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E2E Latency Comparison Benchmark

This benchmark measures E2E Latency across several blockchains. The numbers produced by the benchmark represent an end user’s observed latency from submitting a transaction to getting a transaction confirmation back. We compared the latency of coin transfer transactions across multiple blockchain networks in their mainnet environments. Coin transfer is a straightforward and cost-effective transaction type that is widely supported by SDKs.

The benchmark leverages TS SDKs for the respective blockchains. The logic of 'Coin transfer' transaction for a blockchain is present in the corresponding 'index.js' file. Some common helper functions are present in 'common.js'.

To collect metrics we are using a timeseries database that supports the prometheus remote_write protocol: https://prometheus.io/docs/concepts/remote_write_spec/.

Prerequisites

  • Using a wallet (or client), setup Web3 accounts on the corresponding blockchain(s).
  • Add funds necessary for gas fees and the actual p2p transfer.
  • You will need the private and public keys of the web3 accounts. Be careful not to expose the private keys of the accounts!
  • [Optional] If metrics collection is desired then, a timeseries database that supports prometheus remote_write protocol or something similar will have to be set up.

Install

  • Install Node.js and npm
  • Copy index.js, common.js and package.json to a folder
  • Install the required dependecies. Some examples are: npm i @aptos-labs/ts-sdk npm i @solana/web3.js npm i near-api-js npm i axios

Run an e2e test of the script locally

Pass the env variables and run using node. Some examples are below:

  • Aptos: PING_INTERVAL=900 CHAIN_NAME=mainnet METRICS_URL=<url> METRICS_AUTH_TOKEN=<token> METRICS_TAG=<tag> ACC1_PRIVATE_KEY=<priv_key_sender> ACC2_PRIVATE_KEY=<priv_key_receiver> node index.js
  • Solana: PING_INTERVAL=900 CHAIN_NAME=mainnet-beta METRICS_URL=<url> METRICS_AUTH_TOKEN=<token> METRICS_TAG=<tag> ACC1_PRIVATE_KEY=<priv_key_sender> ACC2_PRIVATE_KEY=<priv_key_receiver> COMMITMENT_LEVEL=confirmed node index.js
  • ETH_BASED_CHAINS (Optimism): PING_INTERVAL=900 CHAIN_NAME=mainnet METRICS_URL=<url> METRICS_AUTH_TOKEN=<token> METRICS_TAG=<tag> COIN_TRANSFER_LATENCY_METRIC_NAME=e2e_p2p_txn_latency_optimism ACC1_PRIVATE_KEY=<priv_key_sender> ACC1_ADDR=<public_addr_sender> ACC2_ADDR=<public_addr_receiver> URL=https://mainnet.optimism.io TRANSFER_AMT=<amt> node index.js
  • NEAR: PING_INTERVAL=900 CHAIN_NAME=mainnet METRICS_URL=<url> METRICS_AUTH_TOKEN=<token> METRICS_TAG=<tag> ACC1_PRIVATE_KEY=<priv_key_sender> ACC1_ID=<public_addr_sender> ACC2_ID=<public_addr_receiver> URL=https://rpc.mainnet.near.org node index.js
  • SUI: PING_INTERVAL=900 CHAIN_NAME=mainnet METRICS_URL=<url> METRICS_AUTH_TOKEN=<token> METRICS_TAG=<tag> ACC1_PRIVATE_KEY=<private-key> URL=https://fullnode.testnet.sui.io:443 node index.js

Note: Some env variables are optional, and env variables needed might change based on the script

Smart Contract

Using the *.move and Move.toml build and deploy the smart contract on the CLI by following steps in the documentation of the blockchain.

Benchmark Results

Live E2E Latency Numbers are displayed here.

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