This repository contains the source code for the Eclipse Paho MQTT C client library.
This code builds libraries which enable applications to connect to an MQTT broker to publish messages, and to subscribe to topics and receive published messages.
Synchronous and various asynchronous programming models are supported.
- MQTT website
- The MQTT 3.1.1 standard
- The MQTT 5.0 standard
- HiveMQ introduction to MQTT
- OASIS Introduction to MQTT presentation
The Paho C client comprises four variant libraries, shared or static:
- paho-mqtt3a - asynchronous (MQTTAsync)
- paho-mqtt3as - asynchronous with SSL/TLS (MQTTAsync)
- paho-mqtt3c - "classic" / synchronous (MQTTClient)
- paho-mqtt3cs - "classic" / synchronous with SSL/TLS (MQTTClient)
Which Paho C API to use, with some history, for context
Detailed API documentation is available online. It is also available by building the Doxygen docs in the doc
directory.
Samples are available in the Doxygen docs and also in src/samples
for reference. These are:
- paho_c_pub.c and paho_c_sub.c: command line utilities to publish and subscribe, -h will give help
- paho_cs_pub.c and paho_cs_sub.c: command line utilities using MQTTClient to publish and subscribe
- MQTTClient_publish.c, MQTTClient_subscribe.c and MQTTClient_publish_async.c: MQTTClient simple code examples
- MQTTAsync_publish.c and MQTTAsync_subscribe.c: MQTTAsync simple code examples
Some potentially useful blog posts:
- Paho client MQTT 5.0 support and command line utilities
- MQTT, QoS and persistence
- A story of MQTT 5.0
Various MQTT and MQTT-SN talks I've given.
A number of environment variables control runtime tracing of the C library.
Tracing is switched on using MQTT_C_CLIENT_TRACE
(a value of ON traces to stdout, any other value should specify a file to trace to).
The verbosity of the output is controlled using the MQTT_C_CLIENT_TRACE_LEVEL
environment variable - valid values are ERROR, PROTOCOL, MINIMUM, MEDIUM and MAXIMUM (from least to most verbose).
The variable MQTT_C_CLIENT_TRACE_MAX_LINES
limits the number of lines of trace that are output.
export MQTT_C_CLIENT_TRACE=ON
export MQTT_C_CLIENT_TRACE_LEVEL=PROTOCOL
Please open issues in the Github project: https://github.com/eclipse-paho/paho.mqtt.c/issues.
Discussion of the Paho clients takes place on the Eclipse paho-dev mailing list.
Follow Eclipse Paho on Twitter: @eclipsepaho
General questions about the MQTT protocol are discussed in the MQTT Google Group.
There is more information available via the MQTT community site.
The build process currently supports a number of Linux "flavors" including ARM and s390, OS X, AIX and Solaris as well as the Windows operating system. The build process requires the following tools:
On Debian based systems this would mean that the following packages have to be installed:
$ apt-get install build-essential gcc make cmake cmake-gui cmake-curses-gui
Also, in order to build a debian package from the source code, the following packages have to be installed
$ apt-get install fakeroot devscripts dh-make lsb-release
Ninja can be downloaded from its github project page in the "releases" section. Optionally it is possible to build binaries with SSL/TLS support. This requires the OpenSSL libraries and includes to be available. E. g. on Debian:
$ apt-get install libssl-dev
The documentation requires doxygen and optionally graphviz:
$ apt-get install doxygen graphviz
If the Paho C library was built with CMake and is already installed on the system, it is relatively easy to set up a CMake build for your application. (If it's not already built and installed read the next section).
The library can be built with several options which create variations of the library for asynchronous or synchronous use; encryption (SSL/TLS) support or not; and whether the library is shared or static. CMake exports all of the libraries that were built as targets, and the user can chose which is best suited for an application.
The package is named: eclipse-paho-mqtt-c
The namespace for all the targets is also: eclipse-paho-mqtt-c
The target names are the same as the library names. The static libraries append -static to the target name even for platforms that use the same base name for shared and static libraries. So:
Target | Description |
---|---|
paho-mqtt3a | asynchronous, no encryption |
paho-mqtt3as | asynchronous with SSL/TLS support |
paho-mqtt3c | synchronous, no encryption |
paho-mqtt3cs | synchronous with SSL/TLS support |
paho-mqtt3a-static | asynchronous, no encryption, static linkage |
paho-mqtt3as-static | asynchronous with SSL/TLS support, static linkage |
paho-mqtt3c-static | synchronous, no encryption, static linkage |
paho-mqtt3cs-static | synchronous with SSL/TLS support, static linkage |
Remember, though, that not all of these targets may be available. It depends on how the library was built.
A sample CMakeLists.txt for an application that uses the asynchronous library with encryption support (paho-mqtt3as) might look like this:
cmake_minimum_required(VERSION 3.5)
project(MyMQTTApp VERSION 1.0.0 LANGUAGES C)
find_package(eclipse-paho-mqtt-c REQUIRED)
add_executable(MyMQTTApp MyMQTTApp.c)
target_link_libraries(MQTTVersion eclipse-paho-mqtt-c::paho-mqtt3as)
If the library was installed to a non-traditional location, you may need to tell CMake where to find it using CMAKE_PREFIX_PATH
. For example, if you installed it in /opt/mqtt/paho.mqtt.c
$ cmake -DCMAKE_PREFIX_PATH=/opt/mqtt/paho.mqtt.c ..
Before compiling, determine the value of some variables in order to configure features, library locations, and other options:
Variable | Default Value | Description |
---|---|---|
PAHO_BUILD_SHARED | TRUE | Build a shared version of the libraries |
PAHO_BUILD_STATIC | FALSE | Build a static version of the libraries |
PAHO_HIGH_PERFORMANCE | FALSE | When set to true, the debugging aids internal tracing and heap tracking are not included. |
PAHO_WITH_SSL | FALSE | Flag that defines whether to build ssl-enabled binaries too. |
OPENSSL_ROOT_DIR | "" (system default) | Directory containing your OpenSSL installation (i.e. /usr/local when headers are in /usr/local/include and libraries are in /usr/local/lib ) |
PAHO_BUILD_DOCUMENTATION | FALSE | Create and install the HTML based API documentation (requires Doxygen) |
PAHO_BUILD_SAMPLES | FALSE | Build sample programs |
PAHO_ENABLE_TESTING | TRUE | Build test and run |
MQTT_TEST_BROKER | tcp://localhost:1883 | MQTT connection URL for a broker to use during test execution |
MQTT_TEST_PROXY | tcp://localhost:1883 | Hostname of the test proxy to use |
MQTT_SSL_HOSTNAME | localhost | Hostname of a test SSL MQTT broker to use |
PAHO_BUILD_DEB_PACKAGE | FALSE | Build debian package |
Using these variables CMake can be used to generate your Ninja or Make files. Using CMake, building out-of-source is the default. Therefore it is recommended to invoke all build commands inside your chosen build directory but outside of the source tree.
An example build session targeting the build platform could look like this:
$ mkdir /tmp/build.paho ; cd /tmp/build.paho
$ cmake -DPAHO_WITH_SSL=TRUE -DPAHO_BUILD_DOCUMENTATION=TRUE \
-DPAHO_BUILD_SAMPLES=TRUE ~/paho.mqtt.c
Invoking cmake and specifying build options can also be performed using cmake-gui or ccmake (see https://cmake.org/runningcmake/). For example:
$ ccmake ~/paho.mqtt.c
To compile/link the binaries, to install, or to generate packages, use these commands:
$ cmake --build .
$ cmake --build . --target install
$ cmake --build . --target package
To build, install, or generate packages, you can also use the generated builder like ninja or make directly after invoking the initial CMake configuration step, such as ninja package
or make -j <number-of-jpbs> package
.
Debug builds can be performed by defining the value of the CMAKE_BUILD_TYPE
option to Debug
. For example:
$ cmake -DCMAKE_BUILD_TYPE=Debug ~/paho.mqtt.c
Test code is available in the test
directory. The tests can be built and executed with the CMake build system. The test execution requires a MQTT broker running. By default, the build system uses localhost
, however it is possible to configure the build to use an external broker. These parameters are documented in the Build Requirements section above.
After ensuring a MQTT broker is available, it is possible to execute the tests by starting the proxy and running ctest
as described below:
$ python ../test/mqttsas.py &
$ ctest -VV
Cross compilation using CMake is performed by using so called "toolchain files" (see: http://www.vtk.org/Wiki/CMake_Cross_Compiling).
The path to the toolchain file can be specified by using CMake's -DCMAKE_TOOLCHAIN_FILE
option. In case no toolchain file is specified, the build is performed for the native build platform.
For your convenience toolchain files for the following platforms can be found in the cmake
directory of Eclipse Paho:
- Linux x86
- Linux ARM11 (a.k.a. the Raspberry Pi)
- Windows x86_64
- Windows x86
The provided toolchain files assume that required compilers/linkers are to be found in the environment, i. e. the PATH-Variable of your user or system. If you prefer, you can also specify the absolute location of your compilers in the toolchain files.
Example invocation for the Raspberry Pi:
$ cmake -GNinja -DPAHO_WITH_SSL=TRUE -DPAHO_BUILD_SAMPLES=TRUE \
-DPAHO_BUILD_DOCUMENTATION=TRUE \
-DOPENSSL_LIB_SEARCH_PATH=/tmp/libssl-dev/usr/lib/arm-linux-gnueabihf \
-DOPENSSL_INC_SEARCH_PATH="/tmp/libssl-dev/usr/include/openssl;/tmp/libssl-dev/usr/include/arm-linux-gnueabihf" \
-DCMAKE_TOOLCHAIN_FILE=~/paho.mqtt.c/cmake/toolchain.linux-arm11.cmake \
~/paho.mqtt.c
Compilers for the Raspberry Pi and other ARM targets can be obtained from ARM (https://developer.arm.com/tools-and-software/open-source-software/developer-tools/gnu-toolchain/downloads)
This example assumes that OpenSSL-libraries and includes have been installed in the /tmp/libssl-dev
directory.
Example invocation for Windows 64 bit:
$ cmake -DPAHO_BUILD_SAMPLES=TRUE \
-DCMAKE_TOOLCHAIN_FILE=~/paho.mqtt.c/cmake/toolchain.win64.cmake \
~/paho.mqtt.c
In this case the libraries and executable are not linked against OpenSSL Libraries. Cross compilers for the Windows platform can be installed on Debian like systems like this:
$ apt-get install gcc-mingw-w64-x86-64 gcc-mingw-w64-i686
Ensure the OpenSSL development package is installed. Then from the client library base directory run:
$ make
$ sudo make install
This will build and install the libraries. To uninstall:
$ sudo make uninstall
To build the documentation requires doxygen and optionally graphviz.
$ make html
The provided GNU Makefile is intended to perform all build steps in the build
directory within the source-tree of Eclipse Paho. Generated binares, libraries, and the documentation can be found in the build/output
directory after completion.
Options that are passed to the compiler/linker can be specified by typical Unix build variables:
Variable | Description |
---|---|
CC | Path to the C compiler |
CFLAGS | Flags passed to compiler calls |
LDFLAGS | Flags passed to linker calls |
You can download and install paho-mqtt using the vcpkg dependency manager:
git clone https://github.com/Microsoft/vcpkg.git
cd vcpkg
./bootstrap-vcpkg.sh
./vcpkg integrate install
./vcpkg install paho-mqtt
The paho-mqtt port in vcpkg is kept up to date by Microsoft team members and community contributors. If the version is out of date, please create an issue or pull request on the vcpkg repository.
(By Frank Pagliughi)
musl libc is is an implementation of the C standard library built on top of the Linux system call API, including interfaces defined in the base language standard, POSIX, and widely agreed-upon extensions.
Users of the Rust library, which wraps this one, had been complaining that they could not compile using the musl build tools. Musl is a small std C lib that can be statically linked. With the latest Paho C library (and a very minor tweak to the build), we're now able to build Rust apps using musl and Paho C that are fully static; no runtime dependencies on the platform; not even on the standard C lib.
$ ./async_publish Publishing a message on the 'test' topic
$ ldd async_publish not a dynamic executable
So, for example, if maintaining a suite of apps for some newer and older embedded Linux boards, the same executables could be deployed without worry about the C ABI on the particular boards.
Certainly C apps using the Paho library could do this also.
As is normal for C programs on Windows, the calling convention is __cdecl. See the Microsoft documentation here:
https://docs.microsoft.com/en-us/cpp/cpp/cdecl?view=vs-2019
If you call this library from another language, you may need to take this into account.