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Netplex_intro



Introduction into Netplex

Contents

Netplex is a generic (stream) server framework. This means, Netplex does a lot of things for a network service that are always the same, regardless of the kind of service:

  • Creation of server sockets
  • Accepting new network connections
  • Organizing multiple threads of execution - either by multiple processes, multiple POSIX threads, or multiplexing
  • Workload management
  • Writing log files
  • Broadcasting messages to all server components
  • Support for a configuration file format
Netplex currently only supports stream sockets (TCP or Unix Domain).

Ocamlnet already includes Netplex adapters for Nethttpd (the HTTP daemon), and RPC servers. It is likely that more adapters for other network protocols will follow.

Netplex can bundle several network services into a single system of components. For example, you could have an RPC service that can be managed over a web interface provided by Nethttpd. Actually, Netplex focuses on such systems of interconnected components. RPC plays a special role in such systems because this is the network protocol the components use to talk to each other. It is also internally used by Netplex for its administrative tasks.

Terminology

In the Netplex world the following words are preferred to refer to the parts of a Netplex system:

  • The Netplex controller is the core component of Netplex. The controller opens sockets and manages how new connections are accepted. For every socket, the controller determines which Netplex container will accept the next connection that is tried to be established. Furthermore, the controller manages the startup and shutdown of the Netplex system.
  • The Netplex services are the user-defined components of a Netplex system. Every service runs in its own process(es) (if multi-processing is selected) or in its own thread(s) (for POSIX multi-threading). It is up to the user to define what a service is.
  • The Netplex protocols are the languages spoken by the services. A protocol is bound to one or more sockets. This means that a service is implemented by a number of protocols.
  • The Netplex containers are processes or threads that may execute a certain service. Every container is bound to a specific service. It is possible that only one container is used for a particular service, but one can also configure that containers are dynamically started and stopped as the workload of the system changes.

Example - A Simple Web Server

In order to create a web server, this main program and the following configuration file are sufficient. (You find an extended example in the "examples/nethttpd" directory of the Ocamlnet tarball.)

let main() =
  (* Create a parser for the standard Netplex command-line arguments: *)
  let (opt_list, cmdline_cfg) = Netplex_main.args() in

  (* Parse the command-line arguments: *)
  Arg.parse
    opt_list
    (fun s -> raise (Arg.Bad ("Don't know what to do with: " ^ s)))
    "usage: netplex [options]";

  (* Select multi-processing: *)
  let parallelizer = Netplex_mp.mp() in  

  (* Start the Netplex system: *)
  Netplex_main.startup
    parallelizer
    Netplex_log.logger_factories
    Netplex_workload.workload_manager_factories
    [ Nethttpd_plex.nethttpd_factory() ]
    cmdline_cfg
;;

Sys.set_signal Sys.sigpipe Sys.Signal_ignore;
main();;

The configuration file:

netplex {
  controller {
    max_level = "debug";    (* Log level *)
    logging {
      type = "stderr";      (* Log to stderr *)
    }
  };
  service {
    name = "My HTTP file service";
    protocol {
      (* This section creates the socket *)
      name = "http";
      address {
        type = "internet";
        bind = "0.0.0.0:80";  (* Port 80 on all interfaces *)
      };
    };
    processor {
      (* This section specifies how to process data of the socket *)
      type = "nethttpd";
      host {
        (* Think of Apache's "virtual hosts" *)
        pref_name = "localhost";
        pref_port = 80;
        names = "*:0";   (* Which requests are matched here: all *)
        uri {
          path = "/";
          service {
            type = "file";
            docroot = "/usr";
            media_types_file = "/etc/mime.types";
            enable_listings = true;
          }
        };
      };
    };
    workload_manager {
      type = "dynamic";
      max_jobs_per_thread = 1;  (* Everything else is senseless *)
      min_free_jobs_capacity = 1;
      max_free_jobs_capacity = 1;
      max_threads = 20;
    };
  }
}

As you can see, the main program is extremely simple. Netplex includes support for command-line parsing, and the rest deals with the question which Netplex modules are made accessible for the configuration file.

Here, we have:

The configuration file consists of nested sections whose extents are denoted by curly braces. The sections are partly defined by Netplex itself (e.g. the controller section and the workload manager section), and partly by the service provider (almost everything inside "processor"). That means that the components of a Netplex system pick "their" part from the configuration file, and that, depending on which components are linked into this system, the config files may look very different.

Here, we have:

  • The controller section sets the log level and the logging method. The latter is done by naming one of the logger factories as logging type. If the factory needs more parameters to create the logger, these can be set inside the logging section.
  • For every service there is a name (can be freely chosen), one or several protocols, a processor, and a workload_manager. The protocol section declare which protocols are available and to which sockets they are bound. Here, the "http" protocol (name can again be freely chosen) is reachable over TCP port 80 on all network interfaces. By having multiple address sections, one can bind the same protocol to multiple sockets.
  • The processor section specifies the type and optionally a lot of parameters (which may be structured into several sections). By setting type to "nethttpd" we select the Nethttpd_plex.nethttpd_factory to create the processor (because "nethttpd" is the default name for this factory). This factory now interprets the other parameters of the processor section. Here, a static HTTP server is defined that uses /usr as document root.
  • Finally, the workload_manager section says how to deal with parallely arriving requests. The type selects the dynamic workload manager which is configured by the other parameters. Roughly said, one container (i.e. process) is created in advance for the next network connection ("pre-fork"), and the upper limit of containers is 20.

Running This Example

If you start this program without any arguments, it will immediately fail because it wants to open /etc/netplex.conf - this is the default name for the configuration file. Use -conf to pass the real name of the above file.

Netplex creates a directory for its internal processing, and this is by default /tmp/.netplex. You can change this directory by setting the socket_directory parameter in the controller section. In this directory, you can find:

  • A directory netplex.controller which refers to the controller component.
  • For every service another directory containing local run-time files. The directory has the same name as the service.
Netplex comes with a generic administration command called netplex-admin. You can use it to send control messages to Netplex systems. For example,

 netplex-admin -list 

outputs the list of services. A more detailed list can be obtained with

 netplex-admin -containers 

The command

 netplex-admin -shutdown 

shuts the system (gracefully) down. It is also possible to broadcast messages to all components:

 netplex-admin name arg1 arg2 ... 

It is up to the components to interpret these messages.

The Process Model

Netplex uses a generalized pre-fork process model. Let me explain this model a bit, as it is important to know it in order to understand Netplex fully.

The most trivial form of a multi-process Unix server is the post-fork model. Although it is not used by Netplex, it is the model explained in many books, and it is what many people think a Unix server has to look like. Actually, the post-fork model has lots of limitations, and is not suited for high-performance servers.

In the post-fork model, the master process accepts new network connections in an endless loop, and whenever a new connection is established, a sub process (container process) is spawned that processes the network traffic. There is a serious logical limitation, and a performance limitation:

  • In the post-fork model every container process can only deal with one connection at a time. The reason is that at the time of spawning the container there is only one connection, and one cannot assign the container another connection later.
  • The post-fork model spawns the container processes at a bad moment. Spawning is a very expensive operation, and doing it just after connection establishment is bad because this means that the client has to wait longer for a response. Furthermore, spawning for every connection wastes system resources.
In the pre-fork model, these disadvantages can be avoided. Here, one or several processes are spawned in advance. Furthermore, these processes cannot only manage one connection but any number, and this can happen sequentially (one connection is processed after the other) or in parallel (using multiplexing).

This is achieved by letting the containers themselves accept the new connections instead of the master process. In the Unix process model it is possible that server sockets are shared by several processes, and every container is allowed to accept the next connection. However, the containers should cooperate, and avoid that several containers call Unix.accept at the same time (as this leads to performance problems when a container must be able to watch several ports for new connections - a problem we do not discuss here). There are many ways to organize such cooperation, and for simplicity, Netplex implements this by exchanging RPC messages with the master process, the controller. Effectively, the controller has the task of scheduling which of the containers accepts the next arriving network connection.

What actually happens is the following. We assume here that we have a number of idle container processes that could accept the next connection.

  • The controller selects one of the containers as the one that will get the next connection.
  • The selected container watches the ports for incoming connections. Note that this is done in a Unixqueue, so that if there are already connections to be processed, this can be done in a multiplexed way in parallel with watching for new connections.
  • When the next connection arrives, the container accepts it, and invokes the service component to process it.
  • Immediately after connection establishment, the container tells the controller what happened, so the controller can watch out for another container to take over the role of accepting further connections.
  • When the connection is fully processed, another control message is sent to the controller because the controller must know at all times how many connections are being processed by which containers. This is simply an important load parameter.
The details of this mechanism are not very interesting for using it. However, one must know that

  • connections are accepted by the sub processes and not by the master process,
  • the sub processes can accept as many connections as they want to, either one after the other, or even several at once,
  • the controller schedules tasks and determines which connection is accepted by which container,
  • there is a certain protocol between controller and container, and although the details are hidden from the user, this has consequences for the user interface. In particular, the reason why the when_done function must be called upon connection termination is that a control message must be sent to the controller.
Another implication of the pre-fork model is that one needs workload management. As processes are created in advance, the question arises how many are created, and when the processes are terminated to free resources. Netplex comes with two workload managers: One manager simply creates a fixed number of processes which are never terminated, and the other manager tries to adapt the number to the load by dynamically starting and stopping processes. This is discussed below in detail.

Creating Sockets

The server sockets are always created by the controller at program startup. This is a strict requirement because only this ensures that the created container processes share the same sockets.

The sockets are descibed in the protocol section of the configuration file. For an Internet socket this section looks like

    protocol {
      name = "<name>";
      address {
        type = "internet";
        bind = "<address>:<port>";
      };
    };

The <name> is only important when there are several protocols in order to distinguish between them. The <address> can be:

  • An IP address of a network interface to bind the socket to this particular interface. Both IPv4 and IPv6 addresses are supported. IPv4 addresses are simply given in "dotted quad" notation (e.g. 192.168.76.23), and IPv6 addresses must be enclosed in brackets (e.g. [fe80::250:56ff:fec0:1]).
  • The special IPv4 address 0.0.0.0 to bind the socket to all IPv4 network interfaces, or the special IPv6 address [::0] to bind it to all IPv6 network interfaces.
  • A resolvable host name which is the same as using the corresponding IP address.
The <port> must be the port number or 0 to use an anonymous port.

For a local (Unix domain) socket, the protocol section looks like

    protocol {
      name = "<name>";
      address {
        type = "local";
        path = "<path>";
      };
    };

where the <path> is the filename of the socket.

One can have several address sections to create several sockets for the same protocol.

Services And Processors

A Netplex system consists of exactly the services that are enumerated in the config file. This means it is not sufficient to build in support for a service into the program, one must also activate it in the config file. This gives the end user of the program a lot of flexibility when running the system: By simply changing the config file one can enable or disable services. It is also possible to run the same program binary several times with different config files.

The services are implemented by processors, which are user-defined objects that handle the network connection after it is accepted by the component. The processor section of the service selects the processor by name, and optionally passes configuration parameters to it:

    processor {
        type = "<name>";
        ... further parameters allowed ...
    }

The mentioned name of the processor type is used to find the so-called factory for the processor (an object with a create_processor method). All factories must be available at Netplex startup so the library knows which factories exist when the config file is interpreted (the factories are an argument of Netplex_main.startup).

Processor objects are somewhat strange in so far as they exist both in the controller and in the container processes. In particular, these objects are created by the controller, and they are duplicated once for all container processes when these are actually created.

The processor objects (of type Netplex_types.processor) consist of a number of methods. We have already seen one of them, process, which is called in the container process when a new connection is accepted. The other methods are called at other points of interest:

Methods called on the controller instance of the processor

  • post_add_hook is immediately called after the addtion of the service to the controller.
  • post_rm_hook is immediately called after the removal of the service from the controller.
  • pre_start_hook is called just before the next container process is spawned.
  • post_finish_hook is called after termination of the container.
Methods called on the container instance of the processor

  • post_start_hook is called just after the container process has been created, but now for the copy of the processor object that lives in the container process. This is a very useful hook method, because one can initialize the container process (e.g. prepare database accesses etc.).
  • pre_finish_hook is called just before the container process will (regularly) terminated.
  • receive_message is called when a message from another container arrives.
  • receive_admin_message is called when a message from the administrator arrives.
  • shutdown is called when the shutdown notification arrives. The shutdown will lead to the termination of the process when all network connections managed by Unixqueue are finished. This method must terminate such connections if they have been created in addition to those Netplex manages. The shutdown notification is generated whenever a container needs to be stopped, for example when it has been idle for too long and is probably not needed right now (workload-induced shutdown), or when the whole system is stopped (administrative shutdown).
  • system_shutdown is another shutdown-related notification. It is only emitted if the whole Netplex system is going to be stopped. In this case, all containers first receive the system_shutdown notifications, so they can prepare the real shutdown that will happen soon. At the time the system_shutdown is emitted, the whole system is still up and running, and so every action is still possible. Only after all containers have finished their system_shutdown callbacks, the real shutdown begins, i.e. shutdown notifications are sent out.
  • global_exception_handler is called for exceptions falling through to the container, and is the last chance to catch them.
Because of the instances in the controller and the containers it is usually a bad idea to store state in the processor object.

If multi-threading is used instead of multi-processing, there is only one instance of the processor that is used in the controller and all containers.

Defining Custom Processors

Using predefined processor factories like Nethttpd_plex.nethttpd_factory is very easy. Fortunately, it is not very complicated to define a custom adapter that makes an arbitrary network service available as Netplex processor.

In principle, you must define a class for the type Netplex_types.processor and the corresponding factory implementing the type Netplex_types.processor_factory. To do the first, simply inherit from Netplex_kit.processor_base and override the methods that should do something instead of nothing. For example, to define a service that outputs the line "Hello world" on the TCP connection, define:

 
class hello_world_processor : processor =
  let empty_hooks = new Netplex_kit.empty_processor_hooks() in
object(self)
  inherit Netplex_kit.processor_base empty_hooks

  method process ~when_done container fd proto_name =
    Unix.clear_nonblock fd;
    let ch = Unix.out_channel_of_descr fd in
    output_string ch "Hello world\n";
    close_out ch;
    when_done()

  method supported_ptypes = [ `Multi_processing; `Multi_threading ]
end

The method process is called whenever a new connection is made. The container is the object representing the container where the execution happens (process is always called from the container). In fd the file descriptor is passed that is the (already accepted) connection. In proto_name the protocol name is passed - here it is unused, but it is possible to process the connection in a way that depends on the name of the protocol.

Note that the file descriptors created by Netplex are in non-blocking mode. It is, however, possible to switch to blocking mode when this is more appropriate (Unix.clear_nonblock).

The argument when_done is very important. It must be called by process! For a synchronous processor like this one it is simply called before process returns to the caller.

For an asynchronous processor (i.e. a processor that handles several connections in parallel in the same process/thread), when_done must be called when the connection is fully processed. This may be at any time in the future.

The class hello_world_processor can now be turned into a factory:

class hello_world_factory : processor_factory =
object(self) 
  method name = "hello_world"
  method create_processor ctrl_cfg cfg_file cfg_addr =
    new hello_world_processor
end

As you see, one can simply choose a name. This is the type of the processor section in the configuration file, i.e. you need

  ...
  service {
    name = "hello world sample";
    ...
    processor {
      type = "hello_world"
    };
    ...
  }
  ...

to activate this factory for a certain service definition. Of course, the instantiated hello_world_factory must also be passed to Netplex_main.startup in order to be available at runtime.

The create_processor method simply creates an object of your class. The argument ctrl_cfg is the configuration of the controller (e.g. you find there the name of the socket directory). In cfg_file the object is passed that accesses the configuration file as tree of parameters. In cfg_addr the address of the processor section is made available, so you can look for additional configuration parameters.

You may wonder why it is necessary to first create empty_hooks. The hook methods are often overridden by the user of processor classes. In order to simplify this, it is common to allow the user to pass a hook object to the processor object:

 
class hello_world_processor hooks : processor =
object(self)
  inherit Netplex_kit.processor_base hooks

  method process ~when_done container fd proto_name = ...
  method supported_ptypes = ...
end

Now, the user can simply define hooks as in

class my_hooks =
object(self)
  inherit Netplex_kit.empty_processor_hooks()

  method post_start_hook container = ...
end

and pass such a hook object into the factory.

Workload Management

Workload managers decide when to start new containers and when to stop useless ones. The simplest manager is created by the Netplex_workload.constant_workload_manager_factory. The user simply defines how many containers are to be started. In the config file this is written as

    workload_manager {
        type = "constant";
        threads = <n>;
    }

where <n> is the number of containers > 0. Often this manager is used to achieve n=1, i.e. to have exactly one container. An example would be a stateful RPC server where it is important that all network connections are handled by the same process. (N.B. n=1 for RPC servers does not enforce that the connections are serialized because Ocamlnet RPC servers can handle multiple connections in parallel, but of course it is enforced that the remote procedures are invoked in a strictly sequential way.)

If n>1, it is tried to achieve that all containers get approximately the same load.

If processes die unexpectedly, the constant workload manager starts new components until the configured number of processes is again reached.

The dynamic workload manager (created by Netplex_workload.dynamic_workload_manager_factory) is able to start and stop containers dynamically. There are a few parameters that control the manager. A "thread" is here another word for a started container. A "job" is an established network connection. Using this terms, the task of the workload manager is to decide how many threads are needed to do a varying number of jobs. The parameters now set how many jobs every thread may execute, and how quickly new threads are created or destroyed to adapt the available thread capacity to the current job load.

If the service processor can only accept one network connection after the other (like Nethttpd_plex), the only reasonable setting is that there is at most one job per thread. If one configures a higher number in this case, unaccepted network connections will queue up resulting in poor performance.

If the service processor can handle several connections in parallel it is possible to allow more than one job per thread. There is no general rule how many jobs per thread are reasonable, one has to experiment to find it out. In this mode of having more than one job per thread, Netplex even allows two service qualities, "normal" and "overload". If possible, Netplex tries to achieve that all containers deliver normal quality, but if the load goes beyond that, it is allowed that containers accept more connections than that. This is called an overload situation. Often it is better to allow overload than to refuse new connections.

The dynamic workload manager is enabled by the section

    workload_manager {
        type = "dynamic";
	... parameters, see below ...
    }

The required parameters are:

  • max_threads: How many containers can be created at maximum for this service.
  • max_jobs_per_thread: How many jobs every container can execute at maximum. The upper limit for the number of jobs is thus max_threads * max_jobs_per_thread.
  • min_free_job_capacity: This parameter controls how quickly new containers are started when the load goes up. It is tried to ensure that there are as many containers so this number of jobs can be additionally performed. This parameter must be at least 1.
  • max_free_job_capacity: This parameter controls how quickly containers are stopped when the load goes down. It is tried to ensure that unused containers are stopped so the capacity for additional jobs is not higher than this parameter. This parameter must be greater or equal than min_free_job_capacity.
In order to configure the overload mode:

  • recommended_jobs_per_thread: The number of jobs a container can do with normal service quality. A higher number is considered as overload.
The effect of this parameter is that it is avoided that a container gets more jobs than recommended as long as possible.

Another parameter is:

  • inactivity_timeout: If a container idles longer than this number of seconds and is not needed to ensure min_free_job_capacity it is shut down. Defaults to 15 seconds.

Messaging

There are two kinds of messages one can send to Netplex containers: normal messages come from another Netplex container, and admin messages are sent using the netplex-admin command.

Messages have a name and a (possibly empty) list of string parameters. They can be sent to an individual receiver container, or to a number of containers, even to all. The sender does not get an acknowledgment when the messages are delivered.

Messages can e.g. be used

  • to signal that internal state is output to log files in order to debug a special situation
  • to enable or disable special features of the running system
  • to flush caches
and for other comparably simple communication needs.

In order to receive a normal message, one must define the receive_message method in the processor object, and to receive an admin message, one must define the receive_admin_message method.

A normal message is sent by the container method send_message. The receiver is identified by the service name, i.e. all containers with the passed name get the message. The name may even contain the wildcard * to select the containers by a name pattern.

An admin message is sent using the netplex-admin command.

There are a few predefined messages understood by all containers:

  • The admin message netplex.threadlist outputs to the log file which process executes which service, and how loaded the processes are.
  • The admin message netplex.connections outputs a line for every connection managed by Netplex, sometimes with details of the protocol interpreter
  • The admin message netplex.logger.set_max_level changes the maximum log level for the container.
  • The admin message netplex.debug.enable enables debug messages. The argument is the debug target as known by Netlog.Debug.
  • The admin message netplex.fd_table outputs the file descriptor table (debug)
In general, messages starting with "netplex." are reserved for Netplex itself.

Logging

Log messages can be written in the containers. The messages are first sent to the controller where they are written to stderr, to files, or to any object of the type Netplex_types.logger. That the messages are first sent to the controller has a lot of advantages: The messages are implicitly serialized, no locking is needed, and it is easy to support log file rotation.

In order to write a log message, one needs the container object. The module Netplex_cenv always knows the container object of the caller, to get it:

let cont = Netplex_cenv.self_cont()

If you call self_conf outside a container, the exception Netplex_cenv.Not_in_container_thread is raised. This is e.g. the case if you call it from the pre_start or post_finish callbacks.

Logging is now done by

let cont = Netplex_cenv.self_cont() in
cont # log level message

where level is one of `Debug, `Info, `Notice, `Warning, `Err, `Crit, `Alert, `Emerg, and message is a string. The levels are the same as for syslog.

You can also call Netplex_cenv.log and Netplex_cenv.logf, which simply use self_cont to get the container and call its log method to write the message.

The config file controls what to do with the log messages. The easiest way is to send all messages to stderr:

  controller {
    max_level = "debug";    (* Log level *)
    logging {
      type = "stderr";      (* Log to stderr *)
    }
  };

Further types of logging are documented in the Netplex_log module.

Debug logging

There are various built-in debug logging streams:

  • Netplex_container.Debug.enable: Logs the perspective of the container. Logged events are e.g. when connections are accepted, and when user-defined hook functions are invoked. These messages are quite interesting for debugging user programs.
  • Netplex_controller.Debug.enable: Logs the perspective of the controller. The events are e.g. state changes, when containers are started, and scheduling decisions. This is less interesting to users, but might nevertheless worth activating it.
  • Netplex_workload.Debug.enable: Outputs messages from the workload manager.
For these messages, the mechanism of Netlog.Debug is used - which has the advantage that messages can also be generated when no Netplex logger is available.

Netplex RPC systems

A short description how to build systems of RPC services is given in Netplex RPC systems.

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