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Which affected all documentation files.
596 lines
33 KiB
Markdown
596 lines
33 KiB
Markdown
---
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title:
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Lightning Layer
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...
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# This discussion of the lightning layer may well be obsoleted
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by the elegant cryptography of [Scriptless Scripts] using adaptive Schnorr
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signatures and of [Anonymous Multi-Hop Locks].
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Contingent payments can reveal a key to an alien blockchain on the bitcoin blockchain, and [zero knowledge contingent payments on the bitcoin chain] can reveal any arbitrarily complex secret that fulfils any arbitrarily complex condition.
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[Scriptless Scripts]:https://tlu.tarilabs.com/cryptography/scriptless-scripts/introduction-to-scriptless-scripts.html
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"Introduction to Scriptless Scripts – Tari Labs University"
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[Anonymous Multi-Hop Locks]: anonymous_multihop_locks_lightning_network.pdf
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"Anonymous Multi-Hop Locks for Blockchain Scalability and Interoperability"
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[zero knowledge contingent payments on the bitcoin chain]:https://bitcoincore.org/en/2016/02/26/zero-knowledge-contingent-payments-announcement/
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"The first successful Zero-Knowledge Contingent Bitcoin Payment"
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I need to understand the [Anonymous Multi-Hop Locks] primitive, and
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rewrite this accordingly.
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Scriptless scripts have the huge advantage of being self enforcing – it is
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impossible to defect from the script, because there is no script – there are
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just actions that are cryptographically possible or impossible.
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But scriptless scripts cannot in themselves solve the hard problem, that all
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participants in a multilateral transaction need to know _in a short time_ that
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the whole multilateral transaction has definitely succeeded or definitely
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failed. This inherently requires a reliable broadcast channel, though if
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everyone is cooperating, they don’t have to actually put anything on that
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channel. But they need the capability to resort to that channel if something
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funny happens, and that capability has to be used or lost within a time limit.
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So, the adapter secret not only has to become known to the participants, it has to become known to the participants within timing limits.
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[Anonymous Multi-Hop Locks] can ensure that the lightning network is
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always in a definite state, and that those parts of it that are undergoing
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state change are locked, but need to be embedded in a protocol that
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ensures that those locks always go away in a short time with commitment
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of the total transaction, or rollback of the total transaction, and that the
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participants in the transaction always know whether the transaction was
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committed or rolled back within a short time. Scriptless scripts are
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timeless, and need to be embedded in scripted scripts that have timing
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constraints, and which require information to be broadcast over a reliable
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broadcast channel if the information is available, yet certain time limits are
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nonetheless exceeded.
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My conclusion was that full circle unbreakability of lightning network
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transactions within time limits needs a reliable broadcast, and I envisaged
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a hierarchy of reliable broadcasters, (sidechains, with some sidechains
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representing a group of bilateral lightning network gateways that act as
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one multilateral lightning network gateway) But this conclusion may be
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wrong or overly simple – though we are still going to need sidechains and
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hierarchical reliable broadcasting, because it can do no end of things that
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are very difficult otherwise.
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But reliable broadcast mechanism both supplies and requires a solution to
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distributed Byzantine fault tolerant consensus, so the problem of getting a
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lock up and bringing it down is a general distributed Byzantine fault
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tolerant consensus problem, and perhaps viewing it as a reliable broadcast
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problem is a misperception and misanalysis.
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Rather, the blockdag requires a mechanism to establish a total order of
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blocks, and the distributed multihop lock requires a mechanism to
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establish the state of the lock, the classic distributed state machine
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problem addressed by Practical Byzantine Fault Tolerant distributed
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consensus. Albeit implementing Practical Byzantine Fault Tolerant
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distributed consensus as a state machine over a blockdag may well be a
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simpler and more humanly intelligible form of this algorithm. But a state
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machine for BEGIN … COMMIT is going to be a fundamentally different
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state machine to the one that constructs a total order of transactions.
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# Lightning layer concept
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The lightning layer is a design that implements something like full reserve
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correspondence banking on top of the blockchain layer, thereby solving
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the problem of the blockchain exposing too much information about
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everyone’s transactions to everyone, allowing a blockchain solution to
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scale to completely replacing fiat currency, and allowing instant on the
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spot transactions.
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A lightning gateway allows instant trustless unilateral transactions (Alice
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pays Bob) between two or more people, but you have to lock up a
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significant amount of money in each gateway, and if you have more than
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two participants, and one of the participants goes off the internet, then
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the protocols necessary for the gateway to keep going between the remaining
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participants become a bit more complicated. Multiparty gateways will be
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(eventually) implemented as sidechains.
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A lightning gateway consists of coin (unspent transaction output) on the
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blockchain that need a joint signature to be spent. The parties to coin
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construct a transaction splitting it up between them before they create that
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coin on the blockchain, and then do not drop that transaction to the
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blockchain layer, keeping the transaction for when one them decides to break
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up the gateway. To change ownership of the coin, to increase the amount of the
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coin owned by one of them and decrease the amount owned by the other, they
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generate a new transaction, and then do not drop that transaction to the
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blockchain layer either.
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And the problem is that we don’t want unilateral transactions. We want Alice
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pays Bob, and Bob gets a proof that he paid Alice, completing the circle.
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And, to work like correspondence banking, we want Alice pays Bob, Bob pays
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Carol, Carol pays Dan, Dan pays Erin, Erin pays Frank, and Frank gets proof
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that he paid Ann, completing the circle.
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And we want every unilateral transaction in the circle to go through, or none
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of them to go through. We want the whole circle of unilateral transactions
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making up a complete multilateral transaction to succeed or every unilateral
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transaction in the whole circle to fail.
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And we want it to normally and usually succeed fast, and if it fails, to take
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a reasonably short time to fail. And if it fails, we want all participants to
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know it has definitely failed after a reasonably short timeout.
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# The Bitcoin lightning layer is not
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It is not correspondence banking with predictable behavior enforced by
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cryptography.
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It is correspondence banking that uses cryptography, where the participants
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trustworthy behaviour is enforced from behind the scenes by unclear authority,
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which is likely to lead to the existing problem where authority is supposed to
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protect you from the bankers, but who protects you from authority?
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For the lightning network to change from a single consistent state of who owns
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what part of each gateway unspent transaction output to another single
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consistent state is equivalent to the well known hard problems of a reliable
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broadcast channel, the Byzantine generals problem, the two generals problem,
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and acid transactions on a distributed database.
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So when I looked at the lightning documents for a lightning layer on top of
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bitcoin I expected to see discussion of smart contracts on the bitcoin layer
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or lightning network protocols on the lightning layer for resolving these hard
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problems and eventually reaching a resolution, so that the network would
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always eventually reach a consistent and intended state. Not seeing them.
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Instead what I do see is that the lightning network is safe because
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“misconduct” will result in you losing your bitcoins.
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It will? Who do you lose them to? How is *misconduct* defined? Who decides
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*misconduct*? The guy who gets your bitcoins? Do we have a central banker of
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the lightning network somewhere?
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We should not be talking about “misconduct”. We should be talking about the
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lighting network entering an inconsistent state due to lost messages, nodes
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going down at inopportune moments, and nodes deviating from the protocol, or
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entering a state that some of the participants in the transaction did not
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intend or expect.
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The cryptographic term for misconduct is “Byzantine failure”, which indeed
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normally results from wickedness, but can result from bugs or data corruption.
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While the usual and archetypal cause of Byzantine failure is that someone
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wrote or modified software for the purposes of betrayal, lying, cheating, and
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stealing, it happens often enough as a result of data corruption or running a
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program that was compiled under a compiler and in an environment different
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from that it was tested and developed on.
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A gateway does a unilateral transaction between the parties on the lightning
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layer who control controlling the gateway unspent transaction output by
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generating a new transaction on the bitcoin layer breaking up the gateway
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between the parties, and the parties refrain from committing that transaction
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to the blockchain, and instead endless generate new transactions, which do not
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get played either, thereby changing what part of the gateway unspent
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transaction output is owned by each party to the gateway.
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*What happens if someone commits an out of date bitcoin layer transaction to
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the blockchain?*
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Does the central banker confiscate the bitcoin of the party who committed the
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transaction. How does he do that?
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Suppose Alice’s gateway to Bob is blocked because she now owns the whole of
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that gateway unspent transaction output, and her gateway to Frankie is blocked
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because Frankie owns all of that gateway.
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So she organizes a transaction that moves bitcoin from the Ann/Bob gateway to
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the Ann/Frankie gateway. So what Alice intends is that Alice pays Bob, Bob
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pays Carol, Carol pays Dan, Dan pays Erin, Erin pays Frank, and Frank pays
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Alice. Except that in the middle the transaction Carol and Erin ungracefully
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disconnect from the network, so that either Ann generated a bitcoin layer
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transaction giving bitcoin to Bob, but Frankie did not generate a bitcoin
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layer transaction to Ann, or the other way around.
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*What happens when a transaction fails and leaves the parties in an inconsistent
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state?*
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Does the central banker decide that Carol and Erin were engaged in
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misconduct and confiscate their bitcoin?*
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# Trustless Unilateral transactions
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If you wanted to buy or sell cryptocurrency for cash or gold, you could
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arrange over the internet to meet someone in person, set up a lightning
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gateway with him, and then, when you met him in person, pay him instantly, on
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the spot, in a trustless unilateral transaction without need to wait some
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considerable time for the payment to clear.
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Suppose you wanted to sell bitcoin for gold, in person, both parties are going
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to meet, probably with a weapon in their pocket. You could create a jointly
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signed unspent transaction output, after you and the other party jointly sign
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a bitcoin layer transaction giving the bitcoin back to you. And then, when
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meeting, create a jointly signed bitcoin layer transaction giving the bitcoin
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to the man who is giving you the gold. Except what is going to stop you from
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committing the earlier transaction to the blockchain a few seconds before the
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meeting?
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OK, let us suppose we have supersedeable transactions. They have to be
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committed to the blockchain for a time before they take effect, and if someone
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submits a transaction with the same signatures but a higher priority, the one
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with lower priority fails to take effect. Then you can endlessly generate
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fresh transactions, each with higher priority than the previous one, and never
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commit them to the blockchain unless the gateway between the parties is
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abandoned.
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It would take a little while for the gateway to become available, but once it
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was available, instant irrevocable payments become possible.
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And if one has an account with a service provider over the internet, one could
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set up a gate way with that service provider, and after each session or each
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service, make a small instant payment, without the cost and delay of making
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transactions on the blockchain.
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It would be possible to do such instant two party transactions with bitcoin
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today, although the wallets are generally not set up to support it, nor is the
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way the main blockchain processes transactions, but with BTC blockchain
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working as it today, such transactions are not trustless. If you want to do a
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BTC transaction you are trusting the lightning network, which means you
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are trusting you do not whom.
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At the time this is written, the lightning network for bitcoin has not been
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adequately implemented, or even fully designed. Existing implementations on
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top of the bitcoin blockchain still require some trust in intermediaries, and
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thus require trust in some mysterious authority with the mysterious
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capability to punish the intermediaries, and to have a real lighting network on
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bitcoin requires changes in bitcoin which the miners are not going along with,
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and which perhaps are underscoped and not fully thought out, ad hoc changes
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to fit with what already existed, and what was politically feasible. And it
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seems that rather less was politically feasible than one might hope.
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# Cryptographic implementation of trustless unilateral transactions
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Ann and Bob create on the blockchain a coin (unspent transaction output,
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utxo) whose corresponding key is the sum of secret key known only to
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Ann, and a secret key known only to Bob. Before they create this coin,
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they create a transaction on it, signed by their joint key, that creates two
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coins, one with a secret key known only to Bob, and one with a secret key
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known only to Ann. They keep this transaction to themselves and do not
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place it on the blockchain.
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# Multilateral (circle) transactions
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The lightning layer will function like correspondence banking, only with
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good behavior cryptographically enforced on the lightning vertices, rather
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than by state supervision of the “banks”. This will require a blockchain
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layer designed to support it.
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Correspondence banking merges large numbers of small transactions into a small
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number of large pooled transactions which are eventually settled on the
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blockchain in one big transaction, with several parties to the transaction
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representing a very large number of parties engaged in a very large number of
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transactions.
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But correspondence banking works by trust, thus the intermediaries have to
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be well known and subject to pressure, which is apt to mean subject to
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government pressure – and government has interests that are in conflict with
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those of people attempting to use a medium of exchange and a store of
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value.
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lightning network correspondence banking
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------------------------------------------------------------------------ -----------------------------------------------------------------------------------
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merges many small two party transactions into a few large transactions merges many small two party transactions into a few large transactions
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lightning vertex bank
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lightning gateway bank account
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trustless need to trust the banks
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instant Slow in that you can never be sure if a transaction will be honored for some time
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Payer id visible to payer vertex, payee id visible to payee vertex Government issued id of payer and payee visible to all intermediaries.
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We have a separate blockchain of supersedeable transactions. A
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transaction gets committed to the primary blockchain after it has been
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sitting on the supersedable chain for a while, if, at the time it is
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evaluated for commitment, all of its inputs are valid unspent outputs on
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the primary blockchain, and none of them are inputs to a currently valid
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higher priority transaction on the blockchain of supersedable
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transactions, the priority being an arbitrary length binary value.
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If one party tries to break up a gateway with an out of date
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distribution, the other party notices it sitting on the supersedable
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blockchain, and issues a more up to date transaction. Normally this
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should never happen, since when one of the parties wants to break up a
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gateway, the other party should agree to a regular transaction. However,
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one party may go offline and stay offline, especially if the last
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transaction reduced the the value of their interest in the gateway to
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zero.
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A gateway in the lightning network layer is a jointly signed coin on the
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blockchain on the blockchain layer. Bob’s account with BigCrypto is a coin
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on the blockchain layer, for which there exists a a jointly signed
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transaction distributing that block between two blocks, one wholly owned by
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Bob, and one wholly owned by BigCrypto, thus giving BigCrypto effective
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offchain control of one part of that block, and Bob effective control of the
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other part of the block, and by generating new superseding transaction, they
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can effectively transfer ownership of part of the block instantly without
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anything going on the blockchain.
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But …
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# Acid
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We have to make sure that transactions are acid on the lightning network as a
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whole, that transactions are atomic, consistent, isolated, and durable.
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## Atomic and consistent
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Ann has an account with Bob, Bob has an account with Carol.
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To change what is Ann’s account requires a transaction signed by
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Bob and Ann, and similarly for Carol.
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Ann wants to pay Carol, but does not want to sign a reduction in her account
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with Bob, unless she is sure that Carol gets the corresponding increase. Bob
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does not want to sign an increase in Carol’s account, unless it gets Ann’s
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signature on a decrease in her account. Not to mention that Ann probably
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does not want to sign a decrease on her account without getting a receipt
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from Carol. Full circle transaction. We need to guarantee that either the
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full circle goes through, or none of the separate unilateral transactions in
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the circle go through.
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## Reliable broadcast channel
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The solution to atomicity and maintaining consistency between different
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entities on the lightning network is the reliable broadcast channel.
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Such as the blockchain itself. Create a special zero value transaction that
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has no outputs and carries its own signature, but can be a required input to
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other transactions, and whose construction requires the cooperation of all
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the parties. Each gateway constructs a transaction only be valid if a code
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is placed on the blockchain that requires the cooperation of all the gateways
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within a short time. Once the code exists, and everyone knows it exists,
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they proceed with bilateral transactions that do not require the code and
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only potentially go on the blockchain. If not everyone knows it exists, and
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it does not appear on the blockchain within a short time, then the
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transaction fails. If everyone knows it exists, the transaction succeeds. If
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not everyone knows it exists, but it appears on the blockchain within the
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time limit, the transaction succeeds, and each party could potentially play
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the transaction, and thus effectively owns the corresponding part of the
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gateway coin, regardless of whether they play it or not.
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A reliable broadcast channel is something that somehow works like a
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classified ad did back in the days of ink on paper newspapers. The physical
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process of producing the newspaper guaranteed that every single copy had the
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exact same classified ad in it, and that ad must have been made public on a
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certain date. Easy to do this with a printing press that puts ink on
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paper. Very hard to do this, with electronic point to point communications.
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But let us assume we somehow have a reliable broadcast channel:
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All the parties agree on a Merkle tree, which binds them if the joint
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signature to that Merkle tree appears on the reliable broadcast channel
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within a certain short time period.
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And, if some of them have the joint signature, then knowing that they could
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upload it to the reliable broadcast channel, they each agree to superseding
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unilateral transactions. If Bob expects payment from Ann and expects to
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make payment to Carol, and he has the joint signature, and knows Carol has a
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copy of the authenticated joint signature, because Carol sent him the
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signature and he sent Ann the signature, of it, then he knows Carol can
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*make* him pay her, and knows he can *make* Ann pay him. So he just goes
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right ahead with unilateral transactions that supersede the transaction that
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relies on the reliable broadcast channel. And if every party to the
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transaction does that, none of them actually broadcast the signature the
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reliable broadcast channel. Which in consequence, by merely being available
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enforces correct behaviour, and is seldom likely to need to actually
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broadcast anything. And when something is actually broadcast on that
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channel, chances are that all the transactions that that broadcast enables
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will have been superseded.
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Each party, when receives a copy of the joint signature that he *could* upload
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to the reliable broadcast channel, sends a copy to the counter party that he
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expects to pay him, and each party, when he receives a copy from the party he
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expects to pay, performs the unilateral payment to that party that supersedes
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and the transaction using the reliable broadcast network.
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And if a party has a copy of the joint signature and the document that it
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signs for the full circle transaction, but finds himself unable to perform
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the superseding unilateral transactions with his counterparties, (perhaps
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their internet connection or their computer went down) then he uploads the
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signature to the reliable broadcast channel.
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When the signature is uploaded to reliable broadcast channel, this does not
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give the reliable broadcast channel any substantial information about the
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amount of the transaction, and who the parties to the transaction are, but the
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node of the channel sees IP addresses, and this could frequently be used to
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reconstruct a pretty good guess about who is transacting with whom and why.
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As we see with Monaro, a partial information leak can be put together with
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lots of other sources of information to reconstruct a very large information
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leak.
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But most of the time, the channel is not likely to be used, which means it
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will have only small fragments of data, not enough to put together to form
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a meaningful picture, hence the privacy leak is unlikely to be very useful
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to those snooping on other people’s business.
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### Other use cases for a reliable broadcast channel
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The use case of joint signatures implies an immutable data structure of the
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tuple oid, hash, public key, and two scalars.
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But another use case is to publicly root private immutable data.
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If you continually upload the latest version, you wind up uploading most of
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tree, or all of it, which does not add significantly to the cost of each
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interaction recorded. The simplest sql friendly data structure is (oid of
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this item, public key, hash, your index of hash, oids of two child hashes)
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with the reliable broadcast channel checking that the child hashes do in fact
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generate the hash, and that the tuple (public key, index of hash) is unique.
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If the data is aged out after say, three months, cannot directly check
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uniqueness and correctness for the nodes that are the roots of big trees. How
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do you know someone has not made up several different and mutually
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inconsistent pasts for immutable append only data structure associated with
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this key?
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To work around this problem, allow unbalanced Merkle trees, consisting of
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(oid of this item, public key, hash, your tree node index, index of the
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highest index leaf governed by this hash, oids of two child hashes) If an
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unbalanced node referencing an old tree root is uploaded at intervals of less
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than three months, it can be used to prove the contents and uniqueness of
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the old balanced binary tree root, since the most recent unbalanced node must
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have also proved contents and uniqueness, using a less recent unbalanced
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node, and unbalanced nodes must also be unique on the tuple (public key,
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index of node, index of highest leaf node governed) Someone can forget his
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old past, and, after three months, start making up a new past, but the
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witness for the new past can only begin on the day he starts the upload. He
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cannot construct several realities, and six months later, choose which
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reality he finds convenient. Or rather he can, but he cannot provide a six
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month earlier witness to it.
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You upload several nodes that constitute the unbalanced tree right side path
|
||
that points at the balanced rest of the old tree every two months, superseding
|
||
the previous right hand side of the unbalanced tree, and thus maintaining a
|
||
chain of proofs stretching into the past that proves that throughout this
|
||
period, there is one and only one immutable data structure associated with
|
||
this public key.
|
||
|
||
A common case is that they key certifying the state of the immutable data may
|
||
change, with the torch being passed from key to key. In which case the
|
||
upload of total state needs to reference the used key, and an earlier,
|
||
normally the earliest, signing key, with links in the chain of keys
|
||
authorizing keys being renewed at less than the timeout interval for data to
|
||
be immutable, but unavailable from the reliable broadcast network. If the
|
||
witness asserts that key is authorized by a chain of keys going back to an
|
||
earlier or the earliest keys, then it relies on its previous witness, rather
|
||
than re-evaluating the entire, possibly very long, chain of keys every time.
|
||
|
||
But, if the witness cannot do that, then the entire, possibly very very long,
|
||
chain of keys and signatures has be uploaded for the witness to record the
|
||
earlier, or earliest key, as authorizing the current ever changing key.
|
||
Similarly if the client starts uploading to a new witness. But such very
|
||
long proofs will only be have to done once in a very long while, and done
|
||
once for everyone.
|
||
|
||
Because of Byzantine failure or network failure, such a chain may fork. The
|
||
protocol has to be such that if a fork develops by network failure,
|
||
it will be fixed, with one of the forks dying when the network functions
|
||
better, and if it fails by Byzantine failure,
|
||
we get two sets of reliable broadcast channels,
|
||
each testifying that the other reliable broadcast channel is unreliable,
|
||
and each testifying that a different fork is the valid fork,
|
||
and which fork you follow depends on which reliable broadcast channel you
|
||
subscribe to.
|
||
|
||
Another use case is for wallet recovery, with mutable data structures
|
||
encrypted by the private key whose primary key is the public key.
|
||
|
||
## implementing and funding a reliable broadcast channel
|
||
|
||
Tardigrade has a somewhat similar architecture to the proposed Reliable
|
||
Broadcast network charges $120 per year for per TB of storage, $45 per
|
||
terabyte of download. So for uploading a single signature, and downloading
|
||
it six times, which one hash, one elliptic point, and two scalars, one
|
||
hundred and twenty eight bytes, so the cost of doing what tardigrade does
|
||
with reliable broadcast network operated by a single operator would be
|
||
$4 × 10^{-7}$ dollars. Which might as well be free, except we have to charge some tiny amount to prevent DDoS.
|
||
|
||
But, when the system is operating at scale, will want the reliable broadcast
|
||
network to have many operators, who synchronize with each other so that the
|
||
data is available to each of them and all of them and from each of them and
|
||
all of them, and can testify when the
|
||
data became available, so the cost will be
|
||
many times that. Which is still insignificant. If the network is composed
|
||
of a hundred operators, and there are substantial overheads to maintain
|
||
synchrony and truth, we are still only looking a cost of $0.0001 per
|
||
transaction. Maybe we should charge for opening the account, and then
|
||
every hundredth transaction.
|
||
|
||
We also want the operators to be genuinely independent and separate from each
|
||
other. We don’t want a single inherently authorized reliable broadcast channel,
|
||
because it is inherently a low cost target for the fifty one percent attack.
|
||
I have been thinking about implementing a reliable broadcast channel as
|
||
byzantine Paxos protocol, but this gives us a massive low cost fifty one
|
||
percent attack vulnerability. If the reliable broadcast channel is cheap
|
||
enough to be useful, it is cheap enough for the fifty one percent attack.
|
||
We want cheap testimony of valuable facts, which makes consensus mechanisms
|
||
unlikely to work.
|
||
|
||
A better way reliably implementing a reliable
|
||
broadcast channel is as a network of trusted witnesses, each of which keeps an
|
||
eye on the reliability of other witnesses, because each periodically uploads
|
||
the unbalanced tree testifying to its total state on several of the others,
|
||
and each makes it data reciprocally available to several of the others, and
|
||
each monitors the availability of several of the others, and each provides a
|
||
signed chain of its total state with each witness, or some witnesses. Because
|
||
the data is reciprocally available, each can testify to the uptime and
|
||
reliability of each of the others, and none can hide its state. Each makes
|
||
each of the nodes in each of its balanced trees available by index, the top
|
||
node in each of its unbalanced right hand tree is signed, and nodes in the
|
||
unbalanced tree constitute a separate sql like table, which times out
|
||
considerably faster than the nodes with a single index.
|
||
|
||
Downtime, failure to provide oids on request, and losing its recent state,
|
||
will be detected and will whack its reputation.
|
||
|
||
And it is up to the individual human to decide which trusted witness to follow,
|
||
which human decision roots all the automatic computer decisions.
|
||
|
||
## isolated
|
||
|
||
Isolated means that one transaction cannot mangle another transaction.
|
||
Easiest way to do this is that one gateway of the lightning network cannot
|
||
handle a transaction while another is pending. Which is going to be a problem
|
||
when we have nodes handling a lot of traffic, but a more efficient fix can
|
||
wait till we have traffic problems.
|
||
|
||
For a more efficient fix, we will need relative as well as absolute
|
||
transactions. A relative transaction, on being appended to an absolute
|
||
transaction, subtracts something from one of the outputs, and adds it to
|
||
another outputs. If this would produce a negative output, the compound
|
||
transaction is invalid. But this can wait until we have busy gateways.
|
||
|
||
## durable
|
||
|
||
Durable means that if something bad happens to your node, you can probably
|
||
recover, and if you don’t recover, no one else has problems.
|
||
|
||
If one party to a gateway goes down and does not come up, possibly because he
|
||
has lost the secret key to the gateway, the other party drops the most recent
|
||
transaction of the lightning layer to the blockchain layer.
|
||
|
||
If one party to a gateway goes down, but eventually comes up again, possibly
|
||
with lost data, they resynchronize.
|
||
|
||
Suppose you lose your wallet?
|
||
|
||
At present the standard way of recovering a wallet is that you create a wallet
|
||
using your BIPS master password, and it scans the blockchain for coins whose
|
||
public key corresponds to the secret keys it might have generated.
|
||
|
||
Which works to recover your money, but does not recover your metadata, and
|
||
will not recover a lightning gateway, since the your public key is not on the
|
||
blockchain, rather the sum of your public key, and the public key of other
|
||
parties to the gateway.
|
||
|
||
Metadata is becoming more important. If you lose your Wasabi wallet metadata,
|
||
you have a big problem, and if we use the wallet as the basis for private end
|
||
to end encrypted messages that can carry money, and for uncensorable social
|
||
networking, the wallet will have a lot of very valuable metadata.
|
||
|
||
We really need cloud backup of wallets, with the wallet encrypted by a secret
|
||
key derived from its master key, and cloud backup paid for though a lightning
|
||
gateway. And this needs to be built into the wallet, the way recovery by
|
||
scanning the blockchain is built into wallets today.
|
||
|
||
# trustless, fast, and free from blockchain analysis
|
||
|
||
That full circle transactions are atomic and consistent means that the
|
||
lightning network can operate without trust or reputation – completely
|
||
pseudonymous parties with no reputation can become nodes in the network,
|
||
making it very hard for the state to apply know your customer pressure.
|
||
|
||
If the full content of each gateway’s ownership never becomes known
|
||
except to the parties to the gateway, then the effect is to mingle and
|
||
merge coins on the blockchain, creating fungibility and untraceability,
|
||
as well as instant transactions.
|
||
|
||
If, on the other hand, we had a rather small number of trusted nodes that
|
||
have a special, central, and privileged position on the
|
||
lightning network, this would recreate the traceability problem of
|
||
correspondence banking. The lightning network has to trust the reliable
|
||
broadcast channels with reliability and broadcasting, but the information on
|
||
that channel is meaningless to anyone other than the parties to the
|
||
transaction.
|