In legacy Fortran MPI programs, near the top of the procedure we would have:
use mpi
or
include'mpi.h'
It is typically recommended to use the OpenMPI Fortran 2008 interface:
use mpi_f08
Intel MPI
Intel MPI supports MPI Fortran 2008 use mpi_f08 since Intel 16.0 EXCEPT for
Windows Intel MPI,
where even Intel 19.0 did not have mpi_f08.
Interfacing MPI 3 with legacy Fortran code
You will notice for example that constants like mpi_comm_world and mpi_real are no longer integer data type, but rather custom types.
Many legacy and even current libraries (such as MUMPS 5) have not yet updated to be polymorphic for this enhanced variable type.
Here is a minimal working example for MUMPS using the backwards compatible OpenMPI 3 interface, grabbing the integer via the %mpi_val property.
program mumps_mpi3
use mpi_f08
include'dmumps_struc.h'! per MUMPS 5 manual
type(dmumps_struc) mumps_par
mumps_par%comm = mpi_comm_world%mpi_val ! %mpi_var emits the legacy integer
end program
Dozens of “free” compilers exist for C, C++ and Fortran.
However, only five compiler families available at no charge support the modern features of these popular compiled languages.
This list covers four compiler families available at no charge that support most of:
C17
C++17
Fortran 2008
GCC
GCC has broad support of modern standards on a very wide range of computing platforms.
GCC’s downside in some cases can be slower runtime performance than compilers having less broad language and platform support.
LLVM Clang and
Flang
have significant industry support, including from Nvidia, and are known for high performance, but somewhat less language feature support and less broad platform support than GCC.
flangFortran 2008 support includes submodule. Flang has really great performance compared to GCC.
PGI
PGI Community Edition
is free to use, and has performance comparable to Intel compilers in many cases.
PGI ≥ 19 should be used for modern Fortran.
PGI supports
CUDA Fortran.
IBM XL compilers are currently for POWER CPUs only e.g. ppc64le.
IBM XL compilers do not work with a typical x86-based computer.
If you have a $2000 Raptor IBM POWER9 desktop, then IBM XL may be for you.
The IBM XL compilers are high-performance compilers that have a free community edition.
IBM XL Fortran has wide support for Fortran 2008.
The procedure described here is for a new user to Docker.
There are certainly more efficient ways to do these tasks that are perhaps less easy for less experienced Docker users.
Please let us know if you have a suggested improvement suitable for novice Docker users.
Install Docker image
add docker group and yourself to this group, to avoid needing sudo for every docker command:
addgroup docker
adduser $(whoami) docker
then reboot (not just logout, an actual system restart)
install Docker on your laptop (the example here is for a Linux laptop)
snap install docker
after this step, sudo should no longer be required.
try the Hello World images, which should auto-download and print a welcome message
docker run hello-world
Search for a desired image.
Consider those images listed as “official”.
You might need to widen your terminal to 155 columns or so to render properly.
Let’s use ubuntu as it’s quite popular for Docker and in general.
docker search ubuntu
get the desired image
docker pull ubuntu
verify the images on your computer
docker images
ubuntu takes just under 100 MB to start.
start the Docker container on your laptop
docker run -it ubuntu
where -it means interactive session
verify the version running, it will have a # superuser prompt:
cat /etc/lsb-release
manage containers
These commands are issued NOT from within the Docker container itself (open a new terminal)
where are containers stored: docker info | grep "Root Dir"
How much space is Docker using altogether: du -sh /var/snap/docker
use previous command to find where your Docker stuff is
list images: docker images -a
list containers (running and stopped): docker ps -a
stop a Docker container: docker stop container_name
start a Docker container: docker start container_name
login to a running Docker container: docker exec -it container_name bash
get container environment variables: docker exec container_name env
cleanup unused containers docker system prune
delete image: docker image rm ubuntu:19.04
Configure Docker image
At least through April 2019, Travis-CI only had up to Ubuntu 16.04 dist: xenial, which does not have OpenCoarrays or other contemporary software that’s in Ubuntu 18.04 Bionic.
Travis-CI (and countless other online, server and computer resources) can use Docker images.
For research reproducability, a Docker image gives a known software state that should be usable for many years.
Interactive setup method tends to make the final image larger than using RUN commands.
So let’s start off by using a Dockerfile as that helps maintain smaller images with repeatable builds.
The Docker container can be turned into a new image that is usable from Travis-CI or any other suitable Docker host.
We do not claim this Dockerfile to be optimal.
Please let us know of suggested improvements.
# based on https://github.com/naftulikay/docker-bionic-vm/blob/master/DockerfileFROM ubuntu:18.04ENV container=docker TERM=xterm LC_ALL=en_US LANGUAGE=en_US LANG=en_US.UTF-8# stop some annoying interactive prompts, also need "-yq" on apt-getENV DEBIAN_FRONTEND=noninteractive# localeRUN apt-get update -q > /dev/null &&\
apt-get install --no-install-recommends -yq apt-utils locales language-pack-en dialog > /dev/null &&\
locale-gen $LANGUAGE $LANG# add sudo commmandRUN apt-get -yq install sudo > /dev/null# create and switch to a non-priviliged (but sudo-enabled) user, arbitrary nameRUN echo "nonprivuser ALL=(ALL) NOPASSWD:ALL" >> /etc/sudoersRUN useradd --no-log-init --home-dir /home/nonprivuser --create-home --shell /bin/bash nonprivuser && adduser nonprivuser sudoUSER nonprivuserWORKDIR /home/nonprivuser# Git/Curl -- don't disable recommends here or you won't have Certification Authority certificates and will failRUN sudo apt-get install -yq git curl > /dev/null# packages specific to your needsRUN sudo apt-get install --no-install-recommends -yq make gfortran libcoarrays-dev libopenmpi-dev open-coarrays-bin > /dev/null &&\
sudo apt-get clean -q# latest cmakeRUN git clone --depth 1 https://github.com/scivision/cmake-utils &&\
mkdir -v /home/nonprivuser/.local &&\
cd cmake-utils && PREFIX=/home/nonprivuser/.local ./cmake_setup.sh > /dev/null &&\
mv -v /home/nonprivuser/.local/cmake* /home/nonprivuser/.local/cmakeENV PATH=$PATH:/home/nonprivuser/.local/cmake/bin# other optional installs# RUN sudo apt-get install --no-install-recommends -yq octave
create the file above named Dockerfile.
build the Docker image:
docker build -t opencoarrays_fortran .
assuming you’re in the same directory as Dockerfile
check the image exists, for me it was about 350 MB:
docker images
Before committing for upload, you must invoke the container.
docker run opencoarrays_fortran
This will almost immediately start and stop, as you didn’t give it a command to run or persist.
get the hexadecimal container ID by:
docker ps -a
the container will have an auto-assigned name like foo_bar.
Note the hexadecimal “container ID”.
upload Docker image
Once you have configured a Docker container on your laptop suitable for your purposes, you may wish to share this container and use it on other hosts such as Travis-CI.
This can be done for free with DockerHub.
Once you are ready to upload the image, note the “container ID”, which is the hexadecimal number at the terminal prompt of the Docker container, under docker ps.
The container hex ID must appear under docker ps, just being in docker images is not enough.
The changes to the image the container made are gathered into a new image.
It may take a minute or two if your image is large.
Ideally with a small image it will take only a couple seconds.
The new image has not yet left your computer, it will show up under
docker images
Once uploaded, your Docker image is visible to the world by default.
{: .alert-box.warning}
If your image is very large > 1 GB, be aware it will take a while to upload, and for the CI system to download.
This is a telltale that it’s important to keep Docker images small.
Setup Travis-CI to use this image
Create .travis.yml:
language: minimal
services: docker
git:
depth: 3
quiet: true
env: Dimg=scivision/opencoarrays_fortran; Dname=fortran-ubuntu
before_install:
# Travis UID does not necessarily match 1000:1000 of Docker FIXME will Docker always be 1000:1000
- sudo chown -R 1000:1000 $TRAVIS_BUILD_DIR
- docker run -d --name $Dname -v $TRAVIS_BUILD_DIR:/home/nonprivuser/travis -w /home/nonprivuser/travis $Dimg tail -f /dev/null# prepend $Dcmd to run commands inside the Docker container
- export Dcmd="docker exec -t $Dname bash -c"
install:
# for this example, I already installed everything I need in the image previously created by the Dockerfile
script:
# all commands must be quoted
- $Dcmd "cd build && cmake .. && cmake --build . && ctest -V"
Notes
each docker exec command is a new shell instance. So changing directories in one docker exec has no effect on subsequent commands for example. Note the CMake one-liner in .travis.yml that configures, builds and tests in one command.
One can very rapidly find files with arbitrary criteria on systems with
GNU Findutils.
This includes Linux, MacOS and Windows Subsystem for Linux.
Examples
Just about any criteria one could think of can be used to rapidly find files.
If working on a remote filesystem mounted over
SSHFS,
we suggest SSHing into that system and running the find command that–it will be orders of magnitude faster.
Most examples use home directory ~ as a starting point just for convenience.
Appending 2>/dev/null to the end of a command removes nuisance messages about file permissions.
If piping the find command, put 2>/dev/null before the pipe.
Find files with “report” in the filename, case-insensitive
find ~ -iname "*report*"
Symbolic soft links
Suppose ~/data is a symbolic link to another directory, either on your computer, a USB hard drive or a server.
By default, find will not search this resource unless you
“resolve” the symbolic link
to a directory by putting a final / like ~/data/:
find ~/data/ -iname "*report*"
See the
findutils manual
symbolic link section for more details, in particular the -H and -L options.
Compiling with Intel compilers on Windows is a distinctive task from MacOS or Linux.
The Intel C, C++ and Fortran compilers masquerade as Visual Studio compilers, especially in their command line options.
For the Intel Fortran compiler on Windows, the build options one normally uses for Intel Fortran on MacOS and Linux do not work, and even error out the compiler.
For C and C++, one must use the icl compiler (there is no icc or icpc on Windows) as if it were MSVC.
That can be perplexing at first for those not coming from the MSVC world.
The scientific computing world and most software engineering tasks not originating in the Microsoft domain use GCC-like compilers, which have completely different sets of compiler options.
Loading Intel compiler environment
It’s important that you load the compilervars.bat script to enable the Intel compilers for each session and NOT the psxevars.bat.
For convenience, make a batch script like %HOMEPATH%\intel.bat containing:
C:\"Program Files (x86)"\IntelSWTools\parallel_studio_xe_2019\compilers_and_libraries_2019\windows\bin\compilervars.bat intel64`set FC=ifort
set CC=icl
set CXX=icl
MPI
Another distinctive feature of using MPI on Windows is that a username and password are required, even on a simple standalone laptop.
Good security practices may include creating a separate unprivileged user account that is only used for MPI jobs.
If this is suitable for your security environment, run MPI jobs in that other user account by from Command Prompt:
runas /user:mympiusername cmd
This opens a new Command Prompt window.
The environment variables are not passed to this new windows, so you may need to run Intel compilervars.bat again.
You can
register
the user credential into the Windows registry, if appropriate for your environment.
If doing so, we would again urge to consider using a separate user account that’s only used for MPI runs.
If you don’t sign in, errors will be like:
Unable to manage jobs using credentials with a blank password. Please enter another account.
PGI via $MKLROOT/../mpi/binding/intel-mpi-binding-kit.tar.gz
Windows Intel MPI is only for the Intel Fortran compiler and none other at this time.
MPI 2008
Intel 19 MPI does not support use mpi_f08 the Fortran 2008 bindings.
To keep compatibility with Intel MPI on Windows, at this time one would consider the legacy Fortran MPI interface:
use mpi
call mpi_init(ierr)
call mpi_finalize(ierr)
end program
The Fortran 77 include mpif.h should not be used in current Fortran programs as it breaks the fundamental Fortran 90 paradigm of modularity.
Setuptools 40.6 added section [options.data_files] to
setup.cfg.
Having setuptools < 40.6 results in this error upon trying to install a Python package:
distutils.errors.DistutilsOptionError: Unsupported distribution option section: [options.data_files]
Fix: upgrade setuptools via:
pip install --upgrade setuptools
Example
A
setup.cfg
might contain [options.data_files] section like:
On Windows, calling Python
sys.executable
or console scripts run as .exe may fail with
Fatal Python error: _Py_HashRandomization_Init: failed to get random numbers to initialize Python
The issue arises when environment variables are passed in via the env= argument to Python
subprocess.
In general, one should add or overwrite variables to the OS environment in subprocess calls as follows in this
example for using Clang and Flang compilers.
os.environ
returns a mapping (general form of dict) of environment variables.
import os
import subprocess
# get a Mapping of all the current environment variables
env = os.environ
# set these to use Clang and Flang compilers
myvar = {'CC': clang, 'CXX': clang++, 'FC': flang}
# %% This is the key section of code--add / overwrite environment variables for this subprocess only.
env.update(myvar)
subprocess.check_call(['meson', 'setup'], env=env)
Summary
Whenever using Python subprocess environment variables, you should generally pass in all the existing environment variables, adding or overwriting the specific variables needed.
Otherwise, fundamental environment variables will be missing and the subprocess call generally won’t work.
By default, when not specified, env=None, which tells subprocess to copy all the environment variables of the shell Python was called from.
In Windows, the
setx
command allows storing environment variables in the Windows registry on a per-user or system basis.
A problem arises when it is desired to remove such variables entirely.
Unlike older versions of Windows, setting a blank value does not work in Windows 10.
Example
Assume one previously set the environment variable CC to the
Intel C compiler
like:
setx CC icc
Now the problem is, you’d like the system to fall back to using whatever default C compiler is on the Windows system.
The existing variable is visible in PowerShell via:
Get-ChildItem Env:CC
But trying to remove the variable with PowerShell command
Remove-Item Env:FC
is only effective for this PowerShell session. The old value of CC comes back upon opening a new PowerShell.
Permanently remove setx variable
To permanently remove the variable, we must remove it from where it’s stored in the Windows registry.
For this example of wanting to delete enviornment variable CC, do from PowerShell:
GNU Octave
remez()
is for Parks-McClellan FIR filter coefficient design in the
octave-signal
package.
This is approximately equivalent to Matlab
firpm().
Install octave-signal
From within Octave terminal:
pkg install -verbose -forge signal
For more details, including compilers needed, see the GNU Octave
pkg install page