-/* Copyright (c) 2009-2015. The SimGrid Team.
- * All rights reserved. */
+/* Copyright (c) 2009-2017. The SimGrid Team. All rights reserved. */
/* This program is free software; you can redistribute it and/or modify it
* under the terms of the license (GNU LGPL) which comes with this package. */
#include "private.h"
-#include <stdio.h>
-#include <xbt.h>
-#include <xbt/replay.h>
+#include "xbt/replay.h"
#include <unordered_map>
#include <vector>
//allocate a single buffer for all recv
void* smpi_get_tmp_recvbuffer(int size){
if (!smpi_process_get_replaying())
- return xbt_malloc(size);
+ return xbt_malloc(size);
if (recvbuffer_size<size){
recvbuffer=static_cast<char*>(xbt_realloc(recvbuffer,size));
recvbuffer_size=size;
/* Helper function */
static double parse_double(const char *string)
{
- double value;
char *endptr;
- value = strtod(string, &endptr);
+ double value = strtod(string, &endptr);
if (*endptr != '\0')
THROWF(unknown_error, 0, "%s is not a double", string);
return value;
static MPI_Datatype decode_datatype(const char *const action)
{
-// Declared datatypes,
switch(atoi(action)) {
case 0:
MPI_CURRENT_TYPE=MPI_DOUBLE;
return MPI_CURRENT_TYPE;
}
-
const char* encode_datatype(MPI_Datatype datatype, int* known)
{
//default type for output is set to MPI_BYTE
// MPI_DEFAULT_TYPE is not set for output, use directly MPI_BYTE
if(known!=nullptr)
*known=1;
- if (datatype==MPI_BYTE){
+ if (datatype==MPI_BYTE)
return "";
- }
if(datatype==MPI_DOUBLE)
return "0";
if(datatype==MPI_INT)
static void action_finalize(const char *const *action)
{
- /* do nothing */
+ /* Nothing to do */
}
static void action_comm_size(const char *const *action)
{
- double clock = smpi_process_simulated_elapsed();
-
communicator_size = parse_double(action[2]);
- log_timed_action (action, clock);
+ log_timed_action (action, smpi_process_simulated_elapsed());
}
static void action_comm_split(const char *const *action)
{
- double clock = smpi_process_simulated_elapsed();
-
- log_timed_action (action, clock);
+ log_timed_action (action, smpi_process_simulated_elapsed());
}
static void action_comm_dup(const char *const *action)
{
- double clock = smpi_process_simulated_elapsed();
-
- log_timed_action (action, clock);
+ log_timed_action (action, smpi_process_simulated_elapsed());
}
static void action_compute(const char *const *action)
int rank = smpi_process_index();
- int dst_traced = smpi_group_rank(smpi_comm_group(MPI_COMM_WORLD), to);
+ int dst_traced = MPI_COMM_WORLD->group()->rank(to);
instr_extra_data extra = xbt_new0(s_instr_extra_data_t,1);
extra->type = TRACING_SEND;
extra->send_size = size;
extra->dst = dst_traced;
extra->datatype1 = encode_datatype(MPI_CURRENT_TYPE, nullptr);
TRACE_smpi_ptp_in(rank, rank, dst_traced, __FUNCTION__, extra);
- if (!TRACE_smpi_view_internals()) {
- TRACE_smpi_send(rank, rank, dst_traced, size*smpi_datatype_size(MPI_CURRENT_TYPE));
- }
+ if (!TRACE_smpi_view_internals())
+ TRACE_smpi_send(rank, rank, dst_traced, 0, size*smpi_datatype_size(MPI_CURRENT_TYPE));
smpi_mpi_send(nullptr, size, MPI_CURRENT_TYPE, to , 0, MPI_COMM_WORLD);
int to = atoi(action[2]);
double size=parse_double(action[3]);
double clock = smpi_process_simulated_elapsed();
- MPI_Request request;
if(action[4])
MPI_CURRENT_TYPE=decode_datatype(action[4]);
MPI_CURRENT_TYPE= MPI_DEFAULT_TYPE;
int rank = smpi_process_index();
- int dst_traced = smpi_group_rank(smpi_comm_group(MPI_COMM_WORLD), to);
+ int dst_traced = MPI_COMM_WORLD->group()->rank(to);
instr_extra_data extra = xbt_new0(s_instr_extra_data_t,1);
extra->type = TRACING_ISEND;
extra->send_size = size;
extra->dst = dst_traced;
extra->datatype1 = encode_datatype(MPI_CURRENT_TYPE, nullptr);
TRACE_smpi_ptp_in(rank, rank, dst_traced, __FUNCTION__, extra);
- if (!TRACE_smpi_view_internals()) {
- TRACE_smpi_send(rank, rank, dst_traced, size*smpi_datatype_size(MPI_CURRENT_TYPE));
- }
+ if (!TRACE_smpi_view_internals())
+ TRACE_smpi_send(rank, rank, dst_traced, 0, size*smpi_datatype_size(MPI_CURRENT_TYPE));
- request = smpi_mpi_isend(nullptr, size, MPI_CURRENT_TYPE, to, 0,MPI_COMM_WORLD);
+ MPI_Request request = smpi_mpi_isend(nullptr, size, MPI_CURRENT_TYPE, to, 0,MPI_COMM_WORLD);
TRACE_smpi_ptp_out(rank, rank, dst_traced, __FUNCTION__);
request->send = 1;
MPI_CURRENT_TYPE= MPI_DEFAULT_TYPE;
int rank = smpi_process_index();
- int src_traced = smpi_group_rank(smpi_comm_group(MPI_COMM_WORLD), from);
+ int src_traced = MPI_COMM_WORLD->group()->rank(from);
instr_extra_data extra = xbt_new0(s_instr_extra_data_t,1);
extra->type = TRACING_RECV;
TRACE_smpi_ptp_out(rank, src_traced, rank, __FUNCTION__);
if (!TRACE_smpi_view_internals()) {
- TRACE_smpi_recv(rank, src_traced, rank);
+ TRACE_smpi_recv(rank, src_traced, rank, 0);
}
log_timed_action (action, clock);
int from = atoi(action[2]);
double size=parse_double(action[3]);
double clock = smpi_process_simulated_elapsed();
- MPI_Request request;
if(action[4])
MPI_CURRENT_TYPE=decode_datatype(action[4]);
MPI_CURRENT_TYPE= MPI_DEFAULT_TYPE;
int rank = smpi_process_index();
- int src_traced = smpi_group_rank(smpi_comm_group(MPI_COMM_WORLD), from);
+ int src_traced = MPI_COMM_WORLD->group()->rank(from);
instr_extra_data extra = xbt_new0(s_instr_extra_data_t,1);
extra->type = TRACING_IRECV;
extra->send_size = size;
size=status.count;
}
- request = smpi_mpi_irecv(nullptr, size, MPI_CURRENT_TYPE, from, 0, MPI_COMM_WORLD);
+ MPI_Request request = smpi_mpi_irecv(nullptr, size, MPI_CURRENT_TYPE, from, 0, MPI_COMM_WORLD);
TRACE_smpi_ptp_out(rank, src_traced, rank, __FUNCTION__);
request->recv = 1;
CHECK_ACTION_PARAMS(action, 0, 0)
double clock = smpi_process_simulated_elapsed();
MPI_Status status;
- int flag = true;
MPI_Request request = get_reqq_self()->back();
get_reqq_self()->pop_back();
extra->type=TRACING_TEST;
TRACE_smpi_testing_in(rank, extra);
- flag = smpi_mpi_test(&request, &status);
+ int flag = smpi_mpi_test(&request, &status);
XBT_DEBUG("MPI_Test result: %d", flag);
/* push back request in vector to be caught by a subsequent wait. if the test did succeed, the request is now nullptr.*/
return;
}
- int rank = request->comm != MPI_COMM_NULL ? smpi_comm_rank(request->comm) : -1;
+ int rank = request->comm != MPI_COMM_NULL ? request->comm->rank() : -1;
- MPI_Group group = smpi_comm_group(request->comm);
- int src_traced = smpi_group_rank(group, request->src);
- int dst_traced = smpi_group_rank(group, request->dst);
+ MPI_Group group = request->comm->group();
+ int src_traced = group->rank(request->src);
+ int dst_traced = group->rank(request->dst);
int is_wait_for_receive = request->recv;
instr_extra_data extra = xbt_new0(s_instr_extra_data_t,1);
extra->type = TRACING_WAIT;
TRACE_smpi_ptp_out(rank, src_traced, dst_traced, __FUNCTION__);
if (is_wait_for_receive)
- TRACE_smpi_recv(rank, src_traced, dst_traced);
+ TRACE_smpi_recv(rank, src_traced, dst_traced, 0);
log_timed_action (action, clock);
}
extra->type = TRACING_WAITALL;
extra->send_size=count_requests;
TRACE_smpi_ptp_in(rank_traced, -1, -1, __FUNCTION__,extra);
-
+ int recvs_snd[count_requests];
+ int recvs_rcv[count_requests];
+ unsigned int i=0;
+ for (auto req : *(get_reqq_self())){
+ if (req && req->recv){
+ recvs_snd[i]=req->src;
+ recvs_rcv[i]=req->dst;
+ }else
+ recvs_snd[i]=-100;
+ i++;
+ }
smpi_mpi_waitall(count_requests, &(*get_reqq_self())[0], status);
- for (auto req : *(get_reqq_self())){
- if (req && req->recv)
- TRACE_smpi_recv(rank_traced, req->src, req->dst);
+ for (i=0; i<count_requests;i++){
+ if (recvs_snd[i]!=-100)
+ TRACE_smpi_recv(rank_traced, recvs_snd[i], recvs_rcv[i],0);
}
TRACE_smpi_ptp_out(rank_traced, -1, -1, __FUNCTION__);
}
if(action[3]) {
root= atoi(action[3]);
- if(action[4]) {
+ if(action[4])
MPI_CURRENT_TYPE=decode_datatype(action[4]);
- }
}
int rank = smpi_process_index();
- int root_traced = smpi_group_index(smpi_comm_group(MPI_COMM_WORLD), root);
+ int root_traced = MPI_COMM_WORLD->group()->index(root);
instr_extra_data extra = xbt_new0(s_instr_extra_data_t,1);
extra->type = TRACING_BCAST;
if(action[4]) {
root= atoi(action[4]);
- if(action[5]) {
+ if(action[5])
MPI_CURRENT_TYPE=decode_datatype(action[5]);
- }
}
int rank = smpi_process_index();
- int root_traced = smpi_group_rank(smpi_comm_group(MPI_COMM_WORLD), root);
+ int root_traced = MPI_COMM_WORLD->group()->rank(root);
instr_extra_data extra = xbt_new0(s_instr_extra_data_t,1);
extra->type = TRACING_REDUCE;
extra->send_size = comm_size;
}
static void action_allToAll(const char *const *action) {
- CHECK_ACTION_PARAMS(action, 2, 2) //two mandatory (send and recv volumes)
- //two optional (corresponding datatypes)
+ CHECK_ACTION_PARAMS(action, 2, 2) //two mandatory (send and recv volumes) and two optional (corresponding datatypes)
double clock = smpi_process_simulated_elapsed();
- int comm_size = smpi_comm_size(MPI_COMM_WORLD);
+ int comm_size = MPI_COMM_WORLD->size();
int send_size = parse_double(action[2]);
int recv_size = parse_double(action[3]);
- MPI_Datatype MPI_CURRENT_TYPE2;
+ MPI_Datatype MPI_CURRENT_TYPE2 = MPI_DEFAULT_TYPE;
if(action[4] && action[5]) {
MPI_CURRENT_TYPE=decode_datatype(action[4]);
MPI_CURRENT_TYPE2=decode_datatype(action[5]);
}
- else{
+ else
MPI_CURRENT_TYPE=MPI_DEFAULT_TYPE;
- MPI_CURRENT_TYPE2=MPI_DEFAULT_TYPE;
- }
void *send = smpi_get_tmp_sendbuffer(send_size*comm_size* smpi_datatype_size(MPI_CURRENT_TYPE));
void *recv = smpi_get_tmp_recvbuffer(recv_size*comm_size* smpi_datatype_size(MPI_CURRENT_TYPE2));
static void action_gather(const char *const *action) {
/* The structure of the gather action for the rank 0 (total 4 processes) is the following:
- 0 gather 68 68 0 0 0
-
- where:
- 1) 68 is the sendcounts
- 2) 68 is the recvcounts
- 3) 0 is the root node
- 4) 0 is the send datatype id, see decode_datatype()
- 5) 0 is the recv datatype id, see decode_datatype()
+ 0 gather 68 68 0 0 0
+ where:
+ 1) 68 is the sendcounts
+ 2) 68 is the recvcounts
+ 3) 0 is the root node
+ 4) 0 is the send datatype id, see decode_datatype()
+ 5) 0 is the recv datatype id, see decode_datatype()
*/
CHECK_ACTION_PARAMS(action, 2, 3)
double clock = smpi_process_simulated_elapsed();
- int comm_size = smpi_comm_size(MPI_COMM_WORLD);
+ int comm_size = MPI_COMM_WORLD->size();
int send_size = parse_double(action[2]);
int recv_size = parse_double(action[3]);
- MPI_Datatype MPI_CURRENT_TYPE2;
+ MPI_Datatype MPI_CURRENT_TYPE2 = MPI_DEFAULT_TYPE;
if(action[4] && action[5]) {
MPI_CURRENT_TYPE=decode_datatype(action[5]);
MPI_CURRENT_TYPE2=decode_datatype(action[6]);
} else {
MPI_CURRENT_TYPE=MPI_DEFAULT_TYPE;
- MPI_CURRENT_TYPE2=MPI_DEFAULT_TYPE;
}
void *send = smpi_get_tmp_sendbuffer(send_size* smpi_datatype_size(MPI_CURRENT_TYPE));
void *recv = nullptr;
int root=0;
if(action[4])
root=atoi(action[4]);
- int rank = smpi_comm_rank(MPI_COMM_WORLD);
+ int rank = MPI_COMM_WORLD->rank();
if(rank==root)
recv = smpi_get_tmp_recvbuffer(recv_size*comm_size* smpi_datatype_size(MPI_CURRENT_TYPE2));
static void action_gatherv(const char *const *action) {
/* The structure of the gatherv action for the rank 0 (total 4 processes) is the following:
- 0 gather 68 68 10 10 10 0 0 0
-
- where:
- 1) 68 is the sendcount
- 2) 68 10 10 10 is the recvcounts
- 3) 0 is the root node
- 4) 0 is the send datatype id, see decode_datatype()
- 5) 0 is the recv datatype id, see decode_datatype()
+ 0 gather 68 68 10 10 10 0 0 0
+ where:
+ 1) 68 is the sendcount
+ 2) 68 10 10 10 is the recvcounts
+ 3) 0 is the root node
+ 4) 0 is the send datatype id, see decode_datatype()
+ 5) 0 is the recv datatype id, see decode_datatype()
*/
-
double clock = smpi_process_simulated_elapsed();
- int comm_size = smpi_comm_size(MPI_COMM_WORLD);
+ int comm_size = MPI_COMM_WORLD->size();
CHECK_ACTION_PARAMS(action, comm_size+1, 2)
int send_size = parse_double(action[2]);
- int *disps = xbt_new0(int, comm_size);
- int *recvcounts = xbt_new0(int, comm_size);
- int i=0,recv_sum=0;
+ int disps[comm_size];
+ int recvcounts[comm_size];
+ int recv_sum=0;
- MPI_Datatype MPI_CURRENT_TYPE2;
+ MPI_Datatype MPI_CURRENT_TYPE2 = MPI_DEFAULT_TYPE;
if(action[4+comm_size] && action[5+comm_size]) {
MPI_CURRENT_TYPE=decode_datatype(action[4+comm_size]);
MPI_CURRENT_TYPE2=decode_datatype(action[5+comm_size]);
- } else {
+ } else
MPI_CURRENT_TYPE=MPI_DEFAULT_TYPE;
- MPI_CURRENT_TYPE2=MPI_DEFAULT_TYPE;
- }
+
void *send = smpi_get_tmp_sendbuffer(send_size* smpi_datatype_size(MPI_CURRENT_TYPE));
void *recv = nullptr;
- for(i=0;i<comm_size;i++) {
+ for(int i=0;i<comm_size;i++) {
recvcounts[i] = atoi(action[i+3]);
recv_sum=recv_sum+recvcounts[i];
- disps[i] = 0;
+ disps[i]=0;
}
int root=atoi(action[3+comm_size]);
- int rank = smpi_comm_rank(MPI_COMM_WORLD);
+ int rank = MPI_COMM_WORLD->rank();
if(rank==root)
recv = smpi_get_tmp_recvbuffer(recv_sum* smpi_datatype_size(MPI_CURRENT_TYPE2));
extra->type = TRACING_GATHERV;
extra->send_size = send_size;
extra->recvcounts= xbt_new(int,comm_size);
- for(i=0; i< comm_size; i++)//copy data to avoid bad free
+ for(int i=0; i< comm_size; i++)//copy data to avoid bad free
extra->recvcounts[i] = recvcounts[i];
extra->root = root;
extra->num_processes = comm_size;
TRACE_smpi_collective_out(smpi_process_index(), -1, __FUNCTION__);
log_timed_action (action, clock);
- xbt_free(recvcounts);
- xbt_free(disps);
}
static void action_reducescatter(const char *const *action) {
/* The structure of the reducescatter action for the rank 0 (total 4 processes) is the following:
-0 reduceScatter 275427 275427 275427 204020 11346849 0
-
- where:
- 1) The first four values after the name of the action declare the recvcounts array
- 2) The value 11346849 is the amount of instructions
- 3) The last value corresponds to the datatype, see decode_datatype().
-
- We analyze a MPI_Reduce_scatter call to one MPI_Reduce and one MPI_Scatterv. */
+ 0 reduceScatter 275427 275427 275427 204020 11346849 0
+ where:
+ 1) The first four values after the name of the action declare the recvcounts array
+ 2) The value 11346849 is the amount of instructions
+ 3) The last value corresponds to the datatype, see decode_datatype().
+*/
double clock = smpi_process_simulated_elapsed();
- int comm_size = smpi_comm_size(MPI_COMM_WORLD);
+ int comm_size = MPI_COMM_WORLD->size();
CHECK_ACTION_PARAMS(action, comm_size+1, 1)
int comp_size = parse_double(action[2+comm_size]);
- int *recvcounts = xbt_new0(int, comm_size);
- int *disps = xbt_new0(int, comm_size);
- int i=0;
+ int recvcounts[comm_size];
int rank = smpi_process_index();
int size = 0;
if(action[3+comm_size])
else
MPI_CURRENT_TYPE= MPI_DEFAULT_TYPE;
- for(i=0;i<comm_size;i++) {
+ for(int i=0;i<comm_size;i++) {
recvcounts[i] = atoi(action[i+2]);
- disps[i] = 0;
size+=recvcounts[i];
}
extra->type = TRACING_REDUCE_SCATTER;
extra->send_size = 0;
extra->recvcounts= xbt_new(int, comm_size);
- for(i=0; i< comm_size; i++)//copy data to avoid bad free
+ for(int i=0; i< comm_size; i++)//copy data to avoid bad free
extra->recvcounts[i] = recvcounts[i];
extra->datatype1 = encode_datatype(MPI_CURRENT_TYPE, nullptr);
extra->comp_size = comp_size;
void *sendbuf = smpi_get_tmp_sendbuffer(size* smpi_datatype_size(MPI_CURRENT_TYPE));
void *recvbuf = smpi_get_tmp_recvbuffer(size* smpi_datatype_size(MPI_CURRENT_TYPE));
-
- mpi_coll_reduce_scatter_fun(sendbuf, recvbuf, recvcounts, MPI_CURRENT_TYPE, MPI_OP_NULL, MPI_COMM_WORLD);
- smpi_execute_flops(comp_size);
+
+ mpi_coll_reduce_scatter_fun(sendbuf, recvbuf, recvcounts, MPI_CURRENT_TYPE, MPI_OP_NULL, MPI_COMM_WORLD);
+ smpi_execute_flops(comp_size);
TRACE_smpi_collective_out(rank, -1, __FUNCTION__);
- xbt_free(recvcounts);
- xbt_free(disps);
log_timed_action (action, clock);
}
static void action_allgather(const char *const *action) {
/* The structure of the allgather action for the rank 0 (total 4 processes) is the following:
- 0 allGather 275427 275427
-
- where:
- 1) 275427 is the sendcount
- 2) 275427 is the recvcount
- 3) No more values mean that the datatype for sent and receive buffer is the default one, see decode_datatype(). */
+ 0 allGather 275427 275427
+ where:
+ 1) 275427 is the sendcount
+ 2) 275427 is the recvcount
+ 3) No more values mean that the datatype for sent and receive buffer is the default one, see decode_datatype().
+ */
double clock = smpi_process_simulated_elapsed();
CHECK_ACTION_PARAMS(action, 2, 2)
int sendcount=atoi(action[2]);
int recvcount=atoi(action[3]);
- MPI_Datatype MPI_CURRENT_TYPE2;
+ MPI_Datatype MPI_CURRENT_TYPE2 = MPI_DEFAULT_TYPE;
if(action[4] && action[5]) {
MPI_CURRENT_TYPE = decode_datatype(action[4]);
MPI_CURRENT_TYPE2 = decode_datatype(action[5]);
- } else {
+ } else
MPI_CURRENT_TYPE = MPI_DEFAULT_TYPE;
- MPI_CURRENT_TYPE2 = MPI_DEFAULT_TYPE;
- }
+
void *sendbuf = smpi_get_tmp_sendbuffer(sendcount* smpi_datatype_size(MPI_CURRENT_TYPE));
void *recvbuf = smpi_get_tmp_recvbuffer(recvcount* smpi_datatype_size(MPI_CURRENT_TYPE2));
extra->recv_size= recvcount;
extra->datatype1 = encode_datatype(MPI_CURRENT_TYPE, nullptr);
extra->datatype2 = encode_datatype(MPI_CURRENT_TYPE2, nullptr);
- extra->num_processes = smpi_comm_size(MPI_COMM_WORLD);
+ extra->num_processes = MPI_COMM_WORLD->size();
TRACE_smpi_collective_in(rank, -1, __FUNCTION__,extra);
static void action_allgatherv(const char *const *action) {
/* The structure of the allgatherv action for the rank 0 (total 4 processes) is the following:
-0 allGatherV 275427 275427 275427 275427 204020
-
- where:
- 1) 275427 is the sendcount
- 2) The next four elements declare the recvcounts array
- 3) No more values mean that the datatype for sent and receive buffer
- is the default one, see decode_datatype(). */
+ 0 allGatherV 275427 275427 275427 275427 204020
+ where:
+ 1) 275427 is the sendcount
+ 2) The next four elements declare the recvcounts array
+ 3) No more values mean that the datatype for sent and receive buffer is the default one, see decode_datatype().
+ */
double clock = smpi_process_simulated_elapsed();
- int comm_size = smpi_comm_size(MPI_COMM_WORLD);
+ int comm_size = MPI_COMM_WORLD->size();
CHECK_ACTION_PARAMS(action, comm_size+1, 2)
- int i=0;
int sendcount=atoi(action[2]);
- int *recvcounts = xbt_new0(int, comm_size);
- int *disps = xbt_new0(int, comm_size);
- int recv_sum=0;
- MPI_Datatype MPI_CURRENT_TYPE2;
+ int recvcounts[comm_size];
+ int disps[comm_size];
+ int recv_sum=0;
+ MPI_Datatype MPI_CURRENT_TYPE2 = MPI_DEFAULT_TYPE;
if(action[3+comm_size] && action[4+comm_size]) {
MPI_CURRENT_TYPE = decode_datatype(action[3+comm_size]);
MPI_CURRENT_TYPE2 = decode_datatype(action[4+comm_size]);
- } else {
+ } else
MPI_CURRENT_TYPE = MPI_DEFAULT_TYPE;
- MPI_CURRENT_TYPE2 = MPI_DEFAULT_TYPE;
- }
+
void *sendbuf = smpi_get_tmp_sendbuffer(sendcount* smpi_datatype_size(MPI_CURRENT_TYPE));
- for(i=0;i<comm_size;i++) {
+ for(int i=0;i<comm_size;i++) {
recvcounts[i] = atoi(action[i+3]);
recv_sum=recv_sum+recvcounts[i];
+ disps[i] = 0;
}
void *recvbuf = smpi_get_tmp_recvbuffer(recv_sum* smpi_datatype_size(MPI_CURRENT_TYPE2));
extra->type = TRACING_ALLGATHERV;
extra->send_size = sendcount;
extra->recvcounts= xbt_new(int, comm_size);
- for(i=0; i< comm_size; i++)//copy data to avoid bad free
+ for(int i=0; i< comm_size; i++)//copy data to avoid bad free
extra->recvcounts[i] = recvcounts[i];
extra->datatype1 = encode_datatype(MPI_CURRENT_TYPE, nullptr);
extra->datatype2 = encode_datatype(MPI_CURRENT_TYPE2, nullptr);
TRACE_smpi_collective_out(rank, -1, __FUNCTION__);
log_timed_action (action, clock);
- xbt_free(recvcounts);
- xbt_free(disps);
}
static void action_allToAllv(const char *const *action) {
/* The structure of the allToAllV action for the rank 0 (total 4 processes) is the following:
- 0 allToAllV 100 1 7 10 12 100 1 70 10 5
-
- where:
- 1) 100 is the size of the send buffer *sizeof(int),
- 2) 1 7 10 12 is the sendcounts array
- 3) 100*sizeof(int) is the size of the receiver buffer
- 4) 1 70 10 5 is the recvcounts array */
+ 0 allToAllV 100 1 7 10 12 100 1 70 10 5
+ where:
+ 1) 100 is the size of the send buffer *sizeof(int),
+ 2) 1 7 10 12 is the sendcounts array
+ 3) 100*sizeof(int) is the size of the receiver buffer
+ 4) 1 70 10 5 is the recvcounts array
+ */
double clock = smpi_process_simulated_elapsed();
- int comm_size = smpi_comm_size(MPI_COMM_WORLD);
+ int comm_size = MPI_COMM_WORLD->size();
CHECK_ACTION_PARAMS(action, 2*comm_size+2, 2)
- int *sendcounts = xbt_new0(int, comm_size);
- int *recvcounts = xbt_new0(int, comm_size);
- int *senddisps = xbt_new0(int, comm_size);
- int *recvdisps = xbt_new0(int, comm_size);
+ int sendcounts[comm_size];
+ int recvcounts[comm_size];
+ int senddisps[comm_size];
+ int recvdisps[comm_size];
- MPI_Datatype MPI_CURRENT_TYPE2;
+ MPI_Datatype MPI_CURRENT_TYPE2 = MPI_DEFAULT_TYPE;
int send_buf_size=parse_double(action[2]);
int recv_buf_size=parse_double(action[3+comm_size]);
MPI_CURRENT_TYPE=decode_datatype(action[4+2*comm_size]);
MPI_CURRENT_TYPE2=decode_datatype(action[5+2*comm_size]);
}
- else{
+ else
MPI_CURRENT_TYPE=MPI_DEFAULT_TYPE;
- MPI_CURRENT_TYPE2=MPI_DEFAULT_TYPE;
- }
void *sendbuf = smpi_get_tmp_sendbuffer(send_buf_size* smpi_datatype_size(MPI_CURRENT_TYPE));
void *recvbuf = smpi_get_tmp_recvbuffer(recv_buf_size* smpi_datatype_size(MPI_CURRENT_TYPE2));
for(int i=0;i<comm_size;i++) {
sendcounts[i] = atoi(action[i+3]);
recvcounts[i] = atoi(action[i+4+comm_size]);
+ senddisps[i] = 0;
+ recvdisps[i] = 0;
}
int rank = smpi_process_index();
TRACE_smpi_collective_out(rank, -1, __FUNCTION__);
log_timed_action (action, clock);
- xbt_free(sendcounts);
- xbt_free(recvcounts);
- xbt_free(senddisps);
- xbt_free(recvdisps);
}
void smpi_replay_run(int *argc, char***argv){
xbt_replay_action_runner(*argc, *argv);
/* and now, finalize everything */
- double sim_time= 1.;
/* One active process will stop. Decrease the counter*/
XBT_DEBUG("There are %zu elements in reqq[*]", get_reqq_self()->size());
if (!get_reqq_self()->empty()){
i++;
}
smpi_mpi_waitall(count_requests, requests, status);
- active_processes--;
- } else {
- active_processes--;
}
+ delete get_reqq_self();
+ active_processes--;
if(active_processes==0){
- /* Last process alive speaking */
- /* end the simulated timer */
- sim_time = smpi_process_simulated_elapsed();
- XBT_INFO("Simulation time %f", sim_time);
+ /* Last process alive speaking: end the simulated timer */
+ XBT_INFO("Simulation time %f", smpi_process_simulated_elapsed());
_xbt_replay_action_exit();
xbt_free(sendbuffer);
xbt_free(recvbuffer);
