerEyeFov); WriteErrorDetails(OVR, result, "Failed to submit the frame of the current layers."); immediateContext.CopyResource(mirrorTextureD3D, backBuffer); swapChain.Present(0, PresentFlags.None); }); #endregion } finally { if (immediateContext != null) { immediateContext.ClearState(); immediateContext.Flush(); } // Release all resources Dispose(inputLayout); Dispose(contantBuffer); Dispose(vertexBuffer); Dispose(shaderSignature); Dispose(pixelShader); Dispose(pixelShaderByteCode); Dispose(vertexShader); Dispose(vertexShaderByteCode); Dispose(mirrorTextureD3D); Dispose(mirrorTexture); Dispose(eyeTextures[0]); Dispose(eyeTextures[1]); Dispose(immediateContext); Dispose(depthStencilState); Dispose(depthStencilView); Dispose(depthBuffer); Dispose(backBufferRenderTargetView); Dispose(backBuffer); Dispose(swapChain); Dispose(factory); // Disposing the device, before the hmd, will cause the hmd to fail when disposing. // Disposing the device, after the hmd, will cause the dispose of the device to fail. // It looks as if the hmd steals ownership of the device and destroys it, when it's shutting down. // device.Dispose(); OVR.Destroy(sessionPtr); } }