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Parallel Graphics APIs. Gregory S. Johnson johnsong@cs.utexas.edu. Topics. Problem: Host / Graphics Performance Mismatch Conventional Solutions Parallelism IRIS Performer (Rohlf and Helman, 1994) Stanford Parallel API (Igehy et al., 1998). Problem.
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Parallel Graphics APIs Gregory S. Johnson johnsong@cs.utexas.edu
Topics • Problem: Host / Graphics Performance Mismatch • Conventional Solutions • Parallelism • IRIS Performer (Rohlf and Helman, 1994) • Stanford Parallel API (Igehy et al., 1998)
Problem • graphics subsystems can process graphics primitives faster than a single-CPU host can deliver the related sequence of commands • when a single-CPU host is busy with non-graphics related tasks (I/O, OS, etc.), the graphics subsystem idles OpenGL command issued OpenGL* command processed
Bottlenecks (Igehy et al.) • overhead associated with encoding API commands • data bandwidth from the API host • data bandwidth into the graphics subsystem • overhead associated with decoding API commands
Solution Directions • utilize the given resources more effectively • add more hardware resources
Conventional SolutionsPacked Primitive Arrays • arrays of primitives stored in system memory which can be issued to the graphics system via a small number of API calls • the use of primitives arrays can result in reduced API overhead and increased bandwidth utilization via DMA glVertexPointer(2, GL_FLOAT, 0, verts); glEnableClientState(GL_VERTEX_ARRAY); glColorPointer(3, GL_FLOAT, 0, colors); glEnableClientState(GL_COLOR_ARRAY); /* “strip” points into an array with triangle strip connectivity */ /* based on the vertices in the “verts” array */ glDrawElements(GL_TRIANGLE_STRIP, length, GL_UNSIGNED_INT, strip);
Conventional SolutionsDisplay Lists • a display list is a set of graphics commands (low level equivalents) stored on the graphics subsystem and typically used as a macro • useful in cases where geometry in a scene is drawn repeatedly • even more useful if the geometry fits on the graphics card itself /* create a "vane" for the tail of the arrow */ glNewList(VANE, GL_COMPILE); glBegin(GL_QUADS); glColor3f(1.0, 1.0, 1.0); glVertex3fv(v1); glVertex3fv(v2); glVertex3fv(v3); glVertex3fv(v4); ... glEnd(); glEndList();
Conventional SolutionsCompression • encoding of scene geometry by the host CPU and decoding by the graphics subsystem • compression of graphics data can reduce inter-subsystem bandwidth requirements at the expense of decoding time GL_SUNX_geometry_compression
Parallelism • inherent parallelism: not all graphics-related commands need be issued in strict order (e.g. drawing opaque primitives on Z-buffer equipped hardware) • parallelism to cover latency: the graphics subsystem is faster at processing commands than the host CPU is at generating them OpenGL commands issued OpenGL* commands processed
Terminology • context is the scope within which graphics state is affected by graphics commands issued (in some sense a binding between graphics state and issued graphics commands)
IRIS Performer: A High Performance Multiprocessing Toolkit for Real-Time 3D GraphicsJohn Rohlf, James HelmanSilicon Graphics Computer Systems (1994)
Summary • discusses the design and implementation of a pair of libraries for developing high performance graphics applications easily • a low-level library to provide high performance rendering via specialized graphics primitives and efficient state management • a high-level library for multiprocessing which utilizes pipeline parallelism for traversing, culling, and issuing elements of a hierarchically organized scene graph
A Tale of Two Libraries • libpr provides efficient graphics primitives, state management, and basic mechanisms in support of efficient rendering • libpf provides support for multiprocessing and hierarchical organization of scene elements
libpr: pfGeoSet • a “primitives array” like data structure which holds homogeneous graphics primitives and associated coloring, normal, and texture mapping (coordinates) data
libpr: State Management • libpr provides 3 mechanisms for setting graphics state • immediate mode: a “state stack” helps reduce unnecessary state changes and is typically used to set global state • display list mode: typically used by libpf to capture a full frame’s worth of data for purposes of multiprocessing • encapsulated mode: motivated by the observation that most state applies to the bulk of a scene; is typically used to tie a small number of state changes to specific geometry
libpr: Multiprocessing Support • libpr doesn’t implement multiprocessing itself • libpr does provide support for shared data including synchronized access • includes “multibuffered” arrays which can be thought of as multiple copies of an array, each at a different stage of processing • multibuffering solves the problems of data exclusion and synchronization
libpf: Scene Graphs • libpf organizes scene elements into scene graphs, for increased modeling, access, and processing efficiency • a scene graph is a tree-like structure containing nodes which correspond to geometry, lights, cameras, coloration, texture, transformations, etc.
libpf: Scene Graph Hierarchy • scene graphs promote top-down state inheritance • the top-down inheritance restriction enables parallel traversal and processing of the scene graph tree • scene graphs also encode a hierarchy of bounding volumes, simplifying intersection testing and culling
libpf: Scene Graph Traversal • intersection traversal: application-driven collision detection • culling traversal: precedes drawing traversals, culling geometry with bounding spheres which fall outside of the view frustrum, and placing the remaining geometry in a (possibly sorted) display list • draw traversal: traverses the display list generated during the culling phase and issues the appropriate commands to the graphics subsystem
libpf: Optimizations • pfFlatten: reduce the number of transformations • pfLOD: level-of-detail based on geometry of varying complexity • pfSequence: animated sequences • pfBillboard: special representation of axially symmetric shapes
libpf: Multiprocessing • a pipelined approach to multiprocessing, whereby different processors execute different stages of the APP -> CULL -> DRAW and APP-> ISECT pipelines
The Design of a Parallel Graphics InterfaceHoman Igehy, Gordon Stoll, Pat HanrahanStanford University (1998)
Summary • discuss several issues (state, mode, order) influencing the design of a graphics API • propose a swank parallel API composed of a small number of extensions to OpenGL • present an implementation of the API within a custom software graphics pipeline • examine the performance of the implementation applied to a pair of graphics-related applications
Thread 1 DrawPrimitives(opaq[1..256]) appBarrier(appBarrierVar) DrawPrimitives(tran[1..256]) glFinish() appBarrier(appBarrierVar) Thread 2 DrawPrimitives(opaq[257..512]) glFinish() appBarrier(appBarrierVar) appBarrier(appBarrierVar) DrawPrimitives(tran[257..512]) Parallelism via Existing OpenGL Constructs • consider a pair of application threads each with its own graphics context, issuing OpenGL commands for a single framebuffer • recall that a stream of OpenGL commands is issued by the host CPU(s) and later executed by the graphics subsystem
Thread 1 DrawPrimitives(opaq[1..256]) appBarrier(appBarrierVar) glpWaitContext(Thread2Ctx) DrawPrimitives(tran[1..256]) appBarrier(appBarrierVar) Thread 2 DrawPrimitives(opaq[257..512]) appBarrier(appBarrierVar) appBarrier(appBarrierVar) glpWaitContext(Thread1Ctx) DrawPrimitives(tran[257..512]) Addition of a Wait Construct • glFinish() commands force the issuing threads to wait for the previously issued graphics commands to complete (on the graphics subsystem) • but synchronization between the application threads in this example is only needed to insure that the graphics commands are issued in order
Thread 1 DrawPrimitives(opaq[1..256]) glpBarrier(glpBarrierVar) DrawPrimitives(tran[1..256]) glpBarrier(glpBarrierVar) Thread 2 DrawPrimitives(opaq[257..512]) glpBarrier(glpBarrierVar) glpBarrier(glpBarrierVar) DrawPrimitives(tran[257..512]) Improved Synchronization • synchronization of the graphics command streams in the previous example is performed by the application threads, stalling them • graphics subsystem-level barriers (many-to-many) and semaphores (point-to-point) synchronization mechanisms are introduced
Serial for (i=0; i<M; i++) for (j=0; j<N; j++) ExtractAndRender(grid[i,j]) Parallel (Unordered) for (i=0; i<M; i++) for (j=(myProc+i)%P; j<N; j+=P) ExtractAndRender(grid[i,j]) Parallel (Ordered) for (i=0; i<M; i++) for (j=(myProc+i)%P; j<N; j+=P) if (i>0) glpPSema(sema[i-1,j]) if (j>0) glpPSema(sema[i,j-1]) ExtractAndRender(grid[i,j]) if (i<M-1) glpVSema(sema[i,j]) if (j<N-1) glpVSema(sema[i,j]) Example: Marching Cubes
Implementation: Argus InfiniteReality pipeline Argus pipeline
Performance • Argus software pipeline on a SGI Origin SMP applied to Nurbs (patch tessellator - embarrassingly parallel) and March (parallel marching cubes) 6, 7, 8 5 4 3 2 1
Convergence • the Performer approach utilizes pipeline parallelism while the Stanford approach utilizes multithreaded parallelism • the authors note that the role of their API is complimentary to that of IRIS Performer which utilizes pipeline parallelism, but is constrained by placing one processor in charge of issuing graphics commands