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view Sphinx/source/plugins/python.rst @ 1114:3ba00e52b267
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author | Alain Mazy <am@orthanc.team> |
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date | Tue, 05 Nov 2024 13:24:16 +0100 |
parents | e70e9f412627 |
children | 40429876c729 |
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.. _python-plugin: Python plugin for Orthanc ========================= .. contents:: Overview -------- This plugin can be used to write :ref:`Orthanc plugins <creating-plugins>` using the `Python programming language <https://en.wikipedia.org/wiki/Python_(programming_language)>`__ instead of the more complex C/C++ programming languages. Python plugins have access to more features and a more consistent SDK than :ref:`Lua scripts <lua>`. The largest part of the Python API is automatically generated from the `Orthanc plugin SDK in C <https://orthanc.uclouvain.be/hg/orthanc/file/Orthanc-1.12.4/OrthancServer/Plugins/Include/orthanc/OrthancCPlugin.h>`__ using the `Clang <https://en.wikipedia.org/wiki/Clang>`__ compiler front-end. As of release 4.3 of the plugin, **the coverage of the C SDK is about 85%** (140 functions are automatically wrapped in Python out of a total of 165 functions from the Orthanc SDK 1.10.0). Starting with release 4.3, the code model that is used to generate the Python wrapper is shared with the :ref:`Java wrapper <java-plugin>`. Source code ----------- * Link to the `official releases of this plugin <https://orthanc.uclouvain.be/downloads/sources/orthanc-python/index.html>`__. * Link to the `code repository <https://orthanc.uclouvain.be/hg/orthanc-python/>`__. * Link to the `Python interface <https://orthanc.uclouvain.be/downloads/cross-platform/orthanc-python/index.html>`__ (cf. :ref:`below <python-code-completion>` for more information about the ``orthanc.pyi`` file). Licensing --------- Pay attention to the fact that this plugin is licensed under the terms of the `AGPL license <https://en.wikipedia.org/wiki/GNU_Affero_General_Public_License>`__. This has an important consequence: If you distribute Orthanc to clients together with one Python script, or if you put an Orthanc server equipped with one Python script on a Web portal, you **must** disclose the source code of your Python script to the Orthanc community under the terms of the AGPL license. We suggest you to put the source code of your Python scripts on the dedicated `"OrthancContributed" repository on GitHub <https://github.com/jodogne/OrthancContributed/tree/master/Plugins>`__, and/or to send it to the `Orthanc Users discussion forum <https://discourse.orthanc-server.org>`__. Check out the :ref:`FAQ about licensing <licensing>` for more context. Usage ----- Docker ...... .. highlight:: python The most direct way of starting Orthanc together with the Python plugin is through :ref:`Docker <docker>`. Let's create the file ``/tmp/hello.py`` that contains the following basic Python script:: print('Hello world!') .. highlight:: json Let's also create the file ``/tmp/orthanc.json`` that contains the following minimal :ref:`configuration for Orthanc <configuration>`:: { "StorageDirectory" : "/var/lib/orthanc/db", "RemoteAccessAllowed" : true, "Plugins" : [ "/usr/local/share/orthanc/plugins" ], "PythonScript" : "/etc/orthanc/hello.py" } .. highlight:: bash Given these two files, Orthanc can be started as follows:: $ docker run -p 4242:4242 -p 8042:8042 --rm \ -v /tmp/orthanc.json:/etc/orthanc/orthanc.json:ro \ -v /tmp/hello.py:/etc/orthanc/hello.py:ro \ jodogne/orthanc-python .. highlight:: text You'll see the following excerpt in the log, which indicates that the Python plugin is properly loaded:: W0331 15:48:12.990661 PluginsManager.cpp:269] Registering plugin 'python' (version mainline) W0331 15:48:12.990691 PluginsManager.cpp:168] Python plugin is initializing W0331 15:48:12.990743 PluginsManager.cpp:168] Using Python script "hello.py" from directory: /etc/orthanc W0331 15:48:12.990819 PluginsManager.cpp:168] Program name: /usr/local/sbin/Orthanc Hello world! `Here <https://github.com/orthanc-server/orthanc-setup-samples/tree/master/docker/python/>`__ is a full example of a more complex setup using the :ref:`orthancteam/orthanc <docker-orthancteam>` images. Microsoft Windows ................. Pre-compiled binaries for Microsoft Windows are now part of the `Windows installers <https://www.orthanc-server.com/download-windows.php>`__ but not installed by default. They are also `available here <https://orthanc.uclouvain.be/downloads/windows-32/orthanc-python/index.html>`__. Beware that one version of the Python plugin can only be run against one version of the Python interpreter. This version is clearly indicated in the filename of the precompiled binaries. Pay also attention to pick the right 32/64 bits version. If you are running Orthanc 64bits, install Python in 64bits and select the 64bits Python plugin too. When you install Python on your Windows machine, make sure to install Python for ``All Users`` and select the ``Add Python to Path`` option. Compiling from source ..................... For GNU/Linux ^^^^^^^^^^^^^ .. highlight:: bash The procedure to compile this plugin from source is similar to that for the :ref:`core of Orthanc <compiling>`. The following commands should work for most UNIX-like distribution (including GNU/Linux):: $ mkdir Build $ cd Build $ cmake .. -DPYTHON_VERSION=3.7 -DSTATIC_BUILD=ON -DCMAKE_BUILD_TYPE=Release $ make Before running CMake, make sure that the Python interpreter and its associated development library are installed. On Ubuntu 18.04 LTS, you would for instance install packages ``libpython3.7-dev`` and ``python3.7``. The compilation will produce the shared library ``OrthancPython``, that can be loaded by properly setting the ``Plugins`` :ref:`configuration option <configuration>` of Orthanc. **Warning:** The shared library is only compatible with the Python interpreter whose version corresponds to the value of the ``PYTHON_VERSION`` argument that was given to CMake. **Note for OS X:** As indicated by `Stephen Douglas Scotti <https://groups.google.com/g/orthanc-users/c/RnmZKFv8FaY/m/HhvOD2A2CAAJ>`__, here is a sample invocation of CMake to force the version of Python to be used on OS X:: $ cmake .. -DPYTHON_VERSION=3.8 -DSTATIC_BUILD=ON -DCMAKE_BUILD_TYPE=Release \ -DPYTHON_LIBRARY=/usr/local/Cellar/python@3.8/3.8.5/Frameworks/Python.framework/Versions/3.8/lib/libpython3.8.dylib \ -DPYTHON_INCLUDE_DIR=/usr/local/Cellar/python@3.8/3.8.5/Frameworks/Python.framework/Versions/3.8/include/python3.8/ For Microsoft Windows ^^^^^^^^^^^^^^^^^^^^^ .. highlight:: text You are of course free to compile the plugin from sources. You'll have to explicitly specify the path to your Python installation while invoking CMake. For instance:: C:\orthanc-python\Build> cmake .. -DPYTHON_VERSION=3.8 -DPYTHON_WINDOWS_ROOT=C:/Python38 \ -DSTATIC_BUILD=ON -DCMAKE_BUILD_TYPE=Release -G "Visual Studio 15 2017" **Note about debug builds**: Usually, building Python modules such as the Python plugin for Orthanc in debug mode (where ``_DEBUG`` is defined) leads to a module (``.exe`` or ``.dll``) that requires a debug build of Python, and debug versions of all the Python libraries. This is quite cumbersome, for it requires building Python on your own or downloading additional debug files. Since using a debug build of Python is only necessary in very specific cases (such as the debugging of code at the boundary between Python and an extension), we have changed the default behavior to use the release Python library by default. This means that you are able to build this plugin in debug mode with the standard Python distribution. In case you need to use the Python debug libraries, you can instruct the build system to do so by setting the ``PYTHON_WINDOWS_USE_RELEASE_LIBS`` CMake option, that is ``ON`` by default, to ``OFF``. The previous build example would then be, should you require a full debug build:: C:\orthanc-python\Build> cmake .. -DPYTHON_VERSION=3.8 -DPYTHON_WINDOWS_ROOT=C:/Python38 \ -DSTATIC_BUILD=ON -DPYTHON_WINDOWS_USE_RELEASE_LIBS=OFF \ -DCMAKE_BUILD_TYPE=Debug -G "Visual Studio 15 2017" Please note that this CMake option only impacts **debug** builds under Windows, when using (any version of) the Microsoft Visual Studio compiler. The precompiled binaries all use release (i.e. non-debug) versions of Python. Configuration options --------------------- The two main configuration options that are available for this plugin are the following: * ``PythonScript`` indicates where the Python script is located. If this configuration option is not provided, the Python plugin is not started. * ``PythonVerbose`` is a Boolean value to make the Python interpreter verbose. Consequently, a minimal :ref:`configuration file <configuration>` for Orthanc could be:: { "Plugins" : [ "." ], "PythonScript" : "my-plugin.py", "PythonVerbose" : false } Starting with release 4.1 of the Python plugin, it is also possible to specify the configuration of the plugin in a dedicated ``Python`` section as follows:: { "Plugins" : [ "." ], "Python" : { "Path" : "my-plugin.py", // Alias for the global "PythonScript" option "Verbose" : false, // Alias for the global "PythonVerbose" option "DisplayMemoryUsage" : false, "AllowThreads" : false } } The option ``Python.DisplayMemoryUsage`` was introduced in release 4.1 of the plugin. If set to ``true``, Orthanc will display the memory usage of the Python interpreter every second. The option ``Python.AllowThreads`` was introduced in release 4.3 of the plugin. If set to ``true``, the Python GIL (`Global Interpreter Lock <https://en.wikipedia.org/wiki/Global_interpreter_lock>`__) is released during the calls to the native SDK. **This allows multiple Python threads to simultaneously access the Orthanc core.** Internally, this corresponds to the ``Py_BEGIN_ALLOW_THREADS`` `construction of Python <https://docs.python.org/3/c-api/init.html#releasing-the-gil-from-extension-code>`__. However, this could possibly introduce concurrency issues: Make sure that your Python code is **thread-safe** before enabling this option! Indeed, different threads must not modify the Python objects that are used during a call to the SDK of Orthanc. .. warning:: Never call your Python plugin ``orthanc.py``! Otherwise, your plugin will conflict with the ``orthanc`` module that is installed at runtime. .. _python-code-completion: Documentation and code completion --------------------------------- Starting with release 4.3 of the Python plugin for Orthanc, a `Python interface (cf. PEP 484 - Type Hints) <https://peps.python.org/pep-0484/>`__ is available. By downloading the file ``orthanc.pyi`` `from this location <https://orthanc.uclouvain.be/downloads/cross-platform/orthanc-python/index.html>`__ and putting it in the same folder as your Python script, your IDE will provide you code completion, as well as full documentation of the Orthanc SDK in the Python language. This file is notably known to work with Visual Studio Code and PyCharm. Samples ------- Extending the REST API ...................... Here is a basic Python script that registers two new routes in the REST API: .. literalinclude:: python/extending-rest-api.py :language: python .. highlight:: json Here is the associated minimal configuration file for Orthanc (provided the Python script is saved as ``rest.py``):: { "Plugins" : [ "." ], "PythonScript" : "rest.py", "PythonVerbose" : false } .. highlight:: bash The route can then be accessed as:: $ curl http://localhost:8042/toto ok Overriding the core REST API ............................ You may also use a python plugin to replace an existing REST API route: .. literalinclude:: python/extending-rest-api-2.py :language: python When calling the REST API from a python plugin, you may use e.g. ``RestApiPost`` to call the native Orthanc REST API and must call ``RestApiPostAfterPlugin`` to call the REST API from plugins. Note however, that, as of Orthanc 1.12.4, the Orthanc plugin SDK does not support multiple plugins implementing the same route. Orthanc will actually accept e.g a Python plugin that overrides a DICOMWeb route but it is impossible to tell which route will be called in the end since this depends on the registration order of the plugins that is not deterministic. .. _python-changes: Listening to changes .................... This sample uploads a DICOM file as soon as Orthanc is started: .. literalinclude:: python/listening-changes.py :language: python .. warning:: In releases <= 3.0 of the Python plugin, deadlocks might emerge if you call other core primitives of Orthanc (such as the REST API) in your callback function. This issue has been `fixed in release 3.1 <https://orthanc.uclouvain.be/hg/orthanc-python/rev/46fe70776d61>`__. As a **temporary workaround** against such deadlocks in releases <= 3.0, if you have to call other primitives of Orthanc, you should make these calls in a separate thread, passing the pending events to be processed through a message queue. Here is the template of a possible solution to postpone such deadlocks as much as possible by relying on the multithreading primitives of Python: .. literalinclude:: python/changes-deadlock-3.0.py :language: python Beware that **this workaround is imperfect** and deadlocks have been observed even if using it! Make sure to upgrade your plugin to solve this issue for good. Note that this temporary workaround is not needed in releases >= 3.1 of the plugin. Accessing the content of a new instance ....................................... .. literalinclude:: python/accessing-new-instance.py :language: python .. warning:: Your callback function will be called synchronously with the core of Orthanc. This implies that deadlocks might emerge if you call other core primitives of Orthanc in your callback (such deadlocks are particular visible in the presence of other plugins or Lua scripts). It is thus strongly advised to avoid any call to the REST API of Orthanc in the callback. If you have to call other primitives of Orthanc, you should make these calls in a separate thread, passing the pending events to be processed through a message queue. Calling pydicom ............... Here is a sample Python plugin that registers a REST callback to dump the content of the dataset of one given DICOM instance stored in Orthanc, using `pydicom <https://pydicom.github.io/>`__: .. literalinclude:: python/pydicom.py :language: python .. highlight:: bash This callback can be called as follows:: $ curl http://localhost:8042/pydicom/19816330-cb02e1cf-df3a8fe8-bf510623-ccefe9f5 Auto-routing studies .................... Here is a sample Python plugin that routes any :ref:`stable study <stable-resources>` to a modality named ``samples`` (as declared in the ``DicomModalities`` configuration option): .. literalinclude:: python/autorouting-1.py :language: python Note that, if you want to use an orthanc plugin to transfer the study, you should use the ``RestApiPostAfterPlugins()`` method: .. literalinclude:: python/autorouting-2.py :language: python .. _python-pil-thumbnail: Rendering a thumbnail using PIL/Pillow ...................................... .. literalinclude:: python/pil.py :language: python .. _python-introspection: Inspecting the available API ............................ Thanks to Python's introspection primitives, it is possible to inspect the API of the ``orthanc`` module in order to dump all the available features: .. literalinclude:: python/inspect-api.py :language: python .. _python-scheduler: Scheduling a task for periodic execution ........................................ The following Python script will periodically (every second) run the function ``Hello()`` thanks to the ``threading`` module: .. literalinclude:: python/periodic-execution.py :language: python .. _python-metadata: Filtering and returning metadata ................................ Besides the main DICOM tags, Orthanc associates some metadata to each resource it stores (this includes the date of last update, the transfer syntax, the remote AET...). People are often interested in getting such metadata while calling the ``/tools/find`` route in the :ref:`REST API <rest-find>`, or even in filtering this metadata the same way they look for DICOM tags. This feature is not built in the core of Orthanc, as metadata is not indexed in the Orthanc database, contrarily to the main DICOM tags. Filtering metadata requires a linear search over all the matching resources, which induces a cost in the performance. Nevertheless, here is a full sample Python script that overwrites the ``/tools/find`` route in order to give access to metadata: .. literalinclude:: python/filtering-metadata.py :language: python **Warning:** In the sample above, the filtering of the metadata is done using Python's `library for regular expressions <https://docs.python.org/3/library/re.html>`__. It is evidently possible to adapt this script in order to use the DICOM conventions about `attribute matching <http://dicom.nema.org/medical/dicom/2019e/output/chtml/part04/sect_C.2.2.2.html>`__. .. highlight:: bash Here is a sample call to retrieve all the studies that were last updated in 2019 thanks to this Python script:: $ curl http://localhost:8042/tools/find -d '{"Level":"Study","Query":{},"Expand":true,"Metadata":{"LastUpdate":"^2019.*$"}}' .. _python-paging: Implementing basic paging ......................... As explained in the FAQ, the :ref:`Orthanc Explorer interface is low-level <improving-interface>`, and is not adapted for end-users. One common need is to implement paging of studies, which calls for server-side sorting of studies. This can be done using the following sample Python plugin that registers a new route ``/sort-studies`` in the REST API of Orthanc: .. literalinclude:: python/paging.py :language: python .. highlight:: bash Here is a sample call to this new REST route, that could be issued by any JavaScript framework (the ``json_pp`` command-line pretty-prints a JSON file):: $ curl http://localhost:8042/sort-studies | json_pp This route also implement paging (i.e. it can limit and offset the returned studies):: $ curl 'http://localhost:8042/sort-studies?offset=2&limit=2' | json_pp Obviously, this basic sample can be improved in many ways. To improve performance, one could for instance cache the result of ``/studies?expand`` in memory by :ref:`listening to changes <python-changes>` in the list of studies (cf. ``orthanc.ChangeType.NEW_STUDY`` and ``orthanc.ChangeType.DELETED``). .. _python_excel: Creating a Microsoft Excel report ................................. As Orthanc plugins have access to any installed Python module, it is very easy to implement a server-side plugin that generates a report in the Microsoft Excel ``.xls`` format. Here is a working example: .. literalinclude:: python/excel.py :language: python If opening the ``http://localhost:8042/report.xls`` URI, this Python will generate a workbook with one sheet that contains the list of studies, with the patient ID, the patient name and the study description. .. _python_authorization: Forbid or allow access to REST resources (authorization, new in 3.0) .................................................................... The following Python script installs a callback that is triggered whenever the HTTP server of Orthanc is accessed: .. literalinclude:: python/authorization-1.py :language: python If access is not granted, the ``Filter`` callback must return ``False``. As a consequence, the HTTP status code would be set to ``403 Forbidden``. If access is granted, the ``Filter`` must return ``true``. The ``request`` argument contains more information about the request (such as the HTTP headers, the IP address of the caller and the GET arguments). Note that this is similar to the ``IncomingHttpRequestFilter()`` callback that is available in :ref:`Lua scripts <lua-filter-rest>`. Thanks to Python, it is extremely easy to call remote Web services for authorization. Here is an example using the ``requests`` library: .. literalinclude:: python/authorization-2.py :language: python This filter could be used together with the following Web service implemented using `Node.js <https://en.wikipedia.org/wiki/Node.js>`__: .. literalinclude:: python/authorization-node-service.js :language: javascript .. _python_lookup_dictionary: Lookup DICOM dictionary (new in 3.2) .................................... Python plugins can access the dictionary of the DICOM tags that are handled by Orthanc: .. literalinclude:: python/lookup-dictionary.py :language: python .. highlight:: text Note how Python introspection is used in order to map the values in enumeration ``orthanc.ValueRepresentation`` to a string description of the value representation. If started, the plugin above would output the following information in the Orthanc logs:: W0611 14:04:08.563957 PluginsManager.cpp:168] Entry in the dictionary: { "Element": 32, "Group": 16, "MaxMultiplicity": 1, "MinMultiplicity": 1, "ValueRepresentation": 11 } W0611 14:04:08.563975 PluginsManager.cpp:168] Name of the value representation: LO .. _python_create_dicom: Creating DICOM instances (new in 3.2) ..................................... The following sample Python script will write on the disk a new DICOM instance including the traditional Lena sample image, and will decode the single frame of this DICOM instance: .. literalinclude:: python/create-dicom.py :language: python .. _python_pil_conversions: Conversions between Orthanc and Python images (new in 3.2) .......................................................... The Python method ``orthanc.Image.GetImageBuffer()`` returns a copy of the memory buffer of an image that is handled Orthanc. Conversely, the Python function ``orthanc.CreateImageFromBuffer()`` can be used to create an Orthanc image from a Python buffer. Taken together, these two functions can be used to do bidirectional conversions between Orthanc images and Python images. Here is a full working example using PIL/Pillow that shows how to decode one frame of a DICOM instance using Orthanc, then to modify this image using PIL, and finally to upload the modified image as a new DICOM instance: .. literalinclude:: python/pil-conversions.py :language: python .. _python_dicom_scp: Handling DICOM SCP requests (new in 3.2) ........................................ Starting with release 3.2 of the Python plugin, it is possible to replace the C-FIND SCP and C-MOVE SCP of Orthanc by a Python script. This feature can notably be used to create a custom DICOM proxy. Here is a minimal example: .. literalinclude:: python/dicom-find-move-scp.py :language: python .. highlight:: text In this sample, the C-FIND SCP will send one single answer that reproduces the values provided by the SCU:: $ findscu localhost 4242 -S -k QueryRetrieveLevel=STUDY -k PatientName=TEST -k SeriesDescription= I: --------------------------- I: Find Response: 1 (Pending) I: I: # Dicom-Data-Set I: # Used TransferSyntax: Little Endian Explicit I: (0008,0005) CS [ISO_IR 100] # 10, 1 SpecificCharacterSet I: (0008,0052) CS [HELLO0-STUDY] # 12, 1 QueryRetrieveLevel I: (0008,103e) LO [HELLO1- ] # 8, 1 SeriesDescription I: (0010,0010) PN [HELLO2-TEST ] # 12, 1 PatientName I: A more realistic Python script could for instance call the route ``/modalities/{...}/query`` in the :ref:`REST API <rest-find-scu>` of Orthanc using ``orthanc.RestApiPost()``, in order to query the content a remote modality through a second C-FIND SCU request (this time issued by Orthanc as a SCU). The C-MOVE SCP can be invoked as follows:: $ movescu localhost 4242 -aem TARGET -aec SOURCE -aet MOVESCU -S -k QueryRetrieveLevel=IMAGE -k StudyInstanceUID=1.2.3.4 The C-MOVE request above would print the following information in the Orthanc logs:: W0610 18:30:36.840865 PluginsManager.cpp:168] C-MOVE request to be handled in Python: { "AccessionNumber": "", "Level": "INSTANCE", "OriginatorAET": "MOVESCU", "OriginatorID": 1, "PatientID": "", "SOPInstanceUID": "", "SeriesInstanceUID": "", "SourceAET": "SOURCE", "StudyInstanceUID": "1.2.3.4", "TargetAET": "TARGET" } It is now up to your Python callback to process the C-MOVE SCU request, for instance by calling the route ``/modalities/{...}/store`` in the :ref:`REST API <rest-store-scu>` of Orthanc using ``orthanc.RestApiPost()``. It is highly advised to create a Python thread to handle the request, in order to avoid blocking Orthanc as much as possible. **Note:** In version 4.2, we have introduced a new version of the C-MOVE SCP handler that can be registered through ``orthanc.RegisterMoveCallback2(CreateMoveCallback, GetMoveSizeCallback, ApplyMoveCallback, FreeMoveCallback)``. This `DICOM to DICOMWeb proxy sample project <https://github.com/orthanc-team/dicom-dicomweb-proxy/blob/main/proxy.py>`__ demonstrates how it can be used. .. _python_worklists: Handling worklist SCP requests (new in 3.2) ........................................... Starting with release 3.2 of the Python plugin, it is possible to answer :ref:`worklist queries <worklist>` using a Python script. This is especially useful to easily create a bridge between Orthanc, HL7/FHIR messages and RIS systems. Indeed, Python provides many tools to handle HL7 such as `python-hl7 library <https://python-hl7.readthedocs.io/en/latest/>`__. The following Python script reproduces features similar to the :ref:`sample modality worklists plugin <worklists-plugin>`: .. literalinclude:: python/worklist.py :language: python .. highlight:: text Here is the result of this plugin on a sample call:: $ findscu -W -k "ScheduledProcedureStepSequence[0].Modality=MR" 127.0.0.1 4242 I: --------------------------- I: Find Response: 1 (Pending) I: I: # Dicom-Data-Set I: # Used TransferSyntax: Little Endian Explicit I: (0008,0005) CS [ISO_IR 100] # 10, 1 SpecificCharacterSet I: (0040,0100) SQ (Sequence with explicit length #=1) # 18, 1 ScheduledProcedureStepSequence I: (fffe,e000) na (Item with explicit length #=1) # 10, 1 Item I: (0008,0060) CS [MR] # 2, 1 Modality I: (fffe,e00d) na (ItemDelimitationItem for re-encoding) # 0, 0 ItemDelimitationItem I: (fffe,e0dd) na (SequenceDelimitationItem for re-encod.) # 0, 0 SequenceDelimitationItem I: I: --------------------------- I: Find Response: 2 (Pending) I: I: # Dicom-Data-Set I: # Used TransferSyntax: Little Endian Explicit I: (0008,0005) CS [ISO_IR 100] # 10, 1 SpecificCharacterSet I: (0040,0100) SQ (Sequence with explicit length #=1) # 18, 1 ScheduledProcedureStepSequence I: (fffe,e000) na (Item with explicit length #=1) # 10, 1 Item I: (0008,0060) CS [MR] # 2, 1 Modality I: (fffe,e00d) na (ItemDelimitationItem for re-encoding) # 0, 0 ItemDelimitationItem I: (fffe,e0dd) na (SequenceDelimitationItem for re-encod.) # 0, 0 SequenceDelimitationItem I: .. _pynetdicom: Replacing DICOM SCP of Orthanc by pynetdicom ............................................ .. highlight:: json Thanks to Python plugins, it is also possible to replace the built-in DICOM SCP of Orthanc by `pynetdicom <https://pydicom.github.io/pynetdicom/stable/examples/storage.html>`__ so as to customize how the DICOM protocol is handled. Firstly, in the configuration file, make sure to disable the Orthanc SCP by setting ``DicomServerEnabled`` to ``false``:: { "Plugins" : [ "." ], "PythonScript" : "pynetdicom.py", "DicomServerEnabled" : false } Secondly, here a basic plugin illustrating how to start and stop the pynetdicom server, and handle incoming C-STORE requests: .. literalinclude:: python/pynetdicom.py :language: python As can be seen in this listing, whenever the pynetdicom receives an incoming C-STORE request, it makes a POST call to the URI ``/instances`` in the REST API of Orthanc in order to store the embedded DICOM dataset into Orthanc. Obviously, one can build more complex DICOM servers by handling more messages than C-STORE alone. .. _python_exception: Catching exceptions ................... Starting with release 3.3 of the Python plugin, the plugin generates a Python exception derived from class ``orthanc.OrthancException`` if an error is encountered. This exception contains a tuple that provides the error code and its textual description. In releases <= 3.2, the Python plugin raised the `built-in exception <https://docs.python.org/3/library/exceptions.html>`__ ``ValueError``. Here is an example showing how to catch exceptions: .. literalinclude:: python/exception.py :language: python .. _python_storage_area: Implementing a custom storage area (new in 3.3) ............................................... Starting with release 3.3 of the Python plugin, it is possible to replace the built-in storage area of Orthanc (that writes :ref:`attachments <metadata>` onto the filesystem in the ``OrthancStorage`` folder by default), by providing 3 Python callbacks to the ``orthanc.RegisterStorageArea()`` function: * The first callback indicates how to **create** an attachment into the storage area. * The second callback indicates how to **read** an attachment from the storage area. * The third callback indicates how to **remove** an attachment out of the storage area. This feature can be used to quickly and easily interface Orthanc with any `object-based storage <https://en.wikipedia.org/wiki/Object_storage>`__ technology available in Python (such as `Ceph <https://en.wikipedia.org/wiki/Ceph_(software)>`__ or AWS S3-like tools). The performance will not be as good as a C/C++ native plugin (cf. the :ref:`cloud storage <object-storage>`, the :ref:`PostgreSQL <postgresql>` and the :ref:`MySQL <mysql>` plugins), but it can be used for prototyping or for basic setups. Here is a full, self-explaining sample: .. literalinclude:: python/storage-area.py :language: python The ``contentType`` can be used to apply a special treatment to some types of attachments (typically, DICOM instances). This parameter takes its values from the ``orthanc.ContentType`` enumeration. .. _python_received_instance: Modifying received instances (new in 4.0) ......................................... Starting with release 4.0 of the Python plugin, it is possible to modify instances received by Orthanc before they are stored in the storage. This is usually easier to perform modification at this stage compared to using the ``/modify`` route once the instances has been stored. .. literalinclude:: python/received-instance-callback.py :language: python Filtering incoming C-Store instances (new in 4.0) ................................................. Starting with release 4.0 of the Python plugin, it is possible to filter instances received from C-Store and return a specific error code to the sending modality. This can be used, e.g, to implement a quota per modality or return an ``out-of-resources`` status if the Orthanc storage is almost full. .. literalinclude:: python/incoming-cstore-filter.py :language: python Storage Commitment SCP (new in 4.1) ................................... Starting with release 4.1 of the Python plugin, it is possible to provide your own implementation of the :ref:`Storage Commitment <storage-commitment>`. This can be used, e.g, to check that you have backup the orthanc data in a long term storage. .. literalinclude:: python/storage-commitment-default.py :language: python .. _python_extend_orthanc_explorer: Extending the Orthanc Explorer interface ........................................ Here is a sample plugin that adds a new button to Orthanc Explorer that triggers a Python function: .. literalinclude:: python/sample-python-button.py :language: python As can be seen in this sample: * The call to ``orthanc.ExtendOrthancExplorer()`` installs the button with JavaScript code that uses the `jQuery Mobile framework <https://demos.jquerymobile.com/1.1.0/>`__ (as of Orthanc 1.12.4, version 1.1.0 of jQuery Mobile is used in Orthanc Explorer). * If clicking on the button, a GET call to the REST API is made to ``../execute-python``. The prefix ``../`` stems from the fact that Orthanc Explorer is branched inside the ``app/`` folder of the REST API of Orthanc. * The GET call to ``../execute-python`` executes the ``ExecutePython()`` callback function that is written in Python. Note that it is only possible to extend Orthanc Explorer 1, which is the built-in Web interface of Orthanc. It is not possible to extend the :ref:`Orthanc Explorer 2 <orthanc-explorer-2>` interface. .. _python_mosaic: Generating a mosaic for a DICOM series ...................................... Thanks to the fact that Python plugins have access to :ref:`PIL/Pillow <python-pil-thumbnail>`, it is quite easy to generate a mosaic from a DICOM series: .. image:: python/mosaic.png :align: center :width: 512 Here is the source code: .. literalinclude:: python/mosaic.py :language: python Performance and concurrency --------------------------- **Important:** This section only applies to UNIX-like systems. The ``multiprocessing`` package will not work on Microsoft Windows as the latter OS has a different model for `forking processes <https://en.wikipedia.org/wiki/Fork_(system_call)>`__. Using slave processes ..................... Let us consider the following sample Python script that makes a CPU-intensive computation on a REST callback: .. literalinclude:: python/multiprocessing-1.py :language: python .. highlight:: text Calling this REST route from the command-line returns the time that is needed to compute 30 million times a squared root on your CPU:: $ curl http://localhost:8042/computation computation done in 4.208 seconds Now, let us call this route three times concurrently (we use bash):: $ (curl http://localhost:8042/computation & curl http://localhost:8042/computation & curl http://localhost:8042/computation ) computation done in 11.262 seconds computation done in 12.457 seconds computation done in 13.360 seconds As can be seen, the computation time has tripled. This means that the computations were not distributed across the available CPU cores. This might seem surprising, as Orthanc is a threaded server (in Orthanc, a pool of C++ threads serves concurrent requests). The explanation is that the Python interpreter (`CPython <https://en.wikipedia.org/wiki/CPython>`__ actually) is built on the top of a so-called `Global Interpreter Lock (GIL) <https://en.wikipedia.org/wiki/Global_interpreter_lock>`__. The GIL is basically a mutex that protects all the calls to the Python interpreter. If multiple C++ threads from Orthanc call a Python callback, only one can proceed at any given time. Note however that the GIL only applies to the Python script: The baseline REST API of Orthanc is not affected by the GIL. The solution is to use the `multiprocessing primitives <https://docs.python.org/3/library/multiprocessing.html>`__ of Python. The "master" Python interpreter that is initially started by the Orthanc plugin, can start several `children processes <https://en.wikipedia.org/wiki/Process_(computing)>`__, each of these processes running a separate Python interpreter. This allows to offload intensive computations from the "master" Python interpreter of Orthanc onto those "slave" interpreters. The ``multiprocessing`` library is actually quite straightforward to use: .. literalinclude:: python/multiprocessing-2.py :language: python .. highlight:: text Here is now the result of calling this route three times concurrently:: $ (curl http://localhost:8042/computation & curl http://localhost:8042/computation & curl http://localhost:8042/computation ) computation done in 4.211 seconds computation done in 4.215 seconds computation done in 4.225 seconds As can be seen, the calls to the Python computation now fully run in parallel (the time is cut down from 12 seconds to 4 seconds, the same as for one isolated request). Note also how the ``multiprocessing`` library allows to make a fine control over the computational resources that are available to the Python script: The number of "slave" interpreters can be easily changed in the constructor of the ``multiprocessing.Pool`` object, and are fully independent of the threads used by the Orthanc server. Obviously, an in-depth discussion about the ``multiprocessing`` library is out of the scope of this document. There are many references available on Internet. Also, note that ``threading`` is not useful here, as Python multithreading is also limited by the GIL, and is more targeted at dealing with costly I/O operations or with the :ref:`scheduling of commands <python-scheduler>`. Slave processes and the "orthanc" module ........................................ Very importantly, pay attention to the fact that **only the "master" Python interpreter has access to the Orthanc SDK**. The "slave" processes have no access to the ``orthanc`` module. You must write your Python plugin so as that all the calls to ``orthanc`` are moved from the slaves process to the master process. For instance, here is how you would parse a DICOM file in a slave process: .. literalinclude:: python/multiprocessing-3.py :language: python Communication primitives such as ``multiprocessing.Queue`` are available to exchange messages from the "slave" Python interpreters to the "master" Python interpreter for more advanced scenarios. NB: Starting with release 3.0 of the Python plugin, it is possible to call the REST API of Orthanc from a slave process in a more direct way. The function ``orthanc.GenerateRestApiAuthorizationToken()`` can be used to create an authorization token that provides full access to the REST API of Orthanc (without have to set credentials in your plugin). Any HTTP client library for Python, such as `requests <https://requests.readthedocs.io/en/master/>`__, can then be used to access the REST API of Orthanc. Here is a minimal example: .. literalinclude:: python/multiprocessing-4.py :language: python Working with virtual environments --------------------------------- By default, Orthanc uses the system-wide Python installation and therefore has access to the python modules that have been installed system-wide. As of version 4.1 of the python plugin, there is no built-in support for working with a `virtual environment <https://docs.python.org/3/library/venv.html>`__. However, you may modify the python path at the very beginning of the script to instruct python to look for modules in your environment. **Example 1**: On a Linux system, consider that you have created a virtual environment in ``/tmp/.venv`` and, you may just an environment variable to instruct the python interpreter to search for modules into your virtual env. E.g, in a Docker container, you may implement it this way:: FROM orthancteam/orthanc-pre-release:bookworm # This example is using a virtual env that is not mandatory when using Docker containers # but recommended since python 3.11 and Debian bookworm based images where you get a warning # when installing system-wide packages. RUN apt-get update && apt install -y python3-venv RUN python3 -m venv /.venv RUN /.venv/bin/pip install pydicom ENV PYTHONPATH=/.venv/lib64/python3.11/site-packages/ RUN mkdir /python COPY * /python/ **Example 2**: On a Linux system, consider that you have created a virtual environment in ``/tmp/.venv`` and you want to use only the modules that have been installed in this virtual environment. In this case, you may simply rewrite ``sys.path``: .. literalinclude:: python/venv-linux.py :language: python **Example 3**: On a Windows system, consider that you have created a virtual environment in ``C:/tmp/.venv/``. Instead of defining ``sys.path`` from scratch, it is possible to simply insert the venv-packages in the ``sys.path``. By adding the ``venv`` to an early index (``0``), any package required by your code will be looked up in the ``venv`` first. And, as a consequence, if the package is not present, the system-wide installation of that package might be loaded: .. literalinclude:: python/venv-windows.py :language: python