macchina.io REMOTE provides secure remote access to connected devices
via HTTP or other TCP-based protocols and applications such as secure shell (SSH),
secure file transfer (SFTP), Virtual Network Computing (VNC) or remote desktop (RDP).
With macchina.io REMOTE, any network-connected device
running the macchina.io REMOTE Device Agent software (WebTunnelAgent
, contained in this SDK)
can be securely accessed remotely over the internet from browsers, mobile apps, desktop,
server or cloud applications.
This even works if the device is behind a NAT router, firewall or proxy server. The device becomes just another host on the internet, addressable via its own URL and protected by the macchina.io REMOTE server against unauthorized or malicious access. macchina.io REMOTE is a great solution for secure remote support and maintenance, as well as for providing secure remote access to devices for end-users via web or mobile apps.
Visit macchina.io/remote to learn more and to register for a free account.
Specifically, see the Getting Started page and the
Frequently Asked Questions for
information on how to use this SDK and the included WebTunnelAgent
executable.
There is also a blog post showing step-by-step instructions to connect a Raspberry Pi.
The macchina.io REMOTE SDK is based on the POCO C++ Libraries. You may want to read README_POCO as well as it contains important information regarding the directory structure and the build system of the SDK.
The SDK contains the WebTunnel
library, which implements the tunnel protocol used by macchina.io REMOTE.
Furthermore, the following executables are included:
WebTunnelAgent
: This executable, also known as macchina.io REMOTE Device Agent, runs on the device and creates the secure tunnel between the device and the macchina.io REMOTE server. This is the most important component of the macchina.io REMOTE SDK.remote-client
: This executable can run on a client machine (Windows, macOS or Linux) to create a secure tunnel from the client machine to the remote device, via the macchina.io REMOTE server. It is required for tunneling TCP-based protocols not directly supported by macchina.io REMOTE, such Modbus/TCP, OPC-UA, database connections, etc.remote-ssh
: This is a variant ofremote-client
that first creates a tunnel connection from your local machine (Windows, macOS or Linux) to the remote device, then launches a SSH client using that tunnel connection.remote-scp
: This is a variant ofremote-client
that first creates a tunnel connection from your local machine (Windows, macOS or Linux) to the remote device, then launches a SCP (Secure/SSH File Copy) client (scp
) using that tunnel connection.remote-sftp
: This is a variant ofremote-client
that first creates a tunnel connection from your local machine (Windows, macOS or Linux) to the remote device, then launches a SFTP (Secure/SSH File Transfer Protocol) client using that tunnel connection.remote-vnc
: This is a variant ofremote-client
that first creates a tunnel connection from your local machine (Windows, macOS or Linux) to a remote device running a VNC (Virtual Network Computing) server, then launches a VNC remote desktop client using that tunnel connection.remote-rdp
: This is a variant ofremote-client
that first creates a tunnel connection from your local machine (Windows, macOS) to a remote Windows device (which must have the remote desktop feature enabled), then launches a Microsoft Remote Desktop (RDP) client using that tunnel connection.
There are also WebTunnelAgentLib
and
WebTunnelClientLib
, which provide the functionality of
WebTunnelAgent
and remote-client
, respetively, in a C API, suitable for integration into applications (not written in C++).
The macchina.io REMOTE SDK, like the POCO C++ Libraries the SDK is based on, is licensed under the Boost Software License.
Pre-built executables for Windows, macOS and some Linux distributions (including Raspberry Pi OS) are available from the macchina.io website.
The easiest way to install the above mentioned executables on a Linux or macOS system from source is to download and run the installer script with the following command:
$ curl https://raw.githubusercontent.com/my-devices/agent-installer/master/install.sh | bash
The script should work on most Debian and RedHat-based Linux distributions including Ubuntu and Raspberry Pi OS. On macOS, Homebrew must be installed.
The script will install all required dependencies, then get the sources from
GitHub and run the steps necessary (see below) to build and install the binaries in /usr/local/bin/
.
If you do not want to or cannot run the installer script, please see the following instructions.
The macchina.io REMOTE SDK requires OpenSSL 1.0 or newer on Linux and macOS systems. We recommend using OpenSSL version 1.1.1l or newer (including OpenSSL 3).
Most Unix/Linux systems already have OpenSSL preinstalled. If your system does not have OpenSSL, please get it from https://www.openssl.org or another source. You do not have to build OpenSSL yourself - a binary distribution is fine. For example, via Debian APT:
$ apt-get install openssl libssl-dev
On macOS, the easiest way to install OpenSSL is via Homebrew:
$ brew install openssl
On Windows, OpenSSL is optional. The default (with CMake) is to build using Windows native SSL/TLS support. However, it's also possible to use OpenSSL instead. The easiest way to install OpenSSL on Windows is to use a binary (prebuild) release, for example the one from Shining Light Productions that comes with a Windows installer.
A C++ compiler (C++14 or newer) is required to build the SDK and applications. The system's default compiler (gcc on Linux, clang on macOS) should be fine on reasonably recent systems. On Windows, Visual C++ is recommended (any version from 2015 to 2019 will do).
CMake 3.2 (or newer) is the recommended way to build the SDK.
All dependencies can be installed with the following commands:
$ sudo apt-get -y update && sudo apt-get -y install git g++ make cmake libssl-dev
$ sudo yum install -y git gcc-c++ make cmake3 openssl-devel
$ brew install cmake openssl
CMake (version 3.2 or newer) is the recommended build system for building the macchina.io REMOTE SDK.
$ git clone https://github.com/my-devices/sdk.git
$ cd sdk
$ mkdir cmake-build
$ cd cmake-build
$ cmake ..
$ cmake --build . --config Release
On macOS, it's necessary to tell CMake where to find the OpenSSL headers
and libraries by setting the OPENSSL_ROOT_DIR
CMake variable.
For example, if OpenSSL 1.1.x has been installed with Homebrew,
the cmake
invocation becomes:
$ cmake .. -DOPENSSL_ROOT_DIR=/usr/local/opt/openssl
On an Apple Silicon Mac, Homebrew installs packages in /opt/homebrew
,
so the command becomes:
$ cmake .. -DOPENSSL_ROOT_DIR=/opt/homebrew/opt/openssl
If you want to link statically with OpenSSL libraries (recommended on
macOS), add the -DOPENSSL_USE_STATIC_LIBS=TRUE
option, e.g.:
$ cmake .. -DOPENSSL_ROOT_DIR=/usr/local/opt/[email protected] -DOPENSSL_USE_STATIC_LIBS=TRUE
Other common ways of building with CMake (e.g., cmake-gui
) will also work.
There are also a number of project-specific CMake variables that can be changed, e.g., to build with OpenSSL on Windows.
With a proper CMake toolchain file (specified via the CMAKE_TOOLCHAIN_FILE
CMake variable),
the SDK can be cross-compiled for embedded Linux systems:
$ cmake .. -DCMAKE_TOOLCHAIN_FILE=/path/to/mytoolchain.cmake -DCMAKE_INSTALL_PREFIX=/path/to/target
If the cross-compiling toolchain does not contain OpenSSL, you'll also have to build it prior to building this project. See Cross Compiling with CMake for instructions.
Note: The resulting executables may contain debug information, which significantly
increases their size.
You should run xxx-yyy-linux-strip
on the resulting executables to reduce their
size before deploying them to the device.
NOTE: See README_iOS.md for iOS builds and README_Android.md for Android builds.
The SDK can be optionally be installed by building the install
target. However,
in most cases this is not necessary. The resulting executables in the cmake-build/bin
directory are statically linked per default and can be moved to any directory desired.
If required, the SDK header files and libraries can be installed with:
$ sudo cmake --build . --target install
The default install location is /usr/local/
on Linux and macOS and
C:\Program Files (x64)\
on Windows and can be overridden by setting
the CMAKE_INSTALL_PREFIX
CMake variable.
WARNING: Be careful when installing to the default location if you also
have the POCO C++ Libraries installed there, as both install locations are
the same. If you need to install (e.g., in order to build the Remote
Manager Gateway), specify an appropriate CMAKE_INSTALL_PREFIX
.
In addition to CMake, the GNU Make based build system from the POCO C++ Libraries is also supported.
The easy way to build the SDK on Linux or macOS is to run the
buildsdk.sh
script:
$ git clone https://github.com/my-devices/sdk.git
$ cd sdk
$ ./buildsdk.sh
It will make the necessary invocations of
the configure script and GNU make to build WebTunnelAgent
and
the client command-line tools, along with the required libraries. With this
build, the required POCO libraries (Foundation
, Net
, Util
, WebTunnel
,
Crypto
and NetSSL_OpenSSL
) will be linked statically into the final
applications. If you don't want this, because you want to use other
parts of POCO in your project and link the shared libraries, you'll
have to run the necessary commands manually. You'll also have to
do a manual build if your target does not have OpenSSL.
The resulting executables will be located in the bin directory.
For cross-compiling for an embedded platform, pass the name of a
build configuration to the buildsdk.sh
script. For example, to build
for Angstrom:
$ ./buildsdk.sh Angstrom
See the build/config directory for available build configurations. If
there's no build configuration that fits your target, you'll have to
create one yourself. This is best done by copying an existing one,
making the necessary changes (typically, changing the name of the
compiler and linker executables to match your particular toolchain,
and modifying compiler/linker settings if necessary).
Specify the name of your new build configuration in the call to buildsdk.sh
.
For more information regarding the build system, see the POCO C++ Libraries documentation at https://docs.pocoproject.org/.
A final note: buildsdk.sh
only builds the release configuration.
If you need a debug build, see below.
To customize the SDK build, invoke the configure script and GNU make manually, as described in README_POCO.
$ ./configure --cflags=-DPOCO_UTIL_NO_XMLCONFIGURATION --no-tests --no-samples --static
$ make -s -j8 DEFAULT_TARGET=static_release
$ export POCO_BASE=`pwd`
$ cd WebTunnel/WebTunnelAgent
$ make -s DEFAULT_TARGET=shared_release
A few notes on the arguments:
--cflags=-DPOCO_UTIL_NO_XMLCONFIGURATION
instructs the build system to omit support for XML configuration files. The result is that the PocoXML library does not need to be linked into the application, saving a few 100Ks of executable size.--no-tests
and--no-samples
instruct the build system not to build the POCO sample applications and the testsuites.--static
instructs the build system to build static libraries.DEFAULT_TARGET=static_release
instructs the build system to only build the release configuration.DEFAULT_TARGET=shared_release
(in the second call to GNU make for building theWebTunnelAgent
and command-line client executables) instructs the build system to link against the shared runtime libraries (C and C++ standard libraries, OpenSSL), but use the static POCO libraries (since only these are available).WEBTUNNEL_ENABLE_TLS=1
enables SSL/TLS support for WebTunnelAgent and the command-line client tools.
If your system does not have OpenSSL, run configure and GNU make as follows:
$ ./configure --cflags=-DPOCO_UTIL_NO_XMLCONFIGURATION --omit=Crypto,NetSSL_OpenSSL --no-tests --no-samples --static
$ make -s -j8 DEFAULT_TARGET=static_release
$ export POCO_BASE=`pwd`
$ cd WebTunnel/Agent
$ make -s WEBTUNNEL_DISABLE_TLS=1 DEFAULT_TARGET=shared_release
For a cross-build for an embedded target, you must specify the build configuration in the
call to ./configure
and the final call to GNU make.
$ ./configure --cflags=-DPOCO_UTIL_NO_XMLCONFIGURATION --no-tests --no-samples --static --config=Angstrom
$ make -s -j8 DEFAULT_TARGET=static_release
$ export POCO_BASE=`pwd`
$ cd WebTunnel/WebTunnelAgent
$ make -s POCO_CONFIG=Angstrom DEFAULT_TARGET=shared_release