Really nice idea. So its like a smart contract that incentivizes publication that a server has been hacked? I also really like how the funding has been handled -- with all the coins stored in the same address and then each server associated with a unique signature. That way, you don't have to split up all the coins among every server and reduce the incentive for an attacker yet you can still identify which server was hacked.

It would be nice if after the attacker broke into the server that they were also incentivized to act on the information as soon as possible (revealing early on when the server was compromised.) I suppose you could split up the coins into different outputs that could optimally be redeemed by the owner at different points in the future -- so they're incentivzed to act lest their reward decays even more (this is of course, assuming that the monetary reward for this is greater than any possible legal consequences for the attacker -- it might not be. Thinking about this some more: it would also be somewhat hard to deny that this -wasn't- a honeypot with such a complex and unique scheme required for transactions, and I for one wouldn't like to reveal that I'd hacked a server if I knew it was all a calculated ploy. Don't honeypots rely on subtly?)

What about also proving to an attacker that by breaking into a server they would be guaranteed a reward? I know that the use-case for this is proof of compromise so incentivizing a security audit would kind of fall more into an active invitation to audit but couldn't you also make a cryptocurrency that allowed coins to be moved based on a service banner existing at a given IP address? Attackers could then break into the server, setup a service that broadcasts their public key hash, and then spend coins locked at this special contract address to that pub key hash which miners would check on redemption (putting aside malicious use-cases for now.)

On Wed, Aug 24, 2016 at 11:46 AM, Peter Todd via bitcoin-dev <bitcoin-dev@lists.linuxfoundation.org> wrote:

Bitcoin-based honeypots incentivise intruders into revealing the fact they have
broken into a server by allowing them to claim a reward based on secret
information obtained during the intrusion. Spending a bitcoin can only be done
by publishing data to a public place - the Bitcoin blockchain - allowing
detection of the intrusion.

The simplest way to achieve this is with one private key per server, with each
server associated with one transaction output spendable by that key. However
this isn't capital efficient if you have multiple servers to protect: if we
have N servers and P bitcoins that we can afford to lose in the compromise, one
key per server gives the intruder only N/P incentive.

Previously Piete Wuille proposed(1) tree signatures for honeypots, with a
single txout protected by a 1-N tree of keys, with each server assigned a
specific key. Unfortunately though, tree signatures aren't yet implemented in
the Bitcoin protocol.

However with a 2-of-2 multisig and the SIGHASH_SINGLE feature we can implement
this functionality with the existing Bitcoin protocol using the following
script:

    2 <honeypot-pubkey> <distriminator-pubkey> 2 CHECKMULTISIG

The honeypot secret key is shared among all N servers, and left on them. The
distriminator secret key meanwhile is kept secret, however for each server a
unique signature is created with SIGHASH_SINGLE, paying a token amount to a
notification address. For each individual server a pre-signed signature created
with the distriminator secret key is then left on the associated server along
with the honeypot secret key.

Recall the SIGHASH_SINGLE flag means that the signature only signs a single
transaction input and transaction output; the transaction is allowed to have
additional inputs and outputs added. This allows the thief to use the honeypot
key to construct a claim transaction with an additional output added that pays
an address that they own with the rest of the funds.

Equally, we could also use SIGHASH_NONE, with the per-server discriminator
being the K value used in the pre-signed transaction.

Note that Jeff Coleman deserves credit as co-inventor of all the above.


Censorship Resistance
=====================

A potential disadvantage of using non-standard SIGHASH flags is that the
transactions involved are somewhat unusual, and may be flagged by
risk analysis at exchanges and the like, a threat to the fungibility of the
reward.

We can improve on the above concept from Todd/Coleman by using a pre-signed
standard transaction instead. The pre-signed transaction spends the honeypot
txout to two addresses, a per-server canary address, and a change address. The
private key associated with the change addres is also left on the server, and
the intruder can then spend that change output to finally collect their reward.

To any external observer the result looks like two normal transactions created
in the process of someone with a standard wallet sending a small amount of
funds to an address, followed by sending a larger amount.


Doublespending
==============

A subtlety in the the two transactions concept is that the intruder doesn't
have the necessary private keys to modify the first transaction, which means
that the honeypot owner can respond to the compromise by doublespending that
transaction, potentially recovering the honeypot while still learning about the
compromise. While this is possible with all honeypots, if the first transaction
is signed with the opt-in RBF flags, and CPFP-aware transaction replacement is
not implemented by miners, the mechanics are particularly disadvantageous to
the intruder, as the honeypot owner only needs to increase the first
transaction's fee slightly to have a high chance of recovering their funds.
With CPFP-aware transaction replacement the intruder could in-turn respond with
a high-fee CPFP second transaction, but currently no such implementation is
known.


Scorched Earth
==============

We can use the "scorched earth" concept to improve the credibility of the
honeypot reward by making it costly for the honeypot owner to doublespend. Here
a second version of the honeypot pre-signed transaction would also be provided
which sepnds the entirety of the honeypot output to fees, and additionally
spends a second output to fees. An economically rational intruder will publish
the first version, which maximizes the funds they get out of the honeypot. If
the owner tries to dishonestly doublespend, they can respond by publishing the
"scorched earth" transaction, encouraging the honeypot owner's honesty and
making CPFP-aware transaction replacement irrelevant.

Of course, miner centralization adds complexity to the above: in many instances
honeypot owners and/or intruders will be able to recover funds from altruistic
miners. Equally, the additional complexity may discourage intruders from making
use of the honeypot entirely.

Note that as an implementation consideration CHECKSEQUENCEVERIFY can be used to
ensure the honeypot output can only be spent with transaction replacement
enabled, as CSV requires nSequence to be set in specific ways in any transation
spending the output.


References
==========

1) https://blockstream.com/2015/08/24/treesignatures/

--
https://petertodd.org 'peter'[:-1]@petertodd.org

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