Explained: The Snax Trustless Authentication Protocol

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The fundamental technology that allows Snax to operate is the binding of the blockchain transactions together with accounts on the social media platforms such as Twitter, Reddit and so on.

Snax blockchain allows you to send transactions to any account name on any public platform integrated into Snax without prior invoicing from the recipient (we call those Social Transactions).

You can be certain that the transaction will reach the recipient without having to rely on a centralized third party (apart, of course, from the social platform itself). This article will explain how Snax Trustless Authentication Protocol works using the example of authentication of the Twitter account.

Don’t trust. But Verify.

This is the main principle of building an open cryptographic system, including blockchain systems.

The authentication solutions built using oAuth 2.0, for example, OpenID connect, work very well with centralized servers, however, it can be hard to implement them in decentralized systems.

These systems are designed to solve a particular problem of when a user (client) needs to get authorized with a certain service (centralized server). However, with blockchain based system authentication and authorization of any user must be verifiable not by one server, but by an outside observer (third party) at any moment of time.

Snax Trustless Authentication Protocol provides solutions to the following problems:

  1. Authentication of users from any public platform on the Snax blockchain.
  2. Presentation of proof of user authentication to any third party at any time.
  3. Completion of any subsequent authentications using Snax account without the participation of the public platform.

Step 1. Authentication.

Take Twitter as an example of an online public platform (Twitter will come integrated into Snax blockchain at the time of main net launch).

Let’s assume that you have a Twitter account and that you want to complete authentication in the Snax blockchain using that account. Authentication will be done using the following algorithm:

  1. Client (user) generates a pair of keys (priv_key, pub_key).
  2. Client selects any unassigned account name (snax_name) on the Snax blockchain (snax_name account will be registered on the blockchain).
  3. Client generates a key (K).
  4. Client calculates a hash function
    H(K, snax_name)=hmac_sha256 (K || hmac_sha256 (K || snax_name))
  5. Client publishes received hash H by creating a tweet from their Twitter account, acknowledging their intent to complete authentication on the Snax blockchain.
  6. Client sends the following information to an oracle:
    – Pair (K, snax_name)
    – Their pub_key, for which the account name snax_name will be registered.
    – Their account name N on Twitter and a link to the authentication tweet (optional, as the authentication tweet can be found by the oracle on the feed using Twitter API)
  7. The Oracle then calculates your hash H and compares it with the hash, found in authentication tweet. If the hashes are identical, the Oracle considers the authentication process to be completed.
  8. Oracle calls on the registration method of the Twitter platform smart contract with arguments of (K, snax_name, pub_key, N, L).
  9. The Twitter platform smart contract then registers account snax_name with the public key pub_key and adds information to the blockchain about successful authentication of a twitter user N, a public key K, and a link L.
Snax authentication process

Step 2. Proof.

It is now essential to explain why the third party might not trust a centralized oracle which has completed the authentication of the user.

Let us consider the following possibilities of a vector attack:

  1. Oracle being compromised.
  2. Forgery of a user’s authentication request by an intruder.

Main defense against this attacks comes from the impossibility of brute forcing the incoming data (K, snax_name) which would satisfy the authentication hash H.

Because the authentication tweet, which contains hash H, is published on Twitter by the owner of the twitter account, an intruder does not have an ability to generate a valid pair (K, snax_name), apart from the one which was provided by the actual owner of the account.

This way, any third party, at any moment of time, can verify the authentication by the owner of the Twitter account N using the following algorithm:

  1. Take the embedded into the blockchain pair about the authentication of the user (K, snax_name).
  2. Generate hash H(K, snax_name).
  3. Go to the published link L.
  4. Verify that the account which has published the tweet L indeed belongs to the account of the user N.
  5. Check the presence of hash H in the tweet L.If the hash is found, then the user authentication is valid.

Step 3. Using Snax account as an authenticator.

Now, that the authentication of a user can be proven, the name of the blockchain account snax_name can be subsequently used as an authenticator of the user of Twitter N. For example, Snax blockchain uses snax_name of the account N for the emission of the SNAX tokens.

This process would also make it possible to create a transaction to any account of the public network, integrated into Snax platform, without a prior invoicing by the recipient. Platforms smart contract will automatically complete the transaction to the snax_name from which the authentication of the receiver has been completed. If the authentication has not yet been finalized, then platform smart contract will wait for its completion to perform the transaction.

Conclusion

We have looked at how the Snax Trustless Authentication Protocol works on a macro level.

Of course, the act of publication of authentication message (e.g. tweet) can cause an inconvenience for the user, however, we do not yet see any reliable alternative technology for creating a trustless authentication.

This inconvenience can be solved by integrating the Snax Trustless Authentication Protocol (or the similar protocol) in API of the existing social networks. It is not a complicated process in general, however, it does require the platform to create a public authentication API available for a third party request.

If you have questions about how Snax emission works, how to receive publisher rewards, or about how to become a block producer for Snax network, feel free to join us in our Discord at https://discord.gg/qygxJAZ. Don’t forget to follow us on Twitter and to clap for this post!

Also, you can find answers to frequent questions here https://snax.one/faq.


Explained: The Snax Trustless Authentication Protocol was originally published in Hacker Noon on Medium, where people are continuing the conversation by highlighting and responding to this story.

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