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= Introduction =
<languages />
[[Category:Software]] [[Category:Pages with video links]]
<translate>
= Introduction = <!--T:1-->


[https://www.arm.com/products/development-tools/hpc-tools/cross-platform/forge/ddt Allinea's DDT] (now called ARM DDT after Allinea was acquired by ARM) is a powerful commercial parallel debugger with GUI interface which can be used to debug serial, MPI, multi-threaded, and CUDA codes (and any combination of the above) written in C, C++ and FORTRAN. [https://www.arm.com/products/development-tools/hpc-tools/cross-platform/forge/map MAP] is another very useful tool from Allinea (now ARM) - an efficient parallel profiler.
<!--T:2-->
[https://www.arm.com/products/development-tools/hpc-tools/cross-platform/forge/ddt ARM DDT] (formerly know as Allinea DDT) is a powerful commercial parallel debugger with a graphical user interface. It can be used to debug serial, MPI, multi-threaded, and CUDA programs, or any combination of the above, written in C, C++, and FORTRAN. [https://www.arm.com/products/development-tools/hpc-tools/cross-platform/forge/map MAP]—an efficient parallel profiler—is another very useful tool from ARM (formerly Allinea).


This software is available on Graham as two separate modules - allinea-cpu (for CPU debugging and profiling) and allinea-gpu (for GPU or mixed CPU/GPU debugging). As this is a GUI application, one has to login to Graham using "-Y" or "-X" ssh switch, for proper X tunelling. For Windows terminals, we recommend using a free program [https://mobaxterm.mobatek.net/download-home-edition.html MobaXterm (Home Edition)] which has everything you need to run DDT - SSH client and X Windows client (also SFTP, VNC and many other services). For Mac you need to install a free X WIndows client [https://www.xquartz.org/ XQuartz].
<!--T:3-->
The following modules are available on Graham:
* ddt-cpu, for CPU debugging and profiling;
* ddt-gpu, for GPU or mixed CPU/GPU debugging.


Both DDT and MAP are normally used interactively through their GUI, which on Graham is accomplished via "salloc" command (see below for the details). MAP can also be used non-interactively in a batch mode, in which case it can be submitted to the scheduler via sbatch command.
<!--T:38-->
The following module is available on Niagara:
* ddt


The current license limits the CPU DDT/MAP use to maximum 512 cpu cores across all users at any given time. For GPU DDT the limit is 8 GPUs.
<!--T:39-->
As this is a GUI application, log in using <code>ssh -Y</code>, and use an [[SSH|SSH client]] like [[Connecting with MobaXTerm|MobaXTerm]] (Windows) or [https://www.xquartz.org/ XQuartz] (Mac) to ensure proper X11 tunnelling.


<!--T:4-->
Both DDT and MAP are normally used interactively through their GUI, which is normally accomplished using the <code>salloc</code> command (see below for details). MAP can also be used non-interactively, in which case it can be submitted to the scheduler with the <code>sbatch</code> command.


= Usage =
<!--T:5-->
== CPU-only (non-CUDA) code ==
The current license limits the use of DDT/MAP to a maximum of 512 CPU cores across all users at any given time, while DDT-GPU is limited to 8 GPUs.


First one has to allocate the node(s) for the debugging / profiling job with salloc (accepts many of the sbatch arguments), e.g.:
= Usage = <!--T:6-->
== CPU-only code, no GPUs ==


<!--T:7-->
1. Allocate the node or nodes on which to do the debugging or profiling. This will open a shell session on the allocated node.
<!--T:8-->
  salloc --x11 --time=0-1:00 --mem-per-cpu=4G --ntasks=4
  salloc --x11 --time=0-1:00 --mem-per-cpu=4G --ntasks=4


Once the resource is allocated, you will get the shell at the allocated node. There you have to load the corresponding module:
<!--T:9-->
2. Load the appropriate module, for example


  module load allinea-cpu
<!--T:10-->
  module load ddt-cpu


The above command will likely fail with a suggestion to load another (older) version of OpenMPI first. If that happens, you should reload the OpenMPI module with the suggested command, and then load the allinea-cpu module:
<!--T:13-->
3. Run the ddt or map command.
 
<!--T:14-->
ddt path/to/code
  map path/to/code


module load openmpi/2.0.2
<!--T:15-->
module load allinea-cpu
:: Make sure the MPI implementation is the default OpenMPI in the DDT/MAP application window, before pressing the ''Run'' button. If this is not the case, press the ''Change'' button next to the ''Implementation:'' string, and select the correct option from the drop-down menu. Also, specify the desired number of cpu cores in this window.


You can then run the ddt or map command as:
<!--T:16-->
4. When done, exit the shell to terminate the allocation.


ddt path/to/code
<!--T:34-->
map path/to/code
IMPORTANT: The current versions of DDT and OpenMPI have a compatibility issue which breaks the important feature of DDT - displaying message queues (available from the "Tools" drop down menu). There is a workaround: before running DDT, you have to execute the following command:


Make sure the MPI implementation is the default "OpenMPI" in the Allinea application window, before pressing the Run button. If this is not the case, press the Change button next to the "Implementation:" string, and pick the correct option from the drop down menu.
<!--T:35-->
$ export OMPI_MCA_pml=ob1


When done, exit the shell (this will terminate the allocation).
<!--T:36-->
Be aware that the above workaround can make your MPI code run slower, so only use this trick when debugging.


== CUDA code ==
== CUDA code == <!--T:17-->


First one has to allocate the node(s) for the debugging job with salloc (accepts many of the sbatch arguments), e.g.:
<!--T:18-->
1. Allocate the node or nodes on which to do the debugging or profiling with <code>salloc</code>. This will open a shell session on the allocated node.  


<!--T:19-->
  salloc --x11 --time=0-1:00 --mem-per-cpu=4G --ntasks=1 --gres=gpu:1
  salloc --x11 --time=0-1:00 --mem-per-cpu=4G --ntasks=1 --gres=gpu:1


Once the resource is allocated, you will get the shell at the allocated node. There you have to load the corresponding module:
<!--T:20-->
2. Load the appropriate module, for example


  module load allinea-gpu
<!--T:21-->
  module load ddt-gpu


The above command can fail with a suggestion to load an older version of OpenMPI first. If that happens, you should reload the OpenMPI module with the suggested command, and then load the allinea-gpu module:
<!--T:22-->
:: This may fail with a suggestion to load an older version of OpenMPI first. In this case, reload the OpenMPI module with the suggested command, and then reload the ddt-gpu module.


<!--T:23-->
  module load openmpi/2.0.2
  module load openmpi/2.0.2
module load allinea-gpu
  module load ddt-gpu


You will also need to make sure a cuda module is loaded:
<!--T:24-->
3. Ensure a cuda module is loaded.


<!--T:25-->
  module load cuda
  module load cuda


You can then run the ddt command as:
<!--T:26-->
4. Run the ddt command.


<!--T:27-->
  ddt path/to/code
  ddt path/to/code


When done, exit the shell (this will terminate the allocation).
<!--T:40-->
If DDT complains about the mismatch between the CUDA driver and toolkit version, execute the following command and the run DDT again (use the version in this command), e.g.
 
<!--T:41-->
export ALLINEA_FORCE_CUDA_VERSION=10.1
 
<!--T:28-->
5. When done, exit the shell to terminate the allocation.
 
== Using VNC to fix the lag == <!--T:51-->
 
<!--T:52-->
[[File:DDT-VNC-1.png|400px|thumb|right|DDT on '''gra-vdi.computecanada.ca''']]
[[File:DDT-VNC-2.png|400px|thumb|right|Program on '''graham.computecanada.ca''']]
 
<!--T:53-->
The instructions above use X11 forwarding. X11 is very sensitive to packet latency. As a result, unless you happen to be on the same campus as the computer cluster, the ddt interface will likely be laggy and frustrating to use. This can be fixed by running ddt under VNC.
 
<!--T:54-->
To do this, follow the directions on our [[VNC|VNC page]] to setup a VNC session. If your VNC session is on the compute node, then you can directly start your program under ddt as above. If you VNC session is on the login node or you are using the graham vdi node, then you need to manual launch the job as follows. From the ddt startup screen
 
<!--T:55-->
* pick the ''manually launch backend yourself'' job start option,
* enter the appropriate information for your job and press the ''listen'' button, and
* press the ''help'' button to the right of ''waiting for you to start the job...''.
 
<!--T:56-->
This will then give you the command you need to run to start your job. Allocate a job on the cluster and start your program as directed. An example of doing this would be (where $USER is your username and $PROGAM ... is the command to start your program)
 
<!--T:57-->
<source lang="bash">[name@cluster-login:~]$ salloc ...
[name@cluster-node:~]$ /cvmfs/restricted.computecanada.ca/easybuild/software/2020/Core/allinea/20.2/bin/forge-client --ddtsessionfile /home/$USER/.allinea/session/gra-vdi3-1 $PROGRAM ...
</source>
 
= Known issues = <!--T:33-->
 
<!--T:42-->
On graham, if you are experiencing issues with getting X11 to work, change permissions on your home directory so that only you have access.
 
<!--T:43-->
First, check (and record if needed) current permissions with
 
<!--T:44-->
  ls -ld /home/$USER
 
<!--T:45-->
The output should begin with:
 
<!--T:46-->
  drwx------
 
<!--T:47-->
If some of the dashes are replaced by letters, that means your group and other users have read, write (unlikely), or execute permissions on your directory.  
 
<!--T:48-->
This command will work to remove read and execute permissions for group and other users:


= Known issues =
<!--T:49-->
  chmod go-rx /home/$USER


=== MPI ===
<!--T:50-->
* For some reason the debugger doesn't show queued MPI messages (e.g. when paused in an MPI deadlock).
After you are done using DDT, you can if you like restore permissions to what they were (assuming you recorded them). More information on how to do this can be found on page [[Sharing_data]].


=== OpenMP ===
= See also = <!--T:37-->
* Memory debugging module (which is off by default) doesn't work.
* [https://youtu.be/Q8HwLg22BpY "Debugging your code with DDT"], video, 55 minutes.
* [[Parallel Debugging with DDT|A short DDT tutorial.]]


=== CUDA ===
</translate>
* Memory debugging module (which is off by default) doesn't work.

Latest revision as of 19:16, 15 July 2024

Other languages:

Introduction[edit]

ARM DDT (formerly know as Allinea DDT) is a powerful commercial parallel debugger with a graphical user interface. It can be used to debug serial, MPI, multi-threaded, and CUDA programs, or any combination of the above, written in C, C++, and FORTRAN. MAP—an efficient parallel profiler—is another very useful tool from ARM (formerly Allinea).

The following modules are available on Graham:

  • ddt-cpu, for CPU debugging and profiling;
  • ddt-gpu, for GPU or mixed CPU/GPU debugging.

The following module is available on Niagara:

  • ddt

As this is a GUI application, log in using ssh -Y, and use an SSH client like MobaXTerm (Windows) or XQuartz (Mac) to ensure proper X11 tunnelling.

Both DDT and MAP are normally used interactively through their GUI, which is normally accomplished using the salloc command (see below for details). MAP can also be used non-interactively, in which case it can be submitted to the scheduler with the sbatch command.

The current license limits the use of DDT/MAP to a maximum of 512 CPU cores across all users at any given time, while DDT-GPU is limited to 8 GPUs.

Usage[edit]

CPU-only code, no GPUs[edit]

1. Allocate the node or nodes on which to do the debugging or profiling. This will open a shell session on the allocated node. 

 salloc --x11 --time=0-1:00 --mem-per-cpu=4G --ntasks=4

2. Load the appropriate module, for example 

 module load ddt-cpu

3. Run the ddt or map command. 

 ddt path/to/code
 map path/to/code
Make sure the MPI implementation is the default OpenMPI in the DDT/MAP application window, before pressing the Run button. If this is not the case, press the Change button next to the Implementation: string, and select the correct option from the drop-down menu. Also, specify the desired number of cpu cores in this window.

4. When done, exit the shell to terminate the allocation.

IMPORTANT: The current versions of DDT and OpenMPI have a compatibility issue which breaks the important feature of DDT - displaying message queues (available from the "Tools" drop down menu). There is a workaround: before running DDT, you have to execute the following command: 

$ export OMPI_MCA_pml=ob1

Be aware that the above workaround can make your MPI code run slower, so only use this trick when debugging.

CUDA code[edit]

1. Allocate the node or nodes on which to do the debugging or profiling with salloc. This will open a shell session on the allocated node. 

 salloc --x11 --time=0-1:00 --mem-per-cpu=4G --ntasks=1 --gres=gpu:1

2. Load the appropriate module, for example 

 module load ddt-gpu
This may fail with a suggestion to load an older version of OpenMPI first. In this case, reload the OpenMPI module with the suggested command, and then reload the ddt-gpu module.
 module load openmpi/2.0.2
 module load ddt-gpu

3. Ensure a cuda module is loaded. 

 module load cuda

4. Run the ddt command. 

 ddt path/to/code

If DDT complains about the mismatch between the CUDA driver and toolkit version, execute the following command and the run DDT again (use the version in this command), e.g. 

export ALLINEA_FORCE_CUDA_VERSION=10.1

5. When done, exit the shell to terminate the allocation.

Using VNC to fix the lag[edit]

DDT on gra-vdi.computecanada.ca
Program on graham.computecanada.ca

The instructions above use X11 forwarding. X11 is very sensitive to packet latency. As a result, unless you happen to be on the same campus as the computer cluster, the ddt interface will likely be laggy and frustrating to use. This can be fixed by running ddt under VNC.

To do this, follow the directions on our VNC page to setup a VNC session. If your VNC session is on the compute node, then you can directly start your program under ddt as above. If you VNC session is on the login node or you are using the graham vdi node, then you need to manual launch the job as follows. From the ddt startup screen

  • pick the manually launch backend yourself job start option,
  • enter the appropriate information for your job and press the listen button, and
  • press the help button to the right of waiting for you to start the job....

This will then give you the command you need to run to start your job. Allocate a job on the cluster and start your program as directed. An example of doing this would be (where $USER is your username and $PROGAM ... is the command to start your program) 

[name@cluster-login:~]$ salloc ...
[name@cluster-node:~]$ /cvmfs/restricted.computecanada.ca/easybuild/software/2020/Core/allinea/20.2/bin/forge-client --ddtsessionfile /home/$USER/.allinea/session/gra-vdi3-1 $PROGRAM ...

Known issues[edit]

On graham, if you are experiencing issues with getting X11 to work, change permissions on your home directory so that only you have access.

First, check (and record if needed) current permissions with 

 ls -ld /home/$USER

The output should begin with: 

 drwx------

If some of the dashes are replaced by letters, that means your group and other users have read, write (unlikely), or execute permissions on your directory.

This command will work to remove read and execute permissions for group and other users: 

 chmod go-rx /home/$USER

After you are done using DDT, you can if you like restore permissions to what they were (assuming you recorded them). More information on how to do this can be found on page Sharing_data.

See also[edit]

Message Passing Interface

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