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BEP-341: Validators can produce consecutive blocks #341

120 changes: 120 additions & 0 deletions BEPs/BEP-341.md
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<pre>
BEP: 341
Title: Validators can produce consecutive blocks
Status: Draft
Type: Standards
Created: 2023-09-27
Discussions(optional): https://forum.bnbchain.org/t/bep-idea-validators-can-produce-consecutive-blocks/2052
</pre>

# BEP-341: Validators can produce consecutive blocks

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- [BEP-341: Validators can produce consecutive blocks](#bep-341-validators-can-produce-consecutive-blocks)
- [1. Summary](#1-summary)
- [2. Abstract](#2-abstract)
- [3. Motivation](#3-motivation)
- [4. Specification](#4-specification)
- [4.1 Scaling Principle](#41-scaling-principle)
- [4.2 Implementation Specification](#42-implementation-specification)
- [4.2.1 Priority Allocation](#421-priority-allocation)
- [4.2.2 Validator Set Switch](#422-validator-set-switch)
- [4.2.3 Block Avoidance](#423-block-avoidance)
- [4.2.4 Governable Number of Consecutive Blocks](#424-governable-number-of-consecutive-blocks)
- [4.2.5 Combatting MEV](#425-combatting-mev)
- [5. Incentive Fairness Analysis](#5-incentive-fairness-analysis)
- [6. Security Analysis](#6-security-analysis)
- [7. Liveness Analysis](#7-liveness-analysis)
- [8. License](#8-license)

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## 1. Summary
Each epoch in BSC consists of multiple slots, and a batch of validators take turns in a predefined order to obtain priority block-producing rights for each slot. This BEP proposes an adjustment to the allocation of priority block-producing rights: each validator receives priority block-producing rights for a predetermined number of consecutive slots per round.
## 2. Abstract
BEP-341 describes a new allocation method for priority block-producing rights, which is logically concise and significantly enhances the system's transaction processing capacity, while remaining orthogonal to transaction processing optimization techniques within blocks.
## 3. Motivation
The BSC ecosystem is active and continuously evolving, requiring ongoing improvements to the system's transaction processing capacity.
## 4. Specification
### 4.1 Scaling Principle
Currently, each validator obtains priority block-producing rights for a single slot and is then rotated, with a fixed block interval of t. The transaction processing limit is t/2 for validating transactions from the previous block and t/2 for processing transactions in the new block.
<div align="center">
<img src=./assets/bep-341/4.1-1.png width=60% />
</div>
Assuming the number of transactions that can be processed is T, the average TPS is calculated as follows:
<div align="center">
<img src=./assets/bep-341/4.1-2.png width=18% />
</div>
After implementing this BEP, each validator can obtain priority block-producing rights for a continuous sequence of n slots in one round. The first block they process still allocates t/2 for validating transactions from the previous block and t/2 for processing transactions in the new block. However, subsequent blocks can skip the transaction validation process and focus on processing transactions in the new block. It is recommended that the processing time for the last block in their current round be only half of the time required to process transactions in the new block. This helps avoid the situation where the first block processed by the next validator is close to being an empty block.
<div align="center">
<img src=./assets/bep-341/4.1-3.png width=60% />
</div>
The TPS after continuous block production is as follows:
<div align="center">
<img src=./assets/bep-341/4.1-4.png width=50% />
</div>
Therefore, the TPS improvement rate is:
<div align="center">
<img src=./assets/bep-341/4.1-5.png width=40% />
</div>
The relationship between the number of continuous blocks produced and TPS improvement is
<div align="center">
<img src=./assets/bep-341/4.1-6.png width=60% />
</div>
As shown in the graph, it is evident that continuous block production cannot double the TPS. There is no benefit when n<3, and increasing n beyond 5 does not proportionally increase the benefits. Therefore, a value within the range [3, 5] is suitable for n; when n=4, r=50%.

### 4.2 Implementation Specification
#### 4.2.1 Priority Allocation
Each epoch predefines a set of validators, with a total of validatorN validators, and each validator within the set has a unique index ranging from [0, validatorN). If the current block height is blockN, then the validators with the following indices obtain priority block-producing rights.
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<div align="center">
<img src=./assets/bep-341/4.2.1.png width=36% />
</div>

#### 4.2.2 Validator Set Switch
Each epoch will choose a new validator set, assuming an epoch contains epochSlots slots. The validator set switch occurs only when the block height reaches Bswitch to prevent epoch block forging. The calculation of Bswitch is as follows:
<div align="center">
<img src=./assets/bep-341/4.2.2.png width=56% />
</div>

#### 4.2.3 Block Avoidance
To prevent fewer than 1/2 of the nodes from controlling the entire network, block producers are required to produce fewer than n blocks within the previous ((validatorN/2+1)\*n-1) historical blocks.


#### 4.2.4 Governable Number of Consecutive Blocks
When n=1, it is equivalent to disabling the feature of consecutive block production, while significant optimization is observed when n belongs to the range [3,5]. Currently, the range for the value of n is set to [1,9] but except 2.

The initial value of n is 1, and changing its value requires the BSC governance process.

#### 4.2.5 Combatting MEV
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As the consecutive period in which a single validator gains priority in block production extends, it may facilitate MEV extraction, potentially leading validators to include more transactions in the later blocks they consecutively produce. To constrain validators to promptly package transactions, within a validator's consecutive priority over n blocks, the transaction fees' split to the SystemRewardContract will increase linearly with block number, capped at the value denoted as systemRewardAntiMEVRatio.
Respectively, the split ratio remains at systemRewardBaseRatio when continuous block production is disabled. Once continuous block production is enabled (i.e., when n > 1), the systemRewardRatio is calculated as:
<div align="center">
<img src=./assets/bep-341/4.2.5-1.png width=150% />
</div>
as shown in the following picture:
<div align="center">
<img src=./assets/bep-341/4.2.5-2.png width=75% />
</div>

The initial value of systemRewardAntiMEVRatio is 0, and changing its value also requires the BSC governance process.

## 5. Incentive Fairness Analysis
Within a single epoch, tail validators have fewer block-producing opportunities, but the allocation of priority rights is unbiased and cannot be manipulated. Therefore, from a statistical perspective, it is fair.

If a validator tries to extract more MEV by placing more transactions in later blocks they produce, it will also increase user transaction confirmation times. To curb this, the systemRewardAntiMEVRatio can be raised through the governance process, which will increase the proportion of transaction fees allocated to the SystemRewardContract. These bonuses will be distributed as Fast Finality voting rewards to validators, keeping their overall benefits unchanged. However, during high traffic and transaction backlog, high-performance validators usually handle more transactions. These changes will reduce the income advantage of having high performance.

## 6. Security Analysis
This BEP relies on BSC's Fast Finality feature. If Fast Finality fails, it may result in the following issues:
1. Nodes intentionally hide mined blocks, potentially leading to longer short-term reorganizations.
2. The probability of finality for transactions increases, requiring waiting for 2/3\*validatorN\*n+ blocks.

## 7. Liveness Analysis
The liveness of the chain remains unchanged, meaning it is required to ensure that at least (validatorN/2+1) validators are active. The proof is as follows:

If (validatorN/2+1) validators are active and none are allowed to produce blocks at a certain moment, each validator must have produced at least n blocks in the past ((validatorN/2+1)\*n-1) blocks. Thus, collectively, at least (validatorN/2+1)\*n blocks must have been produced, which is impossible. Therefore, at any moment, at least one of the (validatorN/2+1) validators must be allowed to produce blocks.

## 8. License
The content is licensed under [CC0](https://creativecommons.org/publicdomain/zero/1.0/).
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3 changes: 2 additions & 1 deletion README.md
Original file line number Diff line number Diff line change
Expand Up @@ -62,9 +62,10 @@ Here is the list of subjects of BEPs:
| [BEP-322](./BEPs/BEP322.md) | Builder API Specification for BNB Smart Chain | Standards | Enabled |
| [BEP-323](./BEPs/BEP323.md) | Bundle Format for Greenfield | Standards | Enabled |
| [BEP-333](./BEPs/BEP333.md) | BNB Chain Fusion | Standards | Enabled |
| [BEP-334](./BEPs/BEP-334.md) | Greenfield CrossChain Permission Module | Standards | Draft |
| [BEP-334](./BEPs/BEP-334.md) | Greenfield CrossChain Permission Module | Standards | Enabled |
| [BEP-335](./BEPs/BEP-335.md) | Greenfield Simplify Storage Provider Exit | Standards | Enabled |
| [BEP-336](./BEPs/BEP-336.md) | Implement EIP-4844: Shard Blob Transactions | Standards | Enabled |
| [BEP-341](./BEPs/BEP-341.md) | Validators can produce consecutive blocks | Standards | Candidate |
| [BEP-342](./BEPs/BEP-342.md) | Implement EIP-5656: MCOPY | Standards | Enabled |
| [BEP-343](./BEPs/BEP-343.md) | Implement EIP-1153: Transient storage opcodes | Standards | Enabled |
| [BEP-344](./BEPs/BEP-344.md) | Implement EIP-6780: SELFDESTRUCT only in same transaction | Standards | Enabled |
Expand Down