[OneDeuxTriSeiGo]

It depends on the implementation. The naive solution is to have every client hold the full chain.

The lightweight solutions come in two flavors, the easy "good enough" solution and the much harder ideal/zero trust solution.

The easy solution (light clients) to avoiding carrying the full chain is to simply rely on some set of known/trusted "beacon" servers that you are willing to trust to relay you the chain state and send you what information you need.

The hard solution is called a "super light" client. One of the famous super light client implementations is called flyclient[1]. It relies on some tricks with proof of work to only store log2(n) blocks out of the n blocks in the whole chain. It gives you enough security to be able to verify that your chain is valid and constructed from the origin block as well as allowing it to use the longest chain rule to decide what chain is the current "official" chain for the network just like you would with a full chain history.

There's another approach called NiPiPoWs [2] (non-interactive proofs of proofs-of-work) which is conceptually similar but is a bit more generally useful (outside of just as a light client system). A few networks adopted it but idk how prevalent its use is nowadays.

Note that flyclient, NiPiPoWs and most super light clients tend to rely on properties of proof of work as well as UTxO accounting models which disqualify their use for most networks. Cardano at the very least seems to have figured their own version out [3][4] and it exists kind of as a conceptual redesign of NiPiPoWs but for stake based systems (and actually came out of NiPiPoW research).

And of course super light clients still require miners to hold the full chain state generally but there's work[5][6] on how to do "light mining" which of course would allow everybody to abandon old chain state and only keep the data they care about.

Note: a lot of the research I linked is inter related as these are the researchers I kept up more closely with last time I was deep in the ecosystem but there's a lot of work on the topic in general coming at these problems from different angles.

--------------------------

1. Flyclient: Super-Light Clients for Cryptocurrencies - https://eprint.iacr.org/2019/226

2. Compact Storage of Superblocks for NIPoPoW Applications - https://eprint.iacr.org/2019/1444

3. Mithril: Stake-based Threshold Multisignatures - https://eprint.iacr.org/2021/916

4. The velvet path to superlight blockchain clients - https://dl.acm.org/doi/abs/10.1145/3479722.3480999

5. Mining in Logarithmic Space - https://dl.acm.org/doi/abs/10.1145/3460120.3484784

6. SNACKs: Leveraging Proofs of Sequential Work for Blockchain Light Clients - https://eprint.iacr.org/2022/240

[coolThingsFirst]

has there been any useful application of this outside of bitcoin as currency? Seems like a solid technical idea with lots of woo-woo on top of it.

[dollylambda]

You could argue the useful application has been that of a time-stamping service, which is what you need to order a transaction history.

[OneDeuxTriSeiGo]

Yeah at it's core a blockchain based cryptocurrency is a consensus system and decentralised resource market where the resource in question is space in the blocks within some time bound and verifiable proof of the time and state they were accepted in.

That core feature of "providing a total ordering for state changes and events with formal trust bounds" turns out to have a lot of potential uses.

Now of course truly providing correct timestamps or really any clock mechanism in a trustless way turns out to be massively difficult. And not just in a blockchain but really in any decentralised/distributed system. It's a famously unsolved problem.

There's some research[1] on how to go about providing a "global time"/"global clock" for cryptocurrencies without external trust assumptions but it's extraordinarily academic and most if not all systems just assume trusted time within some bound and hope for the best.

1. Permissionless Clock Synchronization with Public Setup - https://eprint.iacr.org/2022/1220

[dollylambda]

In a sense, a POW blockchain such as bitcoin can convey global time/global clock if all participants understand the average block propagation is 10 "minutes"? Sometimes longer, sometimes shorter but converges to 10 minutes in aggregate.

Over great distances this breaks down given limits on the speeds of transmition (speed of light), however, if transmission was instantaneous (quantum entanglement?), that would solve the dilemma of what does "now" mean light-years away given our relativistic idea of time between here and there.

[OneDeuxTriSeiGo]

Oh yeah. Sorry I misspoke a bit. I should have said that global time/clocks are an unsolved problem in non-proof-of-work systems.

Proof of work does a decent job approximating a monotonic clock but that only works when you are expending obscene amounts of energy on a global scale. And like you said it breaks down over longer distances (however luckily we don't have to deal with that too much now).

But in any non-PoW system, a "trustless" global clock is extremely non-trivial.

[dollylambda]

Thats because POW solves the Byzantine Generals problem as I understand it. Before POW, that problem was intractable (extremeley non-trivial). Its always lammented that so much energy is needed to solve the problem, although that seems to be the nature of the problem. Maybe time and energy are inexorably linked.

[OneDeuxTriSeiGo]

Which part? Blockchain in general?

[coolThingsFirst]

Blockchain and smart contracts.

[OneDeuxTriSeiGo]

There's certainly application outside of currencies. Bluesky/atproto for example is built on DIDs (decentralised IDs) and IPLD (the data format/standard of IPFS). Both are very heavily rooted in cryptocurrency tech.

There's a joke in the atproto community that it's a blockchain but without the currency because of this.

[dboreham]

Neither DID nor IPLD have anything to do with cryptocurrency from a technical perspective. At least no more than do X.509 and ssh.

[OneDeuxTriSeiGo]

IPLD is literally a merkle tree data structure format standardised by IPFS which is heavily rooted in cryptocurrency and in fact has its own cryptocurrency created by the IPFS devs: Filecoin.

DIDs were created by cryptocurrency orgs. The standard was created by a bunch of cryptocurrency groups working with the W3C and the entire time it was being developed, it was derided by non-cryptocurrency people as just another way for cryptocurrency to scam people. It doesn't stop being related to cryptocurrency once you realise it's useful.