]> AND Private Git Repository - loba.git/blobdiff - process.h
Logo AND Algorithmique Numérique Distribuée

Private GIT Repository
Revert "Use a do..while() loop instead of this ugly continue statement."
[loba.git] / process.h
index 78fc507f963b58491477fc9e2a064efc7685bddf..c31d21345ab6c05993b7be8bab5cff20ea4e1f8e 100644 (file)
--- a/process.h
+++ b/process.h
@@ -4,19 +4,24 @@
 #define USE_UNORDERED_MAP 1
 //#undef USE_UNORDERED_MAP
 
 #define USE_UNORDERED_MAP 1
 //#undef USE_UNORDERED_MAP
 
-#include <vector>
+#include <algorithm>
+#include <functional>
 #ifdef USE_UNORDERED_MAP
 #ifdef USE_UNORDERED_MAP
-#  include <tr1/unordered_map>
-#  define MAP_TEMPLATE std::tr1::unordered_map
+#  include <unordered_map>
+#  define MAP_TEMPLATE std::unordered_map
 #else
 #  include <map>
 #  define MAP_TEMPLATE std::map
 #endif
 #else
 #  include <map>
 #  define MAP_TEMPLATE std::map
 #endif
+#include <vector>
 #include <msg/msg.h>
 #include <xbt/log.h>
 #include "communicator.h"
 #include <msg/msg.h>
 #include <xbt/log.h>
 #include "communicator.h"
+#include "misc.h"
+#include "msg_thread.h"
 #include "neighbor.h"
 #include "options.h"
 #include "neighbor.h"
 #include "options.h"
+#include "synchro.h"
 
 class process {
 public:
 
 class process {
 public:
@@ -27,8 +32,21 @@ public:
     process(int argc, char* argv[]);
     virtual ~process();
 
     process(int argc, char* argv[]);
     virtual ~process();
 
-    double get_comp() const                { return comp; }
-    double get_real_load() const           { return real_load; }
+    double get_real_load() const           { return real_load;            }
+    double get_comp_amount() const         { return acc.comp_amount;      }
+    unsigned get_comp_iter() const         { return comp_iter;            }
+    unsigned get_all_comp_iter() const     { return all_comp_iter;        }
+    double get_iter_deviation() const;
+    double get_data_send_amount() const    { return acc.data_send.amount; }
+    double get_data_recv_amount() const    { return acc.data_recv.amount; }
+    unsigned get_data_send_count() const   { return acc.data_send.count;  }
+    unsigned get_data_recv_count() const   { return acc.data_recv.count;  }
+    double get_ctrl_send_amount() const    { return acc.ctrl_send.amount; }
+    double get_ctrl_recv_amount() const    { return acc.ctrl_recv.amount; }
+    unsigned get_ctrl_send_count() const   { return acc.ctrl_send.count;  }
+    unsigned get_ctrl_recv_count() const   { return acc.ctrl_recv.count;  }
+    double get_idle_duration() const       { return idle_duration;        }
+    double get_convergence() const         { return convergence;          }
 
     int run();
 
 
     int run();
 
@@ -41,13 +59,19 @@ protected:
 
     // Get and set current load, which may be real load, or expected
     // load if opt::bookkeeping is true.
 
     // Get and set current load, which may be real load, or expected
     // load if opt::bookkeeping is true.
-    double get_load() const;
-    void set_load(double load);
+    double get_load() const                { return expected_load; }
+
+    // The load balancing algorithm comes here...
+    virtual void load_balance();
 
     // Register some amount of load to send to given neighbor.
     void send(neighbor& nb, double amount);
     void send(neighbor* nb, double amount) { send(*nb, amount); }
 
 
     // Register some amount of load to send to given neighbor.
     void send(neighbor& nb, double amount);
     void send(neighbor* nb, double amount) { send(*nb, amount); }
 
+    // Sort pneigh by applying comp to their loads
+    template <typename Compare>
+    void pneigh_sort_by_load(const Compare& comp);
+
     // 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,
     // 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,
@@ -63,6 +87,10 @@ private:
     static double total_load_running; // sum of loads while running
     static double total_load_exit; // sum of process loads at exit
 
     static double total_load_running; // sum of loads while running
     static double total_load_exit; // sum of process loads at exit
 
+    static int process_counter;
+    static double total_load_average;
+    static double load_diff_threshold;
+
     typedef MAP_TEMPLATE<m_host_t, neighbor*> rev_neigh_type;
     neigh_type neigh;           // list of neighbors (do not alter
                                 // after construction!)
     typedef MAP_TEMPLATE<m_host_t, neighbor*> rev_neigh_type;
     neigh_type neigh;           // list of neighbors (do not alter
                                 // after construction!)
@@ -78,55 +106,98 @@ private:
 
     unsigned lb_iter;           // counter of load-balancing iterations
     unsigned comp_iter;         // counter of computation iterations
 
     unsigned lb_iter;           // counter of load-balancing iterations
     unsigned comp_iter;         // counter of computation iterations
-
-    double comp;                // total computing done so far (flops)
+    unsigned all_comp_iter;     // counter of computation iterations
+                                // (counting empty iterations too)
 
     double prev_load_broadcast; // used to ensure that we do not send
                                 // a same information messages
     double real_load;           // current load
     double expected_load;       // expected load in bookkeeping mode
 
     double prev_load_broadcast; // used to ensure that we do not send
                                 // a same information messages
     double real_load;           // current load
     double expected_load;       // expected load in bookkeeping mode
-
-    // The load balancing algorithm comes here...
-    virtual void load_balance();
-
-    // 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_all();
-
-    // Returns true if there remains neighbors to listen for
-    bool may_receive() { return ctrl_close_pending || data_close_pending; }
+    double received_load;       // load received from neighbors
+
+    double idle_duration;       // how long we had nothing to compute
+    double convergence;         // date when convergence was achieved, or -1.0
+
+    mutex_t mutex;              // synchronization between threads
+    condition_t cond;
+
+    struct mesg_accounting {
+        double amount;          // sum of message size
+        unsigned count;         // number of messages
+        mesg_accounting(): amount(0.0), count(0) { }
+    };
+    struct accounting {
+        double comp_amount;        // total computing done so far (flops)
+        mesg_accounting data_send; // data messages sent
+        mesg_accounting data_recv; // data messages received
+        mesg_accounting ctrl_send; // ctrl message sent
+        mesg_accounting ctrl_recv; // ctrl message received
+        accounting(): comp_amount(0.0) { }
+    };
+    accounting acc;             // use a structure so that it is
+                                // automatically initialized a
+                                // construction
+
+    void add_comp_amount(double amount) { acc.comp_amount += amount; }
+    void add_data_send_mesg(double amount) {
+        ++acc.data_send.count;
+        acc.data_send.amount += amount;
+    }
+    void add_data_recv_mesg(double amount) {
+        ++acc.data_recv.count;
+        acc.data_recv.amount += amount;
+    }
+    void add_ctrl_send_mesg(double amount) {
+        ++acc.ctrl_send.count;
+        acc.ctrl_send.amount += amount;
+    }
+    void add_ctrl_recv_mesg(double amount) {
+        ++acc.ctrl_recv.count;
+        acc.ctrl_recv.amount += amount;
+    }
+
+    // Load-balancing loop
+    msg_thread* lb_thread;
+    void load_balance_loop();
+
+    // Simulate computation loop
+    void compute_loop();
+
+    // Check for convergence
+    void convergence_check();
+
+    // Check if we need to stop
+    bool still_running();
+
+    // Returns the sum of "to_send" for all neighbors.
+    double get_sum_of_to_send() const;
+
+    // Compute load_to_send (for data_send), subject to the execution parameters
+    static double compute_load_to_send(double desired);
+
+    // Send procedures
+    void ctrl_send(neighbor& nb);
+    void data_send(neighbor& nb);
+    void ctrl_close(neighbor& nb);
+    void data_close(neighbor& nb);
 
     // Receive procedure
     // Parameter "timeout" may be 0 for non-blocking operation, -1 for
     // infinite waiting, or any positive timeout.
 
     // Receive procedure
     // Parameter "timeout" may be 0 for non-blocking operation, -1 for
     // infinite waiting, or any positive timeout.
-    void receive(double timeout);
-
-    // Finalize sends a "close" message to each neighbor and wait for
-    // all of them to answer.
-    void finalize1(neighbor& nb);
-    void finalize();
+    void ctrl_receive(double timeout);
+    void data_receive(double timeout);
+    void handle_message(message* msg, m_host_t from);
 };
 
 };
 
-inline
-double process::get_load() const
-{
-    if (opt::bookkeeping)
-        return expected_load;
-    else
-        return real_load;
-}
-
-inline
-void process::set_load(double load)
+template <typename Compare>
+void process::pneigh_sort_by_load(const Compare& comp)
 {
 {
-    if (opt::bookkeeping)
-        expected_load = load;
-    else
-        real_load = load;
+    using std::placeholders::_1;
+    using std::placeholders::_2;
+    std::sort(pneigh.begin(), pneigh.end(),
+              std::bind(comp,
+                        std::bind(&neighbor::get_load, _1),
+                        std::bind(&neighbor::get_load, _2)));
 }
 
 #endif // !PROCESS_H
 }
 
 #endif // !PROCESS_H