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Efficient reusable Taproot addresses

Reusable taproot addresses

Abstract

This document proposes a new scheme to avoid address reuse while retaining some of the convenience of address reuse, keeping recoverability purely from Bitcoin time chain and avoiding visible fingerprint. The scheme has negligible average overhead.

Motivation

Address reuse is one of the most horrible things people can do for privacy. However, the convenience can not be ignored and human beings are therefore incentivized to reuse addresses. This is especially the case in long-term business relationships, when it's convenient to avoid roundtrip of generating a new address.

There are existing schemes that tried to address this issue:

  • Stealth addresses - they used ECDH to generate a new address for a new transaction putting ephemeral public keys in OP_RETURN outputs As a result they had significant overhead and visible footprint. Nonetheless their version is being used in Monero.
  • Reusable payment codes (BIP 47) - a slight improvement over Stealth addresses. While they only require special transaction for initialization, subsequent transactions being free from overhead and visible fingerprint, the initial transaction must happen before real business activity and it produces effectively toxic change that may be difficult to handle. The initial transaction has no value besides providing convenient privacy. An alternate version proposed sending the required data over Bitmessage. This solved the problem with cost and footprint but introduced inability to recover coins purely from seed. In other words, the key received over bitmessage has to be backed up for every counterparty. Further, it requires yet another protocol that is not widely used.

This document proposes to solve the size/footprint issues of BIP 47 without losing the ability to recover from seed even if one of the parties is unavailable.

Construction

Initial transaction

Similarly to BIP 47, this scheme uses a notification transaction. However unlike BIP 47, the notification transaction is also a "real" transaction. It is the transaction performed when the parties conduct business for the first time using this scheme. The sender of notification transaction MUST be spending at least one input of one of these types:

  • P2PK
  • P2PKH
  • P2SH-P2WPKH
  • P2WPKH
  • P2TR

The sender MUST be capable of receiving to Taproot. The receiver MUST use Taproot for receiveing. (In principle, P2PK could be used instead of Taproot but such would be very unusual and thus suspicious.) The transacting parties MAY use PayJoin but MUST NOT involve a third party in it.

When using this scheme, the sender MUST generate a change using the following algorithm.

  1. Select an input with lowest index, belonging to the sender, being one of the types listed above. Let's call it sender key input.
  2. Let p_sender be the private key associated with sender key input.
  3. Let P_receiver be the Taproot address used by the receiver.
  4. Calculate shared_secret = SHA256(p_sender*P_receiver) (ECDH)
  5. Calculte offset = HMAC(shared_secret, CHANGE_KEY_CONSTANT) where CHANGE_KEY_CONSTANT is an arbitrary constant defined by the protocol
  6. Calculate P_change = (offset + p_sender)*G
  7. Calculate and securely cache relationship_seed = HMAC(shared_secret, RELATIONSHIP_SEED_CONSTANT) where RELATIONSHIP_SEED_CONSTANT is an arbitrary constant defined by the protocol that MUST NOT be equal to CHANGE_KEY_CONSTANT
  8. Use P_change in the change output script

The receiver watches the address and reacts to received transaction by performing this check:

  1. Select an input with lowest index, not belonging to the receiver, being one of the types listed above - the sender key input.
  2. Let P_sender be the public key associated with sender key input.
  3. Let p_receiver be the private key associated with Taproot address used by the receiver.
  4. Calculate shared_secret = SHA256(P_sender*p_receiver) (ECDH)
  5. Calculte offset = HMAC(shared_secret, CHANGE_KEY_CONSTANT)
  6. Calculate P_change = offset*G + P_sender
  7. Check that P_change matches the key used in change.
  8. If the key doesn't match, don't continue
  9. Calculate relationship_seed = HMAC(shared_secret, RELATIONSHIP_SEED_CONSTANT) and cache it securely
  10. Precompute a reasonably large number of offsets using a cryptographically secure PRNG seeded by relationship_seed
  11. For each offset compute P_i = (offset_i + p_receiver) * G
  12. Start watching the chain for incoming transactions on public keys generated above

Repeated sending

Each time the sender wishes to send to the receiver he computes P_i = offset_i * G + P_receiver, where offset_i denotes a random nonce generated by same PRNG mentioned in step 9 above. The sender then sends coins to P_i. The receiver has these addresses and private keys pre-cached so he can easily identify incoming transaction and spend the associated coins whenever needed.

Recovery

Sender

In case of data loss, the sender recovers the history, coins and relationships using this algorithm:

  1. Scan the chain for all transactions associated with BIP32 addresses
  2. Every time a transaction is found which cointains at least two Taproot outputs that don't match any of the BIP32 addresses perform the following
  3. For each output attempt to repeat the algorithm above deriving the shared_secret and the change output and check if the change output matches one of the outputs in the transaction
  4. If match was found precompute offsets and the associated addresses and add them with the change output to the list of scanned addresses.

Receiver

  1. Scan the chain for all transactions associated with BIP32 addresses
  2. Every time a transaction is found which contains at least one additional Taproot output, attempt to recompute shared_secret and check if any of the outputs matches expected change
  3. If a match is found, precompute the offsets and add the corresponding keys to the list of scanned addresses.

Conclusion

As can be seen from the above, the notification transaction looks like a regular transaction. Since the outside observers can not compute shared_secret (assuming ECDH is secure), they can not determine whether this protocol is being used nor compute the following addresses. The protocol has same advantages over Stealth addresses as BIP 47, but in addition, the notification transactions can not be identified by outside parties, the changes are not neccessarily that toxic (mixing is obviously still recommended) and the overhead is generally lower.

While it may seem that the overhead is zero, it's not exactly the case. The overhead of notification transaction over not using this protocol is:

  • The contruction requires Taproot which is on average a little bit larger than P2WPKH.
  • Skipping the change output in the rare cases when it wouldn't be needed (sufficient UTXO available) is not possible.
  • Tricks using PayJoin to open a Lightning channel or participate in other contracts are not possible or require additional output.
  • Opening a Lightning channel with the change or sending the change to someone else is impossible.
  • Batching several notification transactions produces a change output for each receiver. On the bright side, this can be used to simulate Samourai-style Stonewall, getting a bit more privacy for the added fee.

It can be argued that until various batching tricks become widely used this overhead is small.

@Kixunil
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Kixunil commented Mar 10, 2022

@w0xlt perfect, would you be up for making it into a library?

@w0xlt
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w0xlt commented Mar 11, 2022

Done !
https://github.com/w0xlt/reusable-taproot-addresses

To use the lib (example):

Cargo.toml

[package]
name = "test-lib"
version = "0.1.0"
edition = "2021"

[dependencies]
reusable_taproot_addresses = { git = "https://github.com/w0xlt/reusable-taproot-addresses.git" }
secp256k1 = { git = "https://github.com/rust-bitcoin/rust-secp256k1.git", rev = "39e47fb64", features = [ "rand-std", "bitcoin_hashes", "std" ] }
bech32 = "0.8.1"

main.rs

use bech32::{ToBase32, Variant};
use reusable_taproot_addresses::{sender, receiver};
use secp256k1::{Secp256k1, KeyPair, SecretKey, PublicKey};


fn main() {
    #![allow(non_snake_case)]

    let secp = Secp256k1::new();

    let sender_key_pair = KeyPair::new(&secp, &mut secp256k1::rand::thread_rng());
    let sender_secret_key = SecretKey::from_keypair(&sender_key_pair);
    let sender_pub_key = PublicKey::from_keypair(&sender_key_pair);

    let receiver_key_pair = KeyPair::new(&secp, &mut secp256k1::rand::thread_rng());
    let receiver_secret_key = SecretKey::from_keypair(&receiver_key_pair);
    let receiver_pub_key = PublicKey::from_keypair(&receiver_key_pair);

    let (P_change_sender, relationship_seed) = sender::generate_change_output_script(
        &sender_secret_key,
        &receiver_pub_key);

    let sender_change_address = bech32::encode("bc", P_change_sender.serialize().to_base32(), Variant::Bech32m).unwrap();
    println!("Change address that will be used by the sender:\n{}\n---", sender_change_address);

    let sender_addresses = sender::generate_public_keys_to_send(
        &relationship_seed,
        &receiver_pub_key);

    let receive_addresses = receiver::generate_public_keys_to_watch(
        &P_change_sender,
        &sender_pub_key,
        &receiver_secret_key);

    println!("Addresses calculated by the sender. Must match those calculated by the receiver.");

    for sa in sender_addresses {
        let encoded = bech32::encode("bc", sa.serialize().to_base32(), Variant::Bech32m).unwrap();
        println!("{}: {}", sa, encoded);
    }

    println!("---");

    println!("Addresses calculated by the receiver.");

    for ra in receive_addresses {
        let encoded = bech32::encode("bc", ra.serialize().to_base32(), Variant::Bech32m).unwrap();
        println!("{}: {}", ra, encoded);
    }

    println!("---");
}

@w0xlt
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w0xlt commented Mar 11, 2022

I configured the lib so that it has 3 external interfaces (functions).
They are:

pub fn sender::generate_change_output_script(sender_secret_key: &SecretKey, receiver_pub_key: &PublicKey) -> (PublicKey, [u8; 32]);

pub fn sender::generate_public_keys_to_send(relationship_seed: &[u8; 32], receiver_pub_key: &PublicKey) -> Vec<PublicKey>;

pub fn receiver::generate_public_keys_to_watch(P_change_sender: &PublicKey, sender_pub_key: &PublicKey, receiver_secret_key: &SecretKey) -> Vec<PublicKey>;

If another approach is preferred, let me know.

@dergigi
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dergigi commented Mar 14, 2022

Typo: receiveing -> receiving

@afilini
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afilini commented Mar 21, 2022

I hope it's not too late to propose changes to the protocol: I have recently implemented BIP47 in BDK and one of the issues I found was that in some cases it can be hard for a light wallet to recover the sender's pubkey, for instance if the server uses a P2PK or bare multisig input, because the pubkeys are not listed in the witness/scriptsig of the transaction. For a light client it can be hard to fetch an arbitrary tx given its txid (think about Core without txindex, or a wallet using compact block filters).

Taproot suffers from this same issue, because only the signature makes it into the witness of the tx. I'm wondering if it's possible to use some crypto magic to allow the receiver to recover the public key given the signature.

I should mention that I'm also not a fan of the fact that this protocol tweaks the change address. I know it's not as efficient, but I think I would still prefer something that uses an explicit OP_RETURN to notify the receiver, like BIP47 does. Assuming the receiver's payment code is public (if it's not I would have to communicate with the receiver to get a private code, which means I could just get an address) it's not that much worse in terms of privacy in my opinion.

EDIT:

@RubenSomsen just made me realize that this protocol assumes the receiver can give a fresh address to every different sender, so what I said earlier about the notification address being publicly known doesn't apply.

As @inaltoasinistra already pointed out, if there's interaction this protocol provides little benefits to just giving out an xpub imho

@w0xlt
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w0xlt commented Mar 23, 2022

I think we can use relationship_seed as master_seed in a new BIP32 wallet with some protocol-fixed derivation path .... The receiver can just importdescriptor(xpriv/m/PROTOCOL_FIXED_PATH/*) and let bitcoin core(or any other descriptor wallet) do its thing.

Since relationship_seed is the same for receiver and sender (relationship_seed = HMAC (shared_secret, RELATIONSHIP_SEED_CONSTANT)for both), how can this be used as a master seed for the receiver? I assume the sender will have access to the same addresses in this case.

I'm wondering what is the best way to integrate this with current version of Bitcoin Core or, at least, with rawtr() PR.

@sanket1729
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sanket1729 commented Mar 23, 2022

@w0xlt, my initial text was wrong(incomplete). You are right, what I described is insecure! Here is an updated version. Note that I have not thought about it enough to prove that it is secure.

The complete protocol would be:

Here all small letters p represents private keys and P represents public keys.

  1. After the first payment, the receiver would import the descriptor with the master private key p'_r = relationship_seed + p_reciever. For chain_code, it will choose some fixed defined constant. Note that the sender can compute the xpub using P'r = P_reciever + relationship_seed*G. The receiver will import the descriptor xpriv(p'r, fixed_chain_code)/Fixed_derivatoin_path. The sender can also similarly compute xpub(P'_R, fixed_chain_code)/Fixed_derivation_path. Now, the sender can send coins by deriving new addresses.

  2. The sender backup is however annoying. We need to explicitly keep track of coins. The corresponding private key is p'_s = relationship_seed + p_sender. We can then just use import rawtr(p's).

You would need some other software to do the EC/field math operations.

@w0xlt
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w0xlt commented Mar 25, 2022

@sanket1729 Thanks for your suggestions.

I applied them in the library and they worked.

The sender function generates a public key and the receive function, the private key of this public key.

pub fn sender::generate_master_extended_public_key(relationship_seed: &[u8; 32], receiver_pub_key: &PublicKey) -> PublicKey
pub fn receiver::generate_master_extended_private_key(P_change_sender: &PublicKey,sender_pub_key: &PublicKey, receiver_secret_key: &SecretKey) -> SecretKey

I added a test that confirms that the public key generated by the sender is the same calculated from the private key generated by the receiver.

With this public key, the sender can create the xpub while the receiver, the xpriv as you suggested.

I think this libraty might be ready to be tested with current version of Bitcoin Core + rawtr() PR.

@AdamISZ
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AdamISZ commented Apr 1, 2022

Small nit, in Repeated sending, the first line, you have P_i = offset_i * G + P_receiver * G but it should be without the final * G.

@Kixunil
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Kixunil commented Apr 4, 2022

@afilini no problem, there still needs to be more discussion around these ideas. I'm happy I started something even if not perfect. E.g. @RubenSomsen had some other interesting ideas.

Yes, the only advantage over plain xpub is the sender doesn't need to send xpub to the receiver in the initial interaction to enable refunds. I'm not sure if it's worth the effort but the general progression of technology moving complexity from UI to implementation suggests it could be. I hope that Taproot pubkey not being not hashed could lead to some other ideas.

@w0xlt sorry for not reviewing your library yet, life was hard lately.

@AdamISZ thanks, this kind of mistake is worth fixing.

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