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libQuotient

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The Quotient project aims to produce a Qt-based SDK to develop applications for Matrix. libQuotient is a library that enables client applications. It is the backbone of Quaternion, NeoChat and other projects.

Contacts

You can find Quotient developers in the Matrix room: #quotient:matrix.org.

You can file issues at the project issue tracker. If you find what looks like a security issue, please use instructions in SECURITY.md.

Getting and using libQuotient

Depending on your platform, the library can be obtained from a package management system. Recent releases of Fedora, Debian and openSUSE already have it. Alternatively, you can build the library from the source and bundle it with your application, as described below.

Pre-requisites

To use libQuotient (i.e. build or run applications with it), you'll need:

  • A recent Linux, macOS or Windows system (desktop versions are known to work, and there's also limited positive experience with Android)
    • Recent enough Linux examples: Debian Trixie; Fedora 39; openSUSE Leap 15.6; Ubuntu 24.04 LTS
  • Qt 6.4 or newer - either Open Source or Commercial
  • QtKeychain (https://github.com/frankosterfeld/qtkeychain) - 0.12 or newer is recommended; the build configuration of QtKeychain must use the same Qt major version, that is Qt 6.

To build applications with libQuotient, you'll also need:

  • CMake 3.26 or newer
  • A C++ toolchain that supports at least some subset of C++20 (concepts, in particular):
    • GCC 13 (Windows, Linux, macOS), Clang 16 (Linux), Apple Clang 15 (macOS 14+) and Visual Studio 2022 (Windows) are the oldest officially supported
  • libolm 3.2.5 or newer (the latest 3.x strongly recommended)
  • OpenSSL 3.x (1.1.x may still work but is strongly recommended against)
  • Any build system that works with CMake should be fine; known to work are GNU Make and ninja (recommended) on any platform; NMake and jom on Windows

The requirements to build libQuotient itself are basically the same except that you should install development libraries for the dependencies listed above.

Linux

Just install the prerequisites using your preferred package manager. If your Qt package base is fine-grained you might want to run CMake and look at error messages. The library is entirely offscreen; however, aside from QtCore and QtNetwork it also depends on QtGui in order to handle avatar thumbnails, without any on-screen drawing.

macOS

brew install qt qtkeychain libolm openssl@3 should get you the most recent versions of the runtime libraries.

You may need to add $(brew --prefix qt), $(brew --prefix qtkeychain) etc. to CMAKE_PREFIX_PATH (see below) to make CMake aware of the library locations.

Windows

Install Qt and OpenSSL using The Qt Project official installer; make sure to also tick the CMake box in the list of components to install unless you already have it. This will get you both the runtime libraries and the development files, which are also suitable to build libQuotient itself. If you go this way, you'll have to build QtKeychain from the source code.

Alternatively, you can use vcpkg to install Qt, OpenSSL, and QtKeychain. In that case you're not getting Qt Creator, which is a very nice IDE to deal with Qt-based projects; but if you already use VSCode or CLion, you might prefer this route. You can also mix and match, installing Qt Creator from the official installer and the rest from vcpkg. Mixing Qt from the official installer with Qt Keychain from vcpkg may or may not work, depending on the Qt version used to build Qt Keychain.

If you build from the command line: the commands in further sections imply that cmake is in your PATH, otherwise you have to prepend those commands with actual paths. It's a good idea to run the qtenv2.bat script that can be found in C:\Qt\<Qt version>\<toolchain>\bin (assuming you installed Qt to C:\Qt). This script adds necessary paths to PATH. You might not want to run that script on system startup but it's very handy to setup the environment before building.

If you use a C++ IDE: you should be able to configure CMake path and extra options (CMAKE_PREFIX_PATH, in particular) in its settings. It is recommended NOT to add the path for Qt (or any other library) to PATH explicitly; use CMAKE_PREFIX_PATH instead and leave PATH unchanged. If your IDE is Qt Creator, you shouldn't need to deal with Qt paths at all, just pick the right kit and go straight to building.

You will also need libolm. You'll have to build it yourself - there's no binary for Windows that you can download from vcpkg or elsewhere, as of this writing. The source code is available at https://gitlab.matrix.org/matrix-org/olm; you can use the same toolchain (CMake+MSVC, e.g.) as for the rest of Quotient.

Using the library

If you're just starting a project using libQuotient from scratch, you can copy quotest/CMakeLists.txt to your project and change quotest to your project name. If you already have an existing CMakeLists.txt, you need to insert a find_package(Quotient REQUIRED) line to an appropriate place in it (use find_package(Quotient) if libQuotient is not a hard dependency for you) and then add Quotient to your target_link_libraries() line.

Dynamic linking is only tested on Linux at the moment and is the recommended way of linking with libQuotient on this platform. Static linking is the default on Windows/macOS; feel free to experiment with dynamic linking and provide feedback with your results.

Documentation

A (very basic) overview can be found at the respective wiki page. The Doxygen documentation for the library can be found at https://quotient-im.github.io/libQuotient/. Further on, looking at the source code for Quotest - the test application that comes with libQuotient - may help you with most common use cases such as sending messages, uploading files, setting room state etc.

For examples and patterns of more extensive usage feel free to check out (and copy, with appropriate attribution) the source code of Quaternion (the reference client for libQuotient) or NeoChat.

API/ABI stability

Since Quotient 0.7.2, symbols in all header files of libQuotient except files ending with _p.h and namespace _impl are considered public and covered by API/ABI stability guarantees. Specifically, the API and ABI are backwards compatible within every minor version (0.7.x releases) with every next minor version (0.8, e.g.) breaking the compatibility. Once we reach 1.0, this rule will apply to the major version, aligning with semantic versioning rules. *_p.h files and namespace _impl are not covered by these guarantees; client code should not directly include these files, nor use symbols defined in these locations.

Building the library

On platforms other than Linux you will have to build libQuotient yourself before usage - nobody packaged it so far (contributions welcome!). You may also want to build the library on Linux if you need a newer version or snapshot than that coming in your distro.

The source code is at GitHub. Checking out a certain commit or tag (rather than downloading the archive) along with submodules is strongly recommended. If you want to hack on the library as a part of another project (e.g. you are working on Quaternion but need to do some changes to the library code), it makes sense to make a recursive check out of that project (in this case, Quaternion) and update the library submodule (also recursively) within the appropriate branch. Be mindful of API compatibility restrictions: e.g., each version of Quaternion may require the specific branch of libQuotient (0.8.x, 0.9.x etc.).

Tags consisting solely of digits and fullstops (e.g., 0.7.0) correspond to released versions; tags ending with -betaN or -rcN mark respective pre-releases. If/when packaging pre-releases, it is advised to replace the leading - with ~ (tilde).

libQuotient is a classic CMake-based project; assuming the dependencies are in place, the following commands issued in the root directory of the project sources:

cmake -B build -S . # [-D<cmake-variable>=<value>...], see below
cmake --build build --target all

will get you a compiled library in build (make sure it exists before running). Any C++ IDE that works with CMake should be able to do the same with minimal configuration effort.

Static builds are tested on all supported platforms. Dynamic libraries are the recommended configuratiion on Linux; likely workable on macOS; and untested on Windows (you're welcome to try and report on the results).

Before proceeding, double-check that you have installed development libraries for all prerequisites above. CMake will stop and tell you if something's missing.

The first CMake invocation above configures the build. You can pass CMake variables (such as -DCMAKE_PREFIX_PATH="path1;path2;..." and -DCMAKE_INSTALL_PREFIX=path) to that invocation if needed. CMake documentation (pick the CMake version at the top of the page that you use) describes the standard variables coming with CMake. On top of them, Quotient understands:

  • Quotient_INSTALL_TESTS=<ON/OFF>, ON by default - install quotest along with the library files when install target is invoked. quotest is a small command-line program that (assuming correct parameters, see quotest --help) that tries to connect to a given room as a given user and perform some basic Matrix operations, such as sending messages and small files, redaction, setting room tags etc. This is useful to check the sanity of your library installation.
  • MATRIX_SPEC_PATH and GTAD_PATH - these two variables are used to point CMake to the directory with the matrix-doc repository containing API files and to a GTAD binary. These two are used to generate C++ files from Matrix Client-Server API description made in OpenAPI notation. This is not needed if you just need to build the library; if you're really into hacking on it, please read the respective sections in CONTRIBUTING.md and CODE_GENERATION.md.
  • QUOTIENT_FORCE_NAMESPACED_INCLUDES=<ON/OFF>, OFF by default (note that QUOTIENT is in caps here, unlike options above) - when this option is set to ON, CMake skips adding <top-level include prefix>/Quotient/ to include paths, thereby forcing the client code to use #include <Quotient/header.h> instead of historically accepted #include <header.h>. By default this is set to OFF for backwards compatibility; eventually this default may/will change so it is recommended to at least occasionally add -DQUOTIENT_FORCE_NAMESPACED_INCLUDES=1 to a CMake invocation (or set the variable in your IDE) and make sure your code has prefixed paths.

You can install the library with CMake:

cmake --build . --target install

This will also install cmake package config files; once this is done, you should be able to use quotest/CMakeLists.txt to compile quotest with the installed library. As mentioned above, installation of the quotest binary along with the rest of the library can be skipped by setting Quotient_INSTALL_TESTS to OFF.

Troubleshooting

Building fails

  • If cmake fails with

    CMake Warning at CMakeLists.txt:11 (find_package):
      By not providing "FindQt6Widgets.cmake" in CMAKE_MODULE_PATH this project
      has asked CMake to find a package configuration file provided by
      "Qt6Widgets", but CMake did not find one.
    

    then you need to set the right -DCMAKE_PREFIX_PATH variable, see above.

  • If cmake fails with a message similar to:

    CMake Error at /usr/lib64/cmake/Qt6Core/Qt6CoreVersionlessTargets.cmake:37 (message):
      Some (but not all) targets in this export set were already defined.
    
      Targets Defined: Qt::Core
    
      Targets not yet defined: Qt::CorePrivate
    

    then you likely have both Qt 5 and Qt 6 on your system, and your code uses a different major version of Qt than Quotient. Make sure you configure the build so that the same major Qt version is used both by libQuotient and your code.

Logging configuration

libQuotient uses Qt's logging categories to make switching certain types of logging easier. In case of troubles at runtime (bugs, crashes) you can increase logging if you add the following to the QT_LOGGING_RULES environment variable:

quotient.<category>.<level>=<flag>

where

  • <category> is one of: main, jobs, jobs.sync, jobs.thumbnail, events, events.state (covering both the "usual" room state and account data), events.members, events.messages, events.ephemeral, database, network, e2ee and profiler - you can always find the full list in Quotient/logging_categories_p.h;
  • <level> is one of debug, info, and warning;
  • <flag> is either true or false.

You can use * (asterisk) as a wildcard for any part between two dots, and semicolon is used for a separator. Latter statements override former ones, so if you want to switch on all debug logs except jobs you can set QT_LOGGING_RULES="quotient.*.debug=true;quotient.jobs.debug=false"

You may also want to set QT_MESSAGE_PATTERN to make logs slightly more informative (see https://doc.qt.io/qt-6/qtlogging.html#qSetMessagePattern for the format description). To give an example, here's what one of the library developers uses for QT_MESSAGE_PATTERN:

`%{time h:mm:ss.zzz}|%{category}|%{if-debug}D%{endif}%{if-info}I%{endif}%{if-warning}W%{endif}%{if-critical}C%{endif}%{if-fatal}F%{endif}|%{message}`

(the scary %{if}s are just encoding the logging level into its initial letter).

Cache format

In case of troubles with room state and caching it may be useful to switch cache format from binary CBOR to plaintext JSON. To do that, set libQuotient/cache_type key in your client's configuration file/registry to json (you might need to create the libQuotient group as it's the only recognised key in it so far). This will make cache saving and loading work slightly slower but the cache will be in text JSON files (very long and with no indentation; prepare a good JSON viewer or text editor with JSON formatting capabilities).