Testing on Multiple Platforms#
Sage is intended to build and run on a variety of platforms, including all major Linux distributions, as well as macOS, and Windows with WSL (Windows Subsystem for Linux).
There is considerable variation among these platforms. To ensure that Sage continues to build correctly on users’ machines, it is crucial to test changes to Sage, in particular when external packages are added or upgraded, on a wide spectrum of platforms.
Testing PRs with GitHub Actions#
GitHub Actions are automatically and constantly testing GitHub PRs to identify errors early and ensure code quality. In particular, Build & Test workflows perform an incremental build of Sage and run doctests on a selection of major platforms including Ubuntu, macOS, and Conda.
Sage buildbots#
Before a new release, the release manager runs a fleet of buildbots to make it sure that Sage builds correctly on all of our supported platforms.
Test reports on sage-release#
Sage developers and users are encouraged to test releases that are announced on Sage Release on their machines and to report the results (successes and failures) by responding to the announcements.
Testing on multiple platforms using Docker#
Docker is a popular virtualization software, running Linux operating system images (“Docker images”) in containers on a shared Linux kernel. These containers can be run using a Docker client on your Linux, Mac, or Windows box, as well as on various cloud services.
To get started, you need to install a Docker client. The clients are available for Linux, Mac, and Windows. The clients for the latter are known as “Docker Desktop”.
Make sure that your Docker client is configured to provide enough RAM to the containers (8 GB are a good choice). In Docker Desktop this setting is in Preferences -> Resources -> Advanced.
Note
All examples in this section were obtained using Docker Desktop for Mac; but the command-line user interface for the other platforms is identical.
As an alternative, you can also run Docker in GitHub Codespaces (or another cloud service) using a container with the Docker-in-Docker feature. Sage provides a suitable dev container configuration .devcontainer/tox-docker-in-docker:
All major Linux distributions provide ready-to-use Docker images, which are published via Docker Hub or other container registries. For example, to run the current stable (LTS) version of Ubuntu interactively, you can use the shell command:
[mkoeppe@sage sage]$ docker run -it ubuntu:latest
root@9f3398da43c2:/#
Here ubuntu
is referred to as the “image (name)” and latest
as
the “tag”. Other releases of Ubuntu are available under different
tags, such as xenial
or devel
.
The above command drops you in a root shell on the container:
root@9f3398da43c2:/# uname -a
Linux 9f3398da43c2 4.19.76-linuxkit #1 SMP Thu Oct 17 19:31:58 UTC 2019 x86_64 x86_64 x86_64 GNU/Linux
root@9f3398da43c2:/# df -h
Filesystem Size Used Avail Use% Mounted on
overlay 181G 116G 56G 68% /
tmpfs 64M 0 64M 0% /dev
tmpfs 2.7G 0 2.7G 0% /sys/fs/cgroup
shm 64M 0 64M 0% /dev/shm
/dev/sda1 181G 116G 56G 68% /etc/hosts
tmpfs 2.7G 0 2.7G 0% /proc/acpi
tmpfs 2.7G 0 2.7G 0% /sys/firmware
Exiting the shell terminates the container:
root@9f3398da43c2:/# ^D
[mkoeppe@sage sage]$
Let us work with a distclean Sage source tree. If you are using git,
a good way to get one (without losing a precious installation in
SAGE_LOCAL
) is by creating a new worktree:
[mkoeppe@sage sage] git worktree add worktree-ubuntu-latest
[mkoeppe@sage sage] cd worktree-ubuntu-latest
[mkoeppe@sage worktree-ubuntu-latest] ls
COPYING.txt ... Makefile ... configure.ac ... src tox.ini
This is not bootstrapped (configure
is missing), so let’s bootstrap it:
[mkoeppe@sage worktree-ubuntu-latest] make configure
...
We can start a container again with same image, ubuntu:latest
, but
this time let’s mount the current directory into it:
[mkoeppe@sage worktree-ubuntu-latest]$ docker run -it --mount type=bind,source=$(pwd),target=/sage ubuntu:latest
root@39d693b2a75d:/# mount | grep sage
osxfs on /sage type fuse.osxfs (rw,nosuid,nodev,relatime,user_id=0,group_id=0,allow_other,max_read=1048576)
root@39d693b2a75d:/# cd sage
root@39d693b2a75d:/sage# ls
COPYING.txt ... Makefile ... config configure configure.ac ... src tox.ini
Typical Docker images provide minimal installations of packages only:
root@39d693b2a75d:/sage# command -v python
root@39d693b2a75d:/sage# command -v gcc
root@39d693b2a75d:/sage#
As you can see above, the image ubuntu:latest
has neither a Python nor
a GCC installed, which are among the build prerequisites of Sage. We
need to install them using the Linux distribution’s package manager first.
Sage facilitates testing various Linux distributions on Docker as follows.
Discovering the system’s package system#
root@39d693b2a75d:/sage# build/bin/sage-guess-package-system
debian
Let’s install gcc, hoping that the Ubuntu package providing it is
simply named gcc
. If we forgot what the package manager on
Debian-derived Linux distributions is called, we can ask Sage for a
reminder:
root@39d693b2a75d:/sage# build/bin/sage-print-system-package-command debian install gcc
apt-get install gcc
We remember that we need to fetch the current package lists from the server first:
root@39d693b2a75d:/sage# apt-get update
root@39d693b2a75d:/sage# apt-get install gcc
Using Sage’s database of distribution prerequisites#
The source code of the Sage distribution contains a database of
package names in various distributions’ package managers. For
example, the file build/pkgs/_prereq/distros/debian.txt
contains the following
# This file, build/pkgs/_prereq/distros/debian.txt, contains names
# of Debian/Ubuntu packages needed for installation of Sage from source.
#
# In addition, the files build/pkgs/SPKG/distros/debian.txt contain the names
# of packages that provide the equivalent of SPKG.
#
# Everything on a line after a # character is ignored.
binutils
make
m4
perl
# python3-minimal is not enough on debian buster, ubuntu bionic - it does not have urllib
python3 # system python for bootstrapping the build
tar
bc
gcc
# On debian buster, need C++ even to survive 'configure'. Otherwise:
# checking how to run the C++ preprocessor... /lib/cpp
# configure: error: in `/sage':
# configure: error: C++ preprocessor "/lib/cpp" fails sanity check
g++
# Needed if we download some packages from a https upstream URL
ca-certificates
From this information, we know that we can use the following command on our container to install the necessary build prerequisites:
root@39d693b2a75d:/sage# apt-get install binutils make m4 perl python3 \
tar bc gcc g++ ca-certificates
Reading package lists... Done
Building dependency tree
Reading state information... Done
tar is already the newest version (1.29b-2ubuntu0.1).
The following additional packages will be installed:
...
Done.
(The Sage Installation Guide also provides such command lines for some distributions; these are automatically generated from the database of package names.)
Now we can start the build:
root@39d693b2a75d:/sage# ./configure
checking for a BSD-compatible install... /usr/bin/install -c
checking for root user... yes
configure: error: You cannot build Sage as root, switch to an unprivileged user.
(If building in a container, use --enable-build-as-root.)
Let’s just follow this helpful hint:
root@39d693b2a75d:/sage# ./configure --enable-build-as-root
checking for a BSD-compatible install... /usr/bin/install -c
...
Using Sage’s database of equivalent distribution packages#
At the end of the ./configure
run, Sage issued a message like the
following:
configure: notice: the following SPKGs did not find equivalent system packages:
boost_cropped bzip2 ... zeromq zlib
checking for the package system in use... debian
configure: hint: installing the following system packages is recommended and
may avoid building some of the above SPKGs from source:
configure: $ sudo apt-get install ... libzmq3-dev libz-dev
configure: After installation, re-run configure using:
configure: $ make reconfigure
This information comes from Sage’s database of equivalent system packages. For example:
$ ls build/pkgs/flint/distros/
alpine.txt cygwin.txt fedora.txt gentoo.txt macports.txt opensuse.txt void.txt
conda.txt debian.txt freebsd.txt homebrew.txt nix.txt repology.txt
$ cat build/pkgs/flint/distros/debian.txt
libflint-dev
Note that these package equivalencies are based on a current stable or testing version of the distribution; the packages are not guaranteed to exist in every release or derivative distribution.
The Sage distribution is intended to build correctly no matter what superset of the set of packages forming the minimal build prerequisites is installed on the system. If it does not, this is a bug of the Sage distribution and should be reported and fixed on a ticket. Crucial part of a bug report is the configuration of the system, in particular a list of installed packages and their versions.
Let us install a subset of these packages:
root@39d693b2a75d:/sage# apt-get install libbz2-dev bzip2 libz-dev
Reading package lists... Done
...
Setting up zlib1g-dev:amd64 (1:1.2.11.dfsg-0ubuntu2) ...
root@39d693b2a75d:/sage#
Committing a container to disk#
After terminating the container, the following command shows the status of the container you just exited:
root@39d693b2a75d:/sage# ^D
[mkoeppe@sage worktree-ubuntu-latest]$ docker ps -a | head -n3
CONTAINER ID IMAGE COMMAND CREATED STATUS
39d693b2a75d ubuntu:latest "/bin/bash" 8 minutes ago Exited (0) 6 seconds ago
9f3398da43c2 ubuntu:latest "/bin/bash" 8 minutes ago Exited (0) 8 minutes ago
We can go back to the container with the command:
[mkoeppe@sage worktree-ubuntu-latest]$ docker start -a -i 39d693b2a75d
root@9f3398da43c2:/#
Here, 39d693b2a75d
is the container id, which appeared in the
shell prompts and in the output of docker ps
.
We can create a new image corresponding to its current state:
root@39d693b2a75d:/# ^D
[mkoeppe@sage worktree-ubuntu-latest]$ docker commit 39d693b2a75d ubuntu-latest-minimal-17
sha256:4151c5ca4476660f6181cdb13923da8fe44082222b984c377fb4fd6cc05415c1
where ubuntu-latest-minimal-17
is an arbitrary symbolic name for the new
image. The output of the command is the id of the new image. We can use either
the symbolic name or the id to refer to the new image.
We can run the image and get a new container with the same state as the one that we terminated. Again we want to mount our worktree into it; otherwise, because we did not make a copy, the new container will have no access to the worktree:
[mkoeppe@sage worktree-ubuntu-latest]$ docker run -it \
--mount type=bind,source=$(pwd),target=/sage ubuntu-latest-minimal-17
root@73987568712c:/# cd sage
root@73987568712c:/sage# command -v gcc
/usr/bin/gcc
root@73987568712c:/sage# command -v bunzip2
/usr/bin/bunzip2
root@73987568712c:/sage# ^D
[mkoeppe@sage worktree-ubuntu-latest]$
The image ubuntu-latest-minimal-17
can be run in as many
containers as we want and can also be shared with other users or
developers so that they can run it in a container on their machine.
(See the Docker documentation on how to share images on Docker Hub or to save images to a
tar archive.)
This facilitates collaboration on fixing portability bugs of the Sage distribution. After reproducing a portability bug on a container, several developers can work on fixing the bug using containers running on their respective machines.
Generating dockerfiles#
Sage also provides a script for generating a Dockerfile
, which is
a recipe for automatically building a new image:
[mkoeppe@sage sage]$ .ci/write-dockerfile.sh debian ":standard: :optional:" > Dockerfile
(The second argument is passed to sage -package list
to find packages for the listed package types.)
The Dockerfile
instructs the command docker build
to build a
new Docker image. Let us take a quick look at the generated file;
this is slightly simplified:
[mkoeppe@sage sage]$ cat Dockerfile
# Automatically generated by SAGE_ROOT/.ci/write-dockerfile.sh
# the :comments: separate the generated file into sections
# to simplify writing scripts that customize this file
...
First, it instructs docker build
to start from an existing base
image…:
...
ARG BASE_IMAGE=ubuntu:latest
FROM ${BASE_IMAGE}
...
Then, to install system packages…:
...
RUN apt-get update && DEBIAN_FRONTEND=noninteractive apt-get install -qqq --no-install-recommends --yes binutils make m4 perl python3 ... libzmq3-dev libz-dev && apt-get clean
Then, to bootstrap and configure…:
RUN mkdir -p /sage
WORKDIR /sage
ADD Makefile VERSION.txt README.md bootstrap configure.ac sage ./
ADD src/doc/bootstrap src/doc/bootstrap
ADD m4 ./m4
ADD build ./build
RUN ./bootstrap
ADD src/bin src/bin
ARG EXTRA_CONFIGURE_ARGS=""
RUN ./configure --enable-build-as-root ${EXTRA_CONFIGURE_ARGS} || (cat config.log; exit 1)
Finally, to build and test…:
ARG NUMPROC=8
ENV MAKE="make -j${NUMPROC}"
ARG USE_MAKEFLAGS="-k"
RUN make ${USE_MAKEFLAGS} base-toolchain
ARG TARGETS_PRE="all-sage-local"
RUN make ${USE_MAKEFLAGS} ${TARGETS_PRE}
ADD src src
ARG TARGETS="build ptest"
RUN make ${USE_MAKEFLAGS} ${TARGETS}
You can customize the image build process by passing build arguments to the
command docker build
. For example:
[mkoeppe@sage sage]$ docker build . -f Dockerfile \
--build-arg BASE_IMAGE=ubuntu:latest \
--build-arg NUMPROC=4 \
--build-arg EXTRA_CONFIGURE_ARGS="--with-python=/usr/bin/python3.42"
These arguments (and their default values) are defined using ARG
commands in the Dockerfile
.
The above command will build Sage from scratch and will therefore take
quite long. Let us instead just do a partial build, consisting of one
small package, by setting the arguments TARGETS_PRE
and
TARGETS
. We use a silent build (make V=0
):
[mkoeppe@sage sage]$ docker build . -f Dockerfile \
--build-arg TARGETS_PRE=ratpoints \
--build-arg TARGETS=ratpoints \
--build-arg USE_MAKEFLAGS="V=0"
Sending build context to Docker daemon 285MB
Step 1/28 : ARG BASE_IMAGE=ubuntu:latest
...
Step 2/28 : FROM ${BASE_IMAGE}
---> 549b9b86cb8d
...
Step 25/28 : RUN make SAGE_SPKG="sage-spkg -y -o" ${USE_MAKEFLAGS} ${TARGETS_PRE}
...
make[1]: Entering directory '/sage/build/make'
sage-logger -p 'sage-spkg -y -o ratpoints-2.1.3.p5' '/sage/logs/pkgs/ratpoints-2.1.3.p5.log'
[ratpoints-2.1.3.p5] installing. Log file: /sage/logs/pkgs/ratpoints-2.1.3.p5.log
[ratpoints-2.1.3.p5] successfully installed.
make[1]: Leaving directory '/sage/build/make'
real 0m18.886s
user 0m1.779s
sys 0m0.314s
Sage build/upgrade complete!
...
---> 2d06689d39fa
Successfully built 2d06689d39fa
We can now start a container using the image id shown in the last step:
[mkoeppe@sage sage]$ docker run -it 2d06689d39fa bash
root@fab59e09a641:/sage# ls -l logs/pkgs/
total 236
-rw-r--r-- 1 root root 231169 Mar 26 22:07 config.log
-rw-r--r-- 1 root root 6025 Mar 26 22:27 ratpoints-2.1.3.p5.log
root@fab59e09a641:/sage# ls -l local/lib/*rat*
-rw-r--r-- 1 root root 177256 Mar 26 22:27 local/lib/libratpoints.a
You can customize the image build process further by editing the
Dockerfile
. For example, by default, the generated Dockerfile
configures, builds, and tests Sage. By deleting or commenting out the
commands for the latter, you can adjust the Dockerfile to stop after
the configure
phase, for example.
Dockerfile
is the default filename for Dockerfiles. You can
change it to any other name, but it is recommended to use
Dockerfile
as a prefix, such as Dockerfile-debian-standard
.
It should be placed within the tree rooted at the current directory
(.
); if you want to put it elsewhere, you need to learn about
details of “Docker build contexts”.
Note that in contrast to the workflow described in the above sections,
the Dockerfile
copies a snapshot of your Sage worktree into
the build container, using ADD
commands, instead of mounting the
directory into it. This copying is subject to the exclusions in the
.gitignore
file (via a symbolic link from .dockerignore
).
Therefore, only the sources are copied, but not your configuration
(such as the file config.status
), nor the $SAGE_LOCAL
tree,
nor any other build artefacts.
Because of this, you can build a Docker image using the generated
Dockerfile
from your main Sage development tree. It does not have
to be distclean to start, and the build will not write into it at all.
Hence, you can continue editing and compiling your Sage development
tree even while Docker builds are running.
Debugging a portability bug using Docker#
Let us do another partial build. We choose a package that we suspect
might not work on all platforms, surf
, which was marked as
“experimental” in 2017:
[mkoeppe@sage sage]$ docker build . -f Dockerfile \
--build-arg BASE_IMAGE=ubuntu:latest \
--build-arg NUMPROC=4 \
--build-arg TARGETS_PRE=surf \
--build-arg TARGETS=surf
Sending build context to Docker daemon 285MB
Step 1/28 : ARG BASE_IMAGE=ubuntu:latest
Step 2/28 : FROM ${BASE_IMAGE}
---> 549b9b86cb8d
...
Step 24/28 : ARG TARGETS_PRE="all-sage-local"
---> Running in 17d0ddb5ad7b
Removing intermediate container 17d0ddb5ad7b
---> 7b51411520c3
Step 25/28 : RUN make SAGE_SPKG="sage-spkg -y -o" ${USE_MAKEFLAGS} ${TARGETS_PRE}
---> Running in 61833bea6a6d
make -j4 build/make/Makefile --stop
...
[surf-1.0.6-gcc6] Attempting to download package surf-1.0.6-gcc6.tar.gz from mirrors
...
[surf-1.0.6-gcc6] http://mirrors.mit.edu/sage/spkg/upstream/surf/surf-1.0.6-gcc6.tar.gz
...
[surf-1.0.6-gcc6] Setting up build directory for surf-1.0.6-gcc6
...
[surf-1.0.6-gcc6] /usr/bin/ld: cannot find -lfl
[surf-1.0.6-gcc6] collect2: error: ld returned 1 exit status
[surf-1.0.6-gcc6] Makefile:504: recipe for target 'surf' failed
[surf-1.0.6-gcc6] make[3]: *** [surf] Error 1
...
[surf-1.0.6-gcc6] Error installing package surf-1.0.6-gcc6
...
Makefile:2088: recipe for target '/sage/local/var/lib/sage/installed/surf-1.0.6-gcc6' failed
make[1]: *** [/sage/local/var/lib/sage/installed/surf-1.0.6-gcc6] Error 1
make[1]: Target 'surf' not remade because of errors.
make[1]: Leaving directory '/sage/build/make'
...
Error building Sage.
The following package(s) may have failed to build (not necessarily
during this run of 'make surf'):
* package: surf-1.0.6-gcc6
last build time: Mar 26 22:07
log file: /sage/logs/pkgs/surf-1.0.6-gcc6.log
build directory: /sage/local/var/tmp/sage/build/surf-1.0.6-gcc6
...
Makefile:31: recipe for target 'surf' failed
make: *** [surf] Error 1
The command '/bin/sh -c make SAGE_SPKG="sage-spkg -y -o" ${USE_MAKEFLAGS} ${TARGETS_PRE}'
returned a non-zero code: 2
Note that no image id is shown at the end; the build failed, and no image is created. However, the container in which the last step of the build was attempted exists:
[mkoeppe@sage sage]$ docker ps -a |head -n3
CONTAINER ID IMAGE COMMAND CREATED STATUS
61833bea6a6d 7b51411520c3 "/bin/sh -c 'make SA…" 9 minutes ago Exited (2) 1 minute ago
73987568712c ubuntu-latest-minimal-17 "/bin/bash" 24 hours ago Exited (0) 23 hours ago
We can copy the build directory from the container for inspection:
[mkoeppe@sage sage]$ docker cp 61833bea6a6d:/sage/local/var/tmp/sage/build ubuntu-build
[mkoeppe@sage sage]$ ls ubuntu-build/surf*/src
AUTHORS TODO curve misc
COPYING acinclude.m4 debug missing
ChangeLog aclocal.m4 dither mkinstalldirs
INSTALL background.pic docs mt
Makefile config.guess draw src
Makefile.am config.log drawfunc surf.1
Makefile.global config.status examples surf.xpm
Makefile.in config.sub gtkgui yaccsrc
NEWS configure image-formats
README configure.in install-sh
Alternatively, we can use docker commit
as explained earlier to
create an image from the container:
[mkoeppe@sage sage]$ docker commit 61833bea6a6d
sha256:003fbd511016fe305bd8494bb1747f0fbf4cb2c788b4e755e9099d9f2014a60d
[mkoeppe@sage sage]$ docker run -it 003fbd511 bash
root@2d9ac65f4572:/sage# (cd /sage/local/var/tmp/sage/build/surf* && /sage/sage --buildsh)
Starting subshell with Sage environment variables set. Don't forget
to exit when you are done.
...
Note: SAGE_ROOT=/sage
(sage-buildsh) root@2d9ac65f4572:surf-1.0.6-gcc6$ ls /usr/lib/libfl*
/usr/lib/libflint-2.5.2.so /usr/lib/libflint-2.5.2.so.13.5.2 /usr/lib/libflint.a /usr/lib/libflint.so
(sage-buildsh) root@2d9ac65f4572:surf-1.0.6-gcc6$ apt-get update && apt-get install apt-file
(sage-buildsh) root@2d9ac65f4572:surf-1.0.6-gcc6$ apt-file update
(sage-buildsh) root@2d9ac65f4572:surf-1.0.6-gcc6$ apt-file search "/usr/lib/libfl.a"
flex-old: /usr/lib/libfl.a
freebsd-buildutils: /usr/lib/libfl.a
(sage-buildsh) root@2d9ac65f4572:surf-1.0.6-gcc6$ apt-get install flex-old
(sage-buildsh) root@2d9ac65f4572:surf-1.0.6-gcc6$ ./spkg-install
checking for a BSD-compatible install... /usr/bin/install -c
checking whether build environment is sane... yes
...
/usr/bin/install -c surf /sage/local/bin/surf
/usr/bin/install -c -m 644 ./surf.1 /sage/local/share/man/man1/surf.1
...
make[1]: Leaving directory '/sage/local/var/tmp/sage/build/surf-1.0.6-gcc6/src'
(sage-buildsh) root@2d9ac65f4572:surf-1.0.6-gcc6$ exit
root@2d9ac65f4572:/sage# exit
[mkoeppe@sage sage]$
A standard case of bitrot.
Automatic Docker-based build testing using tox#
tox is a Python package that is widely used for automating tests of Python projects.
If you are using Docker locally, install tox
for use with your system Python,
for example using:
[mkoeppe@sage sage]$ pip install --user tox
If you run Docker-in-Docker on GitHub Codespaces using our dev container
configuration .devcontainer/tox-docker-in-docker,
tox
is already installed.
Sage provides a sophisticated tox configuration in the file SAGE_ROOT/tox.ini for the purpose of portability testing.
A tox “environment” is identified by a symbolic name composed of several Tox “factors”.
The technology factor describes how the environment is run:
docker
builds a Docker image as described above.local
runs testing on the host OS instead. We explain this technology in a later section.
The next two factors determine the host system configuration: The system factor describes a base operating system image.
Examples are
ubuntu-focal
,debian-buster
,archlinux-latest
,fedora-30
,slackware-14.2
,centos-7-i386
, andubuntu-bionic-arm64
.See SAGE_ROOT/tox.ini for a complete list, and to which images on Docker hub they correspond.
The packages factor describes a list of system packages to be installed on the system before building Sage:
minimal
installs the system packages known to Sage to provide minimal prerequisites for bootstrapping and building the Sage distribution. This corresponds to the packages_bootstrap
and_prereq
.standard
additionally installs all known system packages that are equivalent to standard packages of the Sage distribution, for which the mechanismspkg-configure.m4
is implemented. This corresponds to the packages listed by:[mkoeppe@sage sage]$ sage --package list --has-file=spkg-configure.m4 :standard:
maximal
does the same for all standard and optional packages. This corresponds to the packages listed by:[mkoeppe@sage sage]$ sage --package list :standard: :optional:
The factors are connected by a hyphen to name a system configuration,
such as debian-buster-standard
and centos-7-i386-minimal
.
Finally, the configuration factor (which is allowed to be empty)
controls how the configure
script is run.
The factors are connected by a hyphen to name a tox environment. (The order of the factors does not matter; however, for consistency and because the ordered name is used for caching purposes, we recommend to use the factors in the listed order.)
To run an environment:
[mkoeppe@sage sage]$ tox -e docker-slackware-14.2-minimal
[mkoeppe@sage sage]$ tox -e docker-ubuntu-bionic-standard
Arbitrary extra arguments to docker build
can be supplied through
the environment variable EXTRA_DOCKER_BUILD_ARGS
. For example,
for a non-silent build (make V=1
), use:
[mkoeppe@sage sage]$ EXTRA_DOCKER_BUILD_ARGS="--build-arg USE_MAKEFLAGS=\"V=1\"" \
tox -e docker-ubuntu-bionic-standard
By default, tox uses TARGETS_PRE=all-sage-local
and
TARGETS=build
, leading to a complete build of Sage without the
documentation. If you pass positional arguments to tox (separated
from tox options by --
), then both TARGETS_PRE
and TARGETS
are set to these arguments. In this way, you can build some specific
packages instead of all of Sage, for example:
[mkoeppe@sage sage]$ tox -e docker-centos-8-standard -- ratpoints
If the build succeeds, this will create a new image named
sage-centos-8-standard-with-targets:9.1.beta9-431-gca4b5b2f33-dirty
,
where
the image name is derived from the tox environment name and the suffix
with-targets
expresses that themake
targets given inTARGETS
have been built;the tag name describes the git revision of the source tree as per
git describe --dirty
.
You can ask for tox to create named intermediate images as well. For
example, to create the images corresponding to the state of the OS
after installing all system packages (with-system-packages
) and
the one just after running the configure
script (configured
):
[mkoeppe@sage sage]$ DOCKER_TARGETS="with-system-packages configured with-targets" \
tox -e docker-centos-8-standard -- ratpoints
...
Sending build context to Docker daemon ...
Step 1/109 : ARG BASE_IMAGE=fedora:latest
Step 2/109 : FROM ${BASE_IMAGE} as with-system-packages
...
Step 109/109 : RUN yum install -y zlib-devel || echo "(ignoring error)"
...
Successfully built 4bb14c3d5646
Successfully tagged sage-centos-8-standard-with-system-packages:9.1.beta9-435-g861ba33bbc-dirty
Sending build context to Docker daemon ...
...
Successfully tagged sage-centos-8-standard-configured:9.1.beta9-435-g861ba33bbc-dirty
...
Sending build context to Docker daemon ...
...
Successfully tagged sage-centos-8-standard-with-targets:9.1.beta9-435-g861ba33bbc-dirty
Let’s verify that the images are available:
[mkoeppe@sage sage]$ docker images | head
REPOSITORY TAG IMAGE ID
sage-centos-8-standard-with-targets 9.1.beta9-435-g861ba33bbc-dirty 7ecfa86fceab
sage-centos-8-standard-configured 9.1.beta9-435-g861ba33bbc-dirty 4314929e2b4c
sage-centos-8-standard-with-system-packages 9.1.beta9-435-g861ba33bbc-dirty 4bb14c3d5646
...
Automatic build testing on the host OS using tox -e local-direct#
The local
technology runs testing on the host OS instead.
In contrast to the docker
technology, it does not make a copy of
the source tree. It is most straightforward to run it from a
separate, distclean git worktree.
Let us try a first variant of the local
technology, the tox
environment called local-direct
. Because all builds with tox
begin by bootstrapping the source tree, you will need autotools and
other prerequisites installed in your system. See
build/pkgs/_bootstrap/distros/*.txt
for a list of system packages that
provide these prerequisites.
We start by creating a fresh (distclean) git worktree:
[mkoeppe@sage sage] git worktree add worktree-local
[mkoeppe@sage sage] cd worktree-local
[mkoeppe@sage worktree-local] ls
COPYING.txt ... Makefile ... configure.ac ... src tox.ini
Again we build only a small package. Build targets can be passed as
positional arguments (separated from tox options by --
):
[mkoeppe@sage worktree-local] tox -e local-direct -- ratpoints
local-direct create: /Users/mkoeppe/.../worktree-local/.tox/local-direct
local-direct run-test-pre: PYTHONHASHSEED='2211987514'
...
src/doc/bootstrap:48: installing src/doc/en/installation/debian.txt...
bootstrap:69: installing 'config/config.rpath'
configure.ac:328: installing 'config/compile'
configure.ac:113: installing 'config/config.guess'
...
checking for a BSD-compatible install... /usr/bin/install -c
checking whether build environment is sane... yes
...
sage-logger -p 'sage-spkg -y -o ratpoints-2.1.3.p5' '.../worktree-local/logs/pkgs/ratpoints-2.1.3.p5.log'
[ratpoints-2.1.3.p5] installing. Log file: .../worktree-local/logs/pkgs/ratpoints-2.1.3.p5.log
[ratpoints-2.1.3.p5] successfully installed.
...
local-direct: commands succeeded
congratulations :)
Let’s investigate what happened here:
[mkoeppe@sage worktree-local]$ ls -la
total 2576
drwxr-xr-x 35 mkoeppe staff 1120 Mar 26 22:20 .
drwxr-xr-x 63 mkoeppe staff 2016 Mar 27 09:35 ..
...
lrwxr-xr-x 1 mkoeppe staff 10 Mar 26 20:34 .dockerignore -> .gitignore
-rw-r--r-- 1 mkoeppe staff 74 Mar 26 20:34 .git
...
-rw-r--r-- 1 mkoeppe staff 1212 Mar 26 20:41 .gitignore
...
drwxr-xr-x 7 mkoeppe staff 224 Mar 26 22:11 .tox
...
-rw-r--r-- 1 mkoeppe staff 7542 Mar 26 20:41 Makefile
...
lrwxr-xr-x 1 mkoeppe staff 114 Mar 26 20:45 config.log -> .tox/local-direct/log/config.log
-rwxr-xr-x 1 mkoeppe staff 90411 Mar 26 20:46 config.status
-rwxr-xr-x 1 mkoeppe staff 887180 Mar 26 20:45 configure
-rw-r--r-- 1 mkoeppe staff 17070 Mar 26 20:41 configure.ac
...
lrwxr-xr-x 1 mkoeppe staff 103 Mar 26 20:45 logs -> .tox/local-direct/log
drwxr-xr-x 24 mkoeppe staff 768 Mar 26 20:45 m4
lrwxr-xr-x 1 mkoeppe staff 105 Mar 26 20:45 prefix -> .tox/local-direct/local
-rwxr-xr-x 1 mkoeppe staff 4868 Mar 26 20:34 sage
drwxr-xr-x 16 mkoeppe staff 512 Mar 26 20:46 src
-rw-r--r-- 1 mkoeppe staff 13478 Mar 26 20:41 tox.ini
drwxr-xr-x 4 mkoeppe staff 128 Mar 26 20:46 upstream
There is no local
subdirectory. This is part of a strategy to
keep the source tree clean to the extent possible. In particular:
tox
configured the build to use a separate$SAGE_LOCAL
hierarchy in a directory under the tox environment directory.tox/local-direct
. It created a symbolic linkprefix
that points there, for convenience:[mkoeppe@sage worktree-local]$ ls -l prefix/lib/*rat* -rw-r--r-- 1 mkoeppe staff 165968 Mar 26 20:46 prefix/lib/libratpoints.a
Likewise, it created a separate
logs
directory, again under the tox environment directory, and a symbolic link.
This makes it possible for advanced users to test several local
tox environments (such as local-direct
) out of one worktree. However, because a
build still writes configuration scripts and build artefacts (such as
config.status
) into the worktree, only one local
build can run
at a time in a given worktree.
The tox environment directory will be reused for the next tox
run,
which will therefore do an incremental build. To start a fresh build,
you can use the -r
option.
Automatic build testing on the host OS with best-effort isolation using tox -e local#
tox -e local
(without -direct
) attempts a best-effort
isolation from the user’s environment as follows:
All environment variables are set to standard values; with the exception of
MAKE
andEXTRA_CONFIGURE_ARGS
. In particular,PATH
is set to just/usr/bin:/bin:/usr/sbin:/sbin
; it does not include/usr/local/bin
.
Note, however, that various packages have build scripts that use
/usr/local
or other popular file system locations such as
/opt/sfw/
. Therefore, the isolation is not complete. Using
/usr/local
is considered standard behavior. On the other hand, we
consider a package build script that inspects other file system
locations to be a bug of the Sage distribution, which should be
reported and fixed on a ticket.
Automatic build testing on macOS with a best-effort isolated installation of Homebrew#
XCode on macOS does not provide the prerequisites for bootstrapping the Sage distribution. A good way to install them is using the Homebrew package manager.
In fact, Sage provides a tox environment that automatically installs an isolated copy of Homebrew with all prerequisites for bootstrapping:
[mkoeppe@sage worktree-local]$ tox -e local-homebrew-macos-minimal -- lrslib
local-homebrew-macos-minimal create: .../worktree-local/.tox/local-homebrew-macos-minimal
local-homebrew-macos-minimal run-test-pre: PYTHONHASHSEED='4246149402'
...
Initialized empty Git repository in .../worktree-local/.tox/local-homebrew-macos-minimal/homebrew/.git/
...
Tapped 2 commands and 4942 formulae (5,205 files, 310.7MB).
==> Downloading https://ftp.gnu.org/gnu/gettext/gettext-0.20.1.tar.xz
...
==> Pouring autoconf-2.69.catalina.bottle.4.tar.gz
...
==> Pouring pkg-config-0.29.2.catalina.bottle.1.tar.gz
.../worktree-local/.tox/local-homebrew-macos-minimal/homebrew/Cellar/pkg-config/0.29.2: 11 files, 623.4KB
==> Caveats
==> gettext
gettext is keg-only, which means it was not symlinked into .../worktree-local/.tox/local-homebrew-macos-minimal/homebrew,
because macOS provides the BSD gettext library & some software gets confused if both are in the library path.
If you need to have gettext first in your PATH run:
echo 'export PATH=".../worktree-local/.tox/local-homebrew-macos-minimal/homebrew/opt/gettext/bin:$PATH"' >> ~/.bash_profile
For compilers to find gettext you may need to set:
export LDFLAGS="-L.../worktree-local/.tox/local-homebrew-macos-minimal/homebrew/opt/gettext/lib"
export CPPFLAGS="-I.../worktree-local/.tox/local-homebrew-macos-minimal/homebrew/opt/gettext/include"
...
local-homebrew-macos-minimal run-test: commands[0] | bash -c 'export PATH=.../worktree-local/.tox/local-homebrew-macos-minimal/homebrew/bin:/usr/bin:/bin:/usr/sbin:/sbin && . .homebrew-build-env && ./bootstrap && ./configure --prefix=.../worktree-local/.tox/local-homebrew-macos-minimal/local && make -k V=0 ... lrslib'
...
bootstrap:69: installing 'config/config.rpath'
...
checking for a BSD-compatible install... /usr/bin/install -c
checking whether build environment is sane... yes
...
configure: notice: the following SPKGs did not find equivalent system packages: cbc cliquer ... tachyon xz zeromq
checking for the package system in use... homebrew
configure: hint: installing the following system packages is recommended and may avoid building some of the above SPKGs from source:
configure: $ brew install cmake gcc gsl mpfi ninja openblas gpatch r readline xz zeromq
...
sage-logger -p 'sage-spkg -y -o lrslib-062+autotools-2017-03-03.p1' '.../worktree-local/logs/pkgs/lrslib-062+autotools-2017-03-03.p1.log'
[lrslib-062+autotools-2017-03-03.p1] installing. Log file: .../worktree-local/logs/pkgs/lrslib-062+autotools-2017-03-03.p1.log
[lrslib-062+autotools-2017-03-03.p1] successfully installed.
...
local-homebrew-macos-minimal: commands succeeded
congratulations :)
The tox environment uses the subdirectory homebrew
of the
environment directory .tox/local-homebrew-macos-minimal
as the
Homebrew prefix. This installation does not interact in any way with
a Homebrew installation in /usr/local
that you may have.
The test script sets the PATH
to the bin
directory of the
Homebrew prefix, followed by /usr/bin:/bin:/usr/sbin:/sbin
. It
then uses the script SAGE_ROOT/.homebrew-build-env to set
environment variables so that Sage’s build scripts will find
“keg-only” packages such as gettext
.
The local-homebrew-macos-minimal
environment does not install
Homebrew’s python3
package. It uses XCode’s /usr/bin/python3
as system python. However, because various packages are missing
that Sage considers as dependencies, Sage builds its own copy of
these packages and of python3
.
The local-homebrew-macos-standard
environment additionally
installs (in its separate isolated copy of Homebrew) all Homebrew
packages known to Sage for which the spkg-configure.m4
mechanism
is implemented; this is similar to the docker-standard
tox
environments described earlier. In particular it installs and uses
Homebrew’s python3
package.
By using configuration factors, more variants can be tested.
The local-homebrew-macos-standard-python3_xcode
environment
installs the same packages, but uses XCode’s /usr/bin/python3
.
The local-homebrew-macos-standard-python3_pythonorg
expects an
installation of Python 3.10 in
/Library/Frameworks/Python.framework
; this is where the binary
packages provided by python.org install themselves.
Automatic build testing with a best-effort isolated installation of Conda#
Sage provides environments local-conda-forge-standard
and
local-conda-forge-minimal
that create isolated installations of
Miniconda in the subdirectory conda
of the environment directory.
They do not interact in any way with other installations of Anaconda
or Miniconda that you may have on your system.
The environments use the conda-forge channel and use the python
package and the compilers from this channel.
Options for build testing with the local technology#
The environments using the local
technology can be customized
by setting environment variables.
If
SKIP_SYSTEM_PKG_INSTALL
is set to1
(oryes
), then all steps of installing system packages are skipped in this run. When reusing a previously created tox environment, this option can save time and also give developers more control for experiments with system packages.If
SKIP_BOOTSTRAP
is set to1
(oryes
), then the bootstrapping phase is skipped. When reusing a previously created tox environment, this option can save time.If
SKIP_CONFIGURE
is set to1
(oryes
), then theconfigure
script is not run explicitly. When reusing a previously created tox environment, this option can save time. (TheMakefile
may still rerun configuration usingconfig.status --recheck
.)
The local
technology also defines a special target bash
:
Instead of building anything with make
, it just starts an
interactive shell. For example, in combination with the above
options:
[mkoeppe@sage worktree-local]$ SKIP_SYSTEM_PKG_INSTALL=yes SKIP_BOOTSTRAP=1 SKIP_CONFIGURE=1 tox -e local-homebrew-macos-minimal -- bash
Automatic testing on multiple platforms on GitHub Actions#
The Sage source tree includes a default configuration for GitHub Actions that runs our portability tests on a multitude of platforms on every push of a tag (but not of a branch) to a repository for which GitHub Actions are enabled.
In particular, it automatically runs on our main repository sagemath/sage on every release tag.
This is defined in the files
SAGE_ROOT/.github/workflows/ci-linux.yml (which calls SAGE_ROOT/.github/workflows/docker.yml) and
SAGE_ROOT/.github/workflows/ci-macos.yml (which calls SAGE_ROOT/.github/workflows/macos.yml).
GitHub Actions runs these build jobs on 2-core machines with 7 GB of
RAM memory and 14 GB of SSD disk space, cf.
here,
and has a time limit of 6h per job. This could be just barely enough for a
typical minimal
build followed by make ptest
to succeed; for
added robustness, we split it into two jobs. Our workflow stores
Docker images corresponding to various build phases within these two
jobs on GitHub Packages (ghcr.io).
Build logs can be inspected during the run and become available as “artifacts” when all jobs of the workflow have finished. Each job generates one tarball. “Annotations” highlight certain top-level errors or warnings issued during the build.
In addition to these automatic runs in our main repository, all Sage developers can run the same tests on GitHub Actions in their personal forks of the Sage repository. To prepare this, enable GitHub Actions in your fork of the Sage repository.
As usual we assume that origin
is the name of the remote
corresponding to your GitHub fork of the Sage repository:
$ git remote -v | grep origin
origin https://github.com/mkoeppe/sage.git (fetch)
origin https://github.com/mkoeppe/sage.git (push)
Then the following procedure triggers a run of tests with the default set of system configurations.
Push your branch to
origin
(your fork).Go to the Actions tab of your fork and select the workflow you would like to run, for example “CI Linux”.
Click on “Run workflow” above the list of workflow runs and select your branch as the branch on which the workflow will run.
For more information, see the GitHub documentation.
Alternatively, you can trigger a run of tests by creating and pushing a custom tag as follows.
Create a (“lightweight”, not “annotated”) tag with an arbitrary name, say
ci
(for “Continuous Integration”):git tag -f ci
Then push the tag to your GitHub repository:
git push -f origin ci
(In both commands, the “force” option (-f
) allows overwriting a
previous tag of that name.)
Either way, when the workflow has been triggered, you can inspect it by using the workflow status page in the “Actions” tab of your repository.
Here is how to read it. Each of the items in the left pane represents
a full build of Sage on a particular system configuration. A test
item in the left pane is marked with a green checkmark in the left
pane if make build doc-html
finished without error. (It also runs
package testsuites and the Sage doctests but failures in these are not
reflected in the left pane; see below.)
The right pane (“Artifacts”) offers archives of the logs for download.
Scrolling down in the right pane shows “Annotations”:
Red “check failure” annotations appear for each log file that contains a build error. For example, you might see:
docker (fedora-28, standard) artifacts/logs-commit-8ca1c2df8f1fb4c6d54b44b34b4d8320ebecb164-tox-docker-fedora-28-standard/logs/pkgs/sagetex-3.4.log#L1 ==== ERROR IN LOG FILE artifacts/logs-commit-8ca1c2df8f1fb4c6d54b44b34b4d8320ebecb164-tox-docker-fedora-28-standard/logs/pkgs/sagetex-3.4.log ====
Yellow “check warning” annotations. There are 2 types of these:
Package testsuite or Sage doctest failures, like the following:
docker (fedora-30, standard) artifacts/logs-commit-8ca1c2df8f1fb4c6d54b44b34b4d8320ebecb164-tox-docker-fedora-30-standard/logs/ptest.log#L1 ==== TESTSUITE FAILURE IN LOG FILE artifacts/logs-commit-8ca1c2df8f1fb4c6d54b44b34b4d8320ebecb164-tox-docker-fedora-30-standard/logs/ptest.log ====
Notices from ./configure about not finding equivalent system packages, like the following:
docker (fedora-31, standard) artifacts/logs-commit-8ca1c2df8f1fb4c6d54b44b34b4d8320ebecb164-tox-docker-fedora-31-standard/config.log#L1 configure: notice: the following SPKGs did not find equivalent system packages: cbc cddlib cmake eclib ecm fflas_ffpack flint fplll givaro gp
Clicking on the annotations does not take you to a very useful place. To view details, click on one of the items in the pane. This changes the right pane to a log viewer.
The docker
workflows automatically push images to
ghcr.io
. You find them in the Packages tab of your
GitHub repository.
In order to pull them for use on your computer, you need to first
generate a Personal Access Token providing the read:packages
scope
as follows. Visit https://github.com/settings/tokens/new (this may
prompt you for your GitHub password). As “Note”, type “Access
ghcr.io”; then in “Select scopes”, select the checkbox
for read:packages
. Finally, push the “Generate token” button at
the bottom. This will lead to a page showing your token, such as
de1ec7ab1ec0ffee5ca1dedbaff1ed0ddba11
. Copy this token and paste
it to the command line:
$ echo de1ec7ab1ec0ffee5ca1dedbaff1ed0ddba11 | docker login ghcr.io --username YOUR-GITHUB-USERNAME
where you replace the token by your token, of course, and
YOUR-GITHUB-USERNAME
by your GitHub username.
Now you can pull the image and run it:
$ docker pull ghcr.io/YOUR-GITHUB-USERNAME/sage/sage-fedora-31-standard-configured:f4bd671
$ docker run -it ghcr.io/YOUR-GITHUB-USERNAME/sage/sage-fedora-31-standard-configured:f4bd671 bash
Using our pre-built Docker images published on ghcr.io#
Our portability CI on GitHub Actions builds Docker images for all tested Linux platforms (and system package configurations) and makes them available on GitHub Packages (ghcr.io).
This makes it easy for developers to debug problems that showed up in the build logs for a given platform.
The image version corresponding to the latest development release
receives the additional Docker tag dev
, see for example the Docker
image for the platform ubuntu-focal-standard. Thus,
for example, the following command will work:
$ docker run -it ghcr.io/sagemath/sage/sage-ubuntu-focal-standard-with-targets-optional:dev bash
Unable to find image 'ghcr.io/sagemath/sage/sage-ubuntu-focal-standard-with-targets-optional:dev' locally
dev: Pulling from sagemath/sage/sage-ubuntu-focal-standard-with-targets-optional
d5fd17ec1767: Already exists
67586203f0c7: Pull complete
b63c529f4777: Pull complete
...
159775d1a3d2: Pull complete
Digest: sha256:e6ba5e12f59c6c4668692ef4cfe4ae5f242556482664fb347bf260f32bf8e698
Status: Downloaded newer image for ghcr.io/sagemath/sage/sage-ubuntu-focal-standard-with-targets-optional:dev
root@8055a7ba0607:/sage# ./sage
┌────────────────────────────────────────────────────────────────────┐
│ SageMath version 9.6, Release Date: 2022-05-15 │
│ Using Python 3.8.10. Type "help()" for help. │
└────────────────────────────────────────────────────────────────────┘
sage:
Images whose names end with the suffix -with-targets-optional
are
the results of full builds and a run of make ptest
. They also
contain a copy of the source tree and the full logs of the build and
test.
Also smaller images corresponding to earlier build stages are available:
-with-system-packages
provides a system installation with system packages installed, no source tree,-configured
contains a partial source tree (SAGE_ROOT
) and has completed the bootstrapping phase and the run of theconfigure
script,-with-targets-pre
contains a partial source tree (SAGE_ROOT
) and a full installation of all non-Python packages (SAGE_LOCAL
),-with-targets
contains the full source tree and a full installation of Sage, including the HTML documentation, butmake ptest
has not been run yet.
Platform |
Images |
|
---|---|---|
ubuntu-xenial-toolchain-gcc_9 ‑minimal |
||
‑standard |
||
‑maximal |
||
ubuntu-bionic-gcc_8 ‑minimal |
||
‑standard |
||
‑maximal |
||
ubuntu-focal ‑minimal |
||
‑standard |
||
‑maximal |
||
ubuntu-jammy ‑minimal |
||
‑standard |
||
‑maximal |
||
ubuntu-lunar ‑minimal |
||
‑standard |
||
‑maximal |
||
ubuntu-mantic ‑minimal |
||
‑standard |
||
‑maximal |
||
ubuntu-noble ‑minimal |
||
‑standard |
||
‑maximal |
||
debian-bullseye ‑minimal |
||
‑standard |
||
‑maximal |
||
debian-bookworm ‑minimal |
||
‑standard |
||
‑maximal |
||
debian-trixie ‑minimal |
||
‑standard |
||
‑maximal |
||
debian-sid ‑minimal |
||
‑standard |
||
‑maximal |
||
linuxmint-20.1 ‑minimal |
||
‑standard |
||
‑maximal |
||
linuxmint-20.2 ‑minimal |
||
‑standard |
||
‑maximal |
||
linuxmint-20.3 ‑minimal |
||
‑standard |
||
‑maximal |
||
linuxmint-21 ‑minimal |
||
‑standard |
||
‑maximal |
||
linuxmint-21.1 ‑minimal |
||
‑standard |
||
‑maximal |
||
linuxmint-21.2 ‑minimal |
||
‑standard |
||
‑maximal |
||
linuxmint-21.3 ‑minimal |
||
‑standard |
||
‑maximal |
||
fedora-30 ‑minimal |
||
‑standard |
||
‑maximal |
||
fedora-31 ‑minimal |
||
‑standard |
||
‑maximal |
||
fedora-32 ‑minimal |
||
‑standard |
||
‑maximal |
||
fedora-33 ‑minimal |
||
‑standard |
||
‑maximal |
||
fedora-34 ‑minimal |
||
‑standard |
||
‑maximal |
||
fedora-35 ‑minimal |
||
‑standard |
||
‑maximal |
||
fedora-36 ‑minimal |
||
‑standard |
||
‑maximal |
||
fedora-37 ‑minimal |
||
‑standard |
||
‑maximal |
||
fedora-38 ‑minimal |
||
‑standard |
||
‑maximal |
||
fedora-39 ‑minimal |
||
‑standard |
||
‑maximal |
||
fedora-40 ‑minimal |
||
‑standard |
||
‑maximal |
||
centos-7-devtoolset-gcc_11 ‑minimal |
||
‑standard |
||
‑maximal |
||
centos-stream-9-python3.9 ‑minimal |
||
‑standard |
||
‑maximal |
||
almalinux-8-python3.9 ‑minimal |
||
‑standard |
||
‑maximal |
||
almalinux-9-python3.11 ‑minimal |
||
‑standard |
||
‑maximal |
||
gentoo-python3.10 ‑minimal |
||
‑standard |
||
‑maximal |
||
gentoo-python3.11 ‑minimal |
||
‑standard |
||
‑maximal |
||
gentoo-python3.12 ‑minimal |
||
‑standard |
||
‑maximal |
||
archlinux-latest ‑minimal |
||
‑standard |
||
‑maximal |
||
opensuse-15.5-gcc_11-python3.11 ‑minimal |
||
‑standard |
||
‑maximal |
||
opensuse-tumbleweed-python3.10 ‑minimal |
||
‑standard |
||
‑maximal |
||
opensuse-tumbleweed ‑minimal |
||
‑standard |
||
‑maximal |
||
conda-forge-python3.11 ‑standard |
||
‑maximal |
||
ubuntu-bionic-gcc_8-i386 ‑minimal |
||
‑standard |
||
‑maximal |
||
debian-bullseye-i386 ‑minimal |
||
‑standard |
||
‑maximal |
Using our pre-built Docker images for development in VS Code#
VS Code is very convenient for developing with Docker containers thanks to the Visual Studio Code Dev Containers extension.
If the extension is not already installed, then in VS Code, click the “Extension” icon on the left (or press Ctrl + Shift + X; on macOS, Command + Shift + X) to open a list of extensions. Search for “Dev Containers” and install it.
The extension needs a devcontainer.json
configuration file to work. Sage
provides sample devcontainer.json
configuration files
$SAGE_ROOT/.devcontainer/*/devcontainer.json for this
purpose.
If you open the sage folder in VS Code, it may prompt you whether you would like to open the current directory in the dev container (yes). If it does not, use the command palette (Ctrl + Shift + P), enter the command “Dev Containers: Reopen Folder in Container” , and hit Enter.
If the above code .
command does not work, start VS Code as a regular
application, then in the command palette of VS Code, enter “Dev Containers:
Open Folder in Container”, and hit Enter, and choose the directory
$SAGE_ROOT
of your local Sage repository.
VS Code then prompts you to choose a dev container configuration.
For example, choose “ubuntu-jammy-standard” .devcontainer/portability-ubuntu-jammy-standard/devcontainer.json,
which uses the Docker image based on ubuntu-jammy-standard
, the most recent
development version of Sage (dev
tag), and a full installation of
the Sage distribution (with-targets
). Other dev container configurations
are described below.
Once VS Code starts configuring the dev container, by clicking on “show log”, you can see what it does:
It pulls the prebuilt image from ghcr.io (via SAGE_ROOT/.devcontainer/portability-Dockerfile); note that these are multi-gigabyte images, so it may take a while.
As part of the “onCreateCommand”, it installs additional system packages to support VS Code and for development.
Then, as part of the “updateContentCommand”, it bootstraps and configures the source tree and starts to build Sage from source, reusing the installation (
SAGE_LOCAL
,SAGE_VENV
) from the prebuilt image.
After VS Code finished configuring the dev container (when the message “Done.
Press any key to close the terminal.” appears in the terminal named
“Configuring”), your local Sage repository at $SAGE_ROOT
is available in
the container at the directory /workspaces/<repository name>
. To use Sage
in a terminal, open a new terminal in VS Code, type ./sage
and hit
Enter.
Note
Your Sage at $SAGE_ROOT
was configured and rebuilt inside the dev
container. In particular, $SAGE_ROOT/venv
, $SAGE_ROOT/prefix
, and
(possibly) $SAGE_ROOT/logs
will be symbolic links that work inside the dev
container, but not in your local file system; and also the script
$SAGE_ROOT/sage
will not work. Hence after working with the dev container,
you will want to remove logs
if it is a symbolic link, and rerun the
configure
script.
The Sage source tree contains premade configuration files for all platforms
for which our portability CI builds Docker images, both in the minimal
and
standard
system package configurations. The configuration files can be
generated using the command tox -e update_docker_platforms
(see
SAGE_ROOT/tox.ini for environment variables that take effect).
You can edit a copy of the configuration file to change to a different platform, another version, or build stage. After editing the configuration file, run “Dev Containers: Rebuild Container” from the command palette. See the VS Code devcontainer.json reference and the GitHub introduction to dev containers for more information.
In addition to the
$SAGE_ROOT/.devcontainer/portability-.../devcontainer.json
files, Sage also
provides several other sample devcontainer.json
configuration files in the
directory SAGE_ROOT/.devcontainer.
Files named $SAGE_ROOT/.devcontainer/develop-.../devcontainer.json
configure
containers from a public Docker image that provides SageMath and then updates the
installation of SageMath in this container by building from the current source tree.
develop-docker-computop/devcontainer.json configures a container with the Docker image from the 3-manifolds project, providing SnapPy, Regina, PHCPack, etc.
After VS Code finished configuring the
dev container, to use Sage in a terminal, open a new terminal in VS Code, type ./sage
and hit
Enter.
Files named $SAGE_ROOT/.devcontainer/downstream-.../devcontainer.json
configure
containers with an installation of downstream packages providing SageMath from a
package manager (downstream-archlinux-...
, downstream-conda-forge
;
see also the _sagemath dummy package),
or from a public Docker image that provides SageMath (docker-cocalc
, docker-computop
).
These devcontainer.json
configuration files are useful for testing
user scripts on these deployments of SageMath. You may also find it
useful to copy these configurations into your own projects (they should
work without change) or to adapt them to your needs.
downstream-archlinux-latest/devcontainer.json configures a container with an installation of Arch Linux and its SageMath package. (The suffix
latest
indicates the most recent version of Arch Linux as available on Docker Hub.)downstream-conda-forge-latest/devcontainer.json configures a container with an installation of conda-forge and its SageMath package.
downstream-docker-cocalc/devcontainer.json configures a container with the CoCalc Docker image.
downstream-docker-computop/devcontainer.json configures a container with the Docker image from the 3-manifolds project, providing SnapPy, Regina, PHCPack, etc.
After VS Code finished configuring the
dev container, to use Sage in a terminal, open a new terminal in VS Code, type sage
and hit
Enter. (Do not use ./sage
; this will not work because the source
tree is not configured.)