2d8e2dd7f5
* Implement slashing protection Roll-up of #588 with some conflicts resolved * WIP improvements * Require slot uniqueness for blocks (rather than epochs) * Native DB support for Slot and Epoch * Simplify surrounding/surrounded-by queries * Implement unified slashing protection database A single SQL database saves on open file descriptors. * Make slashing protection concurrency safe. Revive tests, add parallel tests. * Some simplifications * Auto-registration, test clean-ups * More tests, clean-ups, hardening * Fix comments in BLS * Optimise bulk validator registration * Delete outdated tests * Use bundled SQLite in slashing protection * Auto-register validators in simulation * Use real signing_root in slashing protection * Update book for --auto-register * Refine log messages and help flags * Correct typo in Cargo.toml authors * Fix merge conflicts * Safer error handling in sqlite slot/epoch * Address review comments * Add attestation test mutating block root Co-authored-by: pscott <scottpiriou@gmail.com> |
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| .. | ||
| slashing_protection | ||
| src | ||
| Cargo.toml | ||
| README.md | ||
Lighthouse Validator Client
The Validator Client (VC) is a stand-alone binary which connects to a Beacon Node (BN) and fulfils the roles of a validator.
Roles
The VC is responsible for the following tasks:
- Requesting validator duties (a.k.a. shuffling) from the BN.
- Prompting the BN to produce a new block, when a validator's block production duties require.
- Completing all the fields on a new block (e.g., RANDAO reveal, signature) and publishing the block to a BN.
- Prompting the BN to produce a new attestation as per a validator's duties.
- Ensuring that no slashable messages are signed by a validator private key.
- Keeping track of the system clock and how it relates to slots/epochs.
The VC is capable of managing multiple validators in the same process tree.
Implementation
This section describes the present implementation of this VC binary.
Services
Each validator is represented by two services, one which tracks the validator duties and another which performs block production duties.
A separate thread is maintained for each service, for each validator. As such, a single validator utilises three (3) threads (one for the base VC and two for each service) and two validators utilise five (5) threads.
DutiesManagerService
Polls a BN and requests validator responsibilities, as well as a validator
index. The outcome of a successful poll is a EpochDuties struct:
EpochDuties {
validator_index: u64,
block_production_slot: u64,
}
This is stored in the EpochDutiesMap, a HashMap mapping epoch -> EpochDuties.
BlockProducerService
Polls the system clock and determines if a block needs to be produced. Reads
from the EpochDutiesMap maintained by the DutiesManagerService.
If block production is required, performs all the necessary duties to request, complete and return a block from the BN.
Configuration
Validator configurations are stored in a separate data directory from the main Beacon Node
binary. The validator data directory defaults to:
$HOME/.lighthouse-validator, however an alternative can be specified on the command line
with --datadir.
The configuration directory structure looks like:
~/.lighthouse-validator
├── 3cf4210d58ec
│ └── private.key
├── 9b5d8b5be4e7
│ └── private.key
└── cf6e07188f48
└── private.key
Where the hex value of the directory is a portion of the validator public key.
Validator keys must be generated using the separate account_manager binary, which will
place the keys into this directory structure in a format compatible with the validator client.
Be sure to check the readme for account_manager.
The chain specification (slot length, BLS domain, etc.) defaults to foundation parameters, however is temporary and an upgrade will allow these parameters to be read from a file (or initialized on first-boot).
BN Communication
The VC communicates with the BN via a gRPC/protobuf connection.