Steward is a Command & Control backend system for Servers, IOT and Edge platforms where the network link for reaching them can be reliable like local networks, or totally unreliable like satellite links. An end node can even be offline when you give it a command, and Steward will make sure that the command is delivered when the node comes online.

Example use cases:

• Send a specific message to one or many end nodes that will instruct to run scripts or a series of shell commands to change config, restart services and control those systems.
• Gather IOT/OT data from both secure and not secure devices and systems, and transfer them encrypted in a secure way over the internet to your central system for handling those data.
• Collect metrics or monitor end nodes and store the result on a central Steward instance, or pass those data on to another central system for handling metrics or monitoring data.
• Distribute certificates.

As long as you can do something as an operator on in a shell on a system you can do the same with Steward in a secure way to one or all end nodes (servers) in one go with one single message/command.

NB Expect the main branch to have breaking changes. If stability is needed, use the released packages, and read the release notes where changes will be explained.

• steward
  • What is it ?
  • Overview
  • Inspiration
  • Why
  • Publishing and Subscribing processes
    • Publisher
    • Subscriber
    • Logical structure
  • Terminology
  • Features
    • Error messages from nodes
    • Message handling and threads
    • Timeouts and retries for requests
      • REQRelay
        • Relay Step 1
        • Relay Step 2
        • Relay Step 3
        • Relay Step 4
        • Relay Step 5
        • Relay Step 6
    • Flags and configuration file
    • Schema for the messages to send into Steward via the API's
    • Nats messaging timeouts
    • Compression of the Nats message payload
    • startup folder
      • General functionality
      • How to send the reply to another node
      • method timeout
        • Example
    • Request Methods
      • REQOpProcessList
      • REQOpProcessStart
      • REQOpProcessStop
      • REQCliCommand
      • REQCliCommandCont
      • REQTailFile
      • REQHttpGet
      • REQHttpGetScheduled
      • REQHello
      • REQCopyFileFrom
      • REQErrorLog
    • Request Methods used for reply messages
      • REQNone
      • REQToConsole
      • REQToFileAppend
      • REQToFile
      • ReqCliCommand
    • Errors reporting
    • Prometheus metrics
    • Other
  • Howto
    • Options for running
    • How to Run
      • Run Steward in the simplest possible way for testing
        • Nats-server
        • Steward
        • Send messages with Steward
      • Example for starting steward with some more options set
      • Nkey Authentication
      • nats-server (the message broker)
        • Nats-server config with nkey authentication example
    • Message fields explanation
    • How to send a Message
      • Send to socket with netcat
      • Sending a command from one Node to Another Node
        • Example JSON for appending a message of type command into the socket file
        • Specify more messages at once do
        • Send the same message to several hosts by using the toHosts field
        • Tail a log file on a node, and save the result of the tail centrally at the directory specified
        • Example for deleting the ringbuffer database and restarting steward
  • Concepts/Ideas
    • Naming
      • Subject
        • Complete subject example
  • TODO
    • Add Op option the remove messages from the queue on nodes
  • Disclaimer

Command And Control anything like Servers, Containers, VM's or others by creating and sending messages with methods who will describe what to do. Steward will then take the responsibility for making sure that the message are delivered to the receiver, and that the method specified are executed with the given parameters defined. An example of a message.

An example of a request method to feed into the system. All fields are explained in detail further down in the document.

[
    {
        "directory":"/var/cli/command_result/",
        "fileName": "some-file-name.result",
        "toNode": "ship1",
        "method":"REQCliCommand",
        "methodArgs": ["bash","-c","sleep 5 & tree ./"],
        "replyMethod":"REQToFileAppend",
        "ACKTimeout":5,
        "retries":3,
        "replyACKTimeout":5,
        "replyRetries":3,
        "methodTimeout": 10
    }
]

If the receiver toNode is down when the message was sent, it will be retried until delivered within the criterias set for timeouts and retries. The state of each message processed is handled by the owning steward instance where the message originated, and no state about the messages are stored in the NATS message broker.

Since the initial connection from a Steward node is outbound towards the central NATS message broker no inbound firewall openings are needed.

Send Commands with Request Methods to control your servers by passing a messages that will have guaranteed delivery based on the criteries set, and when/if the receiving node is available. The result of the method executed will be delivered back to you from the node you sent it from.

Steward uses NATS as message passing architecture for the commands back and forth from nodes. Delivery is guaranteed within the criterias set. All of the processes in the system are running concurrently, so if something breaks or some process is slow it will not affect the handling and delivery of the other messages in the system.

A node can be a server running any host operating system, a container living in the cloud somewhere, a Rapsberry Pi, or something else that needs to be controlled that have an operating system installed.

Steward can be compiled to run on all major architectures like x86, amd64,arm64, ppc64 and more, with for example operating systems like Linux, OSX, Windows.

The idea for how to handle processes, messages and errors are based on Joe Armstrongs idea behind Erlang described in his Thesis https://erlang.org/download/armstrong_thesis_2003.pdf.

Joe's document describes how to build a system where everything is based on sending messages back and forth between processes in Erlang, and where everything is done concurrently.

I used those ideas as inspiration for building a fully concurrent system to control servers or container based systems by passing messages between processes asynchronously to execute methods, handle errors, or handle the retrying if something fails.

Steward is written in the programming language Go with NATS as the message broker.

With existing solutions there is often either a push or a pull kind of setup to control the nodes.

In a push setup the commands to be executed is pushed to the receiver, but if a command fails because for example a broken network link it is up to you as an administrator to detect those failures and retry them at a later time until it is executed successfully.

In a pull setup an agent is installed at the Edge unit, and the configuration or commands to execute locally are pulled from a central repository. With this kind of setup you can be pretty certain that sometime in the future the node will reach it's desired state, but you don't know when. And if you want to know the current state you will need to have some second service which gives you that information.

In it's simplest form the idea about using an event driven system as the core for management of Edge units is that the sender/publisher are fully decoupled from the receiver/subscriber. We can get an acknowledge message if a message is received or not, and with this functionality we will at all times know the current state of the receiving end.

All parts of the system like processes, method handlers, messages, error handling are running concurrently.

If one process hangs on a long running message method it will not affect the rest of the system.

1. A message in valid format is appended to the in socket.
2. The message is picked up by the system and put on a FIFO ringbuffer.
3. The method type of the message is checked, a subject is created based on the content of the message, and a publisher process to handle the message type for that specific receiving node is started if it does not exist.
4. The message is then serialized to binary format, and sent to the subscriber on the receiving node.
5. If the message is expected to be ACK'ed by the subcriber then the publisher will wait for an ACK if the message was delivered. If an ACK was not received within the defined timeout the message will be resent. The amount of retries are defined within the message.

1. The receiving end will need to have a subscriber process started on a specific subject and be allowed handle messages from the sending nodes to execute the method defined in the message.
2. When a message have been received, a handler for the method type specified in the message will be executed.
3. If the output of the method called is supposed to be returned to the publiser it will do so by using the replyMethod specified.

TODO: Make a diagram here...

• Node: Something with an operating system that have network available. This can be a server, a cloud instance, a container, or other.
• Process: A message handler that knows how to handle messages of a given subject concurrently.
• Message: A message sent from one Steward node to another.

• Error messages will be sent back to the central error handler upon failure on a node.

Tue Sep 21 09:17:55 2021, info: toNode: ship2, fromNode: central, method: REQOpProcessList: max retries reached, check if node is up and running and if it got a subscriber for the given REQ type

• The handling of all messages is done by spawning up a process for handling the message in it's own thread. This allows us to down on the individual message level keep the state for each message both in regards to ACK's, error handling, send retries, and rerun of a method for a message if the first run was not successful.

• Processes for handling messages on a host can be restarted upon failure, or asked to just terminate and send a message back to the operator that something have gone seriously wrong. This is right now just partially implemented to test that the concept works, where the error action is action=no-action.

• Publisher Processes on a node for handling new messages for new nodes will automatically be spawned when needed if it does not already exist.

• Messages not fully processed or not started yet will be automatically rehandled if the service is restarted since the current state of all the messages being processed are stored on the local node in a key value store until they are finished.

• All messages processed by a publisher will be written to a log file after they are processed, with all the information needed to recreate the same message if needed, or it can be used for auditing.

• All handling down to the process and message level are handled concurrently. So if there are problems handling one message sent to a node on a subject it will not affect the messages being sent to other nodes, or other messages sent on other subjects to the same host.

• Message types of both ACK and NACK, so we can decide if we want or don't want an Acknowledge if a message was delivered succesfully. Example: We probably want an ACK when sending some REQCLICommand to be executed, but we don't care for an acknowledge NACK when we send an REQHello event.

• Default timeouts to wait for ACK messages and max attempts to retry sending a message are specified upon startup. This can be overridden on the message level.

• Timeouts can be specified on both the message, and the method.

  • A message can have a timeout used for used for when to resend and how many retries.
  • If the method triggers a shell command, the command can have its own timeout, allowing process timeout for long/stuck commands, or for telling how long the command is supposed to run.

Example of a message with timeouts set:

[
    {
        "directory":"/some/result/directory/",
        "fileName":"my-syslog.log",
        "toNode": "ship2",
        "methodArgs": ["bash","-c","tail -f /var/log/syslog"],
        "replyMethod":"REQToFileAppend",
        "method":"REQCliCommandCont",
        "ACKTimeout":3,
        "retries":3,
        "methodTimeout": 60
    }
]

In the above example, the values set meaning:

• ACKTimeout : Wait 3 seconds for an ACK message.
• retries : If an ACK is not received, retry sending the message 3 times.
• methodTimeout : Let the bash command tail -f ./tmp.log run for 60 seconds before it is terminated.

If no timeout are specified in a message the defaults specified in the etc/config.yaml are used.

Instead of injecting the new Requests on the central server, you can relay messages via another node as long as the nats-server authorization conf permits it. This is what REQRelay is for.

This functionality can be thought of as attaching a terminal to a Steward instance. Instead of injecting messages directly on for example the central Steward instance you can use another Steward instance and relay messages via the central instance.

Example configuration of relay authorization for nats-server can be found in the doc folder.

Example:

[
    {
        "directory":"/var/tail-logs/",
        "fileName": "my-wifi.log",
        "toNode": "node1",
        "relayViaNode": "central",
        "relayReplyMethod": "REQToConsole",
        "methodArgs": ["bash","-c","tail -f /var/log/wifi.log"],
        "method":"REQCliCommandCont",
        "replyMethod":"REQToFileAppend",
        "ACKTimeout":5,
        "retries":3,
        "replyACKTimeout":5,
        "replyRetries":3,
        "methodTimeout": 10
    }
]

                    1                           2                           3       
             ┌─────────────┐             ┌─────────────┐             ┌─────────────┐
------------▷│             │------------▷│             │------------▷│             │
             │   node1     │             │   central   │             │ node2       │
◁------------│             │◁------------│             │◁------------│             │
             └─────────────┘             └─────────────┘             └─────────────┘
                    6                           5                           4       

Steps Explained:

• The relayViaNode field of the message is checked, and If set the message will be encapsulated within a REQRelayInitial message where the original message field values are kept, and put back on the message queue on node1.
• The new REQRelayInitial message will again be picked up on node1 and handled by the REQRelayInitial handler.
• The REQRelayInitial handler will set the message method to REQRelay, and forward the message to the node value in the relayViaNode field.

• On central the REQRelay method handler will recreate the original message, and forward it to node2.

• Node2 receives the request, and executes the original method with the arguments specified.

• The result is sent back to central in the form of a normal reply message.

• When the reply message is received on central a copy of the reply message will be created , and forwarded to node1 where it originated.
• The the original reply method "replyMethod":"REQToFileAppend" is handled on central.

• On node1 the relayReplyMethod is checked for how to handle the message. In this case it is printed to the consoles STDOUT.

Steward supports both the use of flags with values set at startup, and the use of a config file.

• A default config file will be created at first startup if one does not exist
  • The default config will contain default values.
  • Any value also provided via a flag will also be written to the config file.
• If Steward is restarted, the current content of the config file will be used as the new defaults.
  • If you restart Steward without any flags specified, the values of the last run will be read from the config file.
• If new values are provided via CLI flags, they will take precedence over the ones currently in the config file.
  • The new CLI flag values will be written to the config, making it the default for the next restart.
• The config file can be edited directly, removing the need for CLI flag use.
• To create a default config, simply:
  1. Remove the current config file (or move it).
  2. Restart Steward. A new default config file, with default values, will be created.

• toNode : string
• toNodes : string array
• method : string
• methodArgs : string array
• replyMethod : string
• replyMethodArgs : string array
• ACKTimeout : int
• retries : int
• replyACKTimeout : int
• replyRetries : int
• methodTimeout : int
• replyMethodTimeout : int
• directory : string
• fileName : string
• RelayViaNode: string
• RelayReplyMethod: string

The various timeouts for the Nats messages can be controlled via the configuration file or flags.

If the network media is a high latency. satellite links it will make sense to adjust the client timeout to reflect the latency

  -natsConnOptTimeout int
        default nats client conn timeout in seconds (default 20)

The interval in seconds the nats client should try to reconnect to the nats-server if the connection is lost.

  -natsConnectRetryInterval int
        default nats retry connect interval in seconds. (default 10)

Jitter values.

  -natsReconnectJitter int
        default nats ReconnectJitter interval in milliseconds. (default 100)
  -natsReconnectJitterTLS int
        default nats ReconnectJitterTLS interval in seconds. (default 5)

You can choose to enable compression of the payload in the Nats messages.

  -compression string
        compression method to use. defaults to no compression, z = zstd, g = gzip. Undefined value will default to no compression

When starting a Steward instance with compression enabled it is the publishing of the message payload that is compressed.

The subscribing instance of Steward will automatically detect if the message is compressed or not, and decompress it if needed.

With other words, Steward will by default receive and handle both compressed and uncompressed messages, and you decide on the publishing side if you want to enable compression or not.

Messages can be automatically scheduled to be read and executed at startup of Steward.

A folder named startup will be present in the working directory of Steward, and you put the messages to be executed at startup here.

Normally the fromNode field is automatically filled in with the node name of the node where a message originated.

Since messages within the startup folder is not received from another node via the normal message path we need to specify the fromNode field within the message for where we want the reply delivered.

We can also make the request method run for as long as the Steward instance itself is running. We can do that by setting the methodTimeout field to a value of -1.

This can make sense if you for example wan't to continously ping a host, or continously run a script on a node.

[
    {
        "toNode": "ship1",
        "fromNode": "central",
        "method": "REQCliCommandCont",
        "methodArgs": [
            "bash",
            "-c",
            "nc -lk localhost 8888"
        ],
        "replyMethod": "REQToConsole",
        "methodTimeout": 10,
    }
]

This message is put in the ./startup folder on node1.
We send the message to ourself, hence specifying ourself in the toNode field.
We specify the reply messages with the result to be sent to the console on central in the fromNode field.
In the example we start a TCP listener on port 8888, and we want the method to run for as long as Steward is running. So we set the methodTimeout to -1.

Get a list of the running processes.

[
    {
        "directory":"test/dir",
        "fileName":"test.result",
        "toNode": "ship2",
        "method":"REQOpProcessList",
        "methodArgs": [],
        "replyMethod":"REQToFileAppend",
    }
]

Start up a process. Takes the REQ method to start as it's only argument.

[
    {
        "directory":"test/dir",
        "fileName":"test.result",
        "toNode": "ship2",
        "method":"REQOpProcessStart",
        "methodArgs": ["REQHttpGet"],
        "replyMethod":"REQToFileAppend",
    }
]

Stop a process. Takes the REQ method, receiving node name, kind publisher/subscriber, and the process ID as it's arguments.

[
    {
        "directory":"test/dir",
        "fileName":"test.result",
        "toNode": "ship2",
        "method":"REQOpProcessStop",
        "methodArgs": ["REQHttpGet","ship2","subscriber","199"],
        "replyMethod":"REQToFileAppend",
    }
]

Run CLI command on a node. Linux/Windows/Mac/Docker-container or other.

Will run the command given, and return the stdout output of the command when the command is done.

[
    {
        "directory":"some/cli/command",
        "fileName":"cli.result",
        "toNode": "ship2",
        "method":"REQnCliCommand",
        "methodArgs": ["bash","-c","docker ps -a"],
        "replyMethod":"REQToFileAppend",
    }
]

Run CLI command on a node. Linux/Windows/Mac/Docker-container or other.

Will run the command given, and return the stdout output of the command continously while the command runs. Uses the methodTimeout to define for how long the command will run.

[
    {
        "directory":"some/cli/command",
        "fileName":"cli.result",
        "toNode": "ship2",
        "method":"REQCliCommandCont",
        "methodArgs": ["bash","-c","docker ps -a"],
        "replyMethod":"REQToFileAppend",
        "methodTimeout":10,
    }
]

NB: A github issue is filed on not killing all child processes when using pipes golang/go#23019. This is relevant for this request type.

And also a new issue registered golang/go#50436

TODO: Check in later if there are any progress on the issue. When testing the problem seems to appear when using sudo, or tcpdump without the -l option. So for now, don't use sudo, and remember to use -l with tcpdump which makes stdout line buffered. timeout in front of the bash command can also be used to get around the problem with any command executed.

Tail log files on some node, and get the result for each new line read sent back in a reply message. Uses the methodTimeout to define for how long the command will run.

[
    {
        "directory": "/my/tail/files/",
        "fileName": "tailfile.log",
        "toNode": "ship2",
        "method":"REQTailFile",
        "methodArgs": ["/var/log/system.log"],
        "methodTimeout": 10
    }
]

Scrape web url, and get the html sent back in a reply message. Uses the methodTimeout for how long it will wait for the http get method to return result.

[
    {
        "directory": "web",
        "fileName": "web.html",
        "toNode": "ship2",
        "method":"REQHttpGet",
        "methodArgs": ["https://web.ics.purdue.edu/~gchopra/class/public/pages/webdesign/05_simple.html"],
        "replyMethod":"REQToFile",
        "ACKTimeout":10,
        "retries": 3,
        "methodTimeout": 3
    }
]

Schedule scraping of a web web url, and get the html sent back in a reply message. Uses the methodTimeout for how long it will wait for the http get method to return result.

The methodArgs also takes 3 arguments:

1. The URL to scrape.
2. The schedule interval given in seconds.
3. How long the scheduler should run in minutes.

The example below will scrape the URL specified every 30 seconds for 10 minutes.

[
    {
        "directory": "web",
        "fileName": "web.html",
        "toNode": "ship2",
        "method":"REQHttpGet",
        "methodArgs": ["https://web.ics.purdue.edu/~gchopra/class/public/pages/webdesign/05_simple.html","30","10"],
        "replyMethod":"REQToFile",
        "ACKTimeout":10,
        "retries": 3,
        "methodTimeout": 3
    }
]

Send Hello messages.

All nodes have the flag option to start sending Hello message to the central server. The structure of those messages looks like this.

[
    {
        "toNode": "central",
        "method":"REQHello"
    }
]

Copy a file from one node to another node.

• Source node to copy from is specified in the toNode/toNodes field
• The file to copy and the destination node is specified in the methodArgs field:
  1. The first field is the full path of the source file.
  2. The second field is the destination node for where to copy the file to.
  3. The third field is the full path for where to write the copied file.

[
    {
        "directory": "copy",
        "fileName": "copy.log",
        "toNodes": ["central"],
        "method":"REQCopyFileFrom",
        "methodArgs": ["./tmp2.txt","ship2","/tmp/tmp2.txt"],
        "replyMethod":"REQToFileAppend"
    }
]

Method for receiving error logs for Central error logger.

NB: This is not to be used by users. Use REQToFileAppend instead.

Don't send a reply message.

An example could be that you send a REQCliCommand message to some node, and you specify replyMethod: REQNone if you don't care about the resulting output from the original method.

This is a pure replyMethod that can be used to get the data of the reply message printed to stdout where Steward is running.

[
    {
        "directory": "web",
        "fileName": "web.html",
        "toNode": "ship2",
        "method":"REQHttpGet",
        "methodArgs": ["https://web.ics.purdue.edu/~gchopra/class/public/pages/webdesign/05_simple.html"],
        "replyMethod":"REQToConsole",
        "ACKTimeout":10,
        "retries": 3,
        "methodTimeout": 3
    }
]

Append the output of the reply message to a log file specified with the directory and fileName fields.

[
    {
        "directory":"test/dir",
        "fileName":"test.result",
        "toNode": "ship2",
        "method":"REQOpProcessList",
        "methodArgs": [],
        "replyMethod":"REQToFileAppend",
    }
]

Write the output of the reply message to a file specified with the directory and fileName fields, where the writing will write over any existing content of that file.

[
    {
        "directory":"test/dir",
        "fileName":"test.result",
        "toNode": "ship2",
        "method":"REQOpProcessList",
        "methodArgs": [],
        "replyMethod":"REQToFile",
    }
]

ReqCliCommand is a bit special in that it can be used as both method and replyMethod

The final result, if any, of the replyMethod will be sent to the central server.

By using the {{STEWARD_DATA}} you can grab the output of your initial request method, and then use it as input in your reply method.

NB: The echo command in the example below will remove new lines from the data. To also keep any new lines we need to put escaped quotes around the template variable. Like this:

• \"{{STEWARD_DATA}}\"

Example of usage:

[
    {
        "directory":"cli_command_test",
        "fileName":"cli_command.result",
        "toNode": "ship2",
        "method":"REQCliCommand",
        "methodArgs": ["bash","-c","tree"],
        "replyMethod":"REQCliCommand",
        "replyMethodArgs": ["bash", "-c","echo \"{{STEWARD_DATA}}\" > apekatt.txt"],
        "replyMethodTimeOut": 10,
        "ACKTimeout":3,
        "retries":3,
        "methodTimeout": 10
    }
]

Or the same using bash's herestring:

[
    {
        "directory":"cli_command_test",
        "fileName":"cli_command.result",
        "toNode": "ship2",
        "method":"REQCliCommand",
        "methodArgs": ["bash","-c","tree"],
        "replyMethod":"REQCliCommand",
        "replyMethodArgs": ["bash", "-c","cat <<< {{STEWARD_DATA}} > hest.txt"],
        "replyMethodTimeOut": 10,
        "ACKTimeout":3,
        "retries":3,
        "methodTimeout": 10
    }
]

• Errors happening on all nodes will be reported back in to the node name defined with the -centralNodeName flag.

• Prometheus exporters for Metrics.

• More will come. In active development.

The location of the config file are given via an env variable at startup (default "./etc/).

env CONFIG_FOLDER </myconfig/folder/here> <steward binary>

The different fields and their type in the config file. The fields of the config file can also be set by providing flag values at startup. Use the -help flag to get all the options.

    // RingBufferSize
    RingBufferSize int
    // The configuration folder on disk
    ConfigFolder string
    // The folder where the socket file should live
    SocketFolder string
    // TCP Listener for sending messages to the system
    TCPListener string
    // HTTP Listener for sending messages to the system
    HTTPListener string
    // The folder where the database should live
    DatabaseFolder string
    // some unique string to identify this Edge unit
    NodeName string
    // the address of the message broker
    BrokerAddress string
    // NatsConnOptTimeout the timeout for trying the connect to nats broker
    NatsConnOptTimeout int
    // nats connect retry
    NatsConnectRetryInterval int
    // NatsReconnectJitter in milliseconds
    NatsReconnectJitter int
    // NatsReconnectJitterTLS in seconds
    NatsReconnectJitterTLS int
    // The number of the profiling port
    ProfilingPort string
    // host and port for prometheus listener, e.g. localhost:2112
    PromHostAndPort string
    // set to true if this is the node that should receive the error log's from other nodes
    DefaultMessageTimeout int
    // Default value for how long can a request method max be allowed to run.
    DefaultMethodTimeout int
    // default amount of retries that will be done before a message is thrown away, and out of the system
    DefaultMessageRetries int
    // Publisher data folder
    SubscribersDataFolder string
    // central node to receive messages published from nodes
    CentralNodeName string
    // Path to the certificate of the root CA
    RootCAPath string
    // Full path to the NKEY's seed file
    NkeySeedFile string
    // The host and port to expose the data folder
    ExposeDataFolder string
    // Timeout for error messages
    ErrorMessageTimeout int
    // Retries for error messages.
    ErrorMessageRetries int
    // Compression
    Compression string
    // Serialization
    Serialization string
    // SetBlockProfileRate for block profiling
    SetBlockProfileRate int 
    // NOTE:
    // Op commands will not be specified as a flag since they can't be turned off.  
    // Make the current node send hello messages to central at given interval in seconds
    StartPubREQHello int
    // Start the central error logger.
    // Takes a comma separated string of nodes to receive from or "*" for all nodes.
    StartSubREQErrorLog bool
    // Subscriber for hello messages
    StartSubREQHello bool
    // Subscriber for text logging
    StartSubREQToFileAppend bool
    // Subscriber for writing to file
    StartSubREQToFile bool
    // Subscriber for reading files to copy
    StartSubREQCopyFileFrom bool
    // Subscriber for writing copied files to disk
    StartSubREQCopyFileTo bool
    // Subscriber for Echo Request
    StartSubREQPing bool
    // Subscriber for Echo Reply
    StartSubREQPong bool
    // Subscriber for CLICommandRequest
    StartSubREQCliCommand bool
    // Subscriber for REQToConsole
    StartSubREQToConsole bool
    // Subscriber for REQHttpGet
    StartSubREQHttpGet bool
    // Subscriber for tailing log files
    StartSubREQTailFile bool
    // Subscriber for continously delivery of output from cli commands.
    StartSubREQCliCommandCont bool
    // Subscriber for relay messages.
    StartSubREQRelay bool

NB Running Steward like this is perfect for testing in a local test environment, but is not something you would wan't to do in production.

Download the nats-server from https://github.com/nats-io/nats-server/releases/

Or use the curl (replace the version information with wanted version):

curl -L https://github.com/nats-io/nats-server/releases/download/vX.Y.Z/nats-server-vX.Y.Z-linux-amd64.zip -o nats-server.zip

Unpack:

unzip nats-server.zip -d nats-server

Start the nats server listening on local interfaces and port 4222.

./nats-server -D

Steward is written in Go, so you need Go installed to compile it. You can get Go at https://golang.org/dl/.

When Go is installed:

Clone the repository:

git clone https://github.com/RaaLabs/steward.git.

Change directory and build:

cd ./steward/cmd/steward
go build -o steward

Start up a central server which will act as your command and control server.

• env CONFIG_FOLDER=./etc/ ./steward --nodeName="central" --centralNodeName="central"

Start up a node that will attach to the central node

env CONFIG_FOLDER=./etc/ ./steward --nodeName="ship1" --centralNodeName="central" & ./steward --node="ship2"

You can get all the options with ./steward --help

Steward will by default create the data and config directories needed in the current folder. This can be changed by using the different flags or editing the config file.

You can also run multiple instances of Steward on the same machine. For testing you can create sub folders for each steward instance, go into each folder and start steward. When starting each Steward instance make sure you give each node a unique --nodeName.

You can now go to one of the folders for nodes started, and inject messages into the socket file ./tmp/steward.sock with the nc tool.

Example on Mac:

nc -U ./tmp/steward.sock < reqnone.msg

Example on Linux:

nc -NU ./tmp/steward.sock < reqnone.msg

A complete example to start a central node called central.

env CONFIG_FOLDER=./etc/ ./steward \
 -nodeName="central" \
 -defaultMessageRetries=3 \
 -defaultMessageTimeout=5 \
 -subscribersDataFolder="./data" \
 -centralNodeName="central" \
 -startSubREQErrorLog=true \
 -subscribersDataFolder="./var" \
 -brokerAddress="127.0.0.1:4222"

And start another node that will be managed via central.

env CONFIG_FOLDER=./etc/ ./steward \
 -nodeName="ship1" \ 
 -startPubREQHello=200 \
 -centralNodeName="central" \
 -promHostAndPort=":12112" \
 -brokerAddress="127.0.0.1:4222"

NB: By default Steward creates it's folders like ./etc, ./var, and ./data in the folder you're in when you start it. If you want to run multiple instances on the same machine you should create separate folders for each instance, and start Steward when you're in that folder. The location of the folders can also be specified within the config file.

Nkey's can be used for authentication, and you use the nkeySeedFile flag to specify the seed file to use.

Read more in the sections below on how to generate nkey's.

The broker for messaging is Nats-server from https://nats.io. Download, run it, and use the -brokerAddress flag on Steward to point to the ip and port:

-brokerAddress="nats://10.0.0.124:4222"

There is a lot of different variants of how you can setup and confiure Nats. Full mesh, leaf node, TLS, Authentication, and more. You can read more about how to configure the Nats broker called nats-server at https://nats.io/.

port: 4222
tls {
  cert_file: "some.crt"
  key_file: "some.key"
}


authorization: {
    users = [
        {
            # central
            nkey: <USER_NKEY_HERE>
            permissions: {
                publish: {
      allow: ["some.>","errorCentral.>"]
    }
            subscribe: {
      allow: ["some.>","errorCentral.>"]
    }
            }
        }
        {
            # node1
            nkey: <USER_NKEY_HERE>
            permissions: {
                publish: {
                        allow: ["central.>"]
                }
                subscribe: {
                        allow: ["central.>","some.node1.>","some.node10'.>"]
                }
            }
        }
        {
            # node10
            nkey: <USER_NKEY_HERE>
            permissions: {
                publish: {
                        allow: ["some.node1.>","errorCentral.>"]
                }
                subscribe: {
                        allow: ["central.>"]
                }
            }
        }
    ]
}

The official docs for nkeys can be found here https://docs.nats.io/nats-server/configuration/securing_nats/auth_intro/nkey_auth.

• Generate private (seed) and public (user) key pair:

  • nk -gen user -pubout

• Generate a public (user) key from a private (seed) key file called seed.txt.

  • nk -inkey seed.txt -pubout > user.txt

More example configurations for the nats-server are located in the doc folder in this repository.

// The node to send the message to.
ToNode Node `json:"toNode" yaml:"toNode"`
// ToNodes to specify several hosts to send message to in the
// form of an slice/array.
ToNodes []Node `json:"toNodes,omitempty" yaml:"toNodes,omitempty"`
// The actual data in the message. This is typically where we
// specify the cli commands to execute on a node, and this is
// also the field where we put the returned data in a reply
// message.
Data []string `json:"data" yaml:"data"`
// Method, what request type to use, like REQCliCommand, REQHttpGet..
Method Method `json:"method" yaml:"method"`
// Additional arguments that might be needed when executing the
// method. Can be f.ex. an ip address if it is a tcp sender, or the
// shell command to execute in a cli session.
MethodArgs []string `json:"methodArgs" yaml:"methodArgs"`
// ReplyMethod, is the method to use for the reply message.
// By default the reply method will be set to log to file, but
// you can override it setting your own here.
ReplyMethod Method `json:"replyMethod" yaml:"replyMethod"`
// Additional arguments that might be needed when executing the reply
// method. Can be f.ex. an ip address if it is a tcp sender, or the
// shell command to execute in a cli session.
ReplyMethodArgs []string `json:"replyMethodArgs" yaml:"replyMethodArgs"`
// IsReply are used to tell that this is a reply message. By default
// the system sends the output of a request method back to the node
// the message originated from. If it is a reply method we want the
// result of the reply message to be sent to the central server, so
// we can use this value if set to swap the toNode, and fromNode
// fields.
IsReply bool `json:"isReply" yaml:"isReply"`
// From what node the message originated
FromNode Node
// ACKTimeout for waiting for an ack message
ACKTimeout int `json:"ACKTimeout" yaml:"ACKTimeout"`
// Resend retries
Retries int `json:"retries" yaml:"retries"`
// The ACK timeout of the new message created via a request event.
ReplyACKTimeout int `json:"replyACKTimeout" yaml:"replyACKTimeout"`
// The retries of the new message created via a request event.
ReplyRetries int `json:"replyRetries" yaml:"replyRetries"`
// Timeout for long a process should be allowed to operate
MethodTimeout int `json:"methodTimeout" yaml:"methodTimeout"`
// Timeout for long a process should be allowed to operate
ReplyMethodTimeout int `json:"replyMethodTimeout" yaml:"replyMethodTimeout"`
// Directory is a string that can be used to create the
//directory structure when saving the result of some method.
// For example "syslog","metrics", or "metrics/mysensor"
// The type is typically used in the handler of a method.
Directory string `json:"directory" yaml:"directory"`
// FileName is used to be able to set a wanted name
// on a file being saved as the result of data being handled
// by a method handler.
FileName string `json:"fileName" yaml:"fileName"`
// PreviousMessage are used for example if a reply message is
// generated and we also need a copy of  the details of the the
// initial request message.
PreviousMessage *Message
// The node to relay the message via.
RelayViaNode Node `json:"relayViaNode" yaml:"relayViaNode"`
// The node where the relayed message originated, and where we want
// to send back the end result.
RelayFromNode Node `json:"relayFromNode" yaml:"relayFromNode"`
// The original value of the ToNode field of the original message.
RelayToNode Node `json:"relayToNode" yaml:"relayToNode"`
// The original method of the message.
RelayOriginalMethod Method `json:"relayOriginalMethod" yaml:"relayOriginalMethod"`
// The method to use when the reply of the relayed message came
// back to where originated from.
RelayReplyMethod Method `json:"relayReplyMethod" yaml:"relayReplyMethod"`
// done is used to signal when a message is fully processed.
// This is used for signaling back to the ringbuffer that we are
// done with processing a message, and the message can be removed
// from the ringbuffer and into the time series log.

The API for sending a message from one node to another node is by sending a structured JSON object into a listener port in of of the following ways.

• unix socket called steward.sock. By default lives in the ./tmp directory
• tcpListener, specify host:port with startup flag, or config file.
• httpListener, specify host:port with startup flag, or config file.

nc -U ./tmp/steward.sock < myMessage.json

[
    {
        "directory":"/var/steward/cli-command/executed-result",
        "fileName": "some.log",
        "toNode": "ship1",
        "method":"REQCliCommand",
        "methodArgs": ["bash","-c","sleep 3 & tree ./"],
        "ACKTimeout":10,
        "retries":3,
        "methodTimeout": 4
    }
]

[
    {
        "directory":"cli-command-executed-result",
        "fileName": "some.log",
        "toNode": "ship1",
        "method":"REQCliCommand",
        "methodArgs": ["bash","-c","sleep 3 & tree ./"],
        "ACKTimeout":10,
        "retries":3,
        "methodTimeout": 4
    },
    {
        "directory":"cli-command-executed-result",
        "fileName": "some.log",
        "toNode": "ship2",
        "method":"REQCliCommand",
        "methodArgs": ["bash","-c","sleep 3 & tree ./"],
        "ACKTimeout":10,
        "retries":3,
        "methodTimeout": 4
    }
]

[
    {
        "directory": "httpget",
        "fileName": "finn.no.html",
        "toNodes": ["central","ship2"],
        "method":"REQHttpGet",
        "methodArgs": ["https://finn.no"],
        "replyMethod":"REQToFile",
        "ACKTimeout":5,
        "retries":3,
        "methodTimeout": 5
    }
]

[
    {
        "directory": "./my/log/files/",
        "fileName": "some.log",
        "toNode": "ship2",
        "method":"REQTailFile",
        "methodArgs": ["./test.log"],
        "ACKTimeout":5,
        "retries":3,
        "methodTimeout": 200
    }
]

[
    {
        "directory":"system",
        "fileName":"system.log",
        "toNodes": ["ship2"],
        "method":"REQCliCommand",
        "methodArgs": ["bash","-c","rm -rf /usr/local/steward/lib/incomingBuffer.db & systemctl restart steward"],
        "replyMethod":"REQToFileAppend",
        "ACKTimeout":30,
        "retries":1,
        "methodTimeout": 30
    }
]

You can save the content to myfile.JSON and append it to the socket file:

• nc -U ./steward.sock < example/toShip1-REQCliCommand.json

<nodename>.<method>.<event>

Example:

ship3.REQCliCommand.EventACK

For ACK messages (using the reply functionality in NATS) we append the .reply to the subject.

ship3.REQCliCommand.EventACK.reply

Nodename: Are the hostname of the device. This do not have to be resolvable via DNS, it is just a unique name for the host to receive the message.

Event: Desribes if we want and Acknowledge or No Acknowledge when the message was delivered :

• EventACK
• EventNACK

Info: The field Event are present in both the Subject structure and the Message structure. This is due to Event being used in both the naming of a subject, and for specifying message type to allow for specific processing of a message.

Method: Are the functionality the message provide. Example could be for example REQCliCommand or REQHttpGet

For Hello Message to a node named "central" of type Event and there is No Ack.

central.REQHello.EventNACK

For CliCommand message to a node named "ship1" of type Event and it wants an Ack.

ship1.REQCliCommand.EventACK

If messages have been sent, and not picked up by a node it might make sense to have some method to clear messages on a node. This could either be done by message ID, and/or time duration.

All code in this repository are to be concidered not-production-ready, and the use is at your own responsibility and risk. The code are the attempt to concretize the idea of a purely async management system where the controlling unit is decoupled from the receiving unit, and that that we know the state of all the receiving units at all times.

Also read the license file for further details.

Expect the main branch to have breaking changes. If stability is needed, use the released packages, and read the release notes where changes will be explained.