Previously, the TimestampCollector was intended to own the address book
data, so it was intended to be cloneable and hold shared state among all
of its handles. This is now modeled more directly by an
`Arc<Mutex<AddressBook>>`, so the only functionality left in the
`TimestampCollector` is setting up the inital worker, which is better
called `spawn` than `new`.
This also fixes a problem introduced in the previous commit where the
`TimestampCollector` was dropped, causing the worker task to shut down
early.
Now that the `PeerConnector` handles both incoming and outgoing
handshakes, determining the next peer address is definitely out of scope
-- it takes a pre-existing tcp connection.
Failure uses a distinct Fail trait rather than the standard library's
Error trait, which causes a lot of interoperability problems with tower
and other Error-using crates. Since failure was created, the standard
library's Error trait was improved, and its conveniences are now
available without the custom Fail trait using `thiserror` (for easy
error derives) and `anyhow` (for a better boxed Error).
* Don't expose submodules of zebra_network::peer.
* PeerSet, PeerDiscover stubs.
Co-authored-by: Deirdre Connolly <deirdre@zfnd.org>
* Initial work on PeerSet.
This is adapted from the MIT-licensed tower-balance implementation.
* Use PeerSet in the connect stub.
This adds a type alias, BoxedStdError, for a boxed std::error::Error
trait object, and uses it in the where bounds for the generic service
code. In the future, we may want to standardize on using
std::error::Error exclusively, but we would then possibly lose out on
backtrace information.
Add a tower-based peer implementation.
Tower provides middleware for request-response oriented protocols, while Bitcoin/Zcash just send messages which could be interpreted either as requests or responses, depending on context. To bridge this mismatch we define our own internal request/response protocol, and implement a per-peer event loop that scans incoming messages and interprets them either as requests from the remote peer to our node, or as responses to requests we made previously. This is performed by the `PeerService` task, and a corresponding `PeerClient: tower::Service` can send it requests. These tasks are themselves created by a `PeerConnector: tower::Service` which dials a remote peer and performs a handshake.
Deirdre Connolly
Henry de Valence