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wanderer🌟 / js-dfinity-radix-tree



Tree: ad9db87c1c97950a008f8f2e0ea3d81cf300cf06

Files: ad9db87c1c97950a008f8f2e0ea3d81cf300cf06 / README.md

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NPM Package
Build Status
Coverage Status

js-standard-style

install

npm install merkle-radix-tree

SYNOPSIS

This implements a binary merkle radix tree. The point of using a binary radix tree is that it generates smaller proof size then trees with larger radixes. This tree is well suited for storing large dictonaries of fairly random keys. If the keys are not random better performance can be achived by hashing them first. It builds on top of ipld-graph-builder
and the resulting state and proofs are generated using it.

INSTALL

npm install merkle-radix-tree

USAGE

const IPFS = require('ipfs')
const RadixTree = require('merkle-radix-tree')

// start ipfs
const node = new IPFS({
  start: false,
  repo: './ipfs-repo'
})

node.on('ready', async () => {
  const prover = new RadixTree({
    dag: node.dag
  })

  // set some values
  await prover.set('test', 'value')
  await prover.set('doge', 'coin')
  await prover.set('cat', 'dog')
  await prover.set('monkey', 'wrench')

  // create a merkle root and save the tree
  const merkleRoot = await prover.flush()

  // start a new Instance with the root
  const verifier = new RadixTree({
    dag: node.dag,
    root: merkleRoot
  })

  // gets the merkle proof from ipfs-js and returns the result
  const val = await verifier.get('monkey')
  console.log(val)
})

API

'./docs/'

SPEC

'./docs/spec.md'

BENCHMARKS

The result of the benchmarks show that the binary radix tree produces proofs on average %67 small then the Ethereum Trie with 100000 keys stored.

'./benchmarks/benchmarks.md'

TESTS

npm run tests

LICENSE

MPL-2.0)

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