module Netplex_cenv:sig..end
Container environment
Some helper functions to explore the environment from a container.
Most of the following functions must be called from a container context,
i.e. from a process or thread that acts as container, otherwise
the exception Not_in_container_thread is raised. There are also some
functions that can be called from controller context for convenience.
Thread safety: Full. The functions in this module can be called from any thread.
exception Not_in_container_thread
Raised when the caller's thread is not a container thread
Logging functions can be invoked from both container and controller contexts.
val log : Netplex_types.level -> string -> unitWrites a log message
val logf : Netplex_types.level -> ('a, unit, string, unit) Stdlib.format4 -> 'aWrites a log message like printf
val report_connection_string : Unix.file_descr -> string -> stringOutput a log line for the netplex.connections admin message.
The string is the detail to report.
Timer functions can only be invoked from container contexts.
More documentation is available in Netplex_advanced.timers.
type
A timer
val create_timer : (timer -> bool) -> float -> timercreate_timer f tmo: Creates a timer with timeout value tmo:
In tmo seconds f is called, and if this function returns true,
the timer remains active, and another round of timing is arranged.
If the functions returns false or raises an exception, the timer
is stopped.
Timers are also stopped on container shutdown.
Timers are attached to the container event system, and run only
if this event system runs. Also note that f is always called from
the main thread of the container.
val cancel_timer : timer -> unitCancels the timer: The callback function is not called any longer
val cancel_all_timers : unit -> unitCancels all active timers
val timer_id : timer -> intReturns an ID, e.g. useful for debugging
Container variables exist once per container. Primary access is
done via the var and set_var methods of the container class.
The following functions are often more convenient, however.
These functions can only be invoked from container contexts.
More documentation: Netplex_advanced.contvars
exception Container_variable_not_found of string
The variable does not exist
exception Container_variable_type_mismatch of string
The (dynamically typed) variable has the wrong type
val int_var : string -> int
val string_var : string -> string
val float_var : string -> float
val bool_var : string -> boolAccess a variable with simple type. May raise
Container_variable_not_found or Container_variable_type_mismatch
val set_int_var : string -> int -> unit
val set_string_var : string -> string -> unit
val set_float_var : string -> float -> unit
val set_bool_var : string -> bool -> unitSet a variable with simple type
val make_var_type : ('a -> Netplex_types.encap) ->
(Netplex_types.encap -> 'a) -> (string -> 'a) * (string -> 'a -> unit)Create get and set functions for any (monomorphic) type. For example,
to create such function for a type foo, do
module E = Netplex_encap.Make_encap(struct type t = foo end)
let (get, set) =
make_var_type E.wrap E.unwrap
Read on for using functors to create get and set.
module type TYPE =sig..end
Just a (monomorphic) type t
module type VAR_TYPE =sig..end
A (monomorphic) type t with two functions get and set
accessing the container variables
module Make_var_type: Creates get and set like make_var_type.
System control functions can be invoked from both container and controller contexts.
val system_shutdown : unit -> unitInitiates a system shutdown (like the shutdown method of the
controller)
val system_restart : unit -> unitInitiates a system restart (like the restart method of the
controller)
These functions can only be invoked from container contexts,
except send_message.
val send_message : string -> string -> string array -> unitsend_message service_pattern msg_name msg_arguments: Sends
a message to all services and message receivers matching
service_pattern. The pattern may include the wildcard *.
See the Netplex_types.controller.send_message method for
the notification guarantees.
This function can be invoked from both container and controller contexts.
val lookup : string -> string -> string optionlookup service_name protocol_name tries to find a Unix domain
socket for the service and returns it.
On Win32, the returned path refers to a file describing the
IPC mechanism. Use Netplex_sockserv.any_file_client_connector
to convert the path into an RPC connector.
val lookup_container_sockets : string -> string -> string arraylookup_container_sockets service_name protocol_name: returns
the Unix Domain paths of all container sockets for this service and
protocol. These are the sockets declared with address type
"container" in the config file.
On Win32, the returned paths refer to files describing the
IPC mechanism. Use Netplex_sockserv.any_file_client_connector
to convert the paths into RPC connectors.
Container sockets are explained here:
Netplex_advanced.contsocks
val self_cont : unit -> Netplex_types.containerReturns the container running the code of the caller,
or raise Not_in_container_thread if called from outside a
container context.
val self_obj : unit ->
[ `Container of Netplex_types.container
| `Controller of Netplex_types.controller ]Returns the container or the controller running the code of the
caller, or raise Not_found if called from
neither a container not a controller thread.
val current_sys_id : unit -> [ `Process of int | `Thread of int ]Returns the system-dependent thread identifier of the caller (which must be in container or controller context)
val admin_connector : unit -> Rpc_client.mode2Determines the admin socket of the controller, and returns an RPC client connector suitable for connecting with the admin interface of the controller. For instance to initiate a system shutdown from the context of a container:
let conn = Netplex_cenv.admin_connector() in
let client = Netplex_ctrl_clnt.Admin.V2.create_client2 conn in
Netplex_ctrl_clnt.Admin.V2.system_shutdown client ();
Rpc_client.shut_down client
Note that the admin interface is going to evolve, and it is advisable to avoid admin calls whenever possible.
This function must be called from container context.
val run_in_controller_context : Netplex_types.controller -> (unit -> unit) -> unitrun_in_controller_context ctrl f: Arranges that f() is executed
in the context of the controller. This is only possible for
multi-threading but not for multi-processing style! For
programs using multi-processing, see Netplex_cenv.Make_lever
for a workaround.
This function can be called from any thread. The function f is
executed by pushing it onto the event queue, and calling it when
the pushed event is reached. This is usually a safe point for
many kinds of operations, but if controller methods are invoked
the details are left unspecified.
For example, this allows it to start helper threads via
Netplex_kit.add_helper_service at any time.
An example can be found here: Netplex_advanced.levers
val run_in_container_context : Netplex_types.container -> (unit -> unit) -> unitrun_in_container_context cont f: Arranges that f() is executed
in the context of the container cont. This is only possible for
multi-threading but not for multi-processing style!
This function can be called from any thread. The function f is
executed by pushing it onto the event queue, and calling it when
the pushed event is reached. This is usually a safe point for
many kinds of operations, but if container method are invoked
the details are left unspecified.
There is no guarantee that f is called anytime soon - if the
container is busy with something else than with the event queue
the execution will be blocked until these other activities are
over.
Levers are a way to send messages to the controller, and to effectively run functions there that were previously registered.
More documentation: Netplex_advanced.levers
module type FUN_TYPE =sig..end
Abstraction for function types s->t
module type LEVER =sig..end
module Make_lever: Creates a LEVER module from a function type as specified in
FUN_TYPE
val pmanage : unit -> Netsys_pmanage.pmanageAccess the manager for persistent kernel objects with limited lifetime. Among these objects there are shared memory objects, and named semaphores. These objects can usually be deleted when the program finishes (or crashes), but this is not done automatically because of kernel persistency.
See Netplex_admin.unlink for more information.
module Debug:sig..end
