Hi James,

Thanks to bringing to awareness the atomic mining pool thing, it's interesting.

> I'm not a mining expert and so I can't speak to the efficacy of the
> paper as a whole, but direct-from-coinbase payouts seem like a
> desirable feature which avoids some trust in pools. One limitation is
> the size of the coinbase outputs owed to constituent miners; this
> limits the number of participants in the pool.

I'm neither a mining expert, but I wonder if there is not some weird dependency here. The coinbase output scriptpubkey being part of the header's merkle root commitment, the CTV hash being part of the scriptpubkey and the payout outputs being part of the CTV hash, everytime the payout outputs as re-evaluated in function of the last work share submitted, as Laurentia is proposing, the whole payout transaction must be updated, then the CTV hash, then the merkle root commitment, leading all the mining devices to re-fetch a header from the job negotiator (in Stratum V2 parlance), I think ? I don't know the average shares submission frequency for a local pool of size 100 as targeted by Laurentia though the latency hit might downgrade the worthiness of this CTV-based atomic mining pool payouts design...

Beyond, I'm not sure about the trust removal statement of this design, as the job negotiator operator, sounds to always have malleability to select the coinbase output scriptpubkey, therefore selecting any CTV hash assigning all the reward to itself, at the detriment of other mining pool participant. I believe this is not a downside of CTV usage itself, but the fact that the coinbase output scriptpubkey is ultimately signed by the proof-of-work itself.

About compactness, I wonder if an atomic payment pool payouts design favoring the payouts settlement directly over Lightning channels wouldn't offer a smaller on-chain footprint. E.g, maybe the mining pool operator could send a long-term PTLC to each participant covering the period during which a block has odds to be mined by the pool. The PTLCs amounts should be stable once the block template is agreed on. The coinbase output is locked with some scriptless script point. When it is spent by the mining operator, the PTLCs could be fetched by the participant. If the mining operator doesn't spend before time lock expiration, there could be some on-chain fan-out transaction kicking-out. That type of scheme would allow you to save on-chain fees and not to leak the mining pool hashrate distribution. However, I believe it is more complex to make it fit with the SPLNS "real-time"  calculation as it sounds to be proposed by the paper. Just a strawman proposal, if relevant, deserves more thinking.

The paper would deserve to have a fully fleshed-out "coinbase generation" scheme as the description is a bit loose, imo, like:

"Block solve reward is distributed directly from the block to each user, meaning each user gets
a 'mined' transaction directly into their wallet as soon as the block is solved so there is no wait
to get paid and no pool wallet storing user's rewards"

Anyway, left a scratch of further scheme analysis there:
https://github.com/ariard/bitcoin-contracting-primitives-wg/pull/8

Best,
Antoine

Le ven. 19 août 2022 à 12:33, James O'Beirne via bitcoin-dev <bitcoin-dev@lists.linuxfoundation.org> a écrit :
Over the past few months there have been a few potential uses of
OP_CHECKTEMPLATEVERIFY (BIP-119)
(https://github.com/bitcoin/bitcoin/pull/21702) that I've found
interesting.

# Congestion control redux

When I first heard of CTV, a presentation Jeremy did at Chaincode back
in 2018 or '19, he cited congestion control as one of its main use
cases.

The pitch went something like

> When there is a high demand for blockspace it becomes very expensive
> to make transactions. By using OP_CHECKTEMPLATEVERIFY, a large volume
> payment processor may aggregate all their payments into a single O(1)
> transaction for purposes of confirmation. Then, some time later, the
> payments can be expanded out of that UTXO when the demand for
> blockspace is decreased.

(from https://utxos.org/uses/scaling/)

At the time that didn't particularly grab me; the idea of smoothing fee
rates seemed nice but marginal.

But recently, two particular cases have made me reassess the value of
congestion control.

The first stems from the necessity of L2 protocols (payment channels,
vaults, etc.) to, under certain circumstances, settle to the chain in a
timely way in order to prevent abuse of the protocol. If some
unexpected condition (a protocol exploit, large network disconnect, en
masse vault breach, etc.) creates a situation where a large number of
contracts need to settle to the chain in short order, mempools could
fill up and protocol failures could happen for want of mempool/block
space
(https://github.com/jamesob/mempool.work#failure-one-mempool-to-rule-them-all).

In such a case, CTV could be used effectively to "compress" settlement
commitments, get them on-chain, and then facilitate later unpacking of
the CTV ouputs into the contract's true end state.

This amounts to `n` contract-control outputs (e.g. a lightning funding
transaction outputs) being spent into a single CTV output, which
commits to the final settlement state. Multiple parties could
trustlessly collaborate to settle into a single CTV output using
SIGHASH_ALL | ANYONECANPAY. This requires a level of interaction
similar to coinjoins.

Put simply, CTV allows deferring the chainspace required for the final
settlement outputs, but still immediately requires space for the
inputs. This might sound like a temporary reprieve from half-ish of the
space required to settle, but in many (most?) cases the outputs require
substantially more space than the inputs, given that often we're
settling a single UTXO into multiple payouts per party. A 2, 3, or
4-fold increase (depending on the contracting pattern) in capacity
isn't a silver bullet, but it could ameliorate the damage of unexpected
settlement "tidal waves."

Conceptually, CTV is the most parsimonious way to do such a scheme,
since you can't really get smaller than a SHA256 commitment, and that's
essentially all CTV is.

The second congestion control case is related to a recent post Bram
made about stability under a no-block-subsidy regime. He posted

> If transaction fees came in at an even rate over time all at the
> exact same level then they work fine for security, acting similarly
> to fixed block rewards. Unfortunately that isn't how it works in the
> real world. There's a very well established day/night cycle with fees
> going to zero overnight and even longer gaps on weekends and
> holidays. If in the future Bitcoin is entirely dependent on fees for
> security (scheduled very strongly) and this pattern keeps up
> (overwhelmingly likely) then this is going to become a serious
> problem.

(from
https://lists.linuxfoundation.org/pipermail/bitcoin-dev/2022-July/020702.html)

Ryan Grant points out that CTV's congestion control use could help to
smooth fees, creating a less spiky incentive to mine
(https://lists.linuxfoundation.org/pipermail/bitcoin-dev/2022-July/020702.html).

Admittedly the original concern is speculative and a ways off from now,
as others in the thread pointed out. But having CTV-based fee smoothing
as an option certainly doesn't seem like a bad thing.


# Atomic mining pool payouts

Laurentia is a mining pool design that pays participants out directly
from the coinbase of found blocks.

> Block solve reward is distributed directly from the block to each
> user, meaning each user gets a 'mined' transaction directly into
> their wallet as soon as the block is solved so there is no wait to
> get paid and no pool wallet storing user's rewards.

(from
https://laurentiapool.org/wp-content/uploads/2020/05/laurentiapool_whitepaper.pdf)

I'm not a mining expert and so I can't speak to the efficacy of the
paper as a whole, but direct-from-coinbase payouts seem like a
desirable feature which avoids some trust in pools. One limitation is
the size of the coinbase outputs owed to constituent miners; this
limits the number of participants in the pool.

If the payout was instead a single OP_CTV output, an arbitrary number
of pool participants could be paid out "atomically" within a single
coinbase.

---

CTV both in concept and implementation is very simple, and I think it
is likely to continue to yield potential applications.
"Settlement compression" seems like a useful thing, especially in light
of a possible increase in L2 usage, and CTV seems like the simplest
means to enable it.

Interestingly, an analogue for this pattern going the other direction
is possible, e.g. non-interactive channel openings
(https://utxos.org/uses/non-interactive-channels/), which would allow
e.g. opening a lightning channel with a merchant who doesn't want to
have their spending keys constantly accessible from a point-of-sale,
but can still parse/verify CTV commitments.

Regards,
James
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