Converting data for the color space

To compose to the screen or perform floating-point operations, you need to work in the correct color space. We recommend that you perform floating point operations in a linear color space. Then, to present your images to the screen, convert the data to standard RGB data (sRGB, gamma 2.2-corrected) color space. Presenting to the screen in sRGB color space is important for color accuracy. If images are not gamma 2.2-corrected, they allocate too many bits or too much bandwidth to highlights that people can't differentiate, and too few bits or bandwidth to shadow values that people are sensitive to, and so would require more bits or bandwidth to maintain the same visual quality. Therefore, to ensure the best color accuracy, present images to the screen that are gamma 2.2-corrected.

For presentation, integer-valued display formats (such as DXGI_FORMAT_B8G8R8A8_UNORM_SRGB, DXGI_FORMAT_R10G10B10_XR_BIAS_A2_UNORM, and so on) always contain sRGB gamma-corrected data. Float-valued display formats (currently only DXGI_FORMAT_R16G16B16A16_FLOAT) contain linear-valued data.

The _SRGB format modifier indicates to the operating system to help the app place sRGB data on the screen. The app must always place sRGB data into back buffers with integer-valued formats to present the sRGB data to the screen, even if the data doesn't have this format modifier in its format name. For a complete list of display scan-out formats, see display scan-out formats.

When you write floating-point output values from the pixel shader into render-target views (RenderTargetViews) with the _SRGB format modifier that are bound to the pipeline, you convert them to gamma 2.2-corrected color space. Similarly, when shader-resource views (ShaderResourceViews) with the _SRGB format modifier are bound to the pipeline, you convert the values from gamma 2.2-corrected color space to linear color space when you read them from the ShaderResourceViews. The shader can then perform operations on them.

For example, use code similar to this to write floating-point output values from a shader into a RenderTargetView format:



struct PSOut
{
    float4 color : SV_Target;
};

PSOut S( PSIn input )
{
    PSOut output;
    output.color = float4( 1.0, 0.0, 0.0, 1.0 );
    return output;
}


When the 'S' routine returns, the floating point (1, 0, 0, 1) values are converted to the RenderTargetView format. Then, if you assign the _SRGB format modifier to the RenderTargetView, the gamma conversion occurs.

These are steps to follow to ensure that the content that is displayed on the screen has the best color accuracy.

Hh972627.wedge(en-us,VS.85).gifTo ensure color accuracy in the pipeline

  1. If a texture has sRGB content, ensure the ShaderResourceView has the _SRGB format modifier so when you read from the ShaderResourceView into the shader, you convert the texture content from gamma 2.2-corrected color space to linear color space.
  2. Ensure the RenderTargetView also has the _SRGB format modifier so the shader output values are gamma converted.

If you follow the preceding steps, when you call the IDXGISwapChain1::Present1 method, the content that is displayed on the screen has the best color accuracy.

You can use the ID3D11Device::CreateRenderTargetView method to create DXGI_FORMAT_*_SRGB views on back buffers from a swap chain that you create only with a DXGI_FORMAT_*_UNORM format. This is a special exception to the rule for creating render-target views, which states that you can use a different format with ID3D11Device::CreateRenderTargetView only if you created the resource that you want to view with DXGI_FORMAT_*_TYPELESS.

For more info about rules for converting data, see Data Conversion Rules.

For info about how to simultaneously both read from and write to a texture, see Unpacking and Packing DXGI_FORMAT for In-Place Image Editing.

 

 

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