BIP: 112
Title: CHECKSEQUENCEVERIFY
Authors: BtcDrak
Mark Friedenbach
Eric Lombrozo
Status: Draft
Type: Standards Track
Created: 2015-08-10
==Abstract==
This BIP describes a new opcode (CHECKSEQUENCEVERIFY) for the Bitcoin
scripting system that in combination with BIP 68 allows execution
pathways of a script to be restricted based on the age of the output
being spent.
==Summary==
CHECKSEQUENCEVERIFY redefines the existing NOP3 opcode. When executed it
compares the top item on the stack to the nSequence field of the transaction
input containing the scriptSig. If it is greater than or equal to (1 << 31),
or if the transaction version is greater than or equal to 2, the transaction input
sequence is less than or equal to (1 << 31) and the top stack item is less than
the transaction input sequence, script exection continues as if a NOP was executed,
otherwise the script fails.
BIP 68's redefinition of nSequence prevents a non-final transaction
from being selected for inclusion in a block until the corresponding
input has reached the specified age, as measured in block height or
block time. By comparing the argument to CHECKSEQUENCEVERIFY against
the nSequence field, we indirectly verify a desired minimum age of the
the output being spent; until that relative age has been reached any
script execution pathway including the CHECKSEQUENCEVERIFY will fail
to validate, causing the transaction not to be selected for inclusion
in a block.
==Motivation==
BIP 68 repurposes the transaction nSequence field meaning by giving
sequence numbers new consensus-enforced semantics as a relative
lock-time. However, there is no way to build Bitcoin scripts to make
decisions based on this field.
By making the nSequence field accessible to script, it becomes
possible to construct code pathways that only become accessible some
minimum time after proof-of-publication. This enables a wide variety
of applications in phased protocols such as escrow, payment channels,
or bidirectional pegs.
===Examples===
====Escrow with Timeout====
An escrow that times out automatically 30 days after being funded can be
established in the following way. Alice, Bob and Escrow create a 2-of-3
address with the following redeemscript.
IF
2 3 CHECKMULTISIGVERIFY
ELSE
CHECKSEQUENCEVERIFY DROP
CHECKSIGVERIFY
ENDIF
At any time funds can be spent using signatures from any two of Alice,
Bob or the Escrow.
After 30 days Alice can sign alone.
The clock does not start ticking until the payment to the escrow address
confirms.
====Payment Channel Revokation====
Scriptable relative locktime provides a predictable amount of time to respond in
the event a counterparty broadcasts a revoked transaction: Absolute locktime
necessitates closing the channel and reopen it when getting close to the timeout,
whereas with relative locktime, the clock starts ticking the moment the
transactions confirms in a block. It also provides a means to know exactly how
long to wait (in number of blocks) before funds can be pulled out of the channel
in the event of a noncooperative counterparty.
====Hash Time-Locked Contracts====
Hashed Timelock Contracts (HTLCs) can be used to create chains of payments which
is required for lightning network payment channels. The scheme requires both
CHECKSEQUENCEVERIFY and CHECKLOCKTIMEVERIFY to enforce HTLC timeouts and
revokation.
In lightning commitment transactions, CHECKSEQUENCEVERIFY and CHECKLOCKTIMEVERIFY
enforce a delay between publishing the commitment transaction, and spending the
output. The delay is needed so that the counterparty has time to prove the
commitment was revoked and claim the outputs as a penalty.
====Retroactive Invalidation====
In many instances, we would like to create contracts that can be revoked in case
of some future event. However, given the immutable nature of the blockchain, it
is practically impossible to retroactively invalidate a previous commitment that
has already confirmed. The only mechanism we really have for retroactive
invalidation is blockchain reorganization which, for fundamental security
reasons, is designed to be very hard and very expensive to deliberately pull off.
Despite this limitation, we do have a way to provide something fairly similar
using CHECKSEQUENCEVERIFY by constructing scripts with multiple branches of
execution where one or more of the branches are delayed. That's to say, a
delayed branch cannot execute until a certain amount of time has passed since
the transaction containing the script (or a hash of it) confirmed. This provides
a time window in which someone can supply an invalidation condition which spends
the output, effectively invalidating the contract and potentially discouraging
another party from broadcasting the transaction in the first place.
==Specification==
Refer to the reference implementation, reproduced below, for the precise
semantics and detailed rationale for those semantics.
/* Threshold for nSequence: below this value it is interpreted
* as a relative lock-time, otherwise ignored. */
static const uint32_t SEQUENCE_LOCKTIME_THRESHOLD = (1 << 31);
/* Threshold for nSequence when interpreted as a relative
* lock-time: below this value it has units of blocks, otherwise
* seconds. */
static const uint32_t SEQUENCE_UNITS_THRESHOLD = (1 << 30);
case OP_NOP3:
{
if (!(flags & SCRIPT_VERIFY_CHECKSEQUENCEVERIFY)) {
// not enabled; treat as a NOP3
if (flags & SCRIPT_VERIFY_DISCOURAGE_UPGRADABLE_NOPS) {
return set_error(serror, SCRIPT_ERR_DISCOURAGE_UPGRADABLE_NOPS);
}
break;
}
if (stack.size() < 1)
return set_error(serror, SCRIPT_ERR_INVALID_STACK_OPERATION);
// Note that elsewhere numeric opcodes are limited to
// operands in the range -2**31+1 to 2**31-1, however it is
// legal for opcodes to produce results exceeding that
// range. This limitation is implemented by CScriptNum's
// default 4-byte limit.
//
// If we kept to that limit we'd have a year 2038 problem,
// even though the nLockTime field in transactions
// themselves is uint32 which only becomes meaningless
// after the year 2106.
//
// Thus as a special case we tell CScriptNum to accept up
// to 5-byte bignums, which are good until 2**39-1, well
// beyond the 2**32-1 limit of the nLockTime field itself.
const CScriptNum nSequence(stacktop(-1), fRequireMinimal, 5);
// In the rare event that the argument may be < 0 due to
// some arithmetic being done first, you can always use
// 0 MAX CHECKSEQUENCEVERIFY.
if (nSequence < 0)
return set_error(serror, SCRIPT_ERR_NEGATIVE_LOCKTIME);
// To provide for future soft-fork extensibility, if the
// operand is too large to be treated as a relative lock-
// time, CHECKSEQUENCEVERIFY behaves as a NOP.
if (nSequence >= SEQUENCE_LOCKTIME_THRESHOLD)
break;
// Actually compare the specified sequence number with the input.
if (!CheckSequence(nSequence))
return set_error(serror, SCRIPT_ERR_UNSATISFIED_LOCKTIME);
break;
}
bool CheckSequence(const CScriptNum& nSequence) const
{
// Relative lock times are supported by comparing the passed
// in operand to the sequence number of the input.
const int64_t txToSequence = (int64_t)txTo->vin[nIn].nSequence;
// Fail if the transaction's version number is not set high
// enough to trigger BIP 68 rules.
if (static_cast(txTo->nVersion) < 2)
return false;
// Sequence numbers above SEQUENCE_LOCKTIME_THRESHOLD
// are not consensus constrained. Testing that the transaction's
// sequence number is not above this threshold prevents
// using this property to get around a CHECKSEQUENCEVERIFY
// check.
if (txToSequence >= SEQUENCE_LOCKTIME_THRESHOLD)
return false;
// There are two kinds of nSequence: lock-by-blockheight
// and lock-by-blocktime, distinguished by whether
// nSequence < SEQUENCE_UNITS_THRESHOLD.
//
// We want to compare apples to apples, so fail the script
// unless the type of nSequence being tested is the same as
// the nSequence in the transaction.
if (!(
(txToSequence < SEQUENCE_UNITS_THRESHOLD && nSequence < SEQUENCE_UNITS_THRESHOLD) ||
(txToSequence >= SEQUENCE_UNITS_THRESHOLD && nSequence >= SEQUENCE_UNITS_THRESHOLD)
))
return false;
// Now that we know we're comparing apples-to-apples, the
// comparison is a simple numeric one.
if (nSequence > txToSequence)
return false;
return true;
}
==Reference Implementation==
A reference implementation is provided in the following git repository:
https://github.com/maaku/bitcoin/tree/checksequenceverify
==Deployment==
We reuse the double-threshold switchover mechanism from BIPs 34 and
66, with the same thresholds, but for nVersion = 4. The new rules are
in effect for every block (at height H) with nVersion = 4 and at least
750 out of 1000 blocks preceding it (with heights H-1000..H-1) also
have nVersion = 4. Furthermore, when 950 out of the 1000 blocks
preceding a block do have nVersion = 4, nVersion = 3 blocks become
invalid, and all further blocks enforce the new rules.
It is recommended that this soft-fork deployment trigger include other
related proposals for improving Bitcoin's lock-time capabilities, including:
[https://github.com/bitcoin/bips/blob/master/bip-0065.mediawiki BIP 65]:
OP_CHECKLOCKTIMEVERIFY,
[https://github.com/bitcoin/bips/blob/master/bip-0068.mediawiki BIP 68]:
Consensus-enforced transaction replacement signalled via sequence numbers,
and [https://github.com/bitcoin/bips/blob/master/bip-0113.mediawiki BIP 113]:
Median-Past-Time-Lock.
==Credits==
Mark Friedenbach invented the application of sequence numbers to
achieve relative lock-time, and wrote the reference implementation of
CHECKSEQUENCEVERIFY.
The reference implementation and this BIP was based heavily on work
done by Peter Todd for the closely related BIP 65.
BtcDrak authored this BIP document.
Thanks to Eric Lombrozo help with example usecases.
==References==
[https://github.com/bitcoin/bips/blob/master/bip-0068.mediawiki BIP 68] Consensus-enforced transaction replacement signalled via sequence numbers
[https://github.com/bitcoin/bips/blob/master/bip-0065.mediawiki BIP 65] OP_CHECKLOCKTIMEVERIFY
[https://github.com/bitcoin/bips/blob/master/bip-0113.mediawiki BIP 113] Median past block time for time-lock constraints
[http://lists.linuxfoundation.org/pipermail/lightning-dev/2015-July/000021.html HTLCs using OP_CHECKSEQUENCEVERIFY/OP_LOCKTIMEVERIFY and revocation hashes]
[http://lightning.network/lightning-network-paper.pdf Lightning Network]
[http://diyhpl.us/diyhpluswiki/transcripts/sf-bitcoin-meetup/2015-02-23-scaling-bitcoin-to-billions-of-transactions-per-day/ Scaling Bitcoin to Billions of Transactions Per Day]
[http://lists.linuxfoundation.org/pipermail/bitcoin-dev/2015-August/010396.html Softfork deployment considerations]
[https://gist.github.com/sipa/bf69659f43e763540550 Version bits]
[https://lists.linuxfoundation.org/pipermail/bitcoin-dev/2013-April/002433.html Jeremy Spilman Micropayment Channels]
==Copyright==
This document is placed in the public domain.