-/* Copyright (c) 2007-2018. The SimGrid Team. All rights reserved. */
+/* Copyright (c) 2007-2019. 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 "smpi_win.hpp"
+
#include "private.hpp"
#include "smpi_coll.hpp"
#include "smpi_comm.hpp"
#include "smpi_datatype.hpp"
#include "smpi_info.hpp"
#include "smpi_keyvals.hpp"
-#include "smpi_process.hpp"
#include "smpi_request.hpp"
+#include "src/smpi/include/smpi_actor.hpp"
XBT_LOG_NEW_DEFAULT_SUBCATEGORY(smpi_rma, smpi, "Logging specific to SMPI (RMA operations)");
-using simgrid::s4u::Actor;
namespace simgrid{
namespace smpi{
opened_ = 0;
group_ = MPI_GROUP_NULL;
requests_ = new std::vector<MPI_Request>();
- mut_ = xbt_mutex_init();
- lock_mut_ = xbt_mutex_init();
- atomic_mut_ = xbt_mutex_init();
+ mut_ = s4u::Mutex::create();
+ lock_mut_ = s4u::Mutex::create();
+ atomic_mut_ = s4u::Mutex::create();
connected_wins_ = new MPI_Win[comm_size];
connected_wins_[rank_] = this;
count_ = 0;
if(rank_==0){
- bar_ = new simgrid::s4u::Barrier(comm_size);
+ bar_ = new s4u::Barrier(comm_size);
}
mode_=0;
-
+ errhandler_=MPI_ERRORS_ARE_FATAL;
comm->add_rma_win(this);
comm->ref();
Colls::allgather(&(connected_wins_[rank_]), sizeof(MPI_Win), MPI_BYTE, connected_wins_, sizeof(MPI_Win),
MPI_BYTE, comm);
- Colls::bcast(&(bar_), sizeof(simgrid::s4u::Barrier*), MPI_BYTE, 0, comm);
+ Colls::bcast(&(bar_), sizeof(s4u::Barrier*), MPI_BYTE, 0, comm);
Colls::barrier(comm);
}
if (rank_ == 0)
delete bar_;
- xbt_mutex_destroy(mut_);
- xbt_mutex_destroy(lock_mut_);
- xbt_mutex_destroy(atomic_mut_);
if(allocated_ !=0)
xbt_free(base_);
cleanup_attr<Win>();
}
-int Win::attach (void *base, MPI_Aint size){
+int Win::attach(void* /*base*/, MPI_Aint size)
+{
if (not(base_ == MPI_BOTTOM || base_ == 0))
return MPI_ERR_ARG;
base_=0;//actually the address will be given in the RMA calls, as being the disp.
return MPI_SUCCESS;
}
-int Win::detach (void *base){
+int Win::detach(const void* /*base*/)
+{
base_=MPI_BOTTOM;
size_=-1;
return MPI_SUCCESS;
info_=info;
}
-void Win::set_name(char* name){
+void Win::set_name(const char* name){
name_ = xbt_strdup(name);
}
if (assert != MPI_MODE_NOPRECEDE) {
// This is not the first fence => finalize what came before
bar_->wait();
- xbt_mutex_acquire(mut_);
+ mut_->lock();
// This (simulated) mutex ensures that no process pushes to the vector of requests during the waitall.
// Without this, the vector could get redimensionned when another process pushes.
// This would result in the array used by Request::waitall() to be invalidated.
Request::waitall(size, treqs, MPI_STATUSES_IGNORE);
}
count_=0;
- xbt_mutex_release(mut_);
+ mut_->unlock();
}
if(assert==MPI_MODE_NOSUCCEED)//there should be no ops after this one, tell we are closed.
return MPI_SUCCESS;
}
-int Win::put( void *origin_addr, int origin_count, MPI_Datatype origin_datatype, int target_rank,
+int Win::put(const void *origin_addr, int origin_count, MPI_Datatype origin_datatype, int target_rank,
MPI_Aint target_disp, int target_count, MPI_Datatype target_datatype, MPI_Request* request)
{
//get receiver pointer
if(request!=nullptr){
*request=sreq;
}else{
- xbt_mutex_acquire(mut_);
+ mut_->lock();
requests_->push_back(sreq);
- xbt_mutex_release(mut_);
+ mut_->unlock();
}
//push request to receiver's win
- xbt_mutex_acquire(recv_win->mut_);
+ recv_win->mut_->lock();
recv_win->requests_->push_back(rreq);
rreq->start();
- xbt_mutex_release(recv_win->mut_);
+ recv_win->mut_->unlock();
}else{
XBT_DEBUG("Entering MPI_Put from myself to myself, rank %d", target_rank);
//start the send, with another process than us as sender.
sreq->start();
//push request to receiver's win
- xbt_mutex_acquire(send_win->mut_);
+ send_win->mut_->lock();
send_win->requests_->push_back(sreq);
- xbt_mutex_release(send_win->mut_);
+ send_win->mut_->unlock();
//start recv
rreq->start();
if(request!=nullptr){
*request=rreq;
}else{
- xbt_mutex_acquire(mut_);
+ mut_->lock();
requests_->push_back(rreq);
- xbt_mutex_release(mut_);
+ mut_->unlock();
}
}else{
}
-int Win::accumulate( void *origin_addr, int origin_count, MPI_Datatype origin_datatype, int target_rank,
+int Win::accumulate(const void *origin_addr, int origin_count, MPI_Datatype origin_datatype, int target_rank,
MPI_Aint target_disp, int target_count, MPI_Datatype target_datatype, MPI_Op op, MPI_Request* request)
{
XBT_DEBUG("Entering MPI_Win_Accumulate");
// start send
sreq->start();
// push request to receiver's win
- xbt_mutex_acquire(recv_win->mut_);
+ recv_win->mut_->lock();
recv_win->requests_->push_back(rreq);
rreq->start();
- xbt_mutex_release(recv_win->mut_);
+ recv_win->mut_->unlock();
if (request != nullptr) {
*request = sreq;
} else {
- xbt_mutex_acquire(mut_);
+ mut_->lock();
requests_->push_back(sreq);
- xbt_mutex_release(mut_);
+ mut_->unlock();
}
XBT_DEBUG("Leaving MPI_Win_Accumulate");
return MPI_SUCCESS;
}
-int Win::get_accumulate( void *origin_addr, int origin_count, MPI_Datatype origin_datatype, void *result_addr,
- int result_count, MPI_Datatype result_datatype, int target_rank, MPI_Aint target_disp, int target_count,
- MPI_Datatype target_datatype, MPI_Op op, MPI_Request* request){
-
+int Win::get_accumulate(const void* origin_addr, int origin_count, MPI_Datatype origin_datatype, void* result_addr,
+ int result_count, MPI_Datatype result_datatype, int target_rank, MPI_Aint target_disp,
+ int target_count, MPI_Datatype target_datatype, MPI_Op op, MPI_Request*)
+{
//get sender pointer
MPI_Win send_win = connected_wins_[target_rank];
XBT_DEBUG("Entering MPI_Get_accumulate from %d", target_rank);
//need to be sure ops are correctly ordered, so finish request here ? slow.
MPI_Request req;
- xbt_mutex_acquire(send_win->atomic_mut_);
+ send_win->atomic_mut_->lock();
get(result_addr, result_count, result_datatype, target_rank,
target_disp, target_count, target_datatype, &req);
if (req != MPI_REQUEST_NULL)
target_disp, target_count, target_datatype, op, &req);
if (req != MPI_REQUEST_NULL)
Request::wait(&req, MPI_STATUS_IGNORE);
- xbt_mutex_release(send_win->atomic_mut_);
+ send_win->atomic_mut_->unlock();
return MPI_SUCCESS;
}
-int Win::compare_and_swap(void *origin_addr, void *compare_addr,
+int Win::compare_and_swap(const void *origin_addr, void *compare_addr,
void *result_addr, MPI_Datatype datatype, int target_rank,
MPI_Aint target_disp){
//get sender pointer
XBT_DEBUG("Entering MPI_Compare_and_swap with %d", target_rank);
MPI_Request req = MPI_REQUEST_NULL;
- xbt_mutex_acquire(send_win->atomic_mut_);
+ send_win->atomic_mut_->lock();
get(result_addr, 1, datatype, target_rank,
target_disp, 1, datatype, &req);
if (req != MPI_REQUEST_NULL)
put(origin_addr, 1, datatype, target_rank,
target_disp, 1, datatype);
}
- xbt_mutex_release(send_win->atomic_mut_);
+ send_win->atomic_mut_->unlock();
return MPI_SUCCESS;
}
-int Win::start(MPI_Group group, int assert){
+int Win::start(MPI_Group group, int /*assert*/)
+{
/* From MPI forum advices
The call to MPI_WIN_COMPLETE does not return until the put call has completed at the origin; and the target window
will be accessed by the put operation only after the call to MPI_WIN_START has matched a call to MPI_WIN_POST by
return MPI_SUCCESS;
}
-int Win::post(MPI_Group group, int assert){
+int Win::post(MPI_Group group, int /*assert*/)
+{
//let's make a synchronous send here
int i = 0;
int j = 0;
return MPI_SUCCESS;
}
-int Win::lock(int lock_type, int rank, int assert){
+int Win::lock(int lock_type, int rank, int /*assert*/)
+{
MPI_Win target_win = connected_wins_[rank];
if ((lock_type == MPI_LOCK_EXCLUSIVE && target_win->mode_ != MPI_LOCK_SHARED)|| target_win->mode_ == MPI_LOCK_EXCLUSIVE){
- xbt_mutex_acquire(target_win->lock_mut_);
+ target_win->lock_mut_->lock();
target_win->mode_+= lock_type;//add the lock_type to differentiate case when we are switching from EXCLUSIVE to SHARED (no release needed in the unlock)
if(lock_type == MPI_LOCK_SHARED){//the window used to be exclusive, it's now shared.
- xbt_mutex_release(target_win->lock_mut_);
+ target_win->lock_mut_->unlock();
}
} else if (not(target_win->mode_ == MPI_LOCK_SHARED && lock_type == MPI_LOCK_EXCLUSIVE))
target_win->mode_ += lock_type; // don't set to exclusive if it's already shared
target_win->mode_= 0;
target_win->lockers_.remove(comm_->rank());
if (target_mode==MPI_LOCK_EXCLUSIVE){
- xbt_mutex_release(target_win->lock_mut_);
+ target_win->lock_mut_->unlock();
}
int finished = finish_comms(rank);
}
int Win::finish_comms(){
- xbt_mutex_acquire(mut_);
+ mut_->lock();
//Finish own requests
std::vector<MPI_Request> *reqqs = requests_;
int size = static_cast<int>(reqqs->size());
Request::waitall(size, treqs, MPI_STATUSES_IGNORE);
reqqs->clear();
}
- xbt_mutex_release(mut_);
+ mut_->unlock();
return size;
}
int Win::finish_comms(int rank){
- xbt_mutex_acquire(mut_);
+ mut_->lock();
//Finish own requests
std::vector<MPI_Request> *reqqs = requests_;
int size = static_cast<int>(reqqs->size());
myreqqs.clear();
}
}
- xbt_mutex_release(mut_);
+ mut_->unlock();
return size;
}
}
return MPI_SUCCESS;
}
+
+MPI_Errhandler Win::errhandler(){
+ return errhandler_;
+}
+
+void Win::set_errhandler(MPI_Errhandler errhandler){
+ errhandler_=errhandler;
+ if(errhandler_!= MPI_ERRHANDLER_NULL)
+ errhandler->ref();
+}
+
}
}