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Bodyless Block Propagation: A Fully Scalable Blockchain with Pre-Validation


Concetti Chiave
The core message of this paper is that the proposed bodyless block propagation (BBP) scheme can improve the transactions per second (TPS) scalability of blockchain systems from O(1/log(N)) to O(1), where N is the number of nodes in the network, without compromising security.
Sintesi

The paper proposes a novel bodyless block propagation (BBP) scheme to address the low transactions per second (TPS) issue in current blockchain systems. The key idea of BBP is that the blockbody is not validated and transmitted during the block propagation process. Instead, nodes in the blockchain network anticipate the transactions and their ordering in the next upcoming block so that these transactions can be pre-executed and pre-validated before the birth of the block. This allows the system to propagate only the block header, making the block propagation time independent of the number of transactions in the block.

The paper first provides a theoretical analysis showing that BBP can improve the TPS scalability from O(1/log(N)) to O(1), where N is the number of nodes in the network. It then discusses the technical challenges in implementing BBP in Ethereum and proposes solutions:

  1. A Time-specific transaction Selection and Ordering (TSO) algorithm to align the transaction selection and ordering at all nodes.
  2. A pre-packed blockbody (PPB) synchronization protocol to ensure nodes have the same PPB.
  3. A pre-validation algorithm to deal with the undetermined Coinbase address of the next block.

The paper also presents experimental results demonstrating that BBP can reduce block propagation time by 4x compared to the current Ethereum blockchain, and its TPS performance is limited by the node hardware performance rather than block propagation.

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Statistiche
The number of transactions in a block (nt) ranges from 100 to 2000. The ratio of non-executable transactions (nu/nt) can be up to 0.4.
Citazioni
"BBP can improve the TPS scalability from O(1/log(N)) to O(1), where N is the number of nodes in the network." "BBP only propagates the block header, ridding the dependence of block propagation speed on the number of transactions in the blockbody."

Approfondimenti chiave tratti da

by Chonghe Zhao... alle arxiv.org 04-04-2024

https://arxiv.org/pdf/2204.08769.pdf
Bodyless Block Propagation

Domande più approfondite

How can the BBP scheme be extended to other blockchain platforms beyond Ethereum?

The BBP scheme can be extended to other blockchain platforms by adapting the key principles and components of BBP to fit the specific architecture and consensus mechanisms of the target platform. Here are some steps to extend BBP to other platforms: Understand the Blockchain Architecture: Analyze the structure and protocols of the target blockchain platform to identify how BBP can be integrated without disrupting the existing functionalities. Modify Transaction Selection and Ordering: Adjust the Time-specific transaction Selection and Ordering (TSO) algorithm to align with the transaction processing mechanisms of the new platform. Implement Pre-Validation: Develop a pre-validation algorithm tailored to the specific requirements and smart contract capabilities of the new platform. Adapt PPB Synchronization: Customize the PPB synchronization protocol to ensure consistency and synchronization of pre-packed blockbodies across nodes in the new platform. Integrate BBP Forwarding Protocol: Incorporate the bodyless block forwarding protocol into the communication and consensus mechanisms of the target platform.

How can the BBP scheme be integrated with other blockchain scalability solutions, such as sharding or layer-2 technologies, to further enhance the overall system performance?

Integrating the BBP scheme with other blockchain scalability solutions can significantly enhance the overall system performance. Here's how BBP can be combined with sharding or layer-2 technologies: Sharding Integration: Transaction Partitioning: Use sharding to divide the network into smaller groups (shards) and apply BBP within each shard to improve TPS scalability. Cross-Shard Communication: Implement mechanisms for efficient communication and validation of cross-shard transactions to ensure consistency and security. BBP within Shards: Apply BBP within each shard to reduce block propagation time and enhance TPS scalability within the sharded network. Layer-2 Technologies Integration: Off-Chain Processing: Utilize layer-2 solutions like state channels or sidechains for off-chain transaction processing, reducing the on-chain load and enhancing TPS. BBP for On-Chain Settlement: Use BBP for on-chain settlement of transactions that have been processed off-chain, optimizing block propagation time and validation efficiency. Smart Contract Interaction: Enable seamless interaction between layer-2 solutions and BBP for secure and efficient smart contract execution across layers. By integrating BBP with sharding or layer-2 technologies, blockchain platforms can achieve enhanced scalability, improved transaction throughput, and optimized performance while maintaining security and decentralization.

What are the potential security implications of the BBP scheme, and how can they be addressed?

The BBP scheme introduces several security implications that need to be addressed to ensure the integrity and trustworthiness of the blockchain network. Here are some potential security considerations and mitigation strategies: Transaction Consistency: Ensuring that all nodes have the same set of transactions in the pre-packed blockbody is crucial for consensus. Implement robust synchronization protocols to prevent discrepancies. Pre-Validation Vulnerabilities: Pre-validating transactions before block mining can expose the network to potential attack vectors. Employ rigorous validation checks and consensus mechanisms to prevent malicious transactions. Coinbase Transaction Risks: Handling Coinbase transactions during pre-validation poses challenges due to the unknown miner address. Develop algorithms to identify and validate transactions dependent on the Coinbase address securely. Network Attacks: BBP may be susceptible to network-level attacks that disrupt block propagation. Implement encryption, authentication, and secure communication protocols to mitigate network vulnerabilities. Smart Contract Security: As BBP involves executing transactions in advance, ensure that smart contracts are audited for vulnerabilities and adhere to best practices to prevent exploits and attacks. By addressing these security implications through robust protocols, encryption mechanisms, consensus algorithms, and thorough validation processes, the BBP scheme can maintain the security and resilience of the blockchain network.
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