nim-libp2p/examples/tutorial_3_protobuf.nim

166 lines
5.4 KiB
Nim

## # Protobuf usage
##
## In the [previous tutorial](tutorial_2_customproto.md), we created a simple "ping" protocol.
## Most real protocol want their messages to be structured and extensible, which is why
## most real protocols use [protobuf](https://developers.google.com/protocol-buffers) to
## define their message structures.
##
## Here, we'll create a slightly more complex protocol, which parses & generate protobuf
## messages. Let's start by importing our dependencies, as usual:
import chronos
import stew/results # for Opt[T]
import libp2p
## ## Protobuf encoding & decoding
## This will be the structure of our messages:
## ```protobuf
## message MetricList {
## message Metric {
## string name = 1;
## float value = 2;
## }
##
## repeated Metric metrics = 2;
## }
## ```
## We'll create our protobuf types, encoders & decoders, according to this format.
## To create the encoders & decoders, we are going to use minprotobuf
## (included in libp2p).
##
## While more modern technics
## (such as [nim-protobuf-serialization](https://github.com/status-im/nim-protobuf-serialization))
## exists, minprotobuf is currently the recommended method to handle protobuf, since it has
## been used in production extensively, and audited.
type
Metric = object
name: string
value: float
MetricList = object
metrics: seq[Metric]
{.push raises: [].}
proc encode(m: Metric): ProtoBuffer =
result = initProtoBuffer()
result.write(1, m.name)
result.write(2, m.value)
result.finish()
proc decode(_: type Metric, buf: seq[byte]): Result[Metric, ProtoError] =
var res: Metric
let pb = initProtoBuffer(buf)
# "getField" will return a Result[bool, ProtoError].
# The Result will hold an error if the protobuf is invalid.
# The Result will hold "false" if the field is missing
#
# We are just checking the error, and ignoring whether the value
# is present or not (default values are valid).
discard ?pb.getField(1, res.name)
discard ?pb.getField(2, res.value)
ok(res)
proc encode(m: MetricList): ProtoBuffer =
result = initProtoBuffer()
for metric in m.metrics:
result.write(1, metric.encode())
result.finish()
proc decode(_: type MetricList, buf: seq[byte]): Result[MetricList, ProtoError] =
var
res: MetricList
metrics: seq[seq[byte]]
let pb = initProtoBuffer(buf)
discard ?pb.getRepeatedField(1, metrics)
for metric in metrics:
res.metrics &= ?Metric.decode(metric)
ok(res)
## ## Results instead of exceptions
## As you can see, this part of the program also uses Results instead of exceptions for error handling.
## We start by `{.push raises: [].}`, which will prevent every non-async function from raising
## exceptions.
##
## Then, we use [nim-result](https://github.com/arnetheduck/nim-result) to convey
## errors to function callers. A `Result[T, E]` will either hold a valid result of type
## T, or an error of type E.
##
## You can check if the call succeeded by using `res.isOk`, and then get the
## value using `res.value` or the error by using `res.error`.
##
## Another useful tool is `?`, which will unpack a Result if it succeeded,
## or if it failed, exit the current procedure returning the error.
##
## nim-result is packed with other functionalities that you'll find in the
## nim-result repository.
##
## Results and exception are generally interchangeable, but have different semantics
## that you may or may not prefer.
##
## ## Creating the protocol
## We'll next create a protocol, like in the last tutorial, to request these metrics from our host
type
MetricCallback = proc(): Future[MetricList] {.raises: [], gcsafe.}
MetricProto = ref object of LPProtocol
metricGetter: MetricCallback
proc new(_: typedesc[MetricProto], cb: MetricCallback): MetricProto =
var res: MetricProto
proc handle(conn: Connection, proto: string) {.async.} =
let
metrics = await res.metricGetter()
asProtobuf = metrics.encode()
await conn.writeLp(asProtobuf.buffer)
await conn.close()
res = MetricProto.new(@["/metric-getter/1.0.0"], handle)
res.metricGetter = cb
return res
proc fetch(p: MetricProto, conn: Connection): Future[MetricList] {.async.} =
let protobuf = await conn.readLp(2048)
# tryGet will raise an exception if the Result contains an error.
# It's useful to bridge between exception-world and result-world
return MetricList.decode(protobuf).tryGet()
## We can now create our main procedure:
proc main() {.async.} =
let rng = newRng()
proc randomMetricGenerator(): Future[MetricList] {.async.} =
let metricCount = rng[].generate(uint32) mod 16
for i in 0 ..< metricCount + 1:
result.metrics.add(
Metric(name: "metric_" & $i, value: float(rng[].generate(uint16)) / 1000.0)
)
return result
let
metricProto1 = MetricProto.new(randomMetricGenerator)
metricProto2 = MetricProto.new(randomMetricGenerator)
switch1 = newStandardSwitch(rng = rng)
switch2 = newStandardSwitch(rng = rng)
switch1.mount(metricProto1)
await switch1.start()
await switch2.start()
let
conn = await switch2.dial(
switch1.peerInfo.peerId, switch1.peerInfo.addrs, metricProto2.codecs
)
metrics = await metricProto2.fetch(conn)
await conn.close()
for metric in metrics.metrics:
echo metric.name, " = ", metric.value
await allFutures(switch1.stop(), switch2.stop())
# close connections and shutdown all transports
waitFor(main())
## If you run this program, you should see random metrics being sent from the switch1 to the switch2.