9
1
mirror of https://github.com/QuantumPackage/qp2.git synced 2024-12-22 19:43:32 +01:00
qp2/ocaml/Message.ml
2019-03-13 14:08:02 +01:00

568 lines
15 KiB
OCaml

open Sexplib.Std
open Qptypes
(** New job : Request to create a new multi-tasked job *)
module State : sig
type t
val of_string : string -> t
val to_string : t -> string
end = struct
type t = string
let of_string x = x
let to_string x = x
end
module Newjob_msg : sig
type t =
{ state: State.t;
address_tcp: Address.Tcp.t ;
address_inproc: Address.Inproc.t;
}
val create : address_tcp:string -> address_inproc:string -> state:string -> t
val to_string : t -> string
end = struct
type t =
{ state: State.t;
address_tcp: Address.Tcp.t ;
address_inproc: Address.Inproc.t;
}
let create ~address_tcp ~address_inproc ~state =
{ state = State.of_string state;
address_tcp = Address.Tcp.of_string address_tcp ;
address_inproc = Address.Inproc.of_string address_inproc ;
}
let to_string t =
Printf.sprintf "new_job %s %s %s"
( State.to_string t.state )
( Address.Tcp.to_string t.address_tcp )
( Address.Inproc.to_string t.address_inproc )
end
module Endjob_msg : sig
type t =
{ state: State.t;
}
val create : state:string -> t
val to_string : t -> string
end = struct
type t =
{ state: State.t;
}
let create ~state =
{ state = State.of_string state;
}
let to_string t =
Printf.sprintf "end_job %s"
( State.to_string t.state )
end
(** Connect : connect a new client to the task server *)
module Connect_msg : sig
type t = Tcp | Inproc | Ipc
val create : typ:string -> t
val to_string : t -> string
end = struct
type t = Tcp | Inproc | Ipc
let create ~typ =
match typ with
| "tcp" -> Tcp
| "inproc" -> Inproc
| "ipc" -> Ipc
| _ -> assert false
let to_string = function
| Tcp -> "connect tcp"
| Inproc -> "connect inproc"
| Ipc -> "connect ipc"
end
(** ConnectReply : Reply to the connect messsage *)
module ConnectReply_msg : sig
type t =
{ client_id: Id.Client.t ;
state: State.t ;
push_address: Address.t;
}
val create : state:State.t -> client_id:Id.Client.t -> push_address:Address.t -> t
val to_string : t -> string
end = struct
type t =
{ client_id: Id.Client.t ;
state: State.t ;
push_address: Address.t;
}
let create ~state ~client_id ~push_address =
{ client_id ; state ; push_address }
let to_string x =
Printf.sprintf "connect_reply %s %d %s"
(State.to_string x.state)
(Id.Client.to_int x.client_id)
(Address.to_string x.push_address)
end
(** Disconnect : disconnect a client from the task server *)
module Disconnect_msg : sig
type t =
{ client_id: Id.Client.t ;
state: State.t ;
}
val create : state:string -> client_id:int -> t
val to_string : t -> string
end = struct
type t =
{ client_id: Id.Client.t ;
state: State.t ;
}
let create ~state ~client_id =
{ client_id = Id.Client.of_int client_id ; state = State.of_string state }
let to_string x =
Printf.sprintf "disconnect %s %d"
(State.to_string x.state)
(Id.Client.to_int x.client_id)
end
module DisconnectReply_msg : sig
type t =
{
state: State.t ;
}
val create : state:State.t -> t
val to_string : t -> string
end = struct
type t =
{
state: State.t ;
}
let create ~state =
{ state }
let to_string x =
Printf.sprintf "disconnect_reply %s"
(State.to_string x.state)
end
(** AddTask : Add a new task to the queue *)
module AddTask_msg : sig
type t =
{ state: State.t;
tasks: string list;
}
val create : state:string -> tasks:string list -> t
val to_string : t -> string
end = struct
type t =
{ state: State.t;
tasks: string list;
}
let create ~state ~tasks = { state = State.of_string state ; tasks }
let to_string x =
Printf.sprintf "add_task %s %s" (State.to_string x.state) (String.concat "|" x.tasks)
end
(** AddTaskReply : Reply to the AddTask message *)
module AddTaskReply_msg : sig
type t
val create : task_id:Id.Task.t -> t
val to_string : t -> string
end = struct
type t = Id.Task.t
let create ~task_id = task_id
let to_string x =
Printf.sprintf "add_task_reply %d" (Id.Task.to_int x)
end
(** DelTask : Remove a task from the queue *)
module DelTask_msg : sig
type t =
{ state: State.t;
task_ids: Id.Task.t list
}
val create : state:string -> task_ids:int list -> t
val to_string : t -> string
end = struct
type t =
{ state: State.t;
task_ids: Id.Task.t list
}
let create ~state ~task_ids =
{ state = State.of_string state ;
task_ids = List.map Id.Task.of_int task_ids
}
let to_string x =
Printf.sprintf "del_task %s %s"
(State.to_string x.state)
(String.concat "|" @@ List.map Id.Task.to_string x.task_ids)
end
(** DelTaskReply : Reply to the DelTask message *)
module DelTaskReply_msg : sig
type t
val create : task_ids:Id.Task.t list -> more:bool -> t
val to_string : t -> string
end = struct
type t = {
task_ids : Id.Task.t list;
more : bool;
}
let create ~task_ids ~more = { task_ids ; more }
let to_string x =
let more =
if x.more then "more"
else "done"
in
Printf.sprintf "del_task_reply %s %s"
more (String.concat "|" @@ List.map Id.Task.to_string x.task_ids)
end
(** GetTask : get a new task to do *)
module GetTask_msg : sig
type t =
{ client_id: Id.Client.t ;
state: State.t ;
}
val create : state:string -> client_id:int -> t
val to_string : t -> string
end = struct
type t =
{ client_id: Id.Client.t ;
state: State.t ;
}
let create ~state ~client_id =
{ client_id = Id.Client.of_int client_id ; state = State.of_string state }
let to_string x =
Printf.sprintf "get_task %s %d"
(State.to_string x.state)
(Id.Client.to_int x.client_id)
end
(** GetTaskReply : Reply to the GetTask message *)
module GetTaskReply_msg : sig
type t
val create : task_id:Id.Task.t option -> task:string option -> t
val to_string : t -> string
end = struct
type t =
{ task_id: Id.Task.t option ;
task : string option ;
}
let create ~task_id ~task = { task_id ; task }
let to_string x =
match x.task_id, x.task with
| Some task_id, Some task ->
Printf.sprintf "get_task_reply %d %s" (Id.Task.to_int task_id) task
| _ ->
Printf.sprintf "get_task_reply 0"
end
(** GetTasks : get a new task to do *)
module GetTasks_msg : sig
type t =
{ client_id: Id.Client.t ;
state: State.t ;
n_tasks: Strictly_positive_int.t ;
}
val create : state:string -> client_id:int -> n_tasks:int -> t
val to_string : t -> string
end = struct
type t =
{ client_id: Id.Client.t ;
state: State.t ;
n_tasks: Strictly_positive_int.t;
}
let create ~state ~client_id ~n_tasks =
{ client_id = Id.Client.of_int client_id ; state = State.of_string state ;
n_tasks = Strictly_positive_int.of_int n_tasks }
let to_string x =
Printf.sprintf "get_tasks %s %d %d"
(State.to_string x.state)
(Id.Client.to_int x.client_id)
(Strictly_positive_int.to_int x.n_tasks)
end
(** GetTasksReply : Reply to the GetTasks message *)
module GetTasksReply_msg : sig
type t = (Id.Task.t option * string) list
val create : t -> t
val to_string : t -> string
val to_string_list : t -> string list
end = struct
type t = (Id.Task.t option * string) list
let create l = l
let to_string _ =
"get_tasks_reply ok"
let to_string_list x =
"get_tasks_reply ok" :: (
List.map (fun (task_id, task) ->
match task_id with
| Some task_id -> Printf.sprintf "%d %s" (Id.Task.to_int task_id) task
| None -> Printf.sprintf "0 terminate"
) x )
end
(** PutData: put some data in the hash table *)
module PutData_msg : sig
type t =
{ client_id : Id.Client.t ;
state : State.t ;
key : string; }
val create : client_id: int -> state: string -> key: string -> t
val to_string : t -> string
end = struct
type t =
{ client_id : Id.Client.t ;
state : State.t ;
key : string; }
let create ~client_id ~state ~key =
{ client_id = Id.Client.of_int client_id ;
state = State.of_string state;
key ; }
let to_string x =
Printf.sprintf "put_data %s %d %s" (State.to_string x.state)
(Id.Client.to_int x.client_id) x.key
end
(** PutDataReply_msg : Reply to the PutData message *)
module PutDataReply_msg : sig
type t
val create : unit -> t
val to_string : t -> string
end = struct
type t = unit
let create () = ()
let to_string () = "put_data_reply ok"
end
(** GetData: put some data in the hash table *)
module GetData_msg : sig
type t =
{ client_id : Id.Client.t ;
state : State.t ;
key : string; }
val create : client_id: int -> state: string -> key: string -> t
val to_string : t -> string
end = struct
type t =
{ client_id : Id.Client.t ;
state : State.t ;
key : string }
let create ~client_id ~state ~key =
{ client_id = Id.Client.of_int client_id ;
state = State.of_string state;
key }
let to_string x =
Printf.sprintf "get_data %s %d %s" (State.to_string x.state)
(Id.Client.to_int x.client_id) x.key
end
(** GetDataReply_msg : Reply to the GetData message *)
module GetDataReply_msg : sig
type t
val create : value:string -> t
val to_string : t -> string
val to_string_list : t -> string list
end = struct
type t = string
let create ~value = value
let to_string x =
Printf.sprintf "get_data_reply %d %s"
(String.length x) x
let to_string_list x = [
Printf.sprintf "get_data_reply %d"
(String.length x); x ]
end
(** TaskDone : Inform the server that a task is finished *)
module TaskDone_msg : sig
type t =
{ client_id: Id.Client.t ;
state: State.t ;
task_ids: Id.Task.t list ;
}
val create : state:string -> client_id:int -> task_ids:int list -> t
val to_string : t -> string
end = struct
type t =
{ client_id: Id.Client.t ;
state: State.t ;
task_ids: Id.Task.t list;
}
let create ~state ~client_id ~task_ids =
{ client_id = Id.Client.of_int client_id ;
state = State.of_string state ;
task_ids = List.map Id.Task.of_int task_ids;
}
let to_string x =
Printf.sprintf "task_done %s %d %s"
(State.to_string x.state)
(Id.Client.to_int x.client_id)
(String.concat "|" @@ List.map Id.Task.to_string x.task_ids)
end
(** Terminate *)
module Terminate_msg : sig
type t
val create : t
val to_string : t -> string
end = struct
type t = Terminate
let create = Terminate
let to_string x = "terminate"
end
(** Abort *)
module Abort_msg : sig
type t
val create : t
val to_string : t -> string
end = struct
type t = Abort
let create = Abort
let to_string x = "abort"
end
(** OK *)
module Ok_msg : sig
type t
val create : t
val to_string : t -> string
end = struct
type t = Ok
let create = Ok
let to_string x = "ok"
end
(** Error *)
module Error_msg : sig
type t
val create : string -> t
val to_string : t -> string
end = struct
type t = string
let create x = x
let to_string x =
String.concat " " [ "error" ; x ]
end
(** Message *)
type t =
| GetData of GetData_msg.t
| PutData of PutData_msg.t
| GetDataReply of GetDataReply_msg.t
| PutDataReply of PutDataReply_msg.t
| Newjob of Newjob_msg.t
| Endjob of Endjob_msg.t
| Connect of Connect_msg.t
| ConnectReply of ConnectReply_msg.t
| Disconnect of Disconnect_msg.t
| DisconnectReply of DisconnectReply_msg.t
| GetTask of GetTask_msg.t
| GetTasks of GetTasks_msg.t
| GetTaskReply of GetTaskReply_msg.t
| GetTasksReply of GetTasksReply_msg.t
| DelTask of DelTask_msg.t
| DelTaskReply of DelTaskReply_msg.t
| AddTask of AddTask_msg.t
| AddTaskReply of AddTaskReply_msg.t
| TaskDone of TaskDone_msg.t
| Terminate of Terminate_msg.t
| Abort of Abort_msg.t
| Ok of Ok_msg.t
| Error of Error_msg.t
| SetStopped
| SetWaiting
| SetRunning
let of_string s =
let open Message_lexer in
match parse s with
| AddTask_ { state ; tasks } ->
AddTask (AddTask_msg.create ~state ~tasks)
| DelTask_ { state ; task_ids } ->
DelTask (DelTask_msg.create ~state ~task_ids)
| GetTask_ { state ; client_id } ->
GetTask (GetTask_msg.create ~state ~client_id)
| GetTasks_ { state ; client_id ; n_tasks } ->
GetTasks (GetTasks_msg.create ~state ~client_id ~n_tasks)
| TaskDone_ { state ; task_ids ; client_id } ->
TaskDone (TaskDone_msg.create ~state ~client_id ~task_ids)
| Disconnect_ { state ; client_id } ->
Disconnect (Disconnect_msg.create ~state ~client_id)
| Connect_ socket ->
Connect (Connect_msg.create socket)
| NewJob_ { state ; push_address_tcp ; push_address_inproc } ->
Newjob (Newjob_msg.create push_address_tcp push_address_inproc state)
| EndJob_ state ->
Endjob (Endjob_msg.create state)
| GetData_ { state ; client_id ; key } ->
GetData (GetData_msg.create ~client_id ~state ~key)
| PutData_ { state ; client_id ; key } ->
PutData (PutData_msg.create ~client_id ~state ~key)
| Terminate_ -> Terminate (Terminate_msg.create )
| Abort_ -> Abort (Abort_msg.create )
| SetWaiting_ -> SetWaiting
| SetStopped_ -> SetStopped
| SetRunning_ -> SetRunning
| Ok_ -> Ok (Ok_msg.create)
| Error_ m -> Error (Error_msg.create m)
let to_string = function
| GetData x -> GetData_msg.to_string x
| PutData x -> PutData_msg.to_string x
| PutDataReply x -> PutDataReply_msg.to_string x
| GetDataReply x -> GetDataReply_msg.to_string x
| Newjob x -> Newjob_msg.to_string x
| Endjob x -> Endjob_msg.to_string x
| Connect x -> Connect_msg.to_string x
| ConnectReply x -> ConnectReply_msg.to_string x
| Disconnect x -> Disconnect_msg.to_string x
| DisconnectReply x -> DisconnectReply_msg.to_string x
| GetTask x -> GetTask_msg.to_string x
| GetTasks x -> GetTasks_msg.to_string x
| GetTaskReply x -> GetTaskReply_msg.to_string x
| GetTasksReply x -> GetTasksReply_msg.to_string x
| DelTask x -> DelTask_msg.to_string x
| DelTaskReply x -> DelTaskReply_msg.to_string x
| AddTask x -> AddTask_msg.to_string x
| AddTaskReply x -> AddTaskReply_msg.to_string x
| TaskDone x -> TaskDone_msg.to_string x
| Terminate x -> Terminate_msg.to_string x
| Abort x -> Abort_msg.to_string x
| Ok x -> Ok_msg.to_string x
| Error x -> Error_msg.to_string x
| SetStopped -> "set_stopped"
| SetRunning -> "set_running"
| SetWaiting -> "set_waiting"
let to_string_list = function
| GetDataReply x -> GetDataReply_msg.to_string_list x
| GetTasksReply x -> GetTasksReply_msg.to_string_list x
| _ -> assert false