1. Evolution of the Programmable Graphics Pipeline Lecture 2 Original Slides by: Suresh Venkatasubramanian Updates by Joseph Kider

2. Course Roadmap ► Graphics Pipeline (GLSL) ► GPGPU (GLSL)  Briefly ► GPU Computing (CUDA, OpenCL) ► Choose your own adventure  Student Presentation  Final Project ► Goal: Prepare you for your presentation and project

3. Lecture Outline ► A historical perspective on the graphics pipeline  Dimensions of innovation.  Where we are today  Fixed-function vs programmable pipelines ► A closer look at the fixed function pipeline  Walk thru the sequence of operations  Reinterpret these as stream operations ► We can program the fixed-function pipeline !  Some examples ► What constitutes data and memory, and how access affects program design.

4. The evolution of the pipeline Elements of the graphics pipeline: 1.A scene description: vertices, triangles, colors, lighting 2.Transformations that map the scene to a camera viewpoint 3.“Effects”: texturing, shadow mapping, lighting calculations 4.Rasterizing: converting geometry into pixels 5.Pixel processing: depth tests, stencil tests, and other per-pixel operations. Parameters controlling design of the pipeline: 1.Where is the boundary between CPU and GPU ? 2.What transfer method is used ? 3.What resources are provided at each step ? 4.What units can access which GPU memory elements ?

5. Generation I: 3dfx Voodoo (1996) http://accelenation.com/?ac.id.123.2 One of the first true 3D game cards Worked by supplementing standard 2D video card. Did not do vertex transformations: these were done in the CPU Did do texture mapping, z-buffering. Primitive Assembly Primitive Assembly Vertex Transforms Vertex Transforms Frame Buffer Frame Buffer Raster Operations Rasterization and Interpolation CPUGPU PCI

6. Aside: Mario Kart 64 Image from: http://www.gamespot.com/users/my_shoe/ ► High fragment load / low vertex load

7. Aside: Mario Kart Wii High fragment load / low vertex load? Image from: http://wii.ign.com/dor/objects/949580/mario-kart-wii/images/

8. Vertex Transforms Vertex Transforms Generation II: GeForce/Radeon 7500 (1998) http://accelenation.com/?ac.id.123.5 Main innovation: shifting the transformation and lighting calculations to the GPU Allowed multi-texturing: giving bump maps, light maps, and others.. Faster AGP bus instead of PCI Primitive Assembly Primitive Assembly Frame Buffer Frame Buffer Raster Operations Rasterization and Interpolation GPU AGP

9. Vertex Transforms Vertex Transforms Generation III: GeForce3/Radeon 8500(2001) http://accelenation.com/?ac.id.123.7 For the first time, allowed limited amount of programmability in the vertex pipeline Also allowed volume texturing and multi-sampling (for antialiasing) Primitive Assembly Primitive Assembly Frame Buffer Frame Buffer Raster Operations Rasterization and Interpolation GPU AGP Small vertex shaders Small vertex shaders

10. Vertex Transforms Vertex Transforms Generation IV: Radeon 9700/GeForce FX (2002) http://accelenation.com/?ac.id.123.8 This generation is the first generation of fully-programmable graphics cards Different versions have different resource limits on fragment/vertex programs Primitive Assembly Primitive Assembly Frame Buffer Frame Buffer Raster Operations Rasterization and Interpolation AGP Programmable Vertex shader Programmable Vertex shader Programmable Fragment Processor Programmable Fragment Processor Texture Memory

11. Generation IV.V: GeForce6/X800 (2004) Slide adapted from Suresh Venkatasubramanian and Joe Kider ► Simultaneous rendering to multiple buffers ► True conditionals and loops ► PCIe bus ► Vertex texture fetch Vertex Transforms Vertex Transforms Primitive Assembly Primitive Assembly Frame Buffer Frame Buffer Raster Operations Rasterization and Interpolation PCIe Programmable Vertex shader Programmable Vertex shader Programmable Fragment Processor Programmable Fragment Processor Texture Memory

12. NVIDIA NV40 Architecture Image from GPU Gems 2: http://http.developer.nvidia.com/GPUGems2/gpugems2_chapter30.html 6 vertex shader units 16 fragment shader units Vertex Texture Fetch

13. D3D 10 Pipeline Image from David Blythe : http://download.microsoft.com/download/f/2/d/f2d5ee2c-b7ba-4cd0-9686-b6508b5479a1/direct3d10_web.pdf

14. Generation IV.V: GeForce6/X800 (2004) Not exactly a quantum leap, but… ► Simultaneous rendering to multiple buffers ► True conditionals and loops ► Higher precision throughput in the pipeline (64 bits end-to-end, compared to 32 bits earlier.) ► PCIe bus ► More memory/program length/texture accesses ► Texture access by vertex shader Vertex Transforms Vertex Transforms Primitive Assembly Primitive Assembly Frame Buffer Frame Buffer Raster Operations Rasterization and Interpolation AGP Programmable Vertex shader Programmable Vertex shader Programmable Fragment Processor Programmable Fragment Processor Texture Memory

15. Generation V: GeForce8800/HD2900 (2006) Complete quantum leap ► Ground-up rewrite of GPU ► Support for DirectX 10, and all it implies (more on this later) ► Geometry Shader ► Support for General GPU programming ► Shared Memory (NVIDIA only) Input Assembler Input Assembler Programmable Pixel Shader Programmable Pixel Shader Raster Operations Programmable Geometry Shader AGP Programmable Vertex shader Programmable Vertex shader Output Merger

16. Vertex Index Stream 3D API Commands Assembled Primitives Pixel Updates Pixel Location Stream Programmable Fragment Processor Programmable Fragment Processor Transformed Vertices Programmable Vertex Processor Programmable Vertex Processor GPU Front End GPU Front End Primitive Assembly Primitive Assembly Frame Buffer Frame Buffer Raster Operations Rasterization and Interpolation 3D API: OpenGL or Direct3D 3D API: OpenGL or Direct3D 3D Application Or Game 3D Application Or Game Pre-transformed Vertices Pre-transformed Fragments Transformed Fragments GPU Command & Data Stream CPU-GPU Boundary (AGP/PCIe) Fixed-function pipeline

17. Geometry Shaders: Point Sprites

19. Geometry Shaders Image from David Blythe : http://download.microsoft.com/download/f/2/d/f2d5ee2c-b7ba-4cd0-9686-b6508b5479a1/direct3d10_web.pdf

20. NVIDIA G80 Architecture Slide from David Luebke: http://s08.idav.ucdavis.edu/luebke-nvidia-gpu-architecture.pdf

21. NVIDIA G80 Architecture Slide from David Luebke: http://s08.idav.ucdavis.edu/luebke-nvidia-gpu-architecture.pdf

22. Why Unify Shader Processors? Slide from David Luebke: http://s08.idav.ucdavis.edu/luebke-nvidia-gpu-architecture.pdf

23. Why Unify Shader Processors? Slide from David Luebke: http://s08.idav.ucdavis.edu/luebke-nvidia-gpu-architecture.pdf

24. Unified Shader Processors Slide from David Luebke: http://s08.idav.ucdavis.edu/luebke-nvidia-gpu-architecture.pdf

25. Terminology Shader Model Direct3DOpenGLVideo card Example 292.x NVIDIA GeForce 6800 ATI Radeon X800 310.x3.x NVIDIA GeForce 8800 ATI Radeon HD 2900 411.x4.x NVIDIA GeForce GTX 480 ATI Radeon HD 5870

26. Shader Capabilities Table courtesy of A K Peters, Ltd. http://www.realtimerendering.com/

27. Shader Capabilities Table courtesy of A K Peters, Ltd. http://www.realtimerendering.com/

28. Evolution of the Programmable Graphics Pipeline Slide from Mike Houston: http://s09.idav.ucdavis.edu/talks/01-BPS-SIGGRAPH09-mhouston.pdf

29. Evolution of the Programmable Graphics Pipeline Slide from Mike Houston: http://s09.idav.ucdavis.edu/talks/01-BPS-SIGGRAPH09-mhouston.pdf

30. ► Not covered today:  SM 5 / D3D 11 / GL 4  Tessellation shaders ► *cough* student presentation *cough*  Later this semester: NVIDIA Fermi ► Dual warp scheduler ► Configurable L1 / shared memory ► Double precision ► … Evolution of the Programmable Graphics Pipeline

31. New Tool: AMD System Monitor ► Released 01/04/2011 ► http://support.amd.com/us/kbarticles/Pages/AMDSystemMonitor.aspx

32. A closer look at the fixed-function pipeline

33. Pipeline Input (x, y, z) (r, g, b,a) (Nx,Ny,Nz) (tx, ty,[tz]) (tx, ty) VertexImage F(x,y) = (r,g,b,a) Material properties*

34. ModelView Transformation ► Vertices mapped from object space to world space ► M = model transformation (scene) ► V = view transformation (camera) X’ Y’ Z’ W’ XYZ1XYZ1 M * V * Each matrix transform is applied to each vertex in the input stream. Think of this as a kernel operator.

35. Lighting Lighting information is combined with normals and other parameters at each vertex in order to create new colors. Color(v) = emissive + ambient + diffuse + specular Each term in the right hand side is a function of the vertex color, position, normal and material properties.

36. Clipping/Projection/Viewport(3D) ► More matrix transformations that operate on a vertex to transform it into the viewport space. ► Note that a vertex may be eliminated from the input stream (if it is clipped). ► The viewport is two-dimensional: however, vertex z-value is retained for depth testing. Clip test is first example of a conditional in the pipeline. However, it is not a fully general conditional. Why ?

37. Fragment attributes: (r,g,b,a) (x,y,z,w) (tx,ty), … Rasterizing+Interpolation ► All primitives are now converted to fragments. ► Data type change ! Vertices to fragments Texture coordinates are interpolated from texture coordinates of vertices. This gives us a linear interpolation operator for free. VERY USEFUL !

38. Per-fragment operations ► The rasterizer produces a stream of fragments. ► Each fragment undergoes a series of tests with increasing complexity. Test 1: Scissor If (fragment lies in fixed rectangle) let it pass else discard it Test 2: Alpha If( fragment.a >= ) let it pass else discard it. Scissor test is analogous to clipping operation in fragment space instead of vertex space. Alpha test is a slightly more general conditional. Why ?

39. Per-fragment operations ► Stencil test: S(x, y) is stencil buffer value for fragment with coordinates (x,y) ► If f(S(x,y)), let pixel pass else kill it. Update S(x, y) conditionally depending on f(S(x,y)) and g(D(x,y)). ► Depth test: D(x, y) is depth buffer value. ► If g(D(x,y)) let pixel pass else kill it. Update D(x,y) conditionally.

40. Per-fragment operations ► Stencil and depth tests are more general conditionals. Why ? ► These are the only tests that can change the state of internal storage (stencil buffer, depth buffer). ► One of the update operations for the stencil buffer is a “count” operation. Remember this! ► Unfortunately, stencil and depth buffers have lower precision (8, 24 bits resp.)

41. Post-processing ► Blending: pixels are accumulated into final framebuffer storage new-val = old-val op pixel-value If op is +, we can sum all the (say) red components of pixels that pass all tests. Problem: In generation<= IV, blending can only be done in 8-bit channels (the channels sent to the video card); precision is limited. We could use accumulation buffers, but they are very slow.

42. Quick Review: Buffers ► Color Buffers  Front-left  Front-right  Back-left  Back-right ► Depth Buffer (z-buffer) ► Stencil Buffer ► Accumulation Buffer

43. Quick Review: Tests ► Scissor Test If(fragment exists inside rectangle) keepElsedelete ► Alpha Test – Compare fragment’s alpha value against reference value ► Stencil Test – Compare fragment against stencil map ► Depth Test – Compare a fragment’s depth to the depth value already present in the depth buffer  Never  Always  Less  Less-Equal  Greater-Equal  Greater  Not-Equal

44. Readback = Feedback What is the output of a “computation” ? 1. Display on screen. 2. Render to buffer and retrieve values (readback) Readbacks are VERY slow ! PCI and AGP buses are asymmetric: DMA enables fast transfer TO graphics card. Reverse transfer has traditionally not been required, and is much slower. PCIe is symmetric but still very slow compared to GPU speeds. This motivates idea of “pass” being an atomic “unit cost” operation. What options do we have ? 1.Render to off-screen buffers like accumulation buffer 2.Copy from framebuffer to texture memory ? 3.Render directly to a texture ?

45. Time for a puzzle…

46. An Example: Voronoi Diagrams.

47. Definition ► You are given n sites (p 1, p 2, p 3, … p n ) in the plane (think of each site as having a color) ► For any point p in the plane, it is closest to some site p j. Color p with color i. ► Compute this colored map on the plane. In other words, Compute the nearest-neighbour diagram of the sites.

48. Example So how do we do this on the graphics card? Note, this does not use any programmable features of the card

49. Hint: Think in one dimension higher The lower envelope of “cones” centered at the points is the Voronoi diagram of this set of points.

50. The Procedure ► In order to compute the lower envelope, we need to determine, at each pixel, the fragment having the smallest depth value. ► This can be done with a simple depth test.  Allow a fragment to pass only if it is smaller than the current depth buffer value, and update the buffer accordingly. ► The fragment that survives has the correct color.

51. Let’s make this more complicated ► The 1-median of a set of sites is a point q* that minimizes the sum of distances from all sites to itself. q* = arg min Σ d(p, q) WRONG !RIGHT !

52. A First Step Can we compute, for each pixel q, the value F(q) = Σ d(p, q) We can use the cone trick from before, and instead of computing the minimum depth value, compute the sum of all depth values using blending. What’s the catch ?

53. We can’t blend depth values ! ► Using texture interpolation helps here. ► Instead of drawing a single cone, we draw a shaded cone, with an appropriately constructed texture map. ► Then, fragment having depth z has color component 1.0 * z. ► Now we can blend the colors. ► OpenGL has an aggregation operator that will return the overall min Warning: we are ignoring issues of precision.

54. Now we apply a streaming perspective…

55. Two kinds of data ► Stream data (data associated with vertices and fragments)  Color/position/texture coordinates.  Functionally similar to member variables in a C++ object.  Can be used for limited message passing: I modify an object state and send it to you. ► “Persistent” data (associated with buffers).  Depth, stencil, textures. ► Can be modifed by multiple fragments in a single pass. ► Functionally similar to a global array BUT each fragment only gets one location to change. ► Can be used to communicate across passes.

56. Who has access ? ► Memory “connectivity” in the graphics use of a GPU is tricky. ► In a traditional C program, all global variables can be written by all routines. ► In the fixed-function pipeline, certain data is private.  A fragment cannot change a depth or stencil value of a location different from its own.  The framebuffer can be copied to a texture; a depth buffer cannot be copied in this way, and neither can a stencil buffer.  Only a stencil buffer can count (efficiently) ► In the fixed-function pipeline, depth and stencil buffers can be used in a multi-pass computation only via readbacks. ► A texture cannot be written directly. ► In programmable GPUs, the memory connectivity becomes more open, but there are still constraints. Understanding access constraints and memory “connectivity” is a key step in programming the GPU.

57. How does this relate to stream programs ? ► The most important question to ask when programming the GPU is: What can I do in one pass ? ► Limitations on memory connectivity mean that a step in a computation may often have to be deferred to a new pass. ► For example, when computing the second smallest element, we could not store the current minimum in read/write memory. ► Thus, the “communication” of this value has to happen across a pass.

58. Graphics pipeline Graphics pipeline Vertex Index Stream 3D API Commands Assembled Primitives Pixel Updates Pixel Location Stream GPU Front End GPU Front End Primitive Assembly Primitive Assembly Frame Buffer Frame Buffer Raster Operations Rasterization and Interpolation 3D API: OpenGL or Direct3D 3D API: OpenGL or Direct3D 3D Application Or Game 3D Application Or Game GPU Command & Data Stream CPU-GPU Boundary Vertex pipelineFragment pipeline