DragonFly On-Line Manual Pages
LAMTRACE(1) LAM COMMANDS LAMTRACE(1)
lamtrace - Unload LAM trace data.
lamtrace [-hkvR] [-mpi] [-l listno] [-f #secs] [filename] [nodes]
-h Print useful information on this command.
-k Copy and do not remove trace data.
-v Be verbose.
-R Delete all trace data from the specified nodes.
-l Unload only from the given list number.
-mpi Unload trace data for an MPI application.
-f #secs Signal target processes to flush trace data to the
daemon. Then wait #secs before unloading.
filename Place trace data into this file (default: def.lamtr).
The -t option of mpirun(1) and loadgo(1) allows the application to
generate execution traces. These traces are first stored in a buffer
within each application process. When the buffer is full and when the
application terminates, the runtime buffer is flushed to the trace
daemon (a structural component within the LAM daemon). The trace
daemon will also collect data up to a pre-compiled limit. Beyond this
limit, the oldest traces in will be forgotten in favor of the newer
After an application has finished, the record of its execution is
stored in the trace daemons of each node that was running the
application. The lamtrace command can be used to retrieve these traces
and store them in one file for display by a performance visualization
tool, such as xmpi(1). If the application was started by xmpi(1),
lamtrace is not normally needed as the equivalent functionality is
invoked with a button.
Incomplete trace data can be unloaded while the application is running.
The output file must not exist prior to invoking lamtrace. This is a
good situation to use the -k option, which preserves the trace daemon's
contents after unloading. Each reload will then get the entire run's
trace data up to the present time.
A running process is likely to be holding the most recent trace data in
an internal buffer. A standard LAM signal, LAM_SIGTRACE (see doom(1)),
causes trace enabled processes to flush the internal trace buffer to
the daemon. The -f option tells lamtrace to send this signal to all
target processes before unloading trace data. A race condition
develops between the target process storing trace data to the daemon
and the unloading procedure. The problem is foisted upon the user who
gives a delay parameter after -f.
Trace data are organized by node, process identifier and list number.
A process can store traces on any node, although the local node is the
obvious, least intrusive choice. The process can identify itself in
any meaningful way (getpid(2) is a good idea) The list number is also
chosen by the process. These values may be set by an instrumented
library, such as libmpi(3), or directly by the application with
lam_rtrstore(2). Unloading flexibility follows that of storing with
the -l option selecting the list number, and standard LAM command line
mnemonics selecting nodes and processes.
Dropping old traces when a pre-compiled volume limit is reached only
happens for positive list numbers. Traces in negatively numbered lists
will be collected until the underlying system runs out of memory. Do
not use negative list numbers for high volume trace data.
If no process selection is given on the command line, trace data will
be unloaded for all processes on each specified node.
LAM, its trace daemon and lamtrace are all unaware of the format and
meaning of traces.
The -R option does not unload trace data. It causes the target trace
daemons to free the memory occupied by trace data in the given list.
If all lists are specified (no -l option), the trace daemon is
effectively reset to its state after initiating LAM.
Unloading MPI Trace Data
A special capability, selected by the -mpi option, exists to search for
and unload only the trace data generated by an MPI application. For
this purpose, lamtrace is aware of the particular reserved list numbers
that libmpi(3) uses to store traces. It begins by searching all
specified nodes and processes (the whole LAM multicomputer, if nothing
is specified) for a special trace generated by process rank 0 in
MPI_COMM_WORLD of an MPI application. This special trace contains the
node and process identifiers of all processes in that MPI_COMM_WORLD
communicator. lamtrace then uses the node / process information to
collect all trace data generated by libmpi(3).
If multiple world communicators exist within LAM's trace daemons, the
first one found is used. Multiple worlds may be present due to
multiple concurrent applications, trace data from a previous run not
removed (either with lamtrace or lamclean(1)), or an application that
spawns processes. A particular world communicator can be located by
providing precise node and process location to lamtrace.
The -mpi option is not compatible with the -l option.
lamtrace -v -mpi mytraces
Unload trace data into the file "mytraces" from the first MPI
application found in a search of the entire LAM multicomputer.
Report on important steps as they are done.
lamtrace n30 -l 5 p21367
Unload trace data from list 5 of process ID 21367 on node 30.
lamtrace -mpi n30 p21367
Unload trace data from the MPI application world group whose
process rank 0 has PID 21367 and is/was running on node 30.
Since trace data can be unloaded during an application's execution,
there should be a way to incrementally append to an output file. This
is a bit tricky with -mpi, but it can be done.
def.lamtr default output file
mpirun(1), loadgo(1), lam_rtrstore(1), lamclean(1), libmpi(3), xmpi(1)
LAM 7.1.5b2 June, 2008 LAMTRACE(1)