wiki:BasicApi

Version 18 (modified by Nicolas, 16 years ago) (diff)

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The BOINC application programming interface (API)

The BOINC API is a set of C++ functions. Most of the functions have a C interface, so that they can be used from programs written in C and other languages. Unless otherwise specified, the functions return an integer error code; zero indicates success.

BOINC applications may generate graphics, allowing them to provide a screensaver. See the graphics API.

BOINC applications may consist of several programs that are executed in sequence; these are called compound applications. See the compound application API.

Initialization and termination

Initialization for graphical and compound applications are described elsewhere (see links above). Other applications must call

int boinc_init();

before calling other BOINC functions.

When the application has completed it must call

int boinc_finish(int status);

status is nonzero if an error was encountered. This call does not return.

Resolving file names

Applications that use named input or output files must call

int boinc_resolve_filename(char *logical_name, char *physical_name, int len);

or

int boinc_resolve_filename_s(char *logical_name, std::string& physical_name);

to convert logical file names to physical names. For example, instead of

f = fopen("my_file", "r");

the application might use

string resolved_name;
retval = boinc_resolve_filename_s("my_file", resolved_name);
if (retval) fail("can't resolve filename");
f = fopen(resolved_name.c_str(), "r");

boinc_resolve_filename() doesn't need to be used for temporary files.

I/O wrappers

Applications should replace fopen() calls with

boinc_fopen(char* path, char* mode);

This deals with platform-specific problems. On Windows, where security and indexing programs can briefly lock files, boinc_fopen() does several retries at 1-second intervals. On Unix, where signals can cause fopen() to fail with EINTR, boinc_fopen checks for this and does a few retries; it also sets the 'close-on-exec' flag.

Checkpointing

Computations that use a significant amount of time per work unit may want to periodically write the current state of the computation to disk. This is known as checkpointing. The state file must include everything required to start the computation again at the same place it was checkpointed. On startup, the application reads the state file to determine where to begin computation. If the BOINC client quits or exits, the computation can be restarted from the most recent checkpoint.

Frequency of checkpointing is a user preference (e.g. laptop users might want to checkpoint infrequently). An application must call

int boinc_time_to_checkpoint();

whenever it reaches a point where it is able to checkpoint. If this returns nonzero (True) then the application should checkpoint immediately (i.e., write the state file and flush all output files), then call

void boinc_checkpoint_completed();

boinc_time_to_checkpoint() is fast, so it can be called frequently (hundreds or thousands of times a second).

Critical sections

void boinc_begin_critical_section();
void boinc_end_critical_section();

Call these around code segments during which you don't want to be suspended or killed by the core client. Since r14694, critical sections are recursive. This means that you can begin critical section multiple times, but each begin must have a matching end call.

NOTE: This is done automatically while checkpointing.

Atomic file update

To facilitate atomic checkpoint, an application can write to output and state files using the MFILE class.

class MFILE {
public:
    int open(char* path, char* mode);
    int _putchar(char);
    int puts(char*);
    int printf(char* format, ...);
    size_t write(const void* buf, size_t size, size_t nitems);
    int close();
    int flush();
};

MFILE buffers data in memory and writes to disk only on flush() or close(). This lets you write output files and state files more or less atomically.

Credit reporting

By default, the claimed credit of a result is based on the product of its total CPU time and the benchmark values obtained by the core client. This can produce results that are too low if the application uses processor-specific optimizations not present in the core client, is compiled with different compiler settings, or uses a GPU or other non-CPU computing resource. To handle such cases, the following functions can be used.

void boinc_ops_per_cpu_second(double floating_point_ops, double integer_ops);

This lets the application report the results of an application-specific benchmark to the core client, expressed as number of floating-point and integer operations per CPU second.

void boinc_ops_cumulative(double floating_point_ops, double integer_ops);

This lets the application report the total number of floating-point and/or integer operations since the start of the result. If floating_point_ops is nonzero, it's used to compute credit and integer_ops is ignored. boinc_ops_cumulative() may be called multiple times, but only the last call makes any difference.

Reporting progress

The core client GUI displays the percent done of workunits in progress. To keep this display current, an application should periodically call

boinc_fraction_done(double fraction_done);

The fraction_done argument is an estimate of the workunit fraction complete (from 0 to 1). This function is fast and can be called frequently. The sequence of arguments in successive calls should be non-decreasing. An application should never 'reset' and start over if an error occurs; it should exit with an error code.

double boinc_get_fraction_done();

returns the last value set, or -1 if none has been set (this would typically be called from graphics code).

Communicating with the core client

The following functions get information from the core client; this information may be useful for graphics.

int boinc_get_init_data_p(APP_INIT_DATA*);
int boinc_get_init_data(APP_INIT_DATA&);

struct APP_INIT_DATA {
    int major_version;
    int minor_version;
    int release;
    int app_version;
    char app_name[256];
    char symstore[256];
    char acct_mgr_url[256];
    char* project_preferences;
    int userid;
    int teamid;
    int hostid;
    char user_name[256];
    char team_name[256];
    char project_dir[256];
    char boinc_dir[256];
    char wu_name[256];
    char authenticator[256];
    int slot;
    double user_total_credit;
    double user_expavg_credit;
    double host_total_credit;
    double host_expavg_credit;
    double resource_share_fraction;
    HOST_INFO host_info;
    PROXY_INFO proxy_info;  // in case app wants to use network
    GLOBAL_PREFS global_prefs;

    // info about the WU
    double rsc_fpops_est;
    double rsc_fpops_bound;
    double rsc_memory_bound;
    double rsc_disk_bound;

    // the following are used for compound apps,
    // where each stage of the computation is a fixed
    // fraction of the total.
    double fraction_done_start;
    double fraction_done_end;
};

to get the following information:

core versionThe version number of the core client
app_nameThe application name (from the server's DB)
project_preferencesAn XML string containing the user's project-specific preferences.
user_nameThe user's 'screen name' on this project.
team_nameThe user's team name, if any.
project_dirAbsolute path of project directory
boinc_dirAbsolute path of BOINC root directory
wu_nameName of workunit being processed
authenticatorUser's authenticator for this project
slotThe number of the app's 'slot'
user_total_creditUser's total work for this project.
user_expavg_creditUser's recent average work per day.
team_total_creditTeam's total work for this project.
team_expavg_creditTeam's recent average work per day.
host_infoA structure describing the host hardware and OS

An application may call

int boinc_wu_cpu_time(double &cpu_time);

to get its total CPU time (from the beginning of the work unit, not just since the last restart). This excludes CPU time used to render graphics.

Is your application running standalone?

BOINC applications can be run in "standalone" mode for testing, or under the control of the BOINC client. You might want your application to behave differently in the two cases. For example you might want to output debugging information if the application is running standalone. To determine if the application is running in standalone mode or under the control of the BOINC client, call

int boinc_is_standalone(void);

This returns non-zero (True) if the application is running standalone, and zero (False) if the application is running under the control of the BOINC client.

Registering a timer handler

typedef void (*FUNC_PTR)();
void boinc_register_timer_callback(FUNC_PTR);

This registers a timer handler function, which will be called once per second.

Requesting network connection

If your application needs to do network communication and it appears that there is no physical network connection (e.g. gethostbyname() fails for a valid name) then:

  • Call boinc_need_network(). This will alert the user that a network connection is needed.
  • Periodically call boinc_network_poll() until it returns zero.
  • Do whatever communication is needed.
  • When done, call boinc_network_done(). This enables the hangup of a modem connection, if needed.
void boinc_need_network();
int boinc_network_poll();
void boinc_network_done();