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Namespaced Merkle Tree (NMT)

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A Namespaced Merkle Tree is

[...] an ordered Merkle tree that uses a modified hash function so that each node in the tree includes the range of namespaces of the messages in all of the descendants of each node. The leafs in the tree are ordered by the namespace identifiers of the messages. In a namespaced Merkle tree, each non-leaf node in the tree contains the lowest and highest namespace identifiers found in all the leaf nodes that are descendants of the non-leaf node, in addition to the hash of the concatenation of the children of the node. This enables Merkle inclusion proofs to be created that prove to a verifier that all the elements of the tree for a specific namespace have been included in a Merkle inclusion proof.

The concept was first introduced by @musalbas in the LazyLedger academic paper.

Example

package main

import (
    "bytes"
    "crypto/sha256"
    "fmt"

    "github.com/celestiaorg/nmt"
    "github.com/celestiaorg/nmt/namespace"
)

func main() {
    // the tree will use this namespace size (number of bytes)
    nidSize := 1
    // the leaves that will be pushed
    data := [][]byte{
      append(namespace.ID{0}, []byte("leaf_0")...),
      append(namespace.ID{0}, []byte("leaf_1")...),
      append(namespace.ID{1}, []byte("leaf_2")...),
      append(namespace.ID{1}, []byte("leaf_3")...)}
    // Init a tree with the namespace size as well as
    // the underlying hash function:
    tree := nmt.New(sha256.New(), nmt.NamespaceIDSize(nidSize))
    for _, d := range data {
      if err := tree.Push(d); err != nil {
        panic(fmt.Sprintf("unexpected error: %v", err))
      }
    }
    // compute the root
    root, err := tree.Root()
    if err != nil {
      panic(fmt.Sprintf("unexpected error: %v", err))
    }
    // the root's min/max namespace is the min and max namespace of all leaves:
    minNS := nmt.MinNamespace(root, tree.NamespaceSize())
    maxNS := nmt.MaxNamespace(root, tree.NamespaceSize())
    if bytes.Equal(minNS, namespace.ID{0}) {
      fmt.Printf("Min namespace: %x\n", minNS)
    }
    if bytes.Equal(maxNS, namespace.ID{1}) {
      fmt.Printf("Max namespace: %x\n", maxNS)
    }

    // compute proof for namespace 0:
    proof, err := tree.ProveNamespace(namespace.ID{0})
    if err != nil {
      panic("unexpected error")
    }

    // verify proof using the root and the leaves of namespace 0:
    leafs := [][]byte{
      append(namespace.ID{0}, []byte("leaf_0")...),
      append(namespace.ID{0}, []byte("leaf_1")...),
    }

    if proof.VerifyNamespace(sha256.New(), namespace.ID{0}, leafs, root) {
      fmt.Printf("Successfully verified namespace: %x\n", namespace.ID{0})
    }

    if proof.VerifyNamespace(sha256.New(), namespace.ID{2}, leafs, root) {
      panic(fmt.Sprintf("Proof for namespace %x, passed for namespace: %x\n", namespace.ID{0}, namespace.ID{2}))
    }
}

The above will create a Namespaced merkle tree with four leafs which looks like this:

example

Where nid_0 = nid_1 = 0 and nid_2 = nid_3 = 1 and data_i = "leaf_i" for i = 0,...,3.

Related

This implementation was heavily inspired by the initial implementation in celestiaorg/lazyledger-prototype.

Non-endorsed implementations of NMT exist in other languages:

Language Repo
Rust Sovereign-Labs/nmt-rs

Contributing

Markdown files must conform to GitHub Flavored Markdown. Markdown must be formatted with:

Audits

Date Auditor Report
2023/8/18 Informal Systems informal-systems.pdf