This controls installation of all OCR-D modules from source (as git submodules).
It includes a Makefile for their installation into a virtual environment (venv) or Docker container.
(A venv is a local user directory with shell scripts to load/unload itself in the current shell environment via PATH and PYTHONHOME.)
Note: If you are going to install ocrd_all, you may want to first consult the OCR-D setup guide on the OCR-D website. If you are a non-IT user, it is especially recommended you utilize the guide.
Make sure that there is enough free disk space. For a full installation including executables from all modules,
around 22 GiB will be needed (mostly on the same filesystem as the ocrd_all checkout). The same goes for the
maximum-cuda
variant of the prebuilt Docker images (due on the filesystem harboring Docker, typically
/var/lib/docker
).
Also, during build, an additional 5 GiB may be needed for temporary files, typically in the /tmp
directory.
To use a different location path with more free space, set the TMPDIR
variable when calling make
:
TMPDIR=/path/to/my/tempdir make all
The (shell) environment must have a Unicode-based localization.
(Otherwise Python code based on click
will not work, i.e. most OCR-D CLIs.)
This is true for most installations today, and can be verified by:
locale | fgrep .UTF-8
This should show several LC_*
variables. Otherwise, either select another localization globally...
sudo dpkg-reconfigure locales
... or use the Unicode-based POSIX locale temporarily:
export LC_ALL=C.UTF-8
export LANG=C.UTF-8
-
Install git, GNU make and GNU parallel.
# on Debian / Ubuntu: sudo apt install make git parallel
-
Install wget or curl if you want to download Tesseract models.
# on Debian / Ubuntu: sudo apt install wget
-
Install the packages for Python3 development and Python3 virtual environments for your operating system / distribution.
# on Debian / Ubuntu: sudo apt install python3-dev python3-venv
-
Some modules require Tesseract. If your operating system / distribution already provides Tesseract 4.1 or newer, then just install its development package:
# on Debian / Ubuntu: sudo apt install libtesseract-dev
Otherwise, recent Tesseract packages for Ubuntu are available via PPA alex-p.
If no Tesseract is installed, a recent version will be downloaded and built as part of the
ocrd_tesserocr
module rules. -
Other modules will have additional system dependencies.
Note: System dependencies for all modules on Ubuntu 20.04 (or similar) can also be installed automatically by running:
# on Debian / Ubuntu: make modules sudo apt install make sudo make deps-ubuntu
(And you can define the scope of all modules by setting the
OCRD_MODULES
variable as described below. If unsure, consider doing a dry-run first, by usingmake -n
.)
Many executables can utilize Nvidia GPU for much faster computation, if available (i.e. optionally).
For that, as a further prerequisite you need an installation of CUDA Toolkit and additional optimised libraries like cuDNN for your system.
The CUDA version currently supported is 11.8 (but other's may work as well).
Note: CUDA toolkit and libraries (in a development version with CUDA compiler) can also be installed automatically by running:
make ocrd sudo make deps-cuda
This will deploy Micromamba non-intrusively (without system packages or Conda environments), but also share some of the CUDA libraries installed as Python packages system-wide via ld.so.conf rules. If unsure, consider doing a dry-run first, by using
make -n
.)
Run make
with optional parameters for variables and targets like so:
make [PYTHON=python3] [VIRTUAL_ENV=./venv] [OCRD_MODULES="..."] [TARGET...]
Install system packages for all modules. (Depends on modules.)
See system package prerequisites above.
Install CUDA toolkit and libraries. (Depends on ocrd.)
See (optional) GPU support prerequisites above.
Checkout/update all modules, but do not install anything.
Install executables from all modules into the venv. (Depends on modules and ocrd.)
Install only the core
module and its CLI ocrd
into the venv.
(Re-)build a Docker image for all modules/executables. (Depends on modules.)
(Re-)build Docker images for some pre-selected subsets of modules/executables. (Depends on modules.)
(These are the very same variants published as prebuilt images on Docker Hub, cf. CI configuration.)
Note: The image will contain all refs and branches of all checked out modules, which may not be actually needed. If you are planning on building and distributing Docker images with minimal size, consider using
GIT_DEPTH=--single-branch
beforemodules
or runningmake tidy
later-on.
Remove the venv and the modules' build directories.
Print the venv directory, the module directories, and the executable names – as configured by the current variables.
Verify that all executables are runnable and the venv is consistent.
Print available targets and variables.
Further targets:
Download/update that module, but do not install anything.
Install that CLI into the venv. (Depends on that module and on ocrd.)
Override the list of git submodules to include. Targets affected by this include:
- deps-ubuntu (reducing the list of system packages to install)
- modules (reducing the list of modules to checkout/update)
- all (reducing the list of executables to install)
- docker (reducing the list of executables and modules to install)
- show (reducing the list of
OCRD_MODULES
and ofOCRD_EXECUTABLES
to print)
If set to 1
, then when installing executables, does not attempt to git submodule update
any currently checked out modules. (Useful for development when testing different module version
prior to a commit.)
Name of the Python binary to use (at least python3 required).
If set to just python
, then for the target deps-ubuntu
it is assumed that Python is already installed.
Directory prefix to use for local installation.
(This is set automatically when activating a virtual environment on the shell. The build system will re-use the venv if one already exists here, or create one otherwise.)
Override the default path (/tmp
on Unix) where temporary files during build are stored.
Add extra options to the pip install
command like -q
or -v
or -e
.
Note: The latter option will install Python modules in editable mode, i.e. any update to the source would directly affect the executables.
Set to --recursive
to checkout/update all modules recursively. (This usually installs additional tests and models.)
To build the latest Tesseract locally, run this command first:
# Get code, build and install Tesseract with the default English model.
make install-tesseract
make ocrd-tesserocr-recognize
Optionally install additional Tesseract models.
# Download models from tessdata_fast into the venv's tessdata directory.
ocrd resmgr download ocrd-tesserocr-recognize frk.traineddata
ocrd resmgr download ocrd-tesserocr-recognize Latin.traineddata
ocrd resmgr download ocrd-tesserocr-recognize Fraktur.traineddata
Optionally install Tesseract training tools.
make install-tesseract-training
Running make ocrd
or just make
downloads/updates and installs the core
module,
including the ocrd
CLI in a virtual Python 3 environment under ./venv
.
Running make ocrd-tesserocr-recognize
downloads/updates the ocrd_tesserocr
module
and installs its CLIs, including ocrd-tesserocr-recognize
in the venv.
Running make modules
downloads/updates all modules.
Running make all
additionally installs the executables from all modules.
Running make all OCRD_MODULES="core ocrd_tesserocr ocrd_cis"
installs only the executables from these modules.
To use the built executables, simply activate the virtual environment:
. ${VIRTUAL_ENV:-venv}/bin/activate
ocrd --help
ocrd-...
For the Docker image, run it with your data path mounted as a user, and the processor resources as named volume (for model persistency):
docker run -it -u $(id -u):$(id -g) -v $PWD:/data -v ocrd-models:/models ocrd/all
ocrd --help
ocrd-...
In order to make choices permanent, you can put your variable preferences
(or any custom rules) into local.mk
. This file is always included if it exists.
So you don't have to type (and memorise) them on the command line or shell environment.
For example, its content could be:
# restrict everything to a subset of modules
OCRD_MODULES = core ocrd_im6convert ocrd_cis ocrd_tesserocr
# use a non-default path for the virtual environment
VIRTUAL_ENV = $(CURDIR)/.venv
# install in editable mode (i.e. referencing the git sources)
PIP_OPTIONS = -e
# use non-default temporary storage
TMPDIR = $(CURDIR)/.tmp
# avoid automatic submodule updates
NO_UPDATE = 1
Note: When
local.mk
exists, variables can still be overridden on the command line, (i.e.make all OCRD_MODULES=
will build all executables for all modules again), but not from the shell environment (i.e.OCRD_MODULES= make all
will still use the value from local.mk).
Besides native installation, ocrd_all
is also available as prebuilt Docker images
from Docker Hub as ocrd/all
, backed by CI/CD.
You can choose from three tags, minimum
, medium
and maximum
. These differ w.r.t.
which modules are included, with maximum
being the equivalent of doing make all
with the default (unset) value for OCRD_MODULES
.
To download the images on the command line:
docker pull ocrd/all:minimum
# or
docker pull ocrd/all:medium
# or
docker pull ocrd/all:maximum
In addition to these base variants, there are minimum-cuda
, medium-cuda
and maximum-cuda
with GPU support.
(These also need nvidia-docker runtime, which will add the
docker --gpus
option.)
The maximum-cuda
variant will be aliased to latest
as well.
These tags will be overwritten with every new release of ocrd_all (i.e. rolling release). (You can still differentiate and reference them by their sha256 digest if necessary.)
However, the maximum-cuda
variant of each release will also be aliased to a permanent tag by ISO date, e.g. 2023-04-02
.
Usage of the prebuilt Docker image is the same as if you had built the image yourself.
This table lists which tag contains which module:
Module | minimum |
medium |
maximum |
---|---|---|---|
core | ☑ | ☑ | ☑ |
ocrd_cis | ☑ | ☑ | ☑ |
ocrd_fileformat | ☑ | ☑ | ☑ |
ocrd_olahd_client | ☑ | ☑ | ☑ |
ocrd_im6convert | ☑ | ☑ | ☑ |
ocrd_pagetopdf | ☑ | ☑ | ☑ |
ocrd_repair_inconsistencies | ☑ | ☑ | ☑ |
ocrd_tesserocr | ☑ | ☑ | ☑ |
ocrd_wrap | ☑ | ☑ | ☑ |
workflow-configuration | ☑ | ☑ | ☑ |
cor-asv-ann | - | ☑ | ☑ |
dinglehopper | - | ☑ | ☑ |
docstruct | - | ☑ | ☑ |
format-converters | - | ☑ | ☑ |
nmalign | - | ☑ | ☑ |
ocrd_calamari | - | ☑ | ☑ |
ocrd_keraslm | - | ☑ | ☑ |
ocrd_neat | - | ☑ | ☑ |
ocrd_olena | - | ☑ | ☑ |
ocrd_segment | - | ☑ | ☑ |
ocrd_anybaseocr | - | - | ☑ |
ocrd_detectron2 | - | - | ☑ |
ocrd_doxa | - | - | ☑ |
ocrd_kraken | - | - | ☑ |
ocrd_froc | - | - | ☑ |
sbb_binarization | - | - | ☑ |
cor-asv-fst | - | - | - |
ocrd_ocropy | - | - | - |
ocrd_pc_segmentation | - | - | - |
Note: The following modules have been disabled by default and can only be enabled by explicitly setting
OCRD_MODULES
orDISABLED_MODULES
:
cor-asv-fst
(runtime issues)ocrd_ocropy
(better implementation in ocrd_cis available)ocrd_pc_segmentation
(dependency and quality issues)
If you have installed ocrd_all natively and wish to uninstall, first deactivate
the virtual environment and remove the ocrd_all
directory:
rm -rf ocrd_all
Next, remove all contents under ~/.parallel/semaphores:
rm -rf ~/.parallel/semaphores
This repo offers solutions to the following problems with OCR-D integration.
Python modules which are not available in PyPI:
(Solved by installation from source.)
Merging all packages into one venv does not always work. Modules may require mutually exclusive sets of dependent packages.
pip
does not even stop or resolve conflicts – it merely warns!
-
Tensorflow:
- version 2 (required by
ocrd_calamari
,ocrd_anybaseocr
andeynollah
) - version 1 (required by
cor-asv-ann
,ocrd_segment
andocrd_keraslm
)
The temporary solution is to require different package names:
tensorflow>=2
tensorflow-gpu==1.15.*
Both cannot be installed in parallel in different versions, and usually also depend on different versions of CUDA toolkit.
- version 2 (required by
-
OpenCV:
opencv-python-headless
(required by core and others, avoids pulling in X11 libraries)opencv-python
(probably dragged in by third party packages)
As long as we keep reinstalling the headless variant and no such package attempts GUI, we should be fine. Custom build (as needed for ARM) under the module
opencv-python
already creates the headless variant. -
PyTorch:
torch<1.0
torch>=1.0
-
...
(Solved by managing and delegating to different subsets of venvs.)
Modules which do not advertise their system package requirements via make deps-ubuntu
:
(Solved by maintaining these requirements under deps-ubuntu
here.)
Please see our contributing guide to learn how you can support the project.
This software uses GNU parallel. GNU Parallel is a general parallelizer to run multiple serial command line programs in parallel without changing them.
Tange, Ole. (2020). GNU Parallel 20200722 ('Privacy Shield'). Zenodo. https://doi.org/10.5281/zenodo.3956817