module Netcamlbox:sig
..end
A camlbox is owned by the single receiving process. Only this process (or a fork) can look for new messages and can read them. There can be any number of sending processes, i.e. we have a n:1 message passing scenario.
The receiver process creates the camlbox, and is seen as the owner. The receiver is accountible for deleting the camlbox when it is no longer needed.
The sender(s) can send messages to any existing camlbox. There is no notification whether the messages are actually read. The sender, however, blocks when the destination camlbox is full, and will only proceed when the receiver makes room for new messages. If there is space in the camlbox the sender does not need to synchronize with the receiver, i.e. it is possible to put a message into the box when the receiver is busy with something else (asynchronous send operation).
Camlboxes have a fixed capacity of messages, and the message slots have a fixed maximum length. The messages can have any type with only a few restrictions (e.g. no functions and no custom blocks). There is no check whether the sender and the receiver assume the same type of the messages. This is left to the user. Breaking this assumption will lead to unpredictable effects, including program crashes. It is strongly advised to only communicate between processes that run the same executable.
The user is also responsible for keeping only references to
existing messages. It is possible to get a value pointer
for a certain message via camlbox_get
and then to delete the message.
The user must no longer access the value - once the value is deleted
it may be overwritten, and the program may crash. Another danger
is that message values are modified so that pointers to heap
values are put into the message. This may lead to delayed crashes
when the heap value is moved to a different location or is even
deleted by the garbage collector. There is nothing the camlbox
implementation can do about that. If this is a problem, it is
advised to use camlbox_get_copy
instead which is not dangerous
in this respect.
On the system level, camlboxes are stored in POSIX shared memory objects. These objects have kernel persistence and continue to live after the process creating the camlbox has terminated without unlinking the box.
This module requires Ocaml 3.11 or newer. The system must support
POSIX shared memory and POSIX semaphores. Camlboxes may be used
in multi-threaded programs as long as the values camlbox
and
camlbox_sender
are not used by several threads at the same time.
Examples. There a few examples in the distribution tarball (examples/camlbox).
Multi-core: Camlboxes can be used to gain speed-ups on multi-cores. See examples/camlbox/README in the distribution tarball for an example how to accomplish this.
Integration into event-based programs: See the section
below, Integration into event-based programs.
typecamlbox_address =
string
type 'a
camlbox
camlbox
may receive messages of type 'a
type 'a
camlbox_sender
'a
to a camlboxexception Empty
exception Message_too_big
val create_camlbox : camlbox_address -> int -> int -> 'a camlbox
create_camlbox addr n size
: Creates a new camlbox for up to
n
messages of size
bytes. The messages are numbered from
0 to n-1
. The camlbox is only meaningful for the creating
process, and must not be directly accessed by other processes.
Other processes can only send using a camlbox_sender
.
It is an error if the camlbox already exists.
It is suggested that the result of create_camlbox
is immediately
coerced to the right type t
, e.g.
let box = (create_camlbox addr n size : t camlbox)
as this ensures type safety for all following operations.
Note that camlboxes have kernel persistence! They are not
automatically deleted when the process finishes. Call unlink_camlbox
to delete camlboxes.
val unlink_camlbox : camlbox_address -> unit
camlbox_address
as input will not find the box anymore. The
box, however, continues to exist until the receiver and the senders
are done with it.val format_camlbox : camlbox_address ->
Unix.file_descr -> int -> int -> 'a camlbox
format_camlbox addr fd n size
: The file fd
is mapped into memory,
and formatted as camlbox.
In Ocamlnet-3.6, the function got the extra camlbox_address
argument.
val camlbox_addr : 'a camlbox -> camlbox_address
val camlbox_saddr : 'a camlbox_sender -> camlbox_address
val camlbox_fd : camlbox_address -> Unix.file_descr
val camlbox_capacity : camlbox_address -> int
n
val camlbox_bcapacity : 'a camlbox -> int
val camlbox_scapacity : 'a camlbox_sender -> int
val camlbox_msg_size : camlbox_address -> int
val camlbox_bmsg_size : 'a camlbox -> int
val camlbox_smsg_size : 'a camlbox_sender -> int
val camlbox_messages : camlbox_address -> int
val camlbox_bmessages : 'a camlbox -> int
val camlbox_smessages : 'a camlbox_sender -> int
val camlbox_get : 'a camlbox -> int -> 'a
camlbox_get box k
: Returns message number k
from box
.
The returned value lives in the camlbox, and using it is only
safe as long as the camlbox exists and the message is not
deleted.
If there is no message at k
the exception Empty
will be
raised.
The result value must have the same type as the sent value.
This is not checked, however. Violating this rule is likely
to crash the program.
val camlbox_get_copy : 'a camlbox -> int -> 'a
camlbox_get box k
: Returns a deep copy of message number k
from box
.
This is safer than camlbox_get
, because the returned value remains
valid when the message is deleted from the box.
If there is no message at k
the exception Empty
will be
raised.
The result value must have the same type as the sent value.
This is not checked, however. Violating this rule is likely
to crash the program.
val camlbox_delete : 'a camlbox -> int -> unit
camlbox_delete box k
: Deletes the message number k
from box
.
Any value obtained via camlbox_get
for a message or a part
of a message becomes invalid and must not be used anymore.
There is no way to check this - violating this rule is likely
to crash the program. (In doubt use camlbox_get_copy
instead
which cannot interfer with camlbox_delete
.)
If there is no message at k
the exception Empty
will be
raised.
val camlbox_wait : 'a camlbox -> int list
camlbox_wait
. The
order of the messages is not specified.
Only one thread at a time must wait for new messages.
It is allowed that this function returns the empty list.
val camlbox_cancel_wait : 'a camlbox -> unit
camlbox_wait
operation called by a different threadval camlbox_sender : camlbox_address -> 'a camlbox_sender
It is suggested that the result of camlbox_sender
is immediately
coerced to the right type t
, e.g.
let box = (camlbox_sender addr : t camlbox_sender)
as this ensures type safety for all following operations.val camlbox_sender_of_fd : camlbox_address -> Unix.file_descr -> 'a camlbox_sender
camlbox_fd
.
Ocamlnet-3.6: new arg camlbox_address
val camlbox_send : ?prefer:int ->
?slot:int Pervasives.ref -> 'a camlbox_sender -> 'a -> unit
char
,
bool
, int
, nor a variant type), and a number of restrictions apply:Message_too_big
is raised.int32
, int64
, and nativeint
.camlbox_get
because atoms are duplicated,
and no longer unique. For example, a test if array=[||] then...
is likely not to work. Use if Array.length array = 0 then...
,
or use camlbox_get_copy
for extraction.This function blocks until the receiving camlbox has free space.
Several threads may try to send messages at the same time.
prefer
: suggests a slot for sending
slot
: the actual slot number is stored here
val camlbox_wake : 'a camlbox_sender -> unit
camlbox_wait
will return the empty list.
This function is non-blocking.
The functions camlbox_wait
and camlbox_send
may both block the
execution of the program when no message has arrived, and no space
is available, respectively. This is a challenge for event-based
programs where all waiting is bound to events on file descriptors.
Generally, Camlboxes use semaphores for speed. The results are good, often only 4 microseconds for sending and receiving a short message. This is only possible because semaphores implement a fast path where the help of the kernel is not needed, i.e. no context switch happens. This is basically incompatible with the style of waiting implemented for file descriptors, because this kind of waiting for an event must always go through the kernel, and is thus slower by design.
But anyway, what to do if Camlboxes need to be integrated into
a program that bases already on file descriptor polling? Of course,
speed will decrease, but maybe not dramatically. We assume here
that the program uses Unixqueue
s as the basic data structure
for organizing polling.
If the program can use the Netmulticore library, there is a very
simple solution. The condition variables provided by this library
allow the integration into Unixqueues, see Netmcore_condition
.
The condition variable is signalled whenever a new message is put
into the Camlbox, and the receiver waits until this signal arrives.
The function Netmcore_condition.wait_e
permits it to integrate
waiting into a Unixqueue.
Otherwise, if Netmulticore is no option (e.g. because the processes
are unrelated that communicate via Camlboxes), the other workaround
is to use threads. A special thread is set up which waits for new
Camlbox messages. Whenever a message arrives, an engine is notified
via a Uq_engines.signal_engine
(which is thread-safe). This engine
can run in a different thread.
module Debug:sig
..end