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[simgrid.git] / src / mc / mc_state.c
1 /* Copyright (c) 2008-2014. The SimGrid Team.
2  * All rights reserved.                                                     */
3
4 /* This program is free software; you can redistribute it and/or modify it
5  * under the terms of the license (GNU LGPL) which comes with this package. */
6
7 #include <assert.h>
8
9 #include "../simix/smx_private.h"
10 #include "xbt/fifo.h"
11 #include "mc_state.h"
12 #include "mc_request.h"
13 #include "mc_private.h"
14 #include "mc_comm_pattern.h"
15 #include "mc_smx.h"
16
17 static void copy_incomplete_communications_pattern(mc_state_t state) {
18   int i;
19   xbt_dynar_t incomplete_process_comms;
20   mc_comm_pattern_t comm;
21   unsigned int cursor;
22   state->incomplete_comm_pattern = xbt_dynar_new(sizeof(xbt_dynar_t), xbt_dynar_free_voidp);
23   for (i=0; i < MC_smx_get_maxpid(); i++) {
24     incomplete_process_comms = xbt_dynar_get_as(incomplete_communications_pattern, i, xbt_dynar_t);
25     xbt_dynar_t incomplete_process_comms_copy = xbt_dynar_new(sizeof(mc_comm_pattern_t), comm_pattern_free_voidp);
26     xbt_dynar_foreach(incomplete_process_comms, cursor, comm) {
27       mc_comm_pattern_t copy_comm = xbt_new0(s_mc_comm_pattern_t, 1);
28       copy_comm->index = comm->index;
29       copy_comm->type = comm->type;
30       copy_comm->comm = comm->comm;
31       copy_comm->rdv = strdup(comm->rdv);
32       copy_comm->data_size = -1;
33       copy_comm->data = NULL;
34       if(comm->type == SIMIX_COMM_SEND){
35         copy_comm->src_proc = comm->src_proc;
36         copy_comm->src_host = comm->src_host;
37         if (comm->data != NULL) {
38           copy_comm->data_size = comm->data_size;
39           copy_comm->data = xbt_malloc0(comm->data_size);
40           memcpy(copy_comm->data, comm->data, comm->data_size);
41         }
42       }else{
43         copy_comm->dst_proc = comm->dst_proc;
44         copy_comm->dst_host = comm->dst_host;
45       }
46       xbt_dynar_push(incomplete_process_comms_copy, &copy_comm);
47     }
48     xbt_dynar_insert_at(state->incomplete_comm_pattern, i, &incomplete_process_comms_copy);
49   }
50 }
51
52 static void copy_index_communications_pattern(mc_state_t state) {
53
54   state->index_comm = xbt_dynar_new(sizeof(unsigned int), NULL);
55   mc_list_comm_pattern_t list_process_comm;
56   unsigned int cursor;
57   xbt_dynar_foreach(initial_communications_pattern, cursor, list_process_comm){
58     xbt_dynar_push_as(state->index_comm, unsigned int, list_process_comm->index_comm);
59   }
60 }
61
62 /**
63  * \brief Creates a state data structure used by the exploration algorithm
64  */
65 mc_state_t MC_state_new()
66 {
67   mc_state_t state = xbt_new0(s_mc_state_t, 1);
68   state->max_pid = MC_smx_get_maxpid();
69   state->proc_status = xbt_new0(s_mc_procstate_t, state->max_pid);
70   state->system_state = NULL;
71   state->num = ++mc_stats->expanded_states;
72   state->in_visited_states = 0;
73   state->incomplete_comm_pattern = NULL;
74   /* Stateful model checking */
75   if((_sg_mc_checkpoint > 0 && (mc_stats->expanded_states % _sg_mc_checkpoint == 0)) ||  _sg_mc_termination){
76     state->system_state = MC_take_snapshot(state->num);
77     if(_sg_mc_comms_determinism || _sg_mc_send_determinism){
78       copy_incomplete_communications_pattern(state);
79       copy_index_communications_pattern(state);
80     }
81   }
82   return state;
83 }
84
85 /**
86  * \brief Deletes a state data structure
87  * \param trans The state to be deleted
88  */
89 void MC_state_delete(mc_state_t state, int free_snapshot){
90   if (state->system_state && free_snapshot){
91     MC_free_snapshot(state->system_state);
92   }
93   if(_sg_mc_comms_determinism || _sg_mc_send_determinism){
94     xbt_free(state->index_comm);
95     xbt_free(state->incomplete_comm_pattern);
96   }
97   xbt_free(state->proc_status);
98   xbt_free(state);
99 }
100
101 void MC_state_interleave_process(mc_state_t state, smx_process_t process)
102 {
103   assert(state);
104   state->proc_status[process->pid].state = MC_INTERLEAVE;
105   state->proc_status[process->pid].interleave_count = 0;
106 }
107
108 void MC_state_remove_interleave_process(mc_state_t state, smx_process_t process)
109 {
110   if (state->proc_status[process->pid].state == MC_INTERLEAVE)
111     state->proc_status[process->pid].state = MC_DONE;
112 }
113
114 unsigned int MC_state_interleave_size(mc_state_t state)
115 {
116   unsigned int i, size = 0;
117
118   for (i = 0; i < state->max_pid; i++) {
119     if ((state->proc_status[i].state == MC_INTERLEAVE)
120         || (state->proc_status[i].state == MC_MORE_INTERLEAVE))
121       size++;
122   }
123
124   return size;
125 }
126
127 int MC_state_process_is_done(mc_state_t state, smx_process_t process)
128 {
129   return state->proc_status[process->pid].state == MC_DONE ? TRUE : FALSE;
130 }
131
132 void MC_state_set_executed_request(mc_state_t state, smx_simcall_t req,
133                                    int value)
134 {
135   state->executed_req = *req;
136   state->req_num = value;
137   smx_process_t process = NULL;
138   mc_procstate_t procstate = NULL;
139
140   /* The waitany and testany request are transformed into a wait or test request over the
141    * corresponding communication action so it can be treated later by the dependence
142    * function. */
143   switch (req->call) {
144   case SIMCALL_COMM_WAITANY:
145     state->internal_req.call = SIMCALL_COMM_WAIT;
146     state->internal_req.issuer = req->issuer;
147     // FIXME, read from remote process
148     state->internal_comm =
149         *xbt_dynar_get_as(simcall_comm_waitany__get__comms(req), value,
150                           smx_synchro_t);
151     simcall_comm_wait__set__comm(&state->internal_req, &state->internal_comm);
152     simcall_comm_wait__set__timeout(&state->internal_req, 0);
153     break;
154
155   case SIMCALL_COMM_TESTANY:
156     state->internal_req.call = SIMCALL_COMM_TEST;
157     state->internal_req.issuer = req->issuer;
158
159     if (value > 0)
160       // FIXME, read from remote process
161       state->internal_comm =
162           *xbt_dynar_get_as(simcall_comm_testany__get__comms(req), value,
163                             smx_synchro_t);
164
165     simcall_comm_test__set__comm(&state->internal_req, &state->internal_comm);
166     simcall_comm_test__set__result(&state->internal_req, value);
167     break;
168
169   case SIMCALL_COMM_WAIT:
170     state->internal_req = *req;
171     // FIXME, read from remote process
172     state->internal_comm = *(simcall_comm_wait__get__comm(req));
173     simcall_comm_wait__set__comm(&state->executed_req, &state->internal_comm);
174     simcall_comm_wait__set__comm(&state->internal_req, &state->internal_comm);
175     break;
176
177   case SIMCALL_COMM_TEST:
178     state->internal_req = *req;
179     // FIXME, read from remote process
180     state->internal_comm = *simcall_comm_test__get__comm(req);
181     simcall_comm_test__set__comm(&state->executed_req, &state->internal_comm);
182     simcall_comm_test__set__comm(&state->internal_req, &state->internal_comm);
183     break;
184
185   case SIMCALL_MC_RANDOM:
186     state->internal_req = *req;
187     int random_max = simcall_mc_random__get__max(req);
188     if (value != random_max) {
189       MC_EACH_SIMIX_PROCESS(process,
190         procstate = &state->proc_status[process->pid];
191         const smx_process_t issuer = MC_smx_simcall_get_issuer(req);
192         if (process->pid == issuer->pid) {
193           procstate->state = MC_MORE_INTERLEAVE;
194           break;
195         }
196       );
197     }
198     break;
199
200   default:
201     state->internal_req = *req;
202     break;
203   }
204 }
205
206 smx_simcall_t MC_state_get_executed_request(mc_state_t state, int *value)
207 {
208   *value = state->req_num;
209   return &state->executed_req;
210 }
211
212 smx_simcall_t MC_state_get_internal_request(mc_state_t state)
213 {
214   return &state->internal_req;
215 }
216
217 smx_simcall_t MC_state_get_request(mc_state_t state, int *value)
218 {
219   smx_process_t process = NULL;
220   mc_procstate_t procstate = NULL;
221   unsigned int start_count;
222   smx_synchro_t act = NULL;
223
224   MC_EACH_SIMIX_PROCESS(process,
225     procstate = &state->proc_status[process->pid];
226
227     if (procstate->state != MC_INTERLEAVE
228         && procstate->state != MC_MORE_INTERLEAVE)
229         continue;
230     if (!MC_process_is_enabled(process))
231       continue;
232
233     switch (process->simcall.call) {
234         case SIMCALL_COMM_WAITANY:
235           *value = -1;
236           while (procstate->interleave_count <
237                  xbt_dynar_length(simcall_comm_waitany__get__comms
238                                   (&process->simcall))) {
239             if (MC_request_is_enabled_by_idx
240                 (&process->simcall, procstate->interleave_count++)) {
241               *value = procstate->interleave_count - 1;
242               break;
243             }
244           }
245
246           if (procstate->interleave_count >=
247               xbt_dynar_length(simcall_comm_waitany__get__comms
248                                (&process->simcall)))
249             procstate->state = MC_DONE;
250
251           if (*value != -1)
252             return &process->simcall;
253
254           break;
255
256         case SIMCALL_COMM_TESTANY:
257           start_count = procstate->interleave_count;
258           *value = -1;
259           while (procstate->interleave_count <
260                  xbt_dynar_length(simcall_comm_testany__get__comms
261                                   (&process->simcall))) {
262             if (MC_request_is_enabled_by_idx
263                 (&process->simcall, procstate->interleave_count++)) {
264               *value = procstate->interleave_count - 1;
265               break;
266             }
267           }
268
269           if (procstate->interleave_count >=
270               xbt_dynar_length(simcall_comm_testany__get__comms
271                                (&process->simcall)))
272             procstate->state = MC_DONE;
273
274           if (*value != -1 || start_count == 0)
275             return &process->simcall;
276
277           break;
278
279         case SIMCALL_COMM_WAIT:
280           act = simcall_comm_wait__get__comm(&process->simcall);
281           if (act->comm.src_proc && act->comm.dst_proc) {
282             *value = 0;
283           } else {
284             if (act->comm.src_proc == NULL && act->comm.type == SIMIX_COMM_READY
285                 && act->comm.detached == 1)
286               *value = 0;
287             else
288               *value = -1;
289           }
290           procstate->state = MC_DONE;
291           return &process->simcall;
292
293           break;
294
295         case SIMCALL_MC_RANDOM:
296           if (procstate->state == MC_INTERLEAVE)
297             *value = 0;
298           else {
299             if (state->req_num < simcall_mc_random__get__max(&process->simcall))
300               *value = state->req_num + 1;
301           }
302           procstate->state = MC_DONE;
303           return &process->simcall;
304           break;
305
306         default:
307           procstate->state = MC_DONE;
308           *value = 0;
309           return &process->simcall;
310           break;
311
312     }
313   );
314
315   return NULL;
316 }