This week’s newsletter requests testing of the latest release candidates for Bitcoin Core and LND, describes how helping people accept payments to bech32 addresses can lower fees, and lists notable code changes in popular Bitcoin projects.
● Help test Bitcoin Core 0.18.0 release candidates: Bitcoin Core’s third RC for its next major version is available and a fourth is being prepared. Testing is greatly appreciated. Please use this issue for reporting feedback.
● Help test LND 0.6-beta RC4: release candidates for the next major version of LND are being published. Testing by organizations and experienced LN users is encouraged to catch any regressions or serious problems that could affect users of the final release. Open a new issue if you discover any problems.
No notable technical news this week. (Note: When we at Optech started this newsletter, we decided to avoid stuffing short newsletters with fluff pieces and other unnecessary information, so newsletter length varies depending on the actual amount of significant technical news each week. You’ve probably seen us publish an occasional very long newsletter; this week, you see the opposite.)
Bech32 sending support
Week 5 of 24. Until the second anniversary of the segwit soft fork lock-in on 24 August 2019, the Optech Newsletter will contain this weekly section that provides information to help developers and organizations implement bech32 sending support—the ability to pay native segwit addresses. This doesn’t require implementing segwit yourself, but it does allow the people you pay to access all of segwit’s multiple benefits.
One reason your users and customers may want you to implement bech32 sending support is because it’ll allow the receivers of those payments to save on fees when they re-spend that money. This week, we’ll look at how much money they’ll save and discuss how their savings could also help you save money.
For the legacy P2PKH address format implemented in the first version of Bitcoin, the scriptSig that authorizes a spend is typically 107 vbytes. For P2SH-wrapped segwit P2WPKH, this same information is moved to a witness data field that only consumes 1/4 as many vbytes (27 vbytes) but whose P2SH overhead adds 23 vbytes for a total of 50 vbytes. For native segwit P2WPKH, there’s no P2SH overhead, so 27 vbytes is all that’s used.
This means you could argue that P2SH-P2WPKH saves over 50% compared to P2PKH, and that P2WPKH saves another almost 50% compared to P2SH-P2WPKH or 75% compared to P2PKH alone. However, spending transactions contain more than just scriptSigs and witness data, so the way we usually compare savings is by looking at prototype transactions. For example, we imagine a typical transaction containing a single input and two outputs (one to the receiver; one as change back to the spender). In that case:
- Spending P2PKH has a total transaction size of 220 vbytes
- Spending P2SH-P2WPKH has a size of 167 vbytes (24% savings)
- Spending P2WPKH output has a size of 141 vbytes (16% savings vs P2SH-P2WPKH or 35% vs P2PKH)
To compare simple multisig transactions (those that just use a single
OP_CHECKMULTSIG opcode), things get more complex because k-of-n
multisig inputs vary in size depending on the number of signatures (k)
and the number of public keys (n). So, for simplicity’s sake, we’ll
just plot the sizes of legacy P2SH-multisig compared to wrapped P2SH-P2WSH
multisig (up to the maximum 15-of-15 supported by legacy P2SH). We can
see that switching to P2SH-P2WSH can save from about 40% (1-of-2
multisig) to about 70% (15-of-15).
We can then compare P2SH-P2WSH to native P2WSH to see the additional constant-sized savings of about 35 bytes per transaction or about 5% to 15%.
The scripts described above account for almost all scripts being used with addresses that aren’t native segwit. (Users of more complex scripts, such as those used in LN, are mostly using native segwit today.) Those less efficient script types currently consume a majority fraction of block capacity (total block weight). Switching to native segwit in order to reduce a transaction’s weight allows you to reduce its fee by the same percentage without changing how long it’ll take to confirm—all other things being equal.
But all other things aren’t equal. Because the transactions use less block weight, there’s more weight available for other transactions. If the supply of available block weight increases and demand remains constant, we expect prices to go down (unless they’re already at the default minimum relay fee). This means more people spending native segwit inputs lowers the fee not just for those spenders but for everyone who creates transactions—including wallets and services that support sending to bech32 addresses.
Notable code and documentation changes
Notable changes this week in Bitcoin Core, LND, C-Lightning, Eclair, libsecp256k1, and Bitcoin Improvement Proposals (BIPs). Note: all merges described for Bitcoin Core and LND are to their master development branches; some may also be backported to their pending releases.
● Bitcoin Core #15711 generates bech32 addresses by default in the GUI. The user can still generate a P2SH-wrapped segwit address by unchecking a box on the Request Payment screen in case they need to receive money from a service that doesn’t yet provide bech32 sending support. The bitcoind default of generating P2SH-wrapped segwit addresses is not changed.
● C-Lightning #2540 adds an invoice hook that’s called whenever a “valid payment for an unpaid invoice has arrived.” Among other tasks that can be performed when a payment is received, this can be used by a plugin to implement “hold invoices” as previously implemented in LND (see our description of LND #2022 in Newsletter #38).
● C-Lightning #2554 changes the default invoice expiration from one hour to one week. This is the time after which the node will automatically reject attempts to pay the invoice. Services that want to minimize exchange rate risk will need to pass a lower
expiryvalue when using the