master:
These are tools to manage problem packages using the Kattis problem package format.
The problem tools provide the following three programs:
verifyproblem: run a complete check on a problemproblem2pdf: convert a problem statement to pdfproblem2html: convert a problem statement to html
Running any of them with the command-line option -h gives
documentation on what arguments they accept.
A few examples of problem packages can be found in examples.
There are four supported ways of installing and running problemtools. (For non-Linux users, "Method 2" below, to use Docker, is probably the least painful.)
Run
sudo pip3 install git+https://github.com/kattis/problemtools
Or if you don't want a system-wide installation,
pip3 install --user git+https://github.com/kattis/problemtools
With this second option, in order to get the command line scripts, you need
to make sure that the local user bin path used (e.g., on Linux,
$HOME/.local/bin) is in your $PATH.
In order for problemtools to build and run properly, you also need to have LaTeX and various LaTeX packages installed. See Requirements and compatbility below for details on which packages are needed.
This method allows you to run the Kattis problemtools inside a Docker container. This method is supported on any system for which Docker exists, including macOS and Windows 10.
We maintain three official problemtools Docker images on Docker Hub:
-
problemtools/full: this image contains problemtools along with compilers/interpreters for all supported programming languages. -
problemtools/icpc: this image contains problemtools along with compilers/interpreters for the programming languages allowed in the International Collegiate Programming Contest (ICPC): C, C++, Java, Kotlin, and Python 3. Note that the compiler/interpreter versions used might not be exactly the same as those used in the current ICPC season. -
problemtools/minimal: this image only contains problemtools, no additional programming languages. As such, it is not particularly useful on its own, but if you are organizing a contest and want to set up a problemtools environment containing exactly the right set of compilers/interpreters for your contest, this is the recommended starting point.
For example, suppose you want to use the problemtools/icpc image. To get started, install the Docker CLI, and then pull the image:
docker pull problemtools/icpc
Once the image has finished downloading, you can check that it exists on your system using docker images. To launch an interactive container and play around with verifyproblem, problem2pdf, and problem2html run:
docker run --rm -it problemtools/icpc
By default, docker containers do NOT persist storage between runs, so any files you create or modify will be lost when the container stops running. Two common ways of dealing with this are:
- Use a bind mount to mount a directory on your machine into the docker container. This can be done as follows (see Docker documentation for further details):
docker run --rm -it -v ${FULL_PATH_TO_MOUNT}:/kattis_work_dir problemtools/icpc - Persist any changes you want to keep to a remote file system/source control (e.g., a remote Git repository; note, however, that you would first need to install Git in the image).
If you want a more complete environment in the Docker images (e.g., if you want to install git or your favorite editor), feel free to extend them in whichever way you like.
The problemtools/{minimal,icpc,full} images point to the latest
release versions of problemtools. If, for some reason, you want an
image containing the latest development version, you have to build it
yourself from scratch (while there are
problemtools/{minimal,icpc,full}:develop Docker images on Docker
Hub, these are only updated sporadically for testing purposes and not
kept up to date).
If you intend to help develop problemtools, or if you just want a bare-bones way of running them, this is your option.
For this method, you need to clone the repository (just downloading a zip archive of it does not work because the project has submodules that are not included in that zip archive).
In order for the tools to work, you first have to compile the various
support programs, which can be done by running make in the root
directory of problemtools.
When this is done, you can run the three programs
bin/verifyproblem.sh, bin/problem2pdf.sh, and
bin/problem2html.sh directly from the repository.
See Requirements and compatibility below for what other software needs to be installed on your machine in order for problemtools to work correctly.
This applies if you are running on Debian or a Debian derivative, such as Ubuntu.
As with method 3, you need to clone the repository (just downloading a zip archive of it does not work because the project has submodules that are not included in that zip archive).
Run make builddeb in the root of the problemtools repository to
build the package. It will be found as kattis-problemtools_X.Y.deb in
the directory containing problemtools (i.e., one level up from the
root of the repository).
Apart from the build dependencies listed below, building the Debian package requires that the following tools are installed:
debhelper dh-python dpkg-dev
The package can then be installed using (replace <version> as appropriate):
sudo gdebi kattis-problemtools_<version>.deb
This installs the three provided programs in your path and they should now be ready to use.
System-wide problemtools configuration files are placed in
/etc/kattis/problemtools/, and user-specific configuration files are placed
in $HOME/.config/problemtools/ (or in $XDG_CONFIG_HOME if this is defined). The following files can be used to change
problemtools' configuration:
-
languages.yaml. Use it to override problemtools' default programming language configuration. For instance, while the problemtools default is to use the CPython/usr/bin/python3interpreter for Python 3, many contests, as well as the Kattis online judge, use Pypy as the interpreter for Python 3. To change this on your machine, you can simply place a file/etc/kattis/problemtools/languages.yaml(or~/.config/problemtools/languages.yamlif you only want to make the change for your user) containing the following:python3: name: 'Python 3 w/Pypy' run: '/usr/bin/pypy3 "{mainfile}"'
Here, overriding the name of the language is not strictly necessary, but it is often helpful to clearly indicate that Pypy is being used.
For more details on the format of the language specifications and what the default settings are, see the default version of languages.yaml
-
problem.yaml. For most users, this should not be edited. If you are not sure whether you should use it, then you probably shouldn't. This file can be used to specify the system defaults for those problem limits which are not given a fixed default value in the problem format specification. The system defaults assumed by problemtools can be found in (problemtools/config/problem.yaml). For instance, if you are primarily working against a system with a default memory limit of 2 GiB, you can place a file~/.config/problemtools/problem.yamlcontaining:limits: memory: 2048 # (unit is MiB)
(In principle, it is possible to override the defaults of other values than the system-dependent defaults in the problem.yaml metadata files this way, but such usage is very strongly discouraged.)
To build and run the tools, you need Python 3 with the YAML and PlasTeX libraries, and a LaTeX installation.
The dependencies needed to build/install problemtools can be installed with:
sudo apt install automake g++ make libboost-regex-dev libgmp-dev libgmp10 libgmpxx4ldbl python3 python3-pytest python3-setuptools python3-yaml python3-plastex
And the dependencies needed to run problemtools can be installed with:
sudo apt install ghostscript libgmpxx4ldbl python3-minimal python-pkg-resources python3-plastex python3-yaml texlive-fonts-recommended texlive-lang-cyrillic texlive-latex-extra texlive-plain-generic tidy
On Fedora, these dependencies can be installed with:
sudo dnf install boost-regex gcc gmp-devel gmp-c++ python3 python3-pyyaml texlive-latex texlive-collection-fontsrecommended texlive-fancyhdr texlive-subfigure texlive-wrapfig texlive-import texlive-ulem texlive-xifthen texlive-overpic texlive-pbox tidy ghostscript
Followed by:
pip3 install --user plastex
Package is available on the AUR kattis-problemtools-git. Use your favorite AUR helper or follow the installation instructions found here.
The problem tools have not been tested on other platforms. If you do test on another platform, we would be happy to hear what worked and what did not work, so that we can write proper instructions (and try to figure out how to make the non-working stuff work).