This is an implementation of the MQTT Client written in C for embedded use, which supports SSL/TLS via the wolfSSL library. This library was built from the ground up to be multi-platform, space conscious and extensible. Integrates with wolfSSL to provide TLS support.
For details on wolfMQTT see the wolfMQTT Manual.
./autogen.sh
(if cloned from GitHub)./configure
(to see a list of build options use./configure --help
)make
sudo make install
Notes:
- If
wolfssl
was recently installed, runsudo ldconfig
to update the linker cache. - Debug messages can be enabled using
--enable-debug
or--enable-debug=verbose
(for extra logging). - For a list of build options run
./configure --help
. - The build options are generated in a file here:
wolfmqtt/options.h
.
For building wolfMQTT with TLS support in Visual Studio:
- Open the
<wolfssl-root>/wolfssl64.sln
. - Re-target for your Visual Studio version (right-click on solution and choose
Retarget solution
). - Make sure the
Debug DLL
orRelease DLL
configuration is selected. Make note if you are building 32-bitx86
or 64-bitx64
. - Build the wolfSSL solution.
- Copy the
wolfssl.lib
andwolfssl.dll
files into<wolfmqtt-root>
.- For
DLL Debug
withx86
the files are in:DLL Debug
. - For
DLL Release
withx86
the files are in:DLL Release
. - For
DLL Debug
withx64
the files are in:x64/DLL Debug
. - For
DLL Release
withx64
the files are in:x64/DLL Release
.
- For
- Open the
<wolfmqtt-root>/wolfmqtt.sln
solution. - Make sure you have the same architecture (
x86
orx64
selected) as used in wolfSSL above. - By default the include path for the wolfssl headers is
./../wolfssl/
. If your wolfssl root location is different you can go into the project settings and adjust this inC/C++
->General
->Additional Include Directories
. - Configure your Visual Studio build settings using
wolfmqtt/vs_settings.h
. - Build the wolfMQTT solution.
CMake supports compiling in many environments including Visual Studio
if CMake support is installed. The commands below can be run in
Developer Command Prompt
.
mkdir build
cd build
# to use installed wolfSSL location (library and headers)
cmake .. -DWITH_WOLFSSL=/prefix/to/wolfssl/install/
# OR to use a wolfSSL source tree
cmake .. -DWITH_WOLFSSL_TREE=/path/to/wolfssl/
# build
cmake --build .
You can download and install wolfMQTT using the vcpkg:
git clone https://github.com/Microsoft/vcpkg.git
cd vcpkg
./bootstrap-vcpkg.sh
OR for Windows
bootstrap-vcpkg.bat
./vcpkg integrate install
./vcpkg install wolfmqtt
The wolfMQTT port in vcpkg is kept up to date by wolfSSL.
We also have vcpkg ports for wolftpm, wolfssl and curl.
See README.md
at IDE/ARDUINO.README.md
export PATH="/opt/mingw-w32-bin_i686-darwin/bin:$PATH"
export PREFIX=$PWD/build
# wolfSSL
cd wolfssl
./configure --host=i686 CC=i686-w64-mingw32-gcc LD=i686-w64-mingw32-ld CFLAGS="-DWIN32 -DMINGW -D_WIN32_WINNT=0x0600" LIBS="-lws2_32 -L$PREFIX/lib -lwolfssl" --prefix=$PREFIX
make
make install
# wolfMQTT
cd ../wolfmqtt
./configure --host=i686 CC=i686-w64-mingw32-gcc LD=i686-w64-mingw32-ld CFLAGS="-DWIN32 -DMINGW -D_WIN32_WINNT=0x0600 -DBUILDING_WOLFMQTT -I$PREFIX/include" LDFLAGS="-lws2_32 -L$PREFIX/lib -lwolfssl" --prefix=$PREFIX --disable-examples
make
Support for Zephyr is available in the zephyr directory. For instructions on how to build for Zephyr, see the README.md.
The library has three components.
This is where the top level application interfaces for the MQTT client reside.
int MqttClient_Init(MqttClient *client, MqttNet *net, MqttMsgCb msg_cb, byte *tx_buf, int tx_buf_len, byte *rx_buf, int rx_buf_len, int cmd_timeout_ms);
These API's are blocking on MqttNet.read
until error/timeout (cmd_timeout_ms
):
int MqttClient_Connect(MqttClient *client, MqttConnect *connect);
int MqttClient_Publish(MqttClient *client, MqttPublish *publish);
int MqttClient_Subscribe(MqttClient *client, MqttSubscribe *subscribe);
int MqttClient_Unsubscribe(MqttClient *client, MqttUnsubscribe *unsubscribe);
int MqttClient_Ping(MqttClient *client);
int MqttClient_Disconnect(MqttClient *client);
This function blocks waiting for a new publish message to arrive for a maximum duration of timeout_ms
.
int MqttClient_WaitMessage(MqttClient *client, MqttMessage *message, int timeout_ms);
These are the network connect / disconnect interfaces that wrap the MqttNet callbacks and handle WolfSSL TLS:
int MqttClient_NetConnect(MqttClient *client, const char* host, word16 port, int timeout_ms, int use_tls, MqttTlsCb cb);
int MqttClient_NetDisconnect(MqttClient *client);
Helper functions:
const char* MqttClient_ReturnCodeToString(int return_code);
This is where all the packet encoding/decoding is handled.
The header contains the MQTT Packet structures for:
- Connect:
MqttConnect
- Publish / Message:
MqttPublish
/MqttMessage
(they are the same) - Subscribe:
MqttSubscribe
- Unsubscribe:
MqttUnsubscribe
This is where the transport socket optionally wraps TLS and uses the MqttNet
callbacks for the platform specific network handling.
The header contains the MQTT Network structure MqttNet
for network callback and context.
Here are the steps for creating your own implementation.
- Create network callback functions for Connect, Read, Write and Disconnect. See
examples/mqttnet.c
andexamples/mqttnet.h
. - Define the callback functions and context in a
MqttNet
structure. - Call
MqttClient_Init
passing in aMqttClient
structure pointer,MqttNet
structure pointer,MqttMsgCb
function pointer, TX/RX buffers with maximum length and command timeout. - Call
MqttClient_NetConnect
to connect to broker over network. Ifuse_tls
is non-zero value then it will perform a TLS connection. The TLS callbackMqttTlsCb
should be defined for wolfSSL certificate configuration. - Call
MqttClient_Connect
passing pointer toMqttConnect
structure to send MQTT connect command and wait for Connect Ack. - Call
MqttClient_Subscribe
passing pointer toMqttSubscribe
structure to send MQTT Subscribe command and wait for Subscribe Ack (depending on QoS level). - Call
MqttClient_WaitMessage
passing pointer toMqttMessage
to wait for incoming MQTT Publish message.
The example MQTT client is located in /examples/mqttclient/
. This example exercises many of the exposed API’s and prints any incoming publish messages for subscription topic “wolfMQTT/example/testTopic”. This client contains examples of many MQTTv5 features, including the property callback and server assignment of client ID. The mqqtclient example is a good starting template for your MQTT application.
The example MQTT client is located in /examples/mqttsimple/
. This example demonstrates a standalone client using standard BSD sockets. This requires HAVE_SOCKET
to be defined, which comes from the ./configure generated wolfmqtt/config.h
file. All parameters are build-time macros defined at the top of /examples/mqttsimple/mqttsimple.c
.
The example MQTT client is located in /examples/nbclient/
. This example uses non-blocking I/O for message exchange. The wolfMQTT library must be configured with the --enable-nonblock
option (or built with WOLFMQTT_NONBLOCK
).
The MQTT firmware update is located in /examples/firmware/
. This example has two parts. The first is called “fwpush”, which signs and publishes a firmware image. The second is called “fwclient”, which receives the firmware image and verifies the signature. This example publishes message on the topic “wolfMQTT/example/firmware”. The "fwpush" application is an example of using a publish callback to send the payload data.
We setup a wolfMQTT IoT Hub on the Azure server for testing. We added a device called demoDevice
, which you can connect and publish to. The example demonstrates creation of a SasToken, which is used as the password for the MQTT connect packet. It also shows the topic names for publishing events and listening to devicebound
messages. This example only works with ENABLE_MQTT_TLS
set and the wolfSSL library present because it requires Base64 Encode/Decode and HMAC-SHA256. Note: The wolfSSL library must be built with ./configure --enable-base64encode
or #define WOLFSSL_BASE64_ENCODE
. The wc_GetTime
API was added in 3.9.1 and if not present you'll need to implement your own version of this to get current UTC seconds or update your wolfSSL library.
NOTE The Azure broker only supports MQTT v3.1.1
We setup an AWS IoT endpoint and testing device certificate for testing. The AWS server uses TLS client certificate for authentication. The example is located in /examples/aws/
. The example subscribes to $aws/things/"AWSIOT_DEVICE_ID"/shadow/update/delta
and publishes to $aws/things/"AWSIOT_DEVICE_ID"/shadow/update
.
NOTE The AWS broker only supports MQTT v3.1.1
This example enables the wolfMQTT client to connect to the IBM Watson Internet of Things (WIOT) Platform. The WIOT Platform has a limited test broker called "Quickstart" that allows non-secure connections to exercise the component. The example is located in /examples/wiot/
. Works with MQTT v5 support enabled.
NOTE The WIOT Platform will be disabled DEC2023. The demo may still be useful for users of IBM Watson IOT.
The Sensor Network client implements the MQTT-SN protocol for low-bandwidth networks. There are several differences from MQTT, including the ability to use a two byte Topic ID instead the full topic during subscribe and publish. The SN client requires an MQTT-SN gateway. The gateway acts as an intermediary between the SN clients and the broker. This client was tested with the Eclipse Paho MQTT-SN Gateway, which connects by default to the public Eclipse broker, much like our wolfMQTT Client example. The address of the gateway must be configured as the host. The example is located in /examples/sn-client/
.
More about MQTT-SN examples in examples/sn-client/README.md
This example exercises the multithreading capabilities of the client library. The client implements two tasks: one that publishes to the broker; and another that waits for messages from the broker. The publish thread is created NUM_PUB_TASKS
times (5 by default) and sends unique messages to the broker. This feature is enabled using the --enable-mt
configuration option. The example is located in /examples/multithread/
.
The multi-threading feature can also be used with the non-blocking socket (--enable-nonblock).
If you are having issues with thread synchronization on Linux consider using not the conditional signal (WOLFMQTT_NO_COND_SIGNAL
).
In the examples/pub-sub
folder, there are two simple client examples:
- mqtt-pub - publishes to a topic
- mqtt-sub - subscribes to a topic and waits for messages
These examples are useful for quickly testing or scripting.
The command line examples can be executed with optional parameters. To see a list of the available parameters, add the -?
./examples/mqttclient/mqttclient -?
mqttclient:
-? Help, print this usage
-h <host> Host to connect to, default: test.mosquitto.org
-p <num> Port to connect on, default: Normal 1883, TLS 8883
-t Enable TLS
-A <file> Load CA (validate peer)
-K <key> Use private key (for TLS mutual auth)
-c <cert> Use certificate (for TLS mutual auth)
-S <str> Use Host Name Indication, blank defaults to host
-q <num> Qos Level 0-2, default: 0
-s Disable clean session connect flag
-k <num> Keep alive seconds, default: 60
-i <id> Client Id, default: WolfMQTTClient
-l Enable LWT (Last Will and Testament)
-u <str> Username
-w <str> Password
-m <str> Message, default: test
-n <str> Topic name, default: wolfMQTT/example/testTopic
-r Set Retain flag on publish message
-C <num> Command Timeout, default: 30000ms
-P <num> Max packet size the client will accept, default: 1048576
-T Test mode
-f <file> Use file contents for publish
The available options vary depending on the library configuration.
wolfMQTT client library has been tested with the following brokers:
- Adafruit IO by Adafruit
- AWS by Amazon
- Azure by Microsoft
- flespi by Gurtam
- HiveMQ and HiveMQ Cloud by HiveMQ GmbH
- IBM WIoTP Message Gateway by IBM
- Mosquitto by Eclipse
- Paho MQTT-SN Gateway by Eclipse
- VerneMQ by VerneMQ/Erlio
- EMQX broker
The initially supported version with full specification support for all features and packets type such as:
- QoS 0-2
- Last Will and Testament (LWT)
- Client examples for: AWS, Azure IoT, Firmware update, non-blocking and generic.
The wolfMQTT client supports connecting to v5 enabled brokers when configured with the --enable-v5
option.
The following v5.0 specification features are supported by the wolfMQTT client:
- AUTH packet
- User properties
- Server connect ACK properties
- Format and content type for publish
- Server disconnect
- Reason codes and strings
- Maximum packet size
- Server assigned client identifier
- Subscription ID
- Topic Alias
The v5 enabled wolfMQTT client was tested with the following MQTT v5 brokers:
- Mosquitto
** Runs locally.
**
./examples/mqttclient/mqttclient -h localhost
- Flespi
** Requires an account tied token that is regenerated hourly.
**
./examples/mqttclient/mqttclient -h "mqtt.flespi.io" -u "<your-flespi-token>"
- VerneMQ MQTTv5 preview
** Runs locally.
**
./examples/mqttclient/mqttclient -h localhost
- HiveMQ 4.0.0 EAP
** Runs locally.
**
./examples/mqttclient/mqttclient -h localhost
- HiveMQ Cloud
**
./examples/mqttclient/mqttclient -h 833f87e253304692bd2b911f0c18dba1.s1.eu.hivemq.cloud -t -S -u wolf1 -w NEZjcm7i8eRjFKF -p 8883
- EMQX broker
**
./examples/mqttclient/mqttclient -h "broker.emqx.io"
Properties are allocated from a local stack (size MQTT_MAX_PROPS
) by default. Define WOLFMQTT_DYN_PROP
to use malloc for property allocation.
The wolfMQTT SN Client implementation is based on the OASIS MQTT-SN v1.2 specification. The SN API is configured with the --enable-sn
option. There is a separate API for the sensor network API, which all begin with the "SN_" prefix. The wolfMQTT SN Client operates over UDP, which is distinct from the wolfMQTT clients that use TCP. The following features are supported by the wolfMQTT SN Client:
- Register
- Will topic and message set up
- Will topic and message update
- All QoS levels
- Variable-sized packet length field
Unsupported features:
- Automatic gateway discovery is not implemented
- Multiple gateway handling
The SN client was tested using the Eclipse Paho MQTT-SN Gateway (https://github.com/eclipse/paho.mqtt-sn.embedded-c) running locally and on a separate network node. Instructions for building and running the gateway are in the project README.
Recently the OpenQuantumSafe project has integrated their fork of OpenSSL with the mosquito MQTT broker. You can now build wolfMQTT with wolfSSL and liboqs and use that to publish to the mosquito MQTT broker. Currently, wolfMQTT supports the KYBER_LEVEL1
and P256_KYBER_LEVEL1
groups and FALCON_LEVEL1 for authentication in TLS 1.3. This works on Linux.
To get started, you can use the code from the following github pull request:
open-quantum-safe/oqs-demos#143
Follow all the instructions in README.md and USAGE.md. This allows you to create a docker image and a docker network. Then you will run a broker, a subscriber and a publisher. At the end the publisher will exit and the broker and subscriber will remain active. You will need to re-activate the publisher docker instance and get the following files onto your local machine:
- /test/cert/CA.crt
- /test/cert/publisher.crt
- /test/cert/publisher.key
NOTE: Do not stop the broker and the subscriber instances.
Follow the instructions for obtaining and building liboqs and building wolfSSL in section 15 of the following document:
https://github.com/wolfSSL/wolfssl/blob/master/INSTALL
No special flags are required for building wolfMQTT. Simply do the following:
./autogen.sh (if obtained from github)
./configure
make all
make check
Since the broker and subscriber are still running, you can use mqttclient
to publish using post-quantum algorithms in TLS 1.3 by doing the following:
./examples/mqttclient/mqttclient -h 172.18.0.2 -t -A CA.crt -K publisher.key -c publisher.crt -m "Hello from post-quantum wolfMQTT!!" -n test/sensor1 -Q KYBER_LEVEL1
Congratulations! You have just published an MQTT message using TLS 1.3 with the KYBER_LEVEL1
KEM and FALCON_LEVEL1
signature scheme. To use the hybrid group, replace KYBER_LEVEL1
with P256_KYBER_LEVEL1
.
wolfMQTT now supports using libcurl's easy socket interface as a backend.
When enabled, wolfMQTT will use the libcurl API for the socket backend,
and libcurl will use wolfSSL to negotiate TLS.
This can be enabled with --enable-curl
.
At this time wolfMQTT's libcurl option supports both TLS and mTLS, but not Post-Quantum TLS.
To use wolfMQTT with libcurl and wolfSSL:
- build wolfssl with
--enable-curl
and install to/usr/local
. - build libcurl with
--with-wolfssl
and install to/usr/local
.
Finally, build wolfMQTT with --enable-curl
.
The --enable-curl
option works with these combinations:
--enable-mt
--enable-nonblock
--enable-tls
(default enabled)--enable-timeout
(default enabled)
However --enable-curl
is incompatible and not supported with these options:
--enable-all
--enable-sn
To simplify testing a stress build option has been added, --enable-stress=[args]
.
The Stress option enables multithreading and nonblocking, and adds defines for
TEST_NONBLOCK
, NUM_PUB_TASKS
, and NUM_PUB_PER_TASK
.
Examples of usage:
--enable-stress
: stress with default options.--enable-stress=t7,p8
: stress with 7 threads, and 8 publishes per thread.--enable-stress=t7,p8 --enable-curl
: same as above, but with curl backend.
Note: When stress is enabled, the Multithread Example becomes localhost only
and will not connect to remote servers. Additionally the test scripts/stress.test
is added to make check
, and all other tests are disabled.