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Getting Started
First, install the Cap'n Proto tools.
Then, run the following commands:
go install capnproto.org/go/capnp/v3/capnpc-go@latest # install go compiler plugin
GO111MODULE=off go get -u capnproto.org/go/capnp/v3/ # install go-capnproto to $GOPATH
Cap'n Proto works by generating code: your schema can be converted to code for any language that Cap'n Proto supports.
Consider the following schema, stored in foo/books.capnp
:
using Go = import "/go.capnp";
@0x85d3acc39d94e0f8;
$Go.package("books");
$Go.import("foo/books");
struct Book {
title @0 :Text;
# Title of the book.
pageCount @1 :Int32;
# Number of pages in the book.
}
capnpc-go requires that two annotations be present in your schema:
-
$Go.package("books")
: tells the compiler to placepackage books
at the top of the generated Go files. -
$Go.import("foo/books")
: declares the full import path within your project. The compiler uses this to generate the import statement in the auto-generated code, when one of your schemas imports a type from another.
Compilation will fail unless these annotations are present.
To compile this schema into Go code, run the following command:
capnp compile -I$GOPATH/src/capnproto.org/go/capnp/std -ogo foo/books.capnp
This generates the file foo/books.capnp.go
. Note that the path matches the one from the import
annotation.
If you encounter the error:
go: no such plugin (executable should be 'capnpc-go')
go: plugin failed: exit code 1
then ensure your $PATH
is set to include $GOPATH/bin
(e.g. export PATH=$PATH:$GOPATH/bin
or similar).
The data structures contained in foo/books.capnp.go
are special Go structs that can be imported into your programs. Moreover, these can be written to byte-streams.
package main
import (
"os"
"foo/books"
"capnproto.org/go/capnp/v3"
)
func main() {
// Make a brand new empty message. A Message allocates Cap'n Proto structs.
msg, seg, err := capnp.NewMessage(capnp.SingleSegment(nil))
if err != nil {
panic(err)
}
// Create a new Book struct. Every message must have a root struct.
book, err := books.NewRootBook(seg)
if err != nil {
panic(err)
}
book.SetTitle("War and Peace")
book.SetPageCount(1440)
// Write the message to stdout.
err = capnp.NewEncoder(os.Stdout).Encode(msg)
if err != nil {
panic(err)
}
}
These datatypes can also be read from byte-streams, as follows:
package main
import (
"fmt"
"os"
"foo/books"
"capnproto.org/go/capnp/v3"
)
func main() {
// Read the message from stdin.
msg, err := capnp.NewDecoder(os.Stdin).Decode()
if err != nil {
panic(err)
}
// Extract the root struct from the message.
book, err := books.ReadRootBook(msg)
if err != nil {
panic(err)
}
// Access fields from the struct.
title, err := book.Title()
if err != nil {
panic(err)
}
pageCount := book.PageCount()
fmt.Printf("%q has %d pages\n", title, pageCount)
}
In addition, each type has a .Message()
method that returns a capnp.Message
, which can be directly marshaled into []byte
s using Message.Marshal
, and unmarshaled with a corresponding call to Message.Unmarshal
.
Lastly, packed encodings are supported via the following methods:
Serializing data structures is useful, but the real power of Cap'n Proto is the RPC Protocol, based on Object Capabilities. Although you do not need to know anything about Object Capabilities to use Cap'n Proto RPC, it is an immensely powerful tool for writing secure systems, and the previous link provides a good conceptual introduction.
But for now, let's skip over the theory and proceed by example.
Capnp RPC operates on interface
types in your schema. We will begin by reproducing the Arith
RPC server from the Go Standard Library RPC package documentation.
Open a new file called arith.capnp
, and copy/paste the following schema:
using Go = import "/go.capnp";
@0xf454c62f08bc504b;
$Go.package("arith");
$Go.import("arith");
interface Arith {
multiply @0 (a :Int64, b :Int64) -> (:product :Int64);
divide @1 (num :Int64, denom :Int64) -> (quo :Int64, rem :Int64);
}
Now, compile the schema as before:
capnp compile -I$GOPATH/src/capnproto.org/go/capnp/std -ogo arith.capnp
You should take a moment to inspect the generated types in arith.capnp.go
. For interface declarations in your schema, the capnp compiler generates several types:
- A server interface:
Arith_Server
- A client struct:
Arith
-
Param
,Result
andFuture
types for each method ofArith
Notice that the only missing piece is the Arith_Server
implementation. We'll define that below.
☝️ NOTE: the ability to provide multiple implementations of an RPC server is an extremely powerful pattern. It allows you to create such things as mock implementations for testing, and restricted/revokable interface providers for capability-based security.
Let's define our Arith
server. In the same directory, create an arith.go
file and paste in the following code:
package arith
import capnp "capnproto.org/go/capnp/v3"
type ArithServer struct{}
func (Arith) Multiply(ctx context.Context, call Arith_multiply) error {
res, err := call.AllocResults() // allocate the results struct
if err != nil {
return err
}
res.SetProduct(call.Args().A() * call.Args().B())
return nil
}
func (Arith) Divide(ctx context.Context, call Arith_divide) error {
if call.Args().B() == 0 {
return errors.New("divide by zero")
}
res, err := call.AllocResults()
if err != nil {
return err
}
res.SetQuo(call.Args().A() / call.Args().B())
res.SetRem(call.Args().A() % call.Args().B())
return nil
}
We now have a working RPC server implementation for our schema interface. Let's begin by starting a server and listening for incoming RPC calls.
The following snippet instantiates an arith.Arith
server, and exports it over a bidirectional stream.
// Create a new locally implemented arith server.
server := arith.Arith_ServerToClient(arith.ArithServer{})
// Listen for calls, using the server as the bootstrap interface.
// The 'rwc' parameter can be any io.ReadWriteCloser, usually net.Conn.
conn := rpc.NewConn(rpc.NewStreamTransport(rwc), &rpc.Options{
// The BootstrapClient is the RPC interface that will be made available
// to the remote endpoint by default. In this case, Arith.
BootstrapClient: capnp.Client(server),
})
defer conn.Close()
// Block until the connection terminates.
select {
case <-conn.Done():
return nil
case <-ctx.Done():
return conn.Close()
}
And here's the corresponding client setup and RPC call:
// As before, rwc can be any io.ReadWriteCloser, and will typically be
// a net.Conn. The rpc.Options can be nil, if you don't want to override
// the defaults.
conn := rpc.NewConn(rpc.NewStreamTransport(rwc), nil)
defer conn.Close()
// Now we wait until we receive the bootstrap interface from the ArithServer.
// The context can be used to time-out or otherwise abort the bootstrap call.
// It is safe to cancel the context after `Bootstrap` returns.
a := Arith(conn.Bootstrap(ctx))
// Okay! Let's make an RPC call!
//
// There are a few things to notice here:
// 1. We pass a callback function to set parameters on the RPC call. If the
// call takes no arguments, you MAY pass nil.
// 2. We return a Future type, representing the in-flight RPC call. We also
// return a release function, which MUST be called when you're done with
// the RPC call and its results.
f, release := a.Multiply(ctx, func(ps arith.Arith_multiply_Params) error {
ps.SetA(2)
ps.SetB(42)
return nil
})
defer release()
// You can do other things while the RPC call is in-flight, but we're going to
// block until the call completes.
res, err := f.Struct()
if err != nil {
return err
}
log.Println(res.Product()) // prints 84
And that's it! Let's reiterate the key points about calling RPC methods:
- For the sake of simplicity, this example uses an in-memory pipe, but you can use TCP connections, Unix pipes, or any other type that implements
io.ReadWriteCloser
. - The return type for a client call is a promise, not an immediate value.
It isn't until the
Struct()
method is called on a method that theclient
function blocks on the remote side.
A few additional words on the Future type are in order. If your RPC method returns another interface type, you can use the Future to immediately make calls against that as-of-yet-unreturned interface. This relies on a feature of the Cap'n Proto RPC protocol called promise pipelining, the advantage of which is that Cap'n Proto can often optimize away the additional network round-trips when such method calls are chained. This is one of Cap'n Proto's key advantages.
At this point, it would be a good idea to get familiar with Go Cap'n Proto's reference-counting model. It will allow you to understand and reason about the lifetime of interface types, or capabilities, in your code.
For more details on writing schemas, see the Cap'n Proto language reference. The capnp package docs detail the encoding and client API, whereas the rpc package docs detail how to initiate an RPC connection.