Difference between revisions of "Subclassing Application Class"
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A planned MUI interface should allow to run every benchmark separately and run all of them. There is also ''-large'' option, which increases memory sizes of calculated problems, so they do not fit into the processor cache. A general rule of porting is that as few files as possible should be modified. The rule makes it easier to upgrade the port when a new version of original program is released. In the case of SciMark, only one file, ''scimark2.c'' has to be replaced. An advanced port may also replace ''Stopwatch.c'' with code using ''timer.device'' directly for improved time measurements accuracy, this is out of scope of this tutorial however. | A planned MUI interface should allow to run every benchmark separately and run all of them. There is also ''-large'' option, which increases memory sizes of calculated problems, so they do not fit into the processor cache. A general rule of porting is that as few files as possible should be modified. The rule makes it easier to upgrade the port when a new version of original program is released. In the case of SciMark, only one file, ''scimark2.c'' has to be replaced. An advanced port may also replace ''Stopwatch.c'' with code using ''timer.device'' directly for improved time measurements accuracy, this is out of scope of this tutorial however. | ||
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+ | ==GUI Design== | ||
+ | [[File:scimark_gui.png|left]] Of course there is no one and only proper GUI design for SciMark. A simple design, using a limited set of MUI classes is shown on the left. There are five buttons for individual benchmarks and one for running all of them. All these buttons are instances of the ''Text'' class. On the right there are gadgets for displaying benchmark results. These gadgets belong to ''Text'' class too, just having different attributes. The "Large Data" button, of ''Text'' class of course, is a toggle one. Surprisingly the status bar (displaying "Ready.") is not an instance of the ''Text'' class, but ''Gauge'' class. Then it will be able to display a progress bar when running all five tests. |
Revision as of 16:41, 2 January 2011
Grzegorz Kraszewski
Introduction
Every MUI application is (or at least should be) an event driven one. It means the application provides a set of actions, which may be triggered with user activity (like using mouse and keyboard). The straightforward way of implementing this set of actions is to implement it as a set of metods added to some MUI object. For simple programs, the best candidate for adding such methods is the master Application object. More complex programs (for example ones using multi-document interface) may add actions to other classes, for example Window one.
Why methods? Implementing actions as methods has many advantages:
- Methods may be used directly as notification actions. It saves a programmer from using hook tricks or cluttering the main loop with teens of ReturnID values.
- Methods may be coupled directly with scripting language interface (formerly known as ARexx interface) commands.
- Methods used in notifications are executed immediately in response of user actions. No delay is introduced by the main loop (especially if it is not empty).
- A notification triggering attribute value may be passed directly to method, as its parameter.
- Using methods improves code modularity.
The Application
Many programming tutorials tend to bore readers with some useless examples. In this one a "real world" application will be ported to MorphOS and "MUI-fied". The application is SciMark 2. SciMark is yet another CPU/memory benchmark. It performs some typical scientific calculations like Fast Fourier Transform, matrix LU decomposition, sparse matrix multiplication and so on. The benchmark measures mainly CPU speed at floating point calculations, cache efficiency and memory speed. Being written in Java initially, it has been rewritten in C (and in fact in many other languages). The C source is available on the project homepage.
The source uses only pure ANSI C standard, so it is easily compilable on MorphOS using provided Makefile. One has just replace $CC = cc line to $CC = gcc, to match the name of the MorphOS compiler. As a result, a typical shell-based application is obtained. Here are example results for a Pegasos 2 machine with G4 processor:
Not very impressive in fact. This is because no optimizaton flags are passed to the compiler in the makefile. They can be added by inserting a line $CFLAGS = -O3 below the $CC = gcc one. Let's also link with libnix (a statically linked unix environment emulation, see Standard C and C++ Libraries) by adding -noixemul to CFLAGS and LDFLAGS. After rebuilding the program and running it again the results are significantly improved (the program has been compiled with GCC 4.4.4 from the official SDK).
This shows how important is optimization of the code, especially computationally intensive one. Optimized code is more than 4 times faster!
Code Inspection
The original source code is well modularized. Five files: FFT.c, LU.c, MonteCarlo.c, SOR.c and SparseCompRow.c implement the five of single benchmarks. Files array.c and Random.c contain auxiliary functions used in benchmarks. File Stopwatch.c implements time measurement. An important file kernel.c gathers all the above and provides five functions performing complete benchmarks with timing. Finally scimark2.c contains the main() function and implements the shell interface.
A planned MUI interface should allow to run every benchmark separately and run all of them. There is also -large option, which increases memory sizes of calculated problems, so they do not fit into the processor cache. A general rule of porting is that as few files as possible should be modified. The rule makes it easier to upgrade the port when a new version of original program is released. In the case of SciMark, only one file, scimark2.c has to be replaced. An advanced port may also replace Stopwatch.c with code using timer.device directly for improved time measurements accuracy, this is out of scope of this tutorial however.