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Nezha: Deployable and High-Performance Consensus Using Synchronized Clocks

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Nezha


Nezha (哪吒) is a legendary figure in Chinese mythology. Nezha has 3 heads and 6 arms, so he/she achieves much better fault tolerance than ordinary people :)

PS: We have created [an FAQ page]. Please take a look for a better understanding of Nezha.

Paper and Presentation

Nezha: Deployable and High-Performance Consensus Using Synchronized Clocks (VLDB version) [pdf]

Nezha: Deployable and High-Performance Consensus Using Synchronized Clocks(Technical Report) [pdf]

An early presentation of Nezha was made at Stanford Platform Lab Winter Review 2022 [slides]

If you find our work helpful to your research or project, we would very appreciate it if you could add a star to our repo and/or cite our papers. The bibs for the papers are as below.

@article{vldb23-nezha,
author = {Geng, Jinkun and Sivaraman, Anirudh and Prabhakar, Balaji and Rosenblum, Mendel}, 
title = {Nezha: Deployable and High-Performance Consensus Using Synchronized Clocks},
year = {2023},
journal = {Proceedings of the VLDB Endowment},
url = {https://www.vldb.org/pvldb/vol16/p629-geng.pdf},
publisher = {VLDB Endowment},
issn = {2150-8097},
volume = {16},
pages = {629-642},
numpages = {14}
}

@misc{nezha-tech,
  author = {Geng, Jinkun and Sivaraman, Anirudh and Prabhakar, Balaji and Rosenblum, Mendel},
  title = {Nezha: Deployable and High-Performance Consensus Using Synchronized Clocks},
  doi = {10.48550/ARXIV.2206.03285},
  url = {https://arxiv.org/abs/2206.03285},
  publisher = {arXiv},
  year = {2022},
}

Clone Project

git clone --depth=1 https://github.com/Steamgjk/Nezha.git

File Structure

The core part includes three modules (folders), i.e.,

  • replica
  • proxy
  • client

Each module is composed of three files:

  • a header file (e.g., replica.h),
  • a source implementation file (replica.cc),
  • a launching file (e.g., replica_run.cc).

Each process reads an independent yaml file (e.g., nezha-replica-config-0.yaml) to get its full configuration, the sample configuration files are placed in the configs folder

Install Bazel

We use Bazel 5.2.0 for building Nezha.

# Install bazel 5.2.0
# Please follow the instructions at https://bazel.build/install/ubuntu#install-on-ubuntu, 
# or simply run the following commands

sudo apt install -y apt-transport-https curl gnupg
curl -fsSL https://bazel.build/bazel-release.pub.gpg | gpg --dearmor >bazel-archive-keyring.gpg
sudo mv bazel-archive-keyring.gpg /usr/share/keyrings
echo "deb [arch=amd64 signed-by=/usr/share/keyrings/bazel-archive-keyring.gpg] https://storage.googleapis.com/bazel-apt stable jdk1.8" | sudo tee /etc/apt/sources.list.d/bazel.list
sudo apt update
sudo apt install -y bazel-5.2.0
sudo mv /usr/bin/bazel-5.2.0 /usr/bin/bazel
bazel --version

Build Nezha with Bazel

Since Bazel is becoming popular, we have migrated nezha from Makefile-based building system to the bazel building system. The bazel version in use is 5.2.0

cd Nezha && bazel build //replica/... //client/... //proxy/...

After building the project successfully, the executable files will be generated in the folder named bazel-bin

Single-Machine Tests

Please refer to the single-machine instructions to run Nezha under various scenarios (view change, request commit, recovery from failure of replica).

Multi-Machine Tests

We use scripts/launch.py to conduct distributed tests across multiple machines. After the tests have completed, scripts/analysis.py is used to analyze the results to generate performance numbers. The current scripts only support Google Cloud Platform (GCP). They require GCP credentials to create and delete VMs on GCP.

Important Configuration Parameters

Replica

  • replica-ips must include 2f+1 ips
  • replica-id starts from 0 to 2f
  • index-transfer-batch, request-key-transfer-batch, request-transfer-batch. The values of the three batch parameters should be carefully chosen in order not to overflow the maximum size of UDP packets.

Clients

  • We support two types of clients, i.e., open-loop clients and closed-loop clients.
  • Open-loop clients generate requests according to a Poisson process configured with a specific rate.
  • Closed-loop clients use a sliding window protocol to keep a fixed number of requests in flight at any given time, release a new request when an old one is completed.
  • is-openloop: When this flag is true, --poission-rate becomes meaningful.
  • skew-factor and key-number decides the workload, which further affects the commutativity optimization

Proxy

  • shard-num decides how many threads will be launched. 1 shard includes 1 forwarding thread to forward client requests to replicas and 1 replying thread to receive and replies from replicas and does quorum check
  • max-owd is used in the clamping function to estimate one-way delay, more details are described in Sec 4 [Adpative latency bound] of the paper.

Performance Benchmark

Refer to our paper for the relevant performance stats. Compared with the experimental version, we have refactored the codebase with some higher-performance libraries (e.g. libev instead of libevent) and data structures (e.g., ConcurrentMap and ConcurrentQueue). Besides, we have also conducted further optimization with the pipeline. The performance will be somewhat better than the original version used in the paper. New benchmark data will be updated soon.

Authors and Acknowledgment

Nezha project is developed and maintained by Jinkun Geng and his three supervisors, i.e., Prof. Anirudh Sivaraman, Prof. Balaji Prabhakar and Prof. Mendel Rosenblum.

We are fortunate to get the help from many researchers during the development of Nezha. Below we list and acknowledge them according to the timeline.

Dr. Shiyu Liu and Dr. Feiran Wang joined the discussion during the early design of Nezha. Feiran explained the details of CRaft and the related correctness properties. Shiyu explained the principles of Huygens and the other clock sync solutions.

Prof. Dan Ports, Prof. Jialin Li and Dr. Ellis Michael provided helpful discussion related to Speculative Paxos and NOPaxos. Dan also gave us the pointer to crash vector and diskless recovery.

Prof. Jinyang Li listened to our early presentation of Nezha, and gave some useful feedback.

Prof. Seo Jin Park discussed with us about the definition of linearizability and other correctness properties. Seo Jin also provided some explanation about CURP.

Prof. Zhaoguo Wang shared with us his experience in testing Raft.

The Derecho team (Prof. Ken Birman, Dr. Weijia Song, Dr. Sagar Jha, Dr. Lorenzo Rosa, etc) offered technical support and discussion during our measurement of Derecho.

The ClockWork Staff (Dr. Yilong Geng and Dr. Deepak Merugu) offered technical support in deploying Huygens. Dr. Deepak Merugu also gave suggestions on the coding-styles of Nezha codebase. Katie Gioioso provided feedback on Nezha design. Bhagirath Mehta participated in the single-machine test of Nezha.

Prof. Eugene Wu provided suggestions on the revision of Nezha paper.

Prof. Aurojit Panda discussed with us about Nezha's correctness during leader change. Aurojit reviewed our draft and offered some constructive suggestions on the revision.

The Raft community offered much insightful discussion for us. Many community members discussed with us and helped to justify our design decisions about Nezha.

License

Please refer to license.md

Future Plan

(1) Conduct more functionality and performance tests to make Nezha more robust and optimized

(3) Replace the etcd backend for Kubenetes to boost the performance of Kubenetes.

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