Add extract.pl.

[loba.git] / process.h

#ifndef PROCESS_H
#define PROCESS_H

#define USE_UNORDERED_MAP 1
//#undef USE_UNORDERED_MAP

#include <vector>
#ifdef USE_UNORDERED_MAP
#  include <tr1/unordered_map>
#  define MAP_TEMPLATE std::tr1::unordered_map
#else
#  include <map>
#  define MAP_TEMPLATE std::map
#endif
#include <msg/msg.h>
#include <xbt/log.h>
#include "communicator.h"
#include "neighbor.h"

class process {
public:
    static double get_total_load_init()    { return total_load_init;    }
    static double get_total_load_running() { return total_load_running; }
    static double get_total_load_exit()    { return total_load_exit;    }

    process(int argc, char* argv[]);
    virtual ~process();

    double get_load() const                { return load; }

    int run();

protected:
    typedef std::vector<neighbor> neigh_type;
    typedef std::vector<neighbor*> pneigh_type;

    pneigh_type pneigh;         // list of pointers to neighbors that
                                // we are free to reorder

    // Returns the sum of "to_send" for all neighbors.
    double sum_of_to_send() const;

    // Calls neighbor::print(verbose, logp, cat) for each member of neigh.
    void print_loads(bool verbose = false,
                     e_xbt_log_priority_t logp = xbt_log_priority_info,
                     xbt_log_category_t cat = _XBT_LOGV(default)) const;

    // Calls neighbor::print(verbose, logp, cat) for each member of pneigh.
    void print_loads_p(bool verbose = false,
                       e_xbt_log_priority_t logp = xbt_log_priority_info,
                       xbt_log_category_t cat = _XBT_LOGV(default)) const;

private:
    static double total_load_init; // sum of process loads at init
    static double total_load_running; // summ of loads while running
    static double total_load_exit; // sum of process loads at exit

    typedef MAP_TEMPLATE<m_host_t, neighbor*> rev_neigh_type;
    neigh_type neigh;           // list of neighbors (do not alter
                                // after construction!)
    rev_neigh_type rev_neigh;   // map m_host_t -> neighbor

    communicator comm;          // communicator for this process
    int ctrl_close_pending;     // number of "close" messages to wait
                                // on ctrl channel
    int data_close_pending;     // number of "close" messages to wait
                                // on data channel
    bool close_received;        // true if we received a "close" message
    bool finalizing;            // true when finalize() is running

    unsigned lb_iter;           // counter of load-balancing iterations
    unsigned comp_iter;         // counter of computation iterations

    double prev_load_broadcast; // used to ensure that we do not send
                                // a same information messages
    double load;                // current load
    double expected_load;       // expected load in bookkeeping mode

    // The load balancing algorithm comes here...
    // Parameter "my_load" is the load to take into account for myself
    // (may be load or expected load).
    // Returns the total load sent to neighbors.
    virtual double load_balance(double my_load);

    // Virtually do some computation
    void compute();

    // Send procedures, with helpers for bookkeeping mode or not
    void send1_no_bookkeeping(neighbor& nb);
    void send1_bookkeeping(neighbor& nb);
    void send();

    // Returns true if there remains neighbors to listen for
    bool may_receive() { return ctrl_close_pending || data_close_pending; }

    // Receive procedure: wait (or not) for a message to come
    void receive(bool wait);

    // Finalize sends a "close" message to each neighbor and wait for
    // all of them to answer.
    void finalize1(neighbor& nb);
    void finalize();
};

#endif // !PROCESS_H

// Local variables:
// mode: c++
// End: