______________________________________________________________________ The Problem When you're writing an OpenGL application, how do you know whether a particular feature (like depth buffering or texture mapping) is fast enough to be useful? If you want your application to run fast on a variety of machines, while taking advantage of as many hardware features as possible, you need to write code that makes configuration decisions at runtime. For OpenGL's predecessor, IRIS GL, you could call getgdesc() to determine whether a feature had hardware support. For example, you could determine whether a Z buffer existed. If it did, you might assume that Z buffering was fast, and therefore your application would use it. Usually (but not always) this was a reasonable approach. In OpenGL, things are more complicated. All the core features are provided, even when there is no hardware support for them and they must be implemented completely in software. There is no OpenGL routine that reports whether a feature is implemented partially or completely in hardware. Furthermore, features interact in essentially unpredictable ways. For example, a machine might have hardware support for depth buffering, but only for some comparison functions. Or depth buffering might be fast only as long as stencilling is not enabled. Or depth buffering might be fast when drawing to a window, but slow when drawing to a pixmap. And so on. A routine that identifies hardware support for particular features is actually a lot more complicated and less useful than you'd like! ______________________________________________________________________ A Solution So how do you decide whether a given OpenGL feature is fast? The answer is "Measure it." Since the performance of a section of graphics code is dependent on dozens of pieces of information from the runtime environment, no other method is as well-defined and reliable. Performance measurement can be tricky. You need to handle the cases when you're displaying over a network, as well as locally. You also want to think about flushing the graphics pipeline properly, and accounting for the resulting overhead. Measuring all the features needed by your application might take a while -- probably too long to make your users wait for the results each time the application starts. Therefore you'll want to save performance measurements and reuse them whenever possible. And you might want to measure things other than graphics: Disk and network throughput, processing time for a particular set of data, performance on uniprocessor and multiprocessor systems. This document describes two libraries that can help with all of the tasks just mentioned. libpdb "Performance DataBase" routines for measuring execution rates and maintaining a simple database. libisfast A set of routines demonstrating libpdb that answer common questions about the performance of OpenGL features (using reasonable but subjective criteria). These libraries can't substitute for comprehensive benchmarking and performance analysis, and don't replace more sophisticated tools (like IRIS Performer and IRIS Inventor) that optimize application performance in a variety of ways. However, they can handle simple tasks easily. ______________________________________________________________________ libpdb Tutorial libpdb provides five routines: pdbOpen() opens the performance database. pdbReadRate() reads the execution rate for a given benchmark (identified by a machine name, application name, benchmark name, and version string) from the database. pdbMeasureRate() measures the execution rate for a given operation. pdbWriteRate() writes the execution rate for a given benchmark into the database. pdbClose() closes the performance database and writes it back to disk if necessary. All libpdb routines return a value of type pdbStatusT, which is a bitmask of error conditions. If the value is zero (PDB_NO_ERROR), then the call completed successfully. If the value is nonzero, then it is a combination of one or more of the following conditions: PDB_OUT_OF_MEMORY An attempt to allocate memory failed. PDB_SYNTAX_ERROR The database contains one or more records that could not be parsed. PDB_NOT_FOUND The database does not contain the record requested by the application. PDB_CANT_WRITE The database file could not be updated. PDB_NOT_OPEN pdbOpen() was not invoked before calling one of the other libpdb routines. PDB_ALREADY_OPEN pdbOpen() was called while the database is still open (e.g., before pdbClose() is invoked). Every program must call pdbOpen() before using the database, and pdbClose() when the database is no longer needed. pdbOpen() opens the database file (stored in $HOME/.pdb2 on UNIX systems) and reads all the performance measurements into main memory. pdbClose() releases all memory used by the library, and writes the database back to its file if any changes have been made by invoking pdbWriteRate(). Synopsis pdbStatusT pdbOpen(void); pdbStatusT pdbClose(void); pdbOpen() returns PDB_NO_ERROR on success, PDB_OUT_OF_MEMORY if there was insufficient main memory to store the entire database, PDB_SYNTAX_ERROR if the contents of the database could not be parsed or seemed implausible (e.g. a nonpositive performance measurement), or PDB_ALREADY_OPEN if the database has been opened by a previous call to pdbOpen() and not closed by a call to pdbClose(). pdbClose() returns PDB_NO_ERROR on success, PDB_CANT_WRITE if the database file is unwritable for any reason, or PDB_NOT_OPEN if the database is not open. Normally applications should look for the performance data they need before going to the trouble of taking measurements. pdbReadRate() is used for this. Synopsis pdbStatusT pdbReadRate ( const char* machineName, const char* applicationName, const char* benchmarkName, const char* versionString, double* rate ); Example main() { double rate; pdbOpen(); if (pdbReadRate(NULL, "myApp", "triangles", glGetString(GL_VERSION), &rate) == PDB_NO_ERROR) printf("%g triangle calls per second\n", rate); pdbClose(); } The first argument is a zero-terminated string giving the name of the machine for which the measurement is sought. If NULL, the default machine name is used. (In X11 environments, the display name is an appropriate choice, and the default machine name is the content of the DISPLAY environment variable.) The second argument is the name of the application. This is used as an additional database key to reduce accidental collisions between benchmark names. The third argument is the name of the benchmark. The fourth argument is a string identifying the desired version of the benchmark. For OpenGL performance measurements, the string returned by glGetString(GL_VERSION) is a good value for this argument. Other applications might use the version number of the benchmark, rather than the version number of the system under test. The fourth argument is a pointer to a double-precision floating-point variable which receives the performance measurement (the "rate") from the database. The rate indicates the number of benchmark operations per second that were measured on a previous run. if pdbReadRate() returns zero, then it completed successfully and the rate is returned in the last argument. If the requested benchmark is not present in the database, it returns PDB_NOT_FOUND. Finally, if pdbReadRate() is called when the database has not been opened by pdbOpen(), it returns PDB_NOT_OPEN. When the application is run for the first time, or when the performance database file has been removed (perhaps to allow a fresh start after a hardware upgrade), pdbReadRate() will not be able to find the desired benchmark. If this happens, the application should use pdbMeasureRate() to make a measurement. Synopsis pdbStatusT pdbMeasureRate ( pdbCallbackT initialize, pdbCallbackT operation, pdbCallbackT finalize, int calibrate, double* rate ); Example void SetupOpenGLState(void) { /* set all OpenGL state to desired values */ } void DrawTriangles(void) { glBegin(GL_TRIANGLE_STRIP); /* specify some vertices... */ glEnd(); } main() { double rate; pdbOpen(); if (pdbReadRate(NULL, "myApp", "triangles", glGetString(GL_VERSION), &rate) != PDB_NO_ERROR) { SetupOpenGLState(); pdbMeasureRate(glFinish, DrawTriangles, glFinish, 1, &rate); } printf("%g triangle calls per second\n", rate); pdbClose(); } The first argument is a pointer to the initialization function. The initialization function is run before each set of operations. For OpenGL performance measurement, it's appropriate to use glFinish() for initialization, to make sure that the graphics pipe is quiet. However, for other performance measurements, the initialization function could be used to create test data, preload caches, etc. It may be NULL, in which case no initialization is performed. The second argument is a pointer to the operation function. This function performs the operations that are to be measured. Usually you'll want to make sure that any global state needed by the operation is set up before calling the operation function, so that you don't include the cost of the setup operations in the measurement. The third argument is a pointer to a finalization function. This is run once, after all the calls to the operation function are complete. In the example above, we used glFinish() again to ensure that the graphics pipeline is idle. It may be NULL, in which case no finalization is performed. The finalization function must be "calibrated" so that the overhead of calling it may be subtracted from the time used by the operation function. If the fourth argument is nonzero, then pdbMeasureRate() calibrates the finalization function. If the fourth argument is zero, then pdbMeasureRate() uses the results of the previous calibration. Recalibrating each measurement is the safest approach, but it roughly doubles the amount of time needed for a measurement. For OpenGL, it should be OK to calibrate once and recalibrate only when using a different X11 display. The final argument is a pointer to a double-precision floating-point variable which receives the execution rate. This rate is the number of times the operation function was called per second. pdbMeasureRate() attempts to compute a number of repetitions that results in a run time of about one second. (Calibration requires an additional second.) It's reasonably careful about timekeeping on systems with low-resolution clocks. pdbMeasureRate() always returns PDB_NO_ERROR. Once a rate has been measured, it should be stored in the database by calling pdbWriteRate(). Synopsis pdbStatusT pdbWriteRate ( const char* machineName, const char* applicationName, const char* benchmarkName, const char* versionString, double rate ); Example main() { double rate; pdbOpen(); if (pdbReadRate(NULL, "myApp", "triangles", glGetString(GL_VERSION), &rate) != PDB_NO_ERROR) { SetupOpenGL(); pdbMeasureRate(glFinish, DrawTriangles, glFinish, 1, &rate); pdbWriteRate(NULL, "myApp", "triangles", glGetString(GL_VERSION), rate); } printf("%g triangle calls per second\n", rate); pdbClose(); } The first four arguments of pdbWriteRate() match the first four arguments of pdbReadRate(). The final argument is the performance measurement to be saved in the database. pdbWriteRate() will return PDB_NO_ERROR if the performance measurement was added to the in-memory copy of the database, PDB_OUT_OF_MEMORY if there was insufficient main memory to do so, or PDB_NOT_OPEN if the database is not open. When pdbWriteRate() is called, the in-memory copy of the performance database is marked "dirty." pdbClose() takes note of this and writes the database back to disk. ______________________________________________________________________ libisfast Tutorial libisfast is a set of demonstration routines that show how libpdb can be used to measure and maintain OpenGL performance data. libisfast is based on purely subjective performance criteria. If they're appropriate for your application, please feel free to use them. If not, please copy the source code and modify it accordingly. In all cases that follow, the term "triangles" refers to a triangle strip with 37 vertices. The triangles are drawn with perspective projection, lighting, and smooth (Gouraud) shading. Unless otherwise stated, display-list-mode drawing is used. (This makes isfast yield more useful results when the target machine is being accessed over a network.) The app must initialize isfast before performing any performance measurements, and clean up after the measurements are finished. On X11 systems these tasks are accomplished by calling int IsFastXOpenDisplay(const char* displayName); and void IsFastXCloseDisplay(void); respectively. IsFastOpenXDisplay() returns zero if the named display could not be opened, and nonzero if the display was opened successfully. DepthBufferingIsFast() returns nonzero if depth buffered triangles can be drawn at least one-half as fast as triangles without depth buffering: int DepthBufferingIsFast(void); ImmediateModeIsFast() returns nonzero if immediate-mode triangles can be drawn at least one-half as fast as display-listed triangles: int ImmediateModeIsFast(void); Note that one significant use of ImmediateModeIsFast() might be to decide whether a "local" or a "remote" rendering strategy is appropriate. If immediate mode is fast, as on a local workstation, it might be best to use it and avoid the memory cost of duplicating the application's data structures in display lists. If immediate mode is slow, as is likely for a remote workstation, it may be best to use display lists for bulky geometry and textures. StencillingIsFast() returns nonzero if stencilled triangles can be drawn at least one-half as fast as non-stencilled triangles: int StencillingIsFast(void); TextureMappingIsFast() returns nonzero if texture-mapped triangles can be drawn at least one-half as fast as non-texture-mapped triangles: int TextureMappingIsFast(void); Although the routines in libisfast will be useful for a number of applications, we suggest that you study them and modify them for your own use. That way you'll explore the particular performance characteristics of your machines: their sensitivity to triangle size, triangle strip length, culling, stencil function, texture map type, texture coordinate generation method, etc. Keep in mind that while the results of the libisfast routines are interesting, they apply to very limited special cases. You should always consider using a more general tool like Inventor or Performer. ______________________________________________________________________ Notes The source directory has three subdirectories: demo Contains a trivial main program to call the routines in libisfast. libisfast Source code for libisfast. libpdb Source code for libpdb. Each subdirectory has its own makefile, and there is a master makefile in the main source directory. This code has been tested lightly in IRIX 5.3, a UNIX SVR4 environment, on an Indigo2 Extreme and an Onyx RealityEngine. ______________________________________________________________________ Revision History Version 1.0: Initial release. Version 2.0: libpdb: Added support for benchmark version identifiers. This solved problems with out-of-date libpdb databases, but made it necessary to create a new pdb database format and file. Added calibration option for pdbMeasureRate(). This speeds up libisfast significantly. Allowed more special characters in the machine name, application name, benchmark name, and version string. For example, these strings may now contain blanks and tabs. In the database file, special characters are escaped with backslashes. libisfast: Removed dependency on the libtk toolkit. This makes it easier to integrate libisfast with real applications, but exposes some system-specific interfaces. The separation between window-system-independent code and window-system-dependent code is not as thorough as it used to be (I refuse to create *another* toolkit), so porting this version of libisfast to OS/2 or Windows will take a little more effort. Used visinfo package for selecting Visuals. Made calibration operations less frequent. Restructured tests to use display lists wherever possible, in order to get more reasonable results for machines that are accessed over the network. demo: Replaced old initialization and cleanup calls with new ones.
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