boinc/client/sim.h

280 lines
7.2 KiB
C++

#include <vector>
#include "app.h"
#include "time_stats.h"
#include "client_types.h"
#include "../sched/edf_sim.h"
using std::vector;
#define WORK_FETCH_DONT_NEED 0
// project: suspended, deferred, or no new work (can't ask for more work)
// overall: not work_fetch_ok (from CPU policy)
#define WORK_FETCH_OK 1
// project: has more than min queue * share, not suspended/def/nonewwork
// overall: at least min queue, work fetch OK
#define WORK_FETCH_NEED 2
// project: less than min queue * resource share of DL/runnable results
// overall: less than min queue
#define WORK_FETCH_NEED_IMMEDIATELY 3
// project: no downloading or runnable results
// overall: at least one idle CPU
struct SIM_RESULTS {
double cpu_used;
double cpu_wasted;
double cpu_idle;
int nresults_met_deadline;
int nresults_missed_deadline;
double share_violation;
double variety;
double cpu_wasted_frac;
double cpu_idle_frac;
void compute();
void print(FILE* f, const char* title=0);
void parse(FILE* f);
void add(SIM_RESULTS& r);
void divide(int);
void clear();
};
struct PROJECT_RESULTS {
double cpu_used;
double cpu_wasted;
int nresults_met_deadline;
int nresults_missed_deadline;
};
class NORMAL_DIST {
public:
double mean;
double stdev;
int parse(XML_PARSER&, char* end_tag);
double sample();
};
class UNIFORM_DIST {
public:
double lo;
double hi;
int parse(XML_PARSER&, char* end_tag);
double sample();
};
class RANDOM_PROCESS {
double last_time;
double time_left;
bool value;
double off_lambda;
public:
double frac;
double lambda;
int parse(XML_PARSER&, char* end_tag);
bool sample(double);
void init();
RANDOM_PROCESS();
};
class SIM_APP: public APP {
public:
double latency_bound;
double fpops_est;
NORMAL_DIST fpops;
NORMAL_DIST checkpoint_period;
double working_set;
double weight;
SIM_APP(){}
int parse(XML_PARSER&);
};
class SIM_PROJECT: public PROJECT {
public:
RANDOM_PROCESS available;
int index;
int result_index;
double idle_time;
double idle_time_sumsq;
bool idle;
int max_infeasible_count;
// for DCF variants:
int completed_task_count;
double completions_ratio_mean;
double completions_ratio_s;
double completions_ratio_stdev;
double completions_required_stdevs;
int parse(XML_PARSER&);
PROJECT_RESULTS project_results;
void print_results(FILE*, SIM_RESULTS&);
void init();
void backoff();
void update_dcf_stats(RESULT*);
};
class SIM_HOST: public HOST_INFO {
public:
RANDOM_PROCESS available;
RANDOM_PROCESS idle;
double connection_interval;
// min time between network connections
int parse(XML_PARSER&);
};
class CLIENT_STATE {
public:
double now;
vector<PROJECT*> projects;
vector<WORKUNIT*> workunits;
vector<RESULT*> results;
vector<APP*> apps;
ACTIVE_TASK_SET active_tasks;
GLOBAL_PREFS global_prefs;
SIM_HOST host_info;
TIME_STATS time_stats;
CLIENT_STATE();
bool initialized;
bool run_cpu_benchmarks;
FILE* html_out;
void html_start();
void html_rec();
void html_end();
std::string html_msg;
double share_violation();
double variety();
private:
double app_started;
public:
ACTIVE_TASK* lookup_active_task_by_result(RESULT*);
int report_result_error(RESULT&, const char *format, ...);
double available_ram();
double max_available_ram();
void set_client_state_dirty(const char*);
RESULT* lookup_result(PROJECT*, const char*);
// cpu_sched.C
private:
double debt_interval_start;
double total_wall_cpu_time_this_debt_interval;
// "wall CPU time" accumulated since last adjust_debts()
double fetchable_resource_share();
double total_cpu_time_this_debt_interval;
double cpu_shortfall;
bool work_fetch_no_new_work;
bool must_enforce_cpu_schedule;
bool must_schedule_cpus;
bool must_check_work_fetch;
std::vector <RESULT*> ordered_scheduled_results;
void assign_results_to_projects();
RESULT* largest_debt_project_best_result();
RESULT* earliest_deadline_result();
void reset_debt_accounting();
void adjust_debts();
bool possibly_schedule_cpus();
void schedule_cpus();
bool enforce_schedule();
bool no_work_for_a_cpu();
void rr_simulation();
void make_running_task_heap(vector<ACTIVE_TASK*>&);
void print_deadline_misses();
public:
inline double work_buf_min() {
return global_prefs.work_buf_min_days * 86400;
}
double work_buf_additional() {
return global_prefs.work_buf_additional_days * 86400;
}
inline double work_buf_total() {
double x = work_buf_min() + work_buf_additional();
if (x < 1) x = 1;
return x;
}
void request_enforce_schedule(const char*);
void request_schedule_cpus(const char*);
// --------------- cs_apps.C:
private:
double total_resource_share();
double potentially_runnable_resource_share();
double nearly_runnable_resource_share();
public:
double runnable_resource_share();
void request_work_fetch(const char*);
// Check if work fetch needed. Called when:
// - core client starts (CS::init())
// - task is completed or fails
// - tasks are killed
// - an RPC completes
// - project suspend/detch/attach/reset GUI RPC
// - result suspend/abort GUI RPC
int quit_activities();
void set_ncpus();
double estimate_cpu_time(WORKUNIT&);
double get_fraction_done(RESULT* result);
int input_files_available(RESULT*, bool);
ACTIVE_TASK* get_next_graphics_capable_app();
int ncpus;
// number of usable cpus
private:
int nslots;
int app_finished(ACTIVE_TASK&);
bool start_apps();
bool handle_finished_apps();
public:
ACTIVE_TASK* get_task(RESULT*);
// --------------- cs_scheduler.C
private:
bool contacted_sched_server;
int overall_work_fetch_urgency;
double avg_proc_rate();
// --------------- work_fetch.C:
public:
int proj_min_results(PROJECT*, double);
void check_project_timeout();
PROJECT* next_project_master_pending();
PROJECT* next_project_sched_rpc_pending();
PROJECT* next_project_trickle_up_pending();
PROJECT* next_project_need_work();
PROJECT* find_project_with_overdue_results();
double overall_cpu_frac();
double time_until_work_done(PROJECT*, int, double);
bool compute_work_requests();
void scale_duration_correction_factors(double);
void generate_new_host_cpid();
void compute_nuploading_results();
//////////////////
void make_job(SIM_PROJECT*, WORKUNIT*, RESULT*);
void handle_completed_results();
void get_workload(vector<IP_RESULT>&);
int parse_projects(char*);
int parse_host(char*);
void simulate();
bool scheduler_rpc_poll();
bool simulate_rpc(PROJECT*);
void print_project_results(FILE*);
};
class NET_STATUS {
public:
bool have_sporadic_connection;
};
extern CLIENT_STATE gstate;
extern NET_STATUS net_status;
extern FILE* logfile;
extern bool user_active;
extern SIM_RESULTS sim_results;
extern double calculate_exponential_backoff(
int n, double MIN, double MAX
);
extern bool dcf_dont_use;
extern bool dcf_stats;