Ashley
d1ef8507d7
* Initial draft * Add an iterator that helps us get most items * Revert changes to grandpa * Change fields to just be the grandpa authority set and babe epoch changes * Only use the fields we need from the shared authority set * Switch to RPC call * Revert "Only use the fields we need from the shared authority set" This reverts commit 6ede87b0c5fe53f251d7cb45951006a7dc8f9b83. * Add babe_finalized_block_weight from `ashley-improve-sync-state-WIP-loading` * Fix rpc test * Move sync state rpc stuff into sc-sync-state-rpc * Remove as_json_value and remove unwraps from sc-sync-state-rpc * Add clone_inner to SharedAuthoritySet
BABE (Blind Assignment for Blockchain Extension)
BABE is a slot-based block production mechanism which uses a VRF PRNG to randomly perform the slot allocation. On every slot, all the authorities generate a new random number with the VRF function and if it is lower than a given threshold (which is proportional to their weight/stake) they have a right to produce a block. The proof of the VRF function execution will be used by other peer to validate the legitimacy of the slot claim.
The engine is also responsible for collecting entropy on-chain which will be used to seed the given VRF PRNG. An epoch is a contiguous number of slots under which we will be using the same authority set. During an epoch all VRF outputs produced as a result of block production will be collected on an on-chain randomness pool. Epoch changes are announced one epoch in advance, i.e. when ending epoch N, we announce the parameters (randomness, authorities, etc.) for epoch N+2.
Since the slot assignment is randomized, it is possible that a slot is assigned to multiple validators in which case we will have a temporary fork, or that a slot is assigned to no validator in which case no block is produced. Which means that block times are not deterministic.
The protocol has a parameter c [0, 1] for which 1 - c is the probability
of a slot being empty. The choice of this parameter affects the security of
the protocol relating to maximum tolerable network delays.
In addition to the VRF-based slot assignment described above, which we will call primary slots, the engine also supports a deterministic secondary slot assignment. Primary slots take precedence over secondary slots, when authoring the node starts by trying to claim a primary slot and falls back to a secondary slot claim attempt. The secondary slot assignment is done by picking the authority at index:
blake2_256(epoch_randomness ++ slot_number) % authorities_len.
The secondary slots supports either a SecondaryPlain or SecondaryVRF
variant. Comparing with SecondaryPlain variant, the SecondaryVRF variant
generates an additional VRF output. The output is not included in beacon
randomness, but can be consumed by parachains.
The fork choice rule is weight-based, where weight equals the number of primary blocks in the chain. We will pick the heaviest chain (more primary blocks) and will go with the longest one in case of a tie.
An in-depth description and analysis of the protocol can be found here: https://research.web3.foundation/en/latest/polkadot/BABE/Babe.html
License: GPL-3.0-or-later WITH Classpath-exception-2.0