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Brief design documentation for new IPC mechanism allowing foreground Git client to talk with an existing daemon process at a known location using a named pipe or unix domain socket. Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de> Signed-off-by: Jeff Hostetler <jeffhost@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
105 lines
4.8 KiB
Text
105 lines
4.8 KiB
Text
Simple-IPC API
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==============
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The Simple-IPC API is a collection of `ipc_` prefixed library routines
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and a basic communication protocol that allow an IPC-client process to
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send an application-specific IPC-request message to an IPC-server
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process and receive an application-specific IPC-response message.
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Communication occurs over a named pipe on Windows and a Unix domain
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socket on other platforms. IPC-clients and IPC-servers rendezvous at
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a previously agreed-to application-specific pathname (which is outside
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the scope of this design) that is local to the computer system.
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The IPC-server routines within the server application process create a
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thread pool to listen for connections and receive request messages
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from multiple concurrent IPC-clients. When received, these messages
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are dispatched up to the server application callbacks for handling.
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IPC-server routines then incrementally relay responses back to the
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IPC-client.
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The IPC-client routines within a client application process connect
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to the IPC-server and send a request message and wait for a response.
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When received, the response is returned back the caller.
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For example, the `fsmonitor--daemon` feature will be built as a server
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application on top of the IPC-server library routines. It will have
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threads watching for file system events and a thread pool waiting for
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client connections. Clients, such as `git status` will request a list
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of file system events since a point in time and the server will
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respond with a list of changed files and directories. The formats of
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the request and response are application-specific; the IPC-client and
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IPC-server routines treat them as opaque byte streams.
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Comparison with sub-process model
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---------------------------------
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The Simple-IPC mechanism differs from the existing `sub-process.c`
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model (Documentation/technical/long-running-process-protocol.txt) and
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used by applications like Git-LFS. In the LFS-style sub-process model
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the helper is started by the foreground process, communication happens
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via a pair of file descriptors bound to the stdin/stdout of the
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sub-process, the sub-process only serves the current foreground
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process, and the sub-process exits when the foreground process
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terminates.
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In the Simple-IPC model the server is a very long-running service. It
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can service many clients at the same time and has a private socket or
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named pipe connection to each active client. It might be started
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(on-demand) by the current client process or it might have been
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started by a previous client or by the OS at boot time. The server
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process is not associated with a terminal and it persists after
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clients terminate. Clients do not have access to the stdin/stdout of
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the server process and therefore must communicate over sockets or
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named pipes.
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Server startup and shutdown
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---------------------------
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How an application server based upon IPC-server is started is also
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outside the scope of the Simple-IPC design and is a property of the
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application using it. For example, the server might be started or
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restarted during routine maintenance operations, or it might be
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started as a system service during the system boot-up sequence, or it
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might be started on-demand by a foreground Git command when needed.
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Similarly, server shutdown is a property of the application using
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the simple-ipc routines. For example, the server might decide to
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shutdown when idle or only upon explicit request.
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Simple-IPC protocol
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-------------------
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The Simple-IPC protocol consists of a single request message from the
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client and an optional response message from the server. Both the
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client and server messages are unlimited in length and are terminated
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with a flush packet.
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The pkt-line routines (Documentation/technical/protocol-common.txt)
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are used to simplify buffer management during message generation,
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transmission, and reception. A flush packet is used to mark the end
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of the message. This allows the sender to incrementally generate and
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transmit the message. It allows the receiver to incrementally receive
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the message in chunks and to know when they have received the entire
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message.
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The actual byte format of the client request and server response
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messages are application specific. The IPC layer transmits and
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receives them as opaque byte buffers without any concern for the
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content within. It is the job of the calling application layer to
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understand the contents of the request and response messages.
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Summary
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-------
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Conceptually, the Simple-IPC protocol is similar to an HTTP REST
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request. Clients connect, make an application-specific and
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stateless request, receive an application-specific
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response, and disconnect. It is a one round trip facility for
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querying the server. The Simple-IPC routines hide the socket,
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named pipe, and thread pool details and allow the application
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layer to focus on the application at hand.
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