A unique nonce is required for every message sent using a given shared secret key. The nonce doesn't have to be secret; a simple counter is totally fine; changing a single bit in the nonce is going to make the ciphertext look totally different even if the same message is sent twice.

What's a shared secret? It a key calculated from (A's secret key, B's public key) or (A's public key, B's secret key). A and B perform a different calculation, based on what they have, but end up with the same shared secret.

The shared secrets used in `crypto_box`

are 256-bit long. Which is huge. You can safely consider that shared secrets are going to be unique for each "conversation".

So, (A, B), (A, C) and (C, B) can safely exchange messages using the same nonces.
But if A sends a message to B using a given nonce, B cannot send a message to A using the same nonce. Nonces have to be unique for everything exchanged during a conversation between A and B.

So, a simple counter can be fine. Have A pick even numbers, leave odd numbers to B, increment the nonce by 2 after every message sent and you're good to go.

But the cipher used in the `crypto_box`

construction actually has a really huge nonce. 192 bits.

Which means that if you ignore everything I wrote and just pick a random nonce every time you send a message, the probability to get a collision is so small that you can rest assured that it will never ever happen in practice.

Some stream ciphers included in Sodium (AES128-CTR, ChaCha20, Salsa20) have a shorter nonce, and require a counter to avoid collisions. This is why they are in the "advanced" section of the documentation.

But with `crypto_box`

and `crypto_secretbox`

, just pick a random nonce every time (`randombytes_buf(nonce, sizeof nonce)`

) and you will be safe.