mirror of https://github.com/poanetwork/hbbft.git
150 lines
6.6 KiB
Rust
150 lines
6.6 KiB
Rust
//! # Honey Badger BFT
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//!
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//! An implementation of [The Honey Badger of BFT Protocols](https://eprint.iacr.org/2016/199.pdf),
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//! an asynchronous, Byzantine fault tolerant consensus algorithm.
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//!
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//!
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//! ## Consensus
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//!
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//! A consensus algorithm is a protocol that helps a number of nodes agree on some data value.
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//! Byzantine fault tolerant systems can tolerate a number of faulty nodes _f_ (broken, or even
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//! controlled by an attacker), as long as the total number of nodes _N_ is greater than _3 f_.
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//! Asynchronous protocols do not make assumptions about timing: Even if an adversary controls
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//! network scheduling and can delay message delivery, consensus will still be reached as long as
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//! all messages are _eventually_ delivered.
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//!
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//! The Honey Badger consensus algorithm is both Byzantine fault tolerant and asynchronous. It is
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//! also modular, and the subalgorithms it is composed of are exposed in this crate as well, and
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//! usable separately.
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//!
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//! Consensus algorithms are fundamental to resilient, distributed systems such as decentralized
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//! databases and blockchains.
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//!
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//!
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//! ## Usage
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//!
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//! `hbbft` is meant to solve the consensus problem in a distributed application. Participating
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//! nodes provide input to the algorithm and are guaranteed to eventually produce the same output,
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//! after passing several messages back and forth.
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//!
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//! The crate only implements the abstract protocols, it is the application's responsibility to
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//! serialize, sign and send the messages. The application is required to call `handle_message` for
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//! every correctly signed message from a peer. Methods return a [Step](struct.Step.html) data
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//! structure, which contain messages that need to be sent, fault logs indicating misbehaving
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//! peers, and outputs.
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//!
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//! The network must contain a number of nodes that are known to each other by some unique
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//! identifiers (IDs), which is a generic type argument to the algorithms. Where applicable, the
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//! type of the input and output is also generic.
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//!
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//!
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//! ## Algorithms
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//!
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//! Honey Badger is modular, and composed of several algorithms that can also be used independently.
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//!
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//! [**Honey Badger**](honey_badger/index.html)
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//!
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//! The nodes repeatedly input _contributions_ (any user-defined type) and output a sequence of
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//! _batches_. The batches have sequential numbers (_epochs_) and contain one contribution
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//! from at least _N - f_ nodes. The sequence and contents of the batches will be the same in all
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//! nodes.
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//!
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//! [**Dynamic Honey Badger**](dynamic_honey_badger/index.html)
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//!
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//! A modified Honey Badger where validators can dynamically add and remove others to/from the
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//! network. In addition to the transactions, they can input `Add` and `Remove` requests. The
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//! output batches contain information about validator changes.
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//!
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//! [**Queueing Honey Badger**](queueing_honey_badger/index.html)
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//!
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//! A modified Dynamic Honey Badger that has a built-in transaction queue. The nodes input any
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//! number of _transactions_, and output a sequence of batches. Each batch contains a set of
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//! transactions that were input by the nodes, and usually multiple transactions from each node.
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//!
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//! [**Subset**](subset/index.html)
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//!
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//! Each node inputs one item. The output is a set of at least _N - f_ nodes' IDs, together with
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//! their items, and will be the same in every correct node.
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//!
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//! This is the main building block of Honey Badger: In each epoch, every node proposes a number of
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//! transactions. Using the Subset protocol, they agree on at least _N - f_ of those
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//! proposals. The batch contains the union of these sets of transactions.
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//!
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//! [**Broadcast**](broadcast/index.html)
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//!
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//! One node, the _proposer_, inputs an item, and every node receives that item as an output. Even
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//! if the proposer is faulty it is guaranteed that either none of the correct nodes output
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//! anything, or all of them have the same output.
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//!
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//! This is used in Subset to send each node's proposal to the other nodes.
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//!
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//! [**Binary Agreement**](binary_agreement/index.html)
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//!
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//! Each node inputs a binary value: `true` or `false`. As output, either all correct nodes receive
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//! `true` or all correct nodes receive `false`. The output is guaranteed to be a value that was
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//! input by at least one _correct_ node.
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//!
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//! This is used in Subset to decide whether each node's proposal should be included in the subset
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//! or not.
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//!
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//! [**Threshold Sign**](threshold_sign/index.html)
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//!
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//! Each node inputs `()` to broadcast signature shares. Once _f + 1_ nodes have input, all nodes
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//! receive a valid signature. The outcome cannot be known by the adversary before at least one
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//! correct node has provided input, and can be used as a source of pseudorandomness.
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//!
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//! [**Threshold Decrypt**](threshold_decrypt/index.html)
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//!
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//! Each node inputs the same ciphertext, encrypted to the public master key. Once _f + 1_
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//! validators have received input, all nodes output the decrypted data.
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//!
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//! [**Synchronous Key Generation**](sync_key_gen/index.html)
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//!
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//! The participating nodes collaboratively generate a key set for threshold cryptography, such
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//! that each node learns its own secret key share, as well as everyone's public key share and the
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//! public master key. No single trusted dealer is involved and no node ever learns the secret
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//! master key or another node's secret key share.
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//!
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//! Unlike the other algorithms, this one is _not_ asynchronous: All nodes must handle the same
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//! messages, in the same order.
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//!
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//! ## Serialization
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//!
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//! `hbbft` supports [serde](https://serde.rs/): All message types implement the `Serialize` and
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//! `Deserialize` traits so they can be easily serialized or included as part of other serializable
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//! types.
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// We put algorithm structs in `src/algorithm/algorithm.rs`.
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// Some of our constructors return results.
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#![allow(clippy::module_inception, clippy::new_ret_no_self)]
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#![warn(missing_docs)]
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pub use threshold_crypto as crypto;
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mod fault_log;
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mod messaging;
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mod network_info;
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mod traits;
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pub mod binary_agreement;
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pub mod broadcast;
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pub mod dynamic_honey_badger;
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pub mod honey_badger;
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pub mod queueing_honey_badger;
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pub mod sender_queue;
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pub mod subset;
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pub mod sync_key_gen;
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pub mod threshold_decrypt;
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pub mod threshold_sign;
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pub mod transaction_queue;
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pub mod util;
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pub use crate::crypto::pairing;
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pub use crate::fault_log::{Fault, FaultLog};
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pub use crate::messaging::{SourcedMessage, Target, TargetedMessage};
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pub use crate::network_info::{NetworkInfo, ValidatorSet};
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pub use crate::sync_key_gen::{to_pub_keys, PubKeyMap};
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pub use crate::traits::{
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ConsensusProtocol, Contribution, CpStep, Epoched, Message, NodeIdT, SessionIdT, Step,
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};
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