From mboxrd@z Thu Jan 1 00:00:00 1970 Return-Path: Received: from smtp1.linuxfoundation.org (smtp1.linux-foundation.org [172.17.192.35]) by mail.linuxfoundation.org (Postfix) with ESMTPS id 802D89CD for ; Thu, 10 May 2018 12:10:47 +0000 (UTC) X-Greylist: from auto-whitelisted by SQLgrey-1.7.6 Received: from azure.erisian.com.au (cerulean.erisian.com.au [139.162.42.226]) by smtp1.linuxfoundation.org (Postfix) with ESMTPS id 8F2F96B2 for ; Thu, 10 May 2018 12:10:46 +0000 (UTC) Received: from aj@azure.erisian.com.au (helo=sapphire.erisian.com.au) by azure.erisian.com.au with esmtpsa (Exim 4.84_2 #1 (Debian)) id 1fGkPC-0000so-5Y for ; Thu, 10 May 2018 22:10:44 +1000 Received: by sapphire.erisian.com.au (sSMTP sendmail emulation); Thu, 10 May 2018 22:10:27 +1000 Date: Thu, 10 May 2018 22:10:27 +1000 From: Anthony Towns To: bitcoin-dev@lists.linuxfoundation.org Message-ID: <20180510121027.GA17607@erisian.com.au> MIME-Version: 1.0 Content-Type: text/plain; charset=us-ascii Content-Disposition: inline User-Agent: Mutt/1.5.23 (2014-03-12) X-Spam-Score: -1.9 X-Spam-Score-int: -18 X-Spam-Bar: - X-Spam-Status: No, score=-1.9 required=5.0 tests=BAYES_00, T_TVD_FUZZY_SECURITIES,UNPARSEABLE_RELAY autolearn=ham version=3.3.1 X-Spam-Checker-Version: SpamAssassin 3.3.1 (2010-03-16) on smtp1.linux-foundation.org Subject: [bitcoin-dev] MAST/Schnorr related soft-forks X-BeenThere: bitcoin-dev@lists.linuxfoundation.org X-Mailman-Version: 2.1.12 Precedence: list List-Id: Bitcoin Protocol Discussion List-Unsubscribe: , List-Archive: List-Post: List-Help: List-Subscribe: , X-List-Received-Date: Thu, 10 May 2018 12:10:47 -0000 Hello world, After the core dev meetup in March I wrote up some notes of where I think things stand for signing stuff post-Schnorr. It was mostly for my own benefit but maybe it's helpful for others too, so... They're just notes, so may assume a fair bit of background to be able to understand the meaning of the bullet points. In particular, note that I'm using "schnorr" just to describe the signature algorithm, and the terms "key aggregation" to describe turning an n-of-n key multisig setup into a single key setup, and "signature aggregation" to describe combining signatures from many inputs/transactions together: those are often all just called "schnorr signatures" in various places. Anyway! I think it's fair to split the ideas around up as follows: 1) Schnorr CHECKSIG Benefits: - opportunity to change signature encoding from DER to save a few bytes per signature, and have fixed size signatures making tx size calculations easier - enables n-of-n multisig key aggregation (a single pubkey and signature gives n-of-n security; setup non-interactively via muSig, or semi-interactively via proof of possession of private key; interactive signature protocol) - enables m-of-n multisig key aggregation with interactive setup and interactive signature protocol, and possibly substantial storage requirements for participating signers - enables scriptless scripts and discreet log contracts via key aggregation and interactive - enables payment decorrelation for lightning - enables batch validation of signatures, which substantially reduces computational cost of signature verification, provided a single "all sigs valid" or "some sig(s) invalid" output (rather than "sig number 5 is invalid") is sufficient - better than ecdsa due to reducing signature malleability (and possibly due to having a security proof that has had more review?) Approaches: - bump segwit version to replace P2WPKH - replace an existing OP_NOP with OP_CHECKSCHNORRVERIFY - hardfork to allowing existing addresses to be solved via Schnorr sig as alternative to ECDSA 2) Merkelized Abstract Syntax Trees Two main benefits for enabling MAST: - logarithmic scaling for scripts with many alternative paths - only reveals (approximate) number of alternative execution branches, not what they may have been Approaches: - replace an existing OP_NOP with OP_MERKLE_TREE_VERIFY, and treat an item remaining on the alt stack at the end of script exeution as a script and do tail-recursion into it (BIP 116, 117) - bump the segwit version and introduce a "pay-to-merkelized-script" address form (BIP 114) 3) Taproot Requirements: - only feasible if Schnorr is available (required in order to make the pubkey spend actually be a multisig spend) - andytoshi has written up a security proof at https://github.com/apoelstra/taproot Benefits: - combines pay-to-pubkey and pay-to-script in a single address, improving privacy - allows choice of whether to use pubkey or script at spend time, allowing for more efficient spends (via pubkey) without reducing flexibility (via script) Approaches: - bump segwit version and introduce a "pay-to-taproot" address form 4) Graftroot Requirements: - only really feasible if Schnorr is implemented first, so that multiple signers can be required via a single pubkey/signature - people seem to want a security proof for this; not sure if that's hard or straightforward Benefits: - allows delegation of authorisation to spend an output already on the blockchain - constant scaling for scripts with many alternative paths (better than MAST's logarithmic scaling) - only reveals the possibility of alternative execution branches, not what they may have been or if any actually existed Drawbacks: - requires signing keys to be online when constructing scripts (cannot do complicated pay to cold wallet without warming it up) - requires storing signatures for scripts (if you were able to reconstruct the sigs, you could just sign the tx directly and wouldn't use a script) - cannot prove that alternative methods of spending are not possible to anyone who doesn't exclusively hold (part of) the output address private key - adds an extra signature check on script spends Approaches: - bump segwit version and introduce a "pay-to-graftroot" address form 5) Interactive Signature Aggregation Requirements: - needs Schnorr Description: - allows signers to interactively collaborate when constructing a transaction to produce a single signature that covers multiple inputs and/or OP_CHECKSIG invocations that are resolved by Schnorr signatures Benefits: - reduces computational cost of additional signatures (i think?) - reduces witness storage needed for additional signatures to just the sighash flag byte (or bytes, if it's expanded) - transaction batching and coinjoins potentially become cheaper than independent transactions, indirectly improving on-chain privacy Drawbacks: - each soft-fork introduces a checkpoint, such that signatures that are not validated by versions prior to the soft-fork cannot be aggregated with signatures that are validated by versions prior to the soft-fork (see [0] for discussion about avoiding that drawback) Approaches: - crypto logic can be implemented either by Bellare-Neven or MuSig - needs a new p2wpkh output format, so likely warrants a segwit version bump - may warrant allowing multiple aggregation buckets - may warrant peer-to-peer changes and a new per-tx witness 6) Non-interactive half-signature aggregation within transaction Requirements: - needs Schnorr - needs a security proof before deployment Benefits: - can halve the size of non-aggregatable signatures in a transaction - in particular implies the size overhead of a graftroot script is just 32B, the same as a taproot script Drawbacks: - cannot be used with scriptless-script signatures Approaches: - ideally best combined with interactive aggregate signatures, as it has similar implementation requirements 7) New SIGHASH modes These will also need a new segwit version (for p2pk/p2pkh) and probably need to be considered at the same time. 8) p2pk versus p2pkh Whether to stick with a pubkeyhash for the address or just have a pubkey needs to be decided for any new segwit version. 9) Other new opcodes Should additional opcodes in new segwit versions be reserved as OP_NOP or as OP_RETURN_VALID, or something else? Should any meaningful new opcodes be supported or re-enabled? 10) Hard-fork automatic upgrade of p2pkh to be spendable via segwit Making existing p2pk or p2pkh outputs spendable via Schnorr with interactive signature aggregation would likely be a big win for people with old UTXOs, without any decrease in security, especially if done a significant time after those features were supported for new outputs. 11) Should addresses be hashes or scripts? maaku's arguments for general opcodes for MAST make me wonder a bit if the "p2pkh" approach isn't better than the "p2wpkh" approach; ie should we have script opcodes as the top level way to write addresses, rather than picking the "best" form of address everyone should use, and having people have to opt-out of that. probably already too late to actually have that debate though. Anyway, I think what that adds up to is: - Everything other than MAST and maybe some misc new CHECKVERIFY opcodes really needs to be done via new segwit versions - We can evaluate MAST in segwit v0 independently -- use the existing BIPs to deploy MAST for v0; and re-evaluate entirely for v1 and later segwit versions. - There is no point deploying any of this for non-segwit scripts - Having the taproot script be a MAST root probably makes sense. If so, a separate OP_MERKLE_MEMBERSHIP_CHECK opcode still probably makes sense at some point. So I think that adds up to: a) soft-fork for MAST in segwit v0 anytime if there's community/economic support for it? b) soft-fork for OP_CHECK_SCHNORR_SIG_VERIFY in segwit v0 anytime c) soft-fork for segwit v1 providing Schnorr p2pk(h) addresses and taproot+mast addresses in not too much time d) soft-fork for segwit v2 introducing further upgrades, particularly graftroot e) soft-fork for segwit v2 to support interactive signature aggregation f) soft-fork for segwit v3 including non-interactive sig aggregation The rationale there is: (a) and (b) are self-contained and we could do them now. My feeling is better to skip them and go straight to (c) (c) is the collection of stuff that would be a huge win, and seems "easily" technically feasible. signature aggregation seems too complicated to fit in here, and getting the other stuff done while we finish thinking about sigagg seems completely worthwhile. (d) is a followon for (c), in case signature aggregation takes a *really* long while. It could conceivably be done as a different variation of segwit v1, really. It might turn out that there's no urgency for graftroot and it should be delayed until non-interactive sig aggregation is implementable. (e) and (f) are separated just because I worry that non-interactive sig aggregation might not turn out to be possible; doing them as a single upgrade would be preferrable. Cheers, aj [0] https://lists.linuxfoundation.org/pipermail/bitcoin-dev/2018-March/015838.html