Flow-IPC 1.0.1
Flow-IPC project: Full implementation reference.
Structured Message Transport: Messages As Long-lived Data Structures / Advanced Topics
MANUAL NAVIGATION: Preceding Page - Next Page - Table of Contents - Reference

We previously discussed how to transmit structured messages; in this page we get into advanced techniques that treat messages as long-lived data structures to re-share multiple times and potentially modify throughout. (Or go back to the prerequisite preceding page: Structured Message Transport.)

struc::Channel and serialization

In Structured Message Transport we kept things simple: Create struc::Channel. Create a message struc::Msg_out using its .create_msg(). Mutate it via capnp-generated setters. Send it via .send() or .*_request(). Receive it on the other side as a Msg_in (struc::Msg_in) and access it via capnp-generated getters. This may well be perfectly sufficient for many use cases: Messaging is a common IPC paradigm, and in the described capacity struc::Channel provides, on top of the basics: structured data via capnp schemas; and basic request-response/multiplex-demultiplex APIs.

However the abilities of the ipc::transport structured layer go beyond that basic and effective paradigm. Hand-wavily speaking, an ipc::transport::struc::Msg_out (which represents a message, as opposed to message instance, and is not so different conceptually from a container) can be seen as not a short-lived message – that exists essentially just before sending and just after receiving – but as a data structure whose lifetime is practically unlimited (if so desired).

It is probably clear already that capnp provides the ability to express many data structures (as ~anything can be built on top of structs, unions, and Lists). (Granted, things like sorted trees and hash-tables would need some some added code to be conveniently accessed directly within a capnp schema, but that is also possible.)

Note
If a native capnp schema is insufficient for your data structure's performance or semantic needs, we provide first-class-citizen support for direct C++ data structures, including STL-compliant containers, in shared memory. See Shared Memory: Direct Allocation, Transport.

However, beyond that, a number of capabilities are necessary to treat struc::Msg_out and the associated message instances (ipc::transport::struc::Msg_in a/k/a ipc::transport::struc::Channel::Msg_in upon receipt) as long-lived data structures shared among processes. The most basic such capabilities are:

  • modifying a Msg_out after .send()ing (et al);
  • re-.send()ing (et al) a Msg_out over the same channel;
  • re-.send()ing (et al) a Msg_out over a different channel.

As you will soon see, all of these are quite simple and in fact don't even involve any more APIs than those explained in Structured Message Transport.

Potentially one might also want the following property:

  • if a change is made to the original Msg_out, the change is immediately reflected in an associated Msg_in already received by a process (subject to synchronization that is the user's responsibility).

As you will soon see, this merely requires the use of a SHM-backed serializer – but that is already assumed at least in the default recommendation and example code in Structured Message Transport.

Finally, there is the matter of the the lifetime of a given Msg_out and associated Msg_ins. There are a few ways to think about this, but supposing one uses the ipc::session paradigm for channel opening (and possibly SHM use), it can be roughly described as the following capabilities:

  • a Msg_out (+ Msg_ins) lifetime that is at least equal to that of a particular ipc::session::Session;
  • a lifetime exceeding that of the session's.
Note
For completeness we should mention that to be usable 100% completely as simply a data structure coequally shared among all relevant processes, a particular Msg_* would also need to be modifiable (via capnp-generated mutating API) on the receiver side. As of this writing Flow-IPC does not offer such an API. However this would be an incremental and not particularly difficult addition to Flow-IPC. We may add this in the foreseeable future. (Exception: The SHM-provider ipc::shm::arena_lend (SHM-jemalloc) is such that it is conceptually impossible to offer this feature in its case. However ipc::shm::classic is fine in this respect.)

Advice: The topics in this page are not difficult, as long as one simply adjusts their understanding of what a struc::Msg_out (+ associated message instance objects struc::Msg_in) really is. The main adjustment: despite the existence of the convenience method ipc::transport::struc::Channel::create_msg(), and the struc::Channel constructor arguments that make that work, a message is not in reality in any way "attached" to a particular channel. It is actually an independent data structure – in a way like a container. Once one understands its lifetime and this orthogonality to channels, it all (we feel) makes straightforward sense.

A word on Native_handle transmission

We've already mentioned this in Structured Message Transport but to recap/expand: One can load a native handle (FD in POSIX/Unix/Linux parlance) into a Msg_out. A received Msg_in will then contain a handle referring to the same resource description, accessible via ipc::transport::struc::Msg_in::native_handle_or_null(). The Msg_out-stored Native_handle can be unloaded or replaced with another one; this has no effect on the associated Msg_ins. (The underlying resource, such as a file handle or network socket, will be freed once all handles proliferated this way have been freed. Msg_out will do that to its handle on destruction or replacement/unloading via .store_native_handle_or_null(). Msg_in-stored such handles are not auto-freed; it is the user's responsibility upon receipt to access via .native_handle_or_null() and further handle it as she will.)

Fundamentally these Native_handles should be viewed as light-weight; in at least POSIX/Unix/Linux they are ints. Furthermore, as shown above, conceptually (not literally – it is not a mere int copy when crossing a process boundary) speaking they are always copied on transmission. In the rest of the page we speak at length about message payloads being copied or not-copied (zero-copy). To be clear, when we talk of this, we are speaking about the structured-data payload only. Native_handles (conceptually) are always copied when transmitted.

Re-sending a Msg_out; modifying a Msg_out

These actions are so simple that we felt it best to just give recipes for them here at the top, without even first philosophizing about message lifetimes and the like.

To send a Msg_out, you already know you can use struc::Channel methods .send(), async_request(), sync_request(). Obviously up to that point you already know you can mutate the payload via capnp mutating API accessible via struc::Msg_out::body_root()->.

To modify it after a send: You just... do it. body_root()->, etc. Any Builders you've saved from before the send will work just fine too (and be indistinguishable from those re-obtained via a re-invocation of body_root().)

To re-send a Msg_out, whether you've modified it or not: You just... do it. Use the same Msg_out. (There is no way to copy it, as of this writing, so.... Though, technically, you could do that yourself via capnp fanciness; but I digress.)

All of that said, simple as it is, it doesn't answer questions that naturally arise; for example, if one modifies a Msg_out, does an existing related-Msg_in observer "see" it? Time to discuss all that.


Send 1 message over 2+ different channels, with this one weird trick
Actually there is no trick. Got a Msg_out? You can send it over any struc::Channel you've got, as long as the template parameters match (most notably Message_body, the schema); or it won't compile. It doesn't matter which one's .create_msg() you used, or whether you used one at all (it can be explicitly constructed instead).
However this opens up further questions; like "Is it safe?" (Laurence Olivier -> Dustin Hoffman). The answer is slightly tricky. Hopefully we will reveal all in the next couple of sections of this Manual page.

Messages, message instances, message lifetime

A message begins existence when an ipc::transport::struc::Msg_out (a/k/a struc::Channel::Msg_out) is constructed. A message instance begins existence when it is sent via a struc::Channel via a send-method of thereof. It is never accessible, per se, by the user in the sender process; it is first accessible by a user upon receipt via a struc::Channel API (.sync_request() return value, an .expect_*() handler, or an .async_request() handler). Specifically, that message instance lives in that struc::Msg_in (a/k/a struc::Channel::Msg_in).

So the Msg_out is the message; the Msg_ins are the message instances as they are sent+received, each time that occurs.

The key idea to understand is the relationship between the message (Msg_out) and its 0+ message instances – Msg_ins. Simply put:

  • A message instance is a read-only view of the message. (Per the "Note" above the "read-only" restriction may be lifted, in most cases, in an Flow-IPC in the foreseeable future.)
  • If the message is SHM-backed: A message instance accesses the same location in memory, directly, as the message. Perf-wise: no copy is made when the instance is created (i.e., it is sent/received). Algorithmic possibilities-wise: the message instance is the same data structure as the message.
  • If the message is heap-backed: A message instance accesses a different location in memory than the message. Perf-wise: a copy is made when the instance is created (again, at send/receive time). Algorithmic possibilities-wise: the message instance has the same structured as the message but is a copy thereof.

We'll explain "SHM-backed" and "heap-backed" shortly.

Message lifetime

A message's lifetime ends at a certain time depending on whether it's SHM-backed or heap-backed. Ditto for message instance lifetime.

For heap-backed messages it is straightforward, as there's the message, and the instances are subsequent copies thereof.

  • A heap-backed message lasts as long as the process in which it was allocated. One can even shut down all IPC sessions: it is still accessible, modifiable, everything. (This could be useful in its own right.) Saved capnp-generated Builders continue working equally well and so on.
  • A heap-backed message instance lasts as long as the process in which its Msg_in was initially received-into (hence allocated, in the bowels of a struc::Channel). It's a copy of the original message: it's just (as of this writing) a read-only copy. Just as with the original message, you can end all IPC, and you can still access the message instance just fine including via saved capnp-generated Readers.

For SHM-backed messages it is more fun, as the message and subsequent message instances refer to the same data in RAM. The lifetime of those underlying data ends in the last destructor to complete among:

  • the destructor of the original struc::Msg_out;
  • the destructor of each subsequently created struc::Msg_in.

Thus, conceptually, there is a ref-count: 1 for the Msg_out; 1 for each Msg_in. Once it reaches zero, the lifetime of the data ends, and the RAM resources are returned for use by other items. (This is all thread-safe in cross-process fashion. It's fine if destructors run concurrently to each other, with a new related Msg_in being created in another process, etc.)

Note
Msg_ins are exclusively trafficked via Msg_in_ptrs which are mere shared_ptr<Msg_in>s; hence once a particular shared_ptr group reaches ref-count-zero, the destructor is invoked, and voilà for that particular one message instance. This applies regardless of SHM-backed versus heap-backed messages. Meanwile Msg_out can live wherever you want (you can wrap it in a shared_ptr if you want); but don't confuse where these objects live as opposed to where the data structure lives (similarly to a regular std::vector potentially living on the stack but allocating its buffer elsewhere, typically heap but depending on the Allocator used elsewhere).

Constructing messages; reusing messages among different struc::Channels

We can now discuss freely how one creates a Msg_out. You already know about struc::Channel::create_msg(), but in our expanded context here – of infinite lifetimes and SHM-arenas, oh my – it is not quite sufficient and possibly somewhat confusing, as it appears to associate a message with a channel; but the two are (as we've stated earlier) actually orthogonal.

Note
A message instance is created internally by struc::Channel at receipt time. By the time you get the Msg_in_ptr into your code, it's already in existence, and it will go out of existence when that shared_ptr<Msg_in> = Msg_in_ptr's shared-pointer group reaches ref-count-zero.

Formally speaking the backing (SHM versus heap; plus config) of any given Msg_out is controlled via the formal concepts ipc::transport::struc::Struct_builder and ipc::transport::struc::Struct_builder::Config (and the deserialization counterparts ipc::transport::struc::Struct_reader and ipc::transport::struc::Struct_reader::Config). You can read all about them and their impls – or even potentially how to create your own for truly advanced fanciness – by following those links into the Reference and going from there. (In that case you will also need to understand struc::Channel non-tag constructor form as well as the related Struct_builder_config and Struct_reader_config class template paramers which match Struct_builder::Config and Struct_reader::Config concepts repsectively.) Here in the guided Manual we won't get into it to that level of formality and depth. We strive to keep it immediately useful but nevertheless sufficiently advanced for most needs.

So here are the relevant recipes with all currently available types of message backing. Let's start with the simplest one: heap-backed messages.


When to choose heap-backing (over SHM-backing)?
As explained above transmitting a heap-backed message means a copy is made. This has the obvious undesirable performance hit: a copy is made at least into the transport and another out of the transport (possibly another inside the transport, depending on the transport) – instead of zero copies end-to-end. Furthermore this limits the size of a capnp data structure's leaf to what can be serialized into one unstructured message bearable by the underlying ipc::transport::Channel transport(s). (For detail of this limitation see ipc::transport::struc::Heap_fixed_builder class doc header. It also expands on the present discussion generally.) However it may well still be useful for many applications. Informally we recommend SHM-backing as the default choice; but certainly there are use cases where heap-backing works better due to its simplicity. Internally we use it to implement certain internal aspects of the SHM-jemalloc SHM-provider (for example).

For SHM-backed message transmission: Use ipc::transport::struc::Channel_via_heap as your Structured_channel_t template in place of what we used in the example in Structured Message Transport. There we used ipc::transport::struc::shm::classic::Channel albeit invisibly via Session::Structured_channel alias. If your chosen Session type is not SHM-backed – meaning you will not be using ipc::session-provided SHM capabilities at all and ultimately thus chose to use ipc::session::Client_session or ipc::session::Session_server as opposed to a SHM-backed variant thereof – then Session::Structured_channel will yield ipc::transport::struc::Channel_via_heap. Otherwise you can use ipc::session::Session_mv::Structured_channel alias; or ipc::transport::struc::Channel_via_heap explicitly.

There is a number of ways to construct a heap-backed Msg_out. Assuming you use ipc::session to obtain channels, which you generally should barring a very good reason not to, then .create_msg() will work most easily. The resulting Msg_out (and any resulting Msg_ins) are transmissible over that channel or any other struc::Channel upgraded-from a Channel opened from the same Session or Session of the same concrete C++ type. The latter includes (on session-server side) any Session arising from the same Session_server (of which there should be exactly 1 per process).

Messages are conceptually decoupled from specific channels, and your program may be structured in such a way as to not have a struc::Channel available easily when constructing the Msg_out. In that case you can easily construct a matching-type struc::Msg_out explicitly without .create_msg(). You will need a Struct_builder::Config object (which is a light-weight item). This is obtained easily via ipc::session::Session_mv::heap_fixed_builder_config() including the static overload that merely requires a Logger* (which can itself be null if desired).

Going outside the ipc::session paradigm is (as earlier forewarned) outside our scope here, but briefly we can explain that if you go that way you can construct the Struct_builder::Config – actually concretely an ipc::transport::struc::Heap_fixed_builder::Config – explicitly. Certain values will be required for that constructor, and they must be such that all Channels over which the message shall be transmitted (recall that with heap-backed messages the actual message's serialization is copied into/out of the transport) shall be capable of transmitting even the largest possible capnp-serialization segment that would ever be generated given your data. Again: this is outside our scope here, but the Reference includes all necessary information for this advanced use case.

Now let's talk about constructing SHM-backed messages.

In fact, in Structured Message Transport, we provided the recipe for a common use case; namely:

What does session-scope mean? Briefly it means that the lifetime of any resulting messages is limited to that of the Session given by you as an argument to the struc::Channel constructor. The alternative is app-scope. (Please read elsewhere in the Manual to understand these 2 alternatives.) In many applications session-scope is sufficient.

If indeed session-scope is sufficient, then you can use SHM-classic SHM-provider as above; or else select SHM-jemalloc. If writing code in the fashion recommended in this Manual this will flow automatically from your original choice of Client_session (ipc::session::shm::classic::Client_session versus ipc::session::shm::arena_lend::jemalloc::Client_session) or Session_server (ditto modulo the last identifier name). Otherwise use ipc::transport::struc::shm::arena_lend::jemalloc::Channel.

If app-scope is required, then:

  • Use ipc::transport::struc::Channel_base::S_SERIALIZE_VIA_APP_SHM tag arg to struc::Channel constructor.
  • You can still select either SHM-classic or SHM-jemalloc.
    • However, in the latter case (and the latter case only): The session argument to that constructor must be a Server_session; trying to use a Client_session will result in a compile error. With SHM-jemalloc, on the session-client side, it is only possible to construct session-scope SHM-backed data. This is due to the nature of client-sessions combined with the nature of arena-lend style of SHM-provider.

Which SHM-provider to use? That is a major decision and affects not just SHM-backed messages but direct-storage of C++ structures in SHM; see Shared Memory: Direct Allocation, Transport w/r/t the latter. Without a deep dive: See a safety-oriented discussion and nearby recap of non-safety considerations. A lengthier description can be found in the Reference.

Having constructed the properly-typed SHM-backed-config struc::Channel properly using these knobs, it is easiest to use .create_msg() to create Msg_out. Any allocation required as you subsequently mutate it shall occur in the proper SHM arena, and resulting Msg_ins on the receiving side shall properly access it directly there.

Messages are conceptually decoupled from specific channels, and your program may be structured in such a way as to not have a struc::Channel available easily when constructing the Msg_out. In that case you can easily construct a matching-type struc::Msg_out explicitly without .create_msg(). You will need a Struct_builder::Config object (which is a light-weight item). This is obtained via ipc::session::shm::classic::Session_mv::session_shm_builder_config() (session-scope, SHM-classic) or ipc::session::shm::classic::Session_mv::app_shm_builder_config() (app-scope, SHM-classic). For SHM-jemalloc substitute ipc::session::shm::arena_lend::jemalloc::Session_mv::session_shm_builder_config() or ipc::session::shm::arena_lend::jemalloc::Server_session::app_shm_builder_config(). All four methods are available via your Session object (e.g., session.session_shm_builder_config()). The 2 app-scope methods have counterparts ipc::session::shm::classic::Session_server::app_shm_builder_config() and ipc::session::shm::arena_lend::jemalloc::Session_server::app_shm_builder_config() in case an individual Session is not easily accessible.

Going outside the ipc::session paradigm is (as earlier forewarned) outside our scope here, but briefly we can explain that, if you go that way, you can explicitly construct the Struct_builder::Config – actually concretely an ipc::transport::struc::shm::Builder::Config<A> (where A is SHM-provider-determined Shm_arena type, namely ipc::shm::classic::Pool_arena or ipc::shm::arena_lend::jemalloc::Ipc_arena. The Config can, basically, take zeroes for the framing integers and, crucially, a pointer to the Shm_arena in which to allocate. Details as to where to get that Shm_arena are well beyond our scope here; but if you're foregoing ipc::session, you presumably know what you're doing in the first place in this regard.

The last, and considerably important, subject to discuss about SHM-backed Msg_outs is: Which channels can safely/properly transmit a given Msg_out, once it has been constructed and filled out via mutation?

Let's take the session-scope Msg_outs, the simpler case, first. The answer: regardless of what API was used to construct one, it can be sent over any struc::Channel upgraded-from a Channel opened via the same ipc::session::Session as the one SHM-backing the original Msg_out. What Session is that? Answer: If you used .create_msg(), then it's the one passed-in, by you, to struc::Channel constructor. If you used explicit struc::Msg_out constructor, then the backing session is the one you used when calling session.session_shm_builder_config() to provide the required Struct_builder::Config.

So the simplest use case is simply using x.create_msg() and then sending it (as many times as desired) via x.send() (et al); but instead of x.send() (et al) you can use various values instead of x – as long as it's from the same session as x. Also – as channels are otherwise decoupled from their source sessions – ensure the source session is still open. (If you followed advice in Sessions: Teardown; Organizing Your Code, you will be good to go. You would have ceased to use a channel upon learning of the closure of its source session; that is assuming you didn't yourself close them both in the first place.)

If not using x.create_msg() but direct Msg_out construction, you're still fine: Just make sure you keep a clean design as to which session corresponds to what channel(s) and message(s).

As to app-scope Msg_outs: On the session-client side, with SHM-jemalloc there are no app-scope Msg_outs, so it's a moot question. On the session-client side, with SHM-classic, however, there are app-scope Msg_outs... but it is improper to let a Msg_out survive past the end of a given client-side session. However resulting Msg_ins (on the opposing side, so the session-server side) will survive just fine – until the entire Session_server is destroyed; which would occur only if one intends to end all relevant IPC work in the process. The ability to make client-created messages survive past a given session is unique to SHM-classic over SHM-jemalloc. (It is easy to conceive of this being useful in a server-side cache application.)

App-scope Msg_outs on the session-server side can be transmitted over any channel from any session from the same Session_server – of which, again, there shall be exactly 1 per process – as long as the Session_server object has not been destroyed.

The next page is: Shared Memory: Direct Allocation, Transport.


MANUAL NAVIGATION: Preceding Page - Next Page - Table of Contents - Reference