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I'm writing some code that is drawing 2D sprites using D3D11 (SharpDX for WinRT apps). All of this is working, however it is not fast. Here's a bit of the code I'm using:

        // Setup local variables
        var d3dDevice = App.deviceManager.DeviceDirect3D;
        var d3dContext = App.deviceManager.ContextDirect3D;

        var vertices = SharpDX.Direct3D11.Buffer.Create(App.deviceManager.DeviceDirect3D, BindFlags.VertexBuffer, new[]
        {
            // Position                                  Colour                      UV
            x0 - OFFSET, y0 - OFFSET, 0.0f, 1.0f ,       1.0f, 1.0f, 1.0f, 1.0f,     u, v,
            x1 - OFFSET, y1 - OFFSET, 0.0f, 1.0f ,       1.0f, 1.0f, 1.0f, 1.0f,     u2, v,
            x3 - OFFSET, y3 - OFFSET, 0.0f, 1.0f ,       1.0f, 1.0f, 1.0f, 1.0f,     u, v2,
            x2 - OFFSET, y2 - OFFSET, 0.0f, 1.0f ,       1.0f, 1.0f, 1.0f, 1.0f,     u2, v2,
        });

        textureView = new ShaderResourceView( App.deviceManager.DeviceDirect3D, texture );

        // Setup the pipeline
        d3dContext.InputAssembler.SetVertexBuffers( 0, vertexBufferBinding );
        d3dContext.InputAssembler.InputLayout = layout;
        d3dContext.InputAssembler.PrimitiveTopology = PrimitiveTopology.TriangleStrip;
        d3dContext.VertexShader.SetConstantBuffer( 0, constantBuffer );
        d3dContext.VertexShader.Set( vertexShader );
        d3dContext.PixelShader.Set( pixelShader );

        if( textureView != null )
            d3dContext.PixelShader.SetShaderResource( 0, textureView );

        // Draw the quad
        d3dContext.Draw( 4, 0 );

This code is called for every sprite rendered on screen. I can not guarantee the life of each sprite. They could be in the same position next frame or a different position. There could be more, there could be less. According to my profiler, SharpDX.Direct3D11.Buffer.Create is taking 50% of the entire frame when rendering a lot of sprites. I assume there is a better way to do this but I'm struggling to get my head around what to do. Can anyone offer any suggestions for this?

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Do you need additional information on this topic? I would be glad to extend my post, if you feel this question is still unanswered. –  Lucius Jan 21 '13 at 14:37
    
Please feel free. I'm currently on another project so I'm unable to reproduce my problem to provide any additional information but your answer below, while very informative, seemed mostly unrelated to my original question. –  Real World Jan 21 '13 at 19:34

1 Answer 1

Draw calls, creating resources and changing the state of the graphics device has always been (and from my experience still is) very slow. What do I mean by changing state?

  • Setting shaders
  • Binding buffers
  • Changing Textures
  • etc.

If you want a fast performing Direct3D application keep the times you bind anything to the device to a minimum.

Efficient Sprite Rendering

Calling this code for every sprite is not at all necessary. In fact there are methods of drawing thousands of sprites while maintaining a good framerate and still get things done besides of it (physics, game play, rendering a 3D world). There is one general rule, that can usually be applied to all other rendering tasks as well:

Draw as many object as possible with the same draw call.

Because that implies that you set your shaders, buffers, input layouts, etc. only once for similar objects. And sprites are really perfect for this, as different sprites have a LOT in common.

What is a sprite?

A sprite is could be described as a rectangular section of a texture that is drawn to a rectangular section on screen. Here is a stripped down example of the Sprite class I use in my application:

public struct Sprite
{
    public Color4 Color { get; set; }
    public Texture2D Texture { get; set; }
    public Rectangle Source { get; set; }
    public Rectangle Destination { get; set; }
    public float Depth { get; set; }
    public FlipMode Flip { get; set; }
}

The Color property is used as blend color or, when no texture is given, as a solid background color. Source is the rectangular area on the texture. Destination is the area on screen to which the sprite is drawn. Depending on your requirements, the rectangles could be rotated as well. I have two kinds of sprites, one that can be rotated and one that cannot.

Drawing the Sprites

Here are some (unsorted) tips and ideas how to speed up rendering:

Sort the Sprites by Texture

Simply draw sprites with the same texture at the same time. This leads to another important aspect: Store sprite images in sprite maps. Combine all your tiny textures into a larger one and draw them all at once in the same draw call.

Cull your Sprites

Before drawing a sprite test the visibility.

  • Is the sprite even on screen?
  • Is it transparent?
  • Is it occluded by other sprites?

To enable depth culling, also sort them by depth, front first.

Single Vertex Buffer

You basically create a quad mesh for each of your sprites. Then you write the vertices all into the same vertex buffer and draw them.

This is what your vertices could look like for the above Sprite class:

public struct SpriteVertex
{
    public Vector3 Position { get; set; }
    public Vector2 Texcoord { get; set; }
    public Vector4 Color { get; set; }
}

The obvious drawback is, that all the vector math is done in the CPU. Which is a shame, as you could do the same things much faster on the GPU.

Hardware Instancing

You create two vertex buffers:

  • The first contains 4 vertices forming a quad, each vertex with a 2D position and texture coordinates.
  • The second buffer contains all your sprite data, each structure representing a single sprite.

The first buffer is simply bound as the main vertex buffer, while the second one is used as an instance buffer.

Here is the vertex shader I have written for this method:

struct Vertex
{
    float2 Position     : POSITION0;
    float2 Texcoord     : TEXCOORD0;
};

struct Sprite
{
    float4 Color        : COLOR0;
    float4 DestinationA : TEXCOORD1;
    float4 DestinationB : TEXCOORD2;
    float4 SourceA      : TEXCOORD3;
    float4 SourceB      : TEXCOORD4;
    float4 Other        : TEXCOORD5;
};

struct Pixel
{
    float4 Position     : SV_POSITION;
    float2 Texcoord     : TEXCOORD0;
    float4 Color        : COLOR0;
};

cbuffer Screen      : register(b0)
{
    float2 ScreenSize;
};

cbuffer Texture     : register(b1)
{
    float2 TextureSize;
};

float2 Transform(float2 position, float2 scale, float2 origin, float angle, float2 translation)
{
    // Create a 2D rotation matrix
    float2x2 rotation = float2x2(cos(angle), sin(angle), -sin(angle), cos(angle));

    // Apply the scale, origin, rotation and translation
    return mul(position * scale - origin, rotation) + translation;
}

Pixel Main(Vertex vertex, Sprite sprite)
{
    // Transform the vertex position
    float2 position = Transform(
        vertex.Position, 
        sprite.DestinationA.zw,
        sprite.DestinationB.xy,
        sprite.DestinationB.z,
        sprite.DestinationA.xy
    );

    // Bring to screen space
    position.x = position.x / ScreenSize.x * 2 - 1;
    position.y = 1 - position.y / ScreenSize.y * 2;

    float2 texcoord = vertex.Texcoord;

    // Flip the Y axis for the texture coordinates before the transformation
    texcoord.y = 1 - texcoord.y;

    // Transform the texcoords
    texcoord = Transform(
        texcoord, 
        sprite.SourceA.zw,
        sprite.SourceB.xy,
        sprite.SourceB.z,
        sprite.SourceA.xy
    );

    // Bring to texture space
    texcoord.x = texcoord.x / TextureSize.x;
    texcoord.y = texcoord.y / TextureSize.y;

    // Flip the texture coordinates
    float texcoordFlip = sprite.Other.z;
    if (texcoordFlip == 1 || texcoordFlip == 3) texcoord.x = 1 - texcoord.x;
    if (texcoordFlip == 2 || texcoordFlip == 3) texcoord.y = 1 - texcoord.y;

    // Create the output struct
    Pixel pixel = (Pixel)0;
    pixel.Position = float4(position, sprite.Other.x, 1);
    pixel.Texcoord = texcoord;
    pixel.Color = float4(sprite.Color);

    return pixel;
}

Geometry Shader

Yet another method involves the Geometry Shader stage. Just like in the Instancing method, you create a vertex buffer containing the sprite structures. But this time you bind it as the main vertex buffer (no quad needed) and set the Topology to Point.

In you Geometry Shader you then generate the four vertices from the sprite information.

I once tested this method, but soon returned to the Hardware Instancing. As far as I remember, it did not give a great performance boost, but I could have missed something.


Good luck!

share|improve this answer
    
Thanks for your reply but I did not mention changing states at all. I am aware of the drawbacks with this. My problem is with allocation of a buffer to pass in to my vertex shader being slow. Your hardware instancing method sounds useful but I'm not aware of how to do this in DirectX 11. To try and be more clear, my problem is less with understanding efficient rendering (though I have much to learn still) and more with understanding how to write that in DirectX11. Thanks for your help –  Real World Nov 27 '12 at 10:36
    
Performance in graphics applications is a very fuzzy subject. The best guess is keeping everything to a minimum. In your current code the most expensive part may currently be the buffer, so don't allocate/bind it so often. But there is also no reason for reapplying the shaders, constants, input layouts for every sprite. No matter how much it actually slows down rendering, it is definitely a waste of resources. Maybe I will find time to expand on the instancing method tomorrow. –  Lucius Nov 27 '12 at 14:59

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