Crates.io | ingest |
lib.rs | ingest |
version | 0.1.1 |
source | src |
created_at | 2023-08-14 13:58:23.684593 |
updated_at | 2024-09-27 17:34:01.505483 |
description | Single and multi-threaded custom ingestion crate for Stellar Futurenet, written in Rust. |
homepage | https://github.com/xycloo/rs-ingest |
repository | https://github.com/xycloo/rs-ingest |
max_upload_size | |
id | 944192 |
size | 126,392 |
This package provides primitives for building custom ingestion engines on Futurenet. It's inspired from stellars go/ingest
package.
Often, developers either need ingestion features that are outside of Horizon's scope, or need higher availability for the data. For example, a protocol's frontend might need to ingest events into their own database with a very specific filtering or at a large amount, or they might also need to replay history to see if they missed some events.
This crate is being designed with this need in mind, and works on futurenet!
Note: You can also use this crate for pubnet, see the example.
Note: This crate is still a work in progress. The current capabilities of the crate are limited.
Note: Currently only POSIX systems are supported.
Currently, you can both replay history and run online. Running online does not currently support running starting to replay history from a given ledger.
Note that the current implementation is experimental and does not cover all the functionalities that an ingestion crate should, including but not limited to failsafe mechanisms, archiver interaction, custom toml configuration, readers, and overall a more optimized codebase.
Running offline means being able to replay history through a catchup. Replaying history will enable you to process everything that has happened on the network within the specified bounded range.
rs-ingest
allows you to run offline in two modes:
Running single-thread mode is the most straightforward way of using rs-ingest
. This mode will await for the core subprocess to finish catching up and will then allow to retrieve the ledger(s) metadata.
Running single-thread mode will store every ledger meta.
Running multi-thread mode is also pretty simple, but returns a Receiver<MetaResult>
object that receives new ledger meta (already decoded) as soon as it is emitted.
When you run multi-thread mode you will be in charge of how to store the metadata or object derived from it.
When running multi-thread mode you also need to call the closing mechanism manually.
Running online means being able to sync with Futurenet and close ledgers, thus receive ledger close meta. This mode is more suitable for building using real-time data (for example event streaming).
Running online can only be done in multi-thread mode. You'll receive a Receiver<MetaResult>
object which receives ledger close meta as stellar-core closes ledgers.
When running multi-thread mode you also need to call the closing mechanism manually.
rs-ingest
has a closing mechanism that deletes temporary buckets created during execution and clears the objects. Closing is important before re-initiating an action on rs-ingest
. When running single-thread mode, the closing mechanism is triggered within rs-ingest
modules, however when running multi-thread it's the implementor that must decide when to trigger the closing mechanism.
The crate is a WIP, but you can already start playing around the features it currently offers. For example, check out the examples.
The crate is available on crates.io:
ingest = "0.0.3"
Before using the crate, you need the stellar-core
executable. To install the currently futurenet-compatible core:
git clone https://github.com/stellar/stellar-core
cd stellar-core
git checkout v20.0.0rc1
git submodule init
git submodule update
./autogen.sh
CXX=clang++-12 ./configure --enable-next-protocol-version-unsafe-for-production
make
make install [this one might need root access on some machines]
Note. Depending on the machine, you might need a different cmake env var than
CXX=clang++-12
.
Check out LEARN.md