}
/* Helper function */
-static double parse_double(std::string string)
+static double parse_double(const std::string& string)
{
return xbt_str_parse_double(string.c_str(), "%s is not a double");
}
}
};
-void WaitTestParser::parse(simgrid::xbt::ReplayAction& action, std::string)
+void WaitTestParser::parse(simgrid::xbt::ReplayAction& action, const std::string&)
{
CHECK_ACTION_PARAMS(action, 3, 0)
src = std::stoi(action[2]);
tag = std::stoi(action[4]);
}
-void SendRecvParser::parse(simgrid::xbt::ReplayAction& action, std::string)
+void SendRecvParser::parse(simgrid::xbt::ReplayAction& action, const std::string&)
{
CHECK_ACTION_PARAMS(action, 3, 1)
partner = std::stoi(action[2]);
datatype1 = simgrid::smpi::Datatype::decode(action[5]);
}
-void ComputeParser::parse(simgrid::xbt::ReplayAction& action, std::string)
+void ComputeParser::parse(simgrid::xbt::ReplayAction& action, const std::string&)
{
CHECK_ACTION_PARAMS(action, 1, 0)
flops = parse_double(action[2]);
}
-void BcastArgParser::parse(simgrid::xbt::ReplayAction& action, std::string)
+void BcastArgParser::parse(simgrid::xbt::ReplayAction& action, const std::string&)
{
CHECK_ACTION_PARAMS(action, 1, 2)
size = parse_double(action[2]);
datatype1 = simgrid::smpi::Datatype::decode(action[4]);
}
-void ReduceArgParser::parse(simgrid::xbt::ReplayAction& action, std::string)
+void ReduceArgParser::parse(simgrid::xbt::ReplayAction& action, const std::string&)
{
CHECK_ACTION_PARAMS(action, 2, 2)
comm_size = parse_double(action[2]);
datatype1 = simgrid::smpi::Datatype::decode(action[5]);
}
-void AllReduceArgParser::parse(simgrid::xbt::ReplayAction& action, std::string)
+void AllReduceArgParser::parse(simgrid::xbt::ReplayAction& action, const std::string&)
{
CHECK_ACTION_PARAMS(action, 2, 1)
comm_size = parse_double(action[2]);
datatype1 = simgrid::smpi::Datatype::decode(action[4]);
}
-void AllToAllArgParser::parse(simgrid::xbt::ReplayAction& action, std::string)
+void AllToAllArgParser::parse(simgrid::xbt::ReplayAction& action, const std::string&)
{
CHECK_ACTION_PARAMS(action, 2, 1)
comm_size = MPI_COMM_WORLD->size();
datatype2 = simgrid::smpi::Datatype::decode(action[5]);
}
-void GatherArgParser::parse(simgrid::xbt::ReplayAction& action, std::string name)
+void GatherArgParser::parse(simgrid::xbt::ReplayAction& action, const std::string& name)
{
/* The structure of the gather action for the rank 0 (total 4 processes) is the following:
0 gather 68 68 0 0 0
}
}
-void GatherVArgParser::parse(simgrid::xbt::ReplayAction& action, std::string name)
+void GatherVArgParser::parse(simgrid::xbt::ReplayAction& action, const std::string& name)
{
/* 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
recv_size_sum = std::accumulate(recvcounts->begin(), recvcounts->end(), 0);
}
-void ScatterArgParser::parse(simgrid::xbt::ReplayAction& action, std::string)
+void ScatterArgParser::parse(simgrid::xbt::ReplayAction& action, const std::string&)
{
/* The structure of the scatter action for the rank 0 (total 4 processes) is the following:
0 gather 68 68 0 0 0
datatype2 = simgrid::smpi::Datatype::decode(action[6]);
}
-void ScatterVArgParser::parse(simgrid::xbt::ReplayAction& action, std::string)
+void ScatterVArgParser::parse(simgrid::xbt::ReplayAction& action, const std::string&)
{
/* The structure of the scatterv action for the rank 0 (total 4 processes) is the following:
0 gather 68 10 10 10 68 0 0 0
root = (action.size() > 3 + comm_size) ? std::stoi(action[3 + comm_size]) : 0;
}
-void ReduceScatterArgParser::parse(simgrid::xbt::ReplayAction& action, std::string)
+void ReduceScatterArgParser::parse(simgrid::xbt::ReplayAction& action, const std::string&)
{
/* The structure of the reducescatter action for the rank 0 (total 4 processes) is the following:
0 reducescatter 275427 275427 275427 204020 11346849 0
recv_size_sum = std::accumulate(recvcounts->begin(), recvcounts->end(), 0);
}
-void AllToAllVArgParser::parse(simgrid::xbt::ReplayAction& action, std::string)
+void AllToAllVArgParser::parse(simgrid::xbt::ReplayAction& action, const std::string&)
{
/* 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
args.size = status.count;
}
- bool is_recv = false;
+ bool is_recv = false; // Help analyzers understanding that status is not used unintialized
if (name == "recv") {
- Request::recv(nullptr, args.size, args.datatype1, args.partner, args.tag, MPI_COMM_WORLD, &status);
is_recv = true;
+ Request::recv(nullptr, args.size, args.datatype1, args.partner, args.tag, MPI_COMM_WORLD, &status);
} else if (name == "irecv") {
MPI_Request request = Request::irecv(nullptr, args.size, args.datatype1, args.partner, args.tag, MPI_COMM_WORLD);
req_storage.add(request);
+ } else {
+ THROW_IMPOSSIBLE;
}
TRACE_smpi_comm_out(my_proc_id);
void ComputeAction::kernel(simgrid::xbt::ReplayAction&)
{
- TRACE_smpi_computing_in(my_proc_id, args.flops);
smpi_execute_flops(args.flops);
- TRACE_smpi_computing_out(my_proc_id);
}
void TestAction::kernel(simgrid::xbt::ReplayAction&)
TRACE_smpi_comm_in(my_proc_id, __func__, new simgrid::instr::NoOpTIData("test"));
MPI_Status status;
- int flag = Request::test(&request, &status);
+ int flag = 0;
+ Request::test(&request, &status, &flag);
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
Colls::reduce(send_buffer(args.comm_size * args.datatype1->size()),
recv_buffer(args.comm_size * args.datatype1->size()), args.comm_size, args.datatype1, MPI_OP_NULL, args.root, MPI_COMM_WORLD);
- smpi_execute_flops(args.comp_size);
+ private_execute_flops(args.comp_size);
TRACE_smpi_comm_out(my_proc_id);
}
Colls::allreduce(send_buffer(args.comm_size * args.datatype1->size()),
recv_buffer(args.comm_size * args.datatype1->size()), args.comm_size, args.datatype1, MPI_OP_NULL, MPI_COMM_WORLD);
- smpi_execute_flops(args.comp_size);
+ private_execute_flops(args.comp_size);
TRACE_smpi_comm_out(my_proc_id);
}
recv_buffer(args.recv_size_sum * args.datatype1->size()), args.recvcounts->data(),
args.datatype1, MPI_OP_NULL, MPI_COMM_WORLD);
- smpi_execute_flops(args.comp_size);
+ private_execute_flops(args.comp_size);
TRACE_smpi_comm_out(my_proc_id);
}
/** @brief Only initialize the replay, don't do it for real */
void smpi_replay_init(const char* instance_id, int rank, double start_delay_flops)
{
- if (not smpi_process()->initializing()){
- simgrid::s4u::Actor::self()->set_property("instance_id", instance_id);
- simgrid::s4u::Actor::self()->set_property("rank", std::to_string(rank));
- simgrid::smpi::ActorExt::init();
- }
+ xbt_assert(not smpi_process()->initializing());
+
+ simgrid::s4u::Actor::self()->set_property("instance_id", instance_id);
+ simgrid::s4u::Actor::self()->set_property("rank", std::to_string(rank));
+ simgrid::smpi::ActorExt::init();
+
smpi_process()->mark_as_initialized();
smpi_process()->set_replaying(true);
//if we have a delayed start, sleep here.
if (start_delay_flops > 0) {
XBT_VERB("Delayed start for instance - Sleeping for %f flops ", start_delay_flops);
- smpi_execute_flops(start_delay_flops);
+ private_execute_flops(start_delay_flops);
} else {
// Wait for the other actors to initialize also
simgrid::s4u::this_actor::yield();