BOINC applications can optionally provide graphics, which are displayed either in an application window or in a full-screen window (when acting as a screensaver).

General comments about graphics:

BOINC supports process structures where graphics is done:

You can use different structures for different platforms. For example, SETI@home uses monolithic on Windows and shared library on other platforms. Climateprediction.net uses a separate program on all platforms.

Process structures

Monolithic structure

In this approach, graphics are generated by a thread within your main application. The application must call either ".html_text(" int boinc_init_graphics(WORKER_FUNC_PTR worker); // for simple applications int boinc_init_options_graphics(BOINC_OPTIONS&, WORKER_FUNC_PTR worker); // for compound applications ")." where worker() is the main function of your application. Do NOT call boinc_init() or boinc_init_options(). Your application must be linked with libboinc_graphics_api.a, and with your rendering and input-handling functions (see below). It should be linked dynamically with glut and opengl.

boinc_init_graphics() creates a worker thread that runs the main application function. The original thread becomes the graphics thread, which handles GUI events and does rendering. The two threads communicate through application-defined shared memory structures. Typically these structures contain information about the computation, which is used to generate graphics. You must initialize the shared data structure before calling boinc_init_graphics().

Unix/Linux applications that use graphics should compile all files with -D_REENTRANT, since graphics uses multiple threads.

Shared-library structure

In this structure your application consists of two parts: a main program and a shared library. The main program calls either ".html_text(" int boinc_init_graphics_lib(WORKER_FUNC_PTR worker, char* argv0); // for simple apps int boinc_init_options_graphics_lib( BOINC_OPTIONS&, WORKER_FUNC_PTR worker, char* argv0 ) // for compound apps ")." where worker() is as above, and argv0 is the name of the executable as passed in the second argument of main() as argv[0]. The main program must be linked with libboinc_graphics_lib.a

The shared library must have the same name as the executable followed by '.so'. It must be linked with libboinc_graphics_impl.a, with your rendering and input-handling functions, and (dynamically) with glut and opengl.

You must bundle the main program and the shared library together as a multi-file application version.

A typical linking line in building the main program might look like this:
g++ -pthread -o einstein_4.01_i686-pc-linux-gnu app1.o app2.o -lboinc_zip -lboinc_api -lboinc -lboinc_graphics_lib -ldl -lm
where app1.o and app2.o contain the definitions of main() and worker().

A typical linking line in building the shared library might look like this:
g++ -pthread -o einstein_4.01_i686-pc-linux-gnu.so -shared -fPIC app_graphics1.o app_graphics2.o -lboinc_graphics_impl -lboinc -lglut -lGLU -lGL -lX11 -lXmu -ldl -lm
where app_graphics1.o and app_graphics2.o contain the definitions of app_graphics_init(), app_graphics_render(), etc.

In order to communicate data between the worker thread and the graphics thread, the worker() function can call functions from within the shared library. To do this, it makes use of the global variable graphics_lib_handle. If NULL, this means that the host lacks graphics capabilities. If not NULL, the worker can use

communications_function_hook = dlsym(graphics_lib_handle,\"communications_function\");
to resolve pointers to functions which are defined in the graphics code app_graphics.o. In turn, such functions can modify data used by the graphics code.

Separate-program structure

In this approach, an application bundles a 'main program' and a 'graphics program'. The main program executes the graphics program, and kills it when done. The main and graphics programs typically communicate using shared memory; you can use the functions in boinc/lib/shmem.C for this.

The graphics application can be implemented using the BOINC framework, in which case it must initialize with ".html_text(" int boinc_init_options_graphics(BOINC_OPTIONS&, NULL); ")." and supply rendering and input-handling functions.

Either the graphics or the main program can handle graphics messages from the core client. It's easiest to have the graphics program handle them; if the main program handles them, it must convey them to the graphics program.

Rendering and input-handling functions

Programs that use BOINC graphics must supply the following functions:

    void app_graphics_render(int xs, ys, double time_of_day);
This will be called periodically in the graphics thread. It should generate the current graphic. xs and ys are the X and Y sizes of the window, and time_of_day is the relative time in seconds. The function should return true if it actually drew anything. It can refer to the user name, CPU time etc. obtained from boinc_get_init_data(). Applications that don't do graphics must also supply a dummy app_graphics_render() to link with the API.
    void app_graphics_init();
This is called in the graphics thread when a window is created. It must make any calls needed to initialize graphics in the window.
    void app_graphics_resize(int x, int y);
Called when the window size changes.
    void app_graphics_reread_prefs();
This is called, in the graphics thread, whenever the user's project preferences change. It can call ".html_text(" boinc_parse_init_data_file(); boinc_get_init_data(APP_INIT_DATA&); ")." to get the new preferences.

The application must supply the following input-handling functions:

void boinc_app_mouse_move(
    int x, int y,       // new coords of cursor
    bool left,          // whether left mouse button is down
    bool middle,
    bool right
);

void boinc_app_mouse_button(
    int x, int y,       // coords of cursor
    int which,          // which button (0/1/2)
    bool is_down        // true iff button is now down
);

void boinc_app_key_press(
    int, int            // system-specific key encodings
)

void boinc_app_key_release(
    int, int            // system-specific key encodings
)

Limiting frame rate

The following global variables control frame rate:

boinc_max_fps is an upper bound on the number of frames per second (default 30).

boinc_max_gfx_cpu_frac is an upper bound on the fraction of CPU time used for graphics (default 0.5).

Support classes

Several graphics-related classes were developed for SETI@home. They may be of general utility.

REDUCED_ARRAY
Represents a two-dimensional array of data, which is reduced to a smaller dimension by averaging or taking extrema. Includes member functions for drawing the reduced data as a 3D graph in several ways (lines, rectangles, connected surface).
PROGRESS and PROGRESS_2D
Represent progress bars, depicted in 3 or 2 dimensions.
RIBBON_GRAPH
Represents of 3D graph of a function of 1 variable.
MOVING_TEXT_PANEL
Represents a flanged 3D panel, moving cyclically in 3 dimentions, on which text is displayed.
STARFIELD
Represents a set of randomly-generated stars that move forwards or backwards in 3 dimensions.
TEXTURE_DESC
Represents an image (JPEG, Targa, BMP, PNG, or RGB) displayed in 3 dimensions.

The file api/txf_util.C has support functions from drawing nice-looking 3D text.

Static graphics

An application can display a pre-existing image file (JPEG, GIFF, BMP or Targa) as its graphic. This is the simplest approach since you don't need to develop any code. You must include the image file with each workunit. To do this, link the application with api/static_graphics.C (edit this file to use your filename). You can change the image over time, but you must change the (physical, not logical) name of the file each time. "; page_tail(); ?>