Go to file
2020-07-06 11:15:55 +02:00
bsc Disable debug in clang+ompss2 compiler 2020-07-06 11:15:55 +02:00
test Add test subset 2020-06-25 21:02:49 +02:00
.gitignore Ignore vim swap files 2020-07-03 15:14:08 +02:00
default.nix Disable debug in clang+ompss2 compiler 2020-07-06 11:15:55 +02:00
README Add README 2020-07-03 18:25:22 +02:00


                      BSC Nixpkgs: User guide


1 Introduction

  This repository contains a set of nix packages used in the Barcelona
  Supercomputing Center by the Programming Models group.

  Some preliminary steps must be done manually to be able to build and 
  install packages (derivations in nix jargon).

1.1 Network access

  In order to use nix you need to be able to download the sources from 
  Internet. Usually the download requires the ports 22, 80 and 443 to be 
  open for outgoing traffic.

  Unfortunately, in some clusters (as is the case in xeon07) access to 
  Internet is disabled. However you can tunnel the connection by SSH to 
  your local machine, and then reach the Internet.

  There are some guides on how to prepare the proxy server and the 
  tunnel in SSH such as:

    https://www.seniorlinuxadmin.co.uk/ssh-over-proxy.html

  In order to instruct nix to use the proxy connection, you will need to 
  export the https_proxy and http_proxy variables. In the xeon07 node is 
  already configured and you can automatically set those variables to 
  the correct address by loading:

    $ . /scratch/nix/internet

  Consider adding the command to your ~/.bashrc file so you don't need 
  to do it every time you want to use nix.

  Now you should be able to reach the outside world by running:

    $ curl google.com
    <HTML><HEAD><meta http-equiv="content-type" content="text/html;charset=utf-8">
    <TITLE>301 Moved</TITLE></HEAD><BODY>
    <H1>301 Moved</H1>
    The document has moved
    <A HREF="http://www.google.com/">here</A>.
    </BODY></HTML>

1.1 Prepare SSH keys

  Package sources are usually downloaded directly from the git server, 
  so you must be able to access all repositories without a password 
  prompt.

  Most repositories at https://pm.bsc.es/gitlab are open to read for 
  logged users, but there are some exceptions for example the nanos6 
  repository where you must have explicitly granted read access.

  If you don't have a ssh key at ~/.ssh/*.pub create a new one without 
  password protection by running:

    $ ssh-keygen
    Generating public/private rsa key pair.
    Enter file in which to save the key (~/.ssh/id_rsa):
    Enter passphrase (empty for no passphrase):
    Enter same passphrase again:
    Your identification has been saved in ~/.ssh/id_rsa.
    Your public key has been saved in ~/.ssh/id_rsa.pub.
    ...

  By default it will create the private key at ~/.ssh/id_rsa. Copy the 
  contents of your public ssh key in ~/.ssh/id_rsa.pub and paste it in 
  GitLab at:

    https://pm.bsc.es/gitlab/profile/keys

  If you want to select another key rather than the default 
  ~/.ssh/id_rsa then you must configure it for use in the ~/.ssh/config 
  file, adding:

    Host bscpm02.bsc.es
      IdentityFile ~/.ssh/your-private-key

  Finally verify the SSH connection to the server works and you get a 
  greeting from the GitLab server with your username:

    $ ssh git@bscpm02.bsc.es
    PTY allocation request failed on channel 0
    Welcome to GitLab, @rarias!
    Connection to bscpm02.bsc.es closed.

  Verify that you can access rarias/nanos6 repository (otherwise you 
  first need to ask to be granted read access), at:

    https://pm.bsc.es/gitlab/rarias/nanos6
  
  Finally, you should be able to download the rarias/nanos6 git 
  repository without any password interaction by running:

    $ git clone git@bscpm02-bsc-es:rarias/nanos6.git

1.3 Prepare the bsc-nixpkgs repo

  Once you have Internet and you have granted access to the PM GitLab 
  repositories you can begin down the rabbit hole of nix. First ensure 
  that the nix binaries are available in your machine:

    $ nix --version
    nix (Nix) 2.3.6

  Now you are set to install packages with nix. Clone the bsc-nixpkgs 
  repository:

    $ git clone git@bscpm02-bsc-es:rarias/bsc-nixpkgs.git

  Nix looks in the current folder for a file named "default.nix" for 
  packages, so go to the repo:

    $ cd bsc-nixpkgs

  Now you should be able to build nanos6 from the git repository:

    $ nix-build -A bsc.nanos6-git

  The output is placed in the "result" symlink.


2. Basic usage of nix

  Nix is a package manager which handles easily reproducibility and 
  configuration of packages and dependencies. See more info here:

    https://nixos.org/nix/manual/

  We will only cover the basic usage of nix for the BSC packages.

2.1 The user environment

  All nix packages are stored under the /nix directory. When you need to 
  "install" some binary from nix, a symlink is added to a folder 
  included in the $PATH variable. In particular, you should have the 
  something similar added to your $PATH:

    $ echo $PATH | sed 's/:/\n/g' | grep nix
    /home/Computational/rarias/.nix-profile/bin
    /nix/var/nix/profiles/default/bin

  The first one is your custom installation of packages that are stored 
  in your home directory and the second one is the default installation 
  which contains the nix tools (which are installed in the /nix 
  directory as well).

  When you need a program that is not available in your environment, 
  much like when you use "module load ..." you can use nix-env to modify 
  what is currently loaded. For example:

    $ nix-env -iA nixpkgs.cowsay

  The command will download (if not found already in the nix store), 
  compile (if necessary) and load the program `cowsay` from the nixpkgs 
  repository in the environment. You should be able to run it as:

    $ cowsay "hello world"
     _____________
    < hello world >
     -------------
            \   ^__^
             \  (oo)\_______
                (__)\       )\/\
                    ||----w |
                    ||     ||

  You can inspect now the ~/.nix-profile/bin folder, and see that a new 
  symlink was added to the actual installation of the binary:

    $ file ~/.nix-profile/bin/cowsay
    /home/Computational/rarias/.nix-profile/bin/cowsay: symbolic link to 
    `/nix/store/673gczmhr5b449521srz2n7g1klykz6n-cowsay-3.03+dfsg2/bin/cowsay'

  You can list the current packages installed in your environment by 
  running:

    $ nix-env -q
    cowsay-3.03+dfsg2
    nix-2.3.6

  Notice that this setup only affects your user environment. Also, it is 
  permanent for any new session until you modify the environment again 
  and is immediate, all sessions will have the new environment 
  instantaneously.

  You can remove any package from the environment using:

    $ nix-env -e cowsay

  See the manual with `nix-env --help` if you want to know more details.

2.2 Building packages

  Usually, all official packages are already compiled and distributed 
  from a cache server so you don't need to rebuild them again. However, 
  BSC packages are distributed only in source code form as we don't have 
  any binary cache server yet.
  
  Nix will handle the build process without any user interaction (with a 
  few exceptions stated later, which you shouldn't have to worry). If 
  any other user has already built the package then the build process is 
  not needed, and the package is used as is.

  In order to build a BSC package go to the `bsc-nixpkgs` directory, and 
  run:

    $ nix-build -A bsc.dummy

  The package will be built and installed in the /nix directory, then a 
  symlink is placed in the result directory:

    $ find result/ -type f
    result/
    result/bin
    result/bin/dummy

  The way in which nix handles the packages and dependencies ensures 
  that the output of a compilation of any package is exactly the same.  
  You can check the reproducibility of the build by adding the "--check" 
  flag, which will rebuild the package and compare the checksum of every 
  file with the ones installed:

    $ nix-build -A bsc.dummy --check
    ...
    $ echo $?
    0

  A return code of zero ensures the output is bit by bit identical to 
  the one installed. There are some packages that try to include 
  non-reproducible information in the build process as the timestamp 
  which will produce an error. Those packages must be patched to ensure 
  the output is deterministic.

  Notice that if you "cd" into the result/ directory you will be at /nix 
  directory (as you follow the symlink) where you don't have write 
  permission. Therefore if your program attempts to write to the current 
  directory it will fail. It is recommended to instead run your program 
  from the top directory:

    $ result/bin/dummy
    Hello world!

  Or you can install it in the environment:

    $ nix-env -i ./result

  And "cd" into any directory where you want to output some files and 
  just run it by the name:

    $ cd /tmp
    $ dummy
    Hello world!

  Finally, you can remove it from the environment if you don't need it:

    $ nix-env -e dummy

  If you want to know more details use "nix-build --help" to see the 
  manual.

2.3 The build process

  Each package is built following a programmable configuration 
  description in the nix language. Build in nix are performed under very 
  strict conditions. No access any file in the file system is allowed, 
  unless stated in the dependencies of the package which are then 
  available in the build environment.

  There is no network access in the build process and other restrictions 
  are enforced that the build is deterministic. See more details here:

    https://nixos.wiki/wiki/Nix#Sandboxing

  In the "default.nix" file of the bsc-nixpkgs you can see the 
  definition for each package, for example the nbody app:

    nbody = callPackage ./bsc/apps/nbody/default.nix {
      stdenv = pkgs.gcc9Stdenv;
      mpi = intel-mpi;
      icc = icc;
      tampi = tampi;
      nanos6 = nanos6-git;
    };

  The compilation details are specified in the 
  "bsc/apps/nbody/default.nix" file.  You can configure the package by 
  changing the inputs, for example, what specific implementation of 
  nanos6 or MPI you want to use. To change the MPI implementation to the 
  official MPICH package use:

    nbody = callPackage ./bsc/apps/nbody/default.nix {
      stdenv = pkgs.gcc9Stdenv;
      mpi = pkgs.mpich; # Notice pkgs prefix for official packages
      icc = icc;
      tampi = tampi;
      nanos6 = nanos6-git;
    };

  Then you can rebuild the nbody package:

    $ nix-build -A bsc.nbody
    ...

  And verify that the binary is indeed linked to MPICH now:

    $ ldd result/bin/nbody_mpi.N2.2048.exe | grep mpi
        libmpi.so.12 => /nix/store/dwkkcv78a5bs8smflpx9ppp3klhz3i98-mpich-3.3.2/lib/libmpi.so.12 (0x00007f6be0f07000)

  If you modify a package which another package requires as a 
  dependency, nix will rebuild all required packages to propagate your 
  changes on demand.

  However, if you come back to the original configuration, the package 
  will still be in the /nix store (unless the garbage collector was 
  manually run and removed your old build), so you don't need to rebuild 
  it again.

  For example if nbody is configured back to use Intel MPI:

    nbody = callPackage ./bsc/apps/nbody/default.nix {
      stdenv = pkgs.gcc9Stdenv;
      mpi = intel-mpi;
      icc = icc;
      tampi = tampi;
      nanos6 = nanos6-git;
    };

  The build process now is not required:

    $ nix-build -A bsc.nbody
    /nix/store/rbq7wrjcmg6fzd6yhrlnkfvzcavdbdpc-nbody
    $ ldd result/bin/nbody_mpi.N2.2048.exe | grep mpi
        libmpifort.so.12 => /nix/store/jvsjvxj2a08340fpdrqbqix9z3mpp3bd-intel-mpi-2019.7.217/lib/libmpifort.so.12 (0x00007f3a00402000)
        libmpi.so.12 => /nix/store/jvsjvxj2a08340fpdrqbqix9z3mpp3bd-intel-mpi-2019.7.217/lib/libmpi.so.12 (0x00007f39fed34000)

  Take a look at the different package description files in the 
  bsc-nixpkgs repository if you want to understand more details. Also 
  the nix pills are a very good reference:

    https://nixos.org/nixos/nix-pills/

/* vim: set ts=2 sw=2 tw=72 fo=watqc expandtab spell autoindent: */