*msgpack_rpc.txt* For Nvim. {Nvim} NVIM REFERENCE MANUAL by Thiago de Arruda The Msgpack-RPC Interface to Nvim *msgpack-rpc* 1. Introduction |msgpack-rpc-intro| 2. API |msgpack-rpc-api| 3. Connecting |msgpack-rpc-connecting| 4. Clients |msgpack-rpc-clients| 5. Types |msgpack-rpc-types| 6. Wrapping methods |msgpack-rpc-wrap-methods| 7. Vimscript functions |msgpack-rpc-vim-functions| ============================================================================== 1. Introduction *msgpack-rpc-intro* The primary means of controlling a running Nvim instance is through MessagePack-RPC, a messaging protocol that uses the MessagePack serialization format: https://github.com/msgpack/msgpack/blob/7498cf3/spec.md. From now on, we'll be referring to the protocol as msgpack-rpc. At this point, only plugins use msgpack-rpc, but eventually even user interaction will be achieved through the protocol, since user interfaces will be separate programs that control a headless Nvim instance. This is what can be achieved by connecting to the msgpack-rpc interface: - Call any Nvim API function - Listen for Nvim events - Receive remote calls from Nvim Nvim's msgpack-rpc interface can be seen as a more powerful version of Vim's `clientserver` feature. ============================================================================== 2. API *msgpack-rpc-api* The Nvim C API is automatically exposed to the msgpack-rpc interface by the build system, which parses headers at src/nvim/api from the project root. A dispatch function is generated, which matches msgpack-rpc method names with non-static API functions, converting/validating arguments and return values back to msgpack. Client libraries will normally provide wrappers that hide msgpack-rpc details from programmers, which can be automatically generated by reading bundled API metadata from a compiled nvim instance. There are two ways to obtain API metadata: 1. By connecting to a running nvim instance and calling `vim_get_api_info` via msgpack-rpc. This is the preferred way for clients written in dynamically-typed languages, which can define functions at runtime. 2. Through the `--api-info` command-line option, which makes nvim dump a msgpack blob containing metadata to stdout and exit. This is preferred when writing clients for statically-typed languages, which require a separate compilation step. Here's a simple way to get human-readable description of the API (requires Python and the `pyyaml`/`msgpack-python` pip packages): > nvim --api-info | python -c 'import msgpack, sys, yaml; print yaml.dump(msgpack.unpackb(sys.stdin.read()))' > api.yaml ============================================================================== 3. Connecting *msgpack-rpc-connecting* There are four ways to open msgpack-rpc streams to nvim: 1. Through Nvim's stdin/stdout when started with the `--embed` option. This is how other programs can embed nvim. 2. Through the stdin/stdout of a program spawned by the |rpcstart()| function. *$NVIM_LISTEN_ADDRESS* 3. Through the socket automatically created with each instance. To find out the socket location (which is random by default) from a running nvim instance, one can inspect the |$NVIM_LISTEN_ADDRESS| environment variable: > :echo $NVIM_LISTEN_ADDRESS < 4. Through a TCP/IP socket. To make nvim listen on a TCP/IP socket, set the |$NVIM_LISTEN_ADDRESS| environment variable in a shell before starting: > NVIM_LISTEN_ADDRESS=127.0.0.1:6666 nvim < Connecting to the socket is the easiest way a programmer can test the API, which can be done through any msgpack-rpc client library or fully-featured Nvim client (which we'll see below). Here's a ruby script that will print the string 'hello world!' on the current nvim instance: > #!/usr/bin/env ruby # Requires msgpack-rpc: gem install msgpack-rpc # # To run this script, execute it from a running nvim instance (notice the # trailing '&' which is required since nvim won't process events while # running a blocking command): # # :!./hello.rb & # # Or from another shell by setting NVIM_LISTEN_ADDRESS: # $ NVIM_LISTEN_ADDRESS=[address] ./hello.rb require 'msgpack/rpc' require 'msgpack/rpc/transport/unix' nvim = MessagePack::RPC::Client.new(MessagePack::RPC::UNIXTransport.new, ENV['NVIM_LISTEN_ADDRESS']) result = nvim.call(:vim_command, 'echo "hello world!"') < A better way is to use the Python REPL with the `neovim` package, where API functions can be called interactively: > >>> from neovim import attach >>> nvim = attach('socket', path='[address]') >>> nvim.command('echo "hello world!"') < ============================================================================== 4. Implementing new clients *msgpack-rpc-clients* Nvim is still in alpha, so there's no in-depth documentation explaining how to properly implement a client library yet. The Python client (the pip package "neovim") will always be up-to-date with the latest API changes, so its source code is the best documentation currently available. There are some guidelines however: - Separate the transport layer from the rest of the library. See |msgpack-rpc-connecting| for details on how clients can connect to nvim. - Use a MessagePack library that implements at least version 5 of the MessagePack spec, which supports the `bin` and `ext` types used by nvim. - Read API metadata in order to create client-side wrappers for all msgpack-rpc methods. - Use a single-threaded event loop library/pattern. - Use a fiber/coroutine library for the language being used for implementing a client. These greatly simplify concurrency and allow the library to expose a blocking API on top of a non-blocking event loop without the complexity that comes with preemptive multitasking. - Don't assume anything about the order that responses to msgpack-rpc requests will arrive. - Clients should expect to receive msgpack-rpc requests, which need to be handled immediately because Nvim is blocked while waiting for the client response. - Clients should expect to receive msgpack-rpc notifications, but these don't need to be handled immediately because they won't block Nvim (although they should probably be handled immediately anyway). Most of the complexity could be handled by a msgpack-rpc library that supports server to client requests and notifications, but it's not clear if this is part of the msgpack-rpc spec. At least the ruby msgpack-rpc library does not seem to support it: https://github.com/msgpack-rpc/msgpack-rpc-ruby/blob/master/lib/msgpack/rpc/transport/tcp.rb#L150-L158 ============================================================================== 5. Types *msgpack-rpc-types* Nvim's C API uses custom types for all functions (some are just typedefs around C99 standard types). The types can be split into two groups: - Basic types that map natively to msgpack (and probably have a default representation in msgpack-supported programming languages) - Special Nvim types that map to msgpack EXT with custom type codes. Basic type mapping: Nil -> msgpack nil Boolean -> msgpack boolean Integer (signed 64-bit integer) -> msgpack integer Float (IEEE 754 double precision) -> msgpack float String -> msgpack binary Array -> msgpack array Dictionary -> msgpack map Special Nvim types that use msgpack EXT: Buffer -> enum value kObjectTypeBuffer Window -> enum value kObjectTypeWindow Tabpage -> enum value kObjectTypeTabpage The most reliable way of determining the type codes for the special nvim types is at runtime by inspecting the `types` key of metadata dictionary returned by `vim_get_api_info` method. Here's an example json representation of the `types` object: > "types": { "Buffer": { "id": 0 }, "Window": { "id": 1 }, "Tabpage": { "id": 2 } } < Even for statically compiled clients, it's a good practice to avoid hardcoding the type codes, because a client may build for a Nvim version and connect to another that may have different type codes. ============================================================================== 6. Wrapping methods *msgpack-rpc-wrap-methods* As mentioned before, clients should provide an API that hides msgpack-rpc details from programmers, and the API metadata object contains information that makes this task easier: - The "functions" key contains a list of metadata objects for individual functions. - Each function metadata object has type information about the return value and parameters. These can be used for generating strongly-typed APIs in static languages. - Container types may be decorated with type/size constraints, e.g. ArrayOf(Buffer) or ArrayOf(Integer, 2). This can be useful to generate even more strongly-typed APIs. - Methods that operate instances of Nvim's types are prefixed with the type name in lower case, e.g. `buffer_get_line` represents the `get_line` method of a Buffer instance. - Global methods are prefixed with `vim`, e.g. `vim_list_buffers`. So, for an object-oriented language, a client library would have the classes that represent Nvim's types, and the methods of each class could be defined by inspecting the method name prefix. There could also be a singleton Vim class with methods mapped to functions prefixed with `vim_` ============================================================================== 7. Vimscript functions *msgpack-rpc-vim-functions* Four functions related to msgpack-rpc are available in vimscript: 1. |rpcstart()|: Similarly to |jobstart()|, this will spawn a co-process with its standard handles connected to Nvim. The difference is that it's not possible to process raw data to/from the process's stdin/stdout/stderr. This is because the job's stdin and stdout are used as a single msgpack channel that is processed directly by Nvim. 2. |rpcstop()|: Same as |jobstop()|, but operates on handles returned by |rpcstart()|. 3. |rpcrequest()|: Sends a msgpack-rpc request to the process. 4. |rpcnotify()|: Sends a msgpack-rpc notification to the process. The last two functions may also be used with channels created from connections to |$NVIM_LISTEN_ADDRESS|. ============================================================================== vim:tw=78:ts=8:noet:ft=help:norl: