Payment Channels
Payment Channels are a mechanism where two or more parties can directly exchange and update a transaction. The mechanism includes methods for establishing, or opening a payment channel, updating the channel, and finalising, or closing the payment channel. The mechanism also covers the possibility of any of the parties becoming unresponsive, usually by enabling the recovery of funds after a fixed time.
Payment channels support extremely rapid transaction updates with only the final closing transaction being timestamped on the blockchain.
Payment channels can be useful for streaming data, operating a sequence of events, or operating with a live dataset in applications such as gaming and more.
Properties
- Payment channels can be opened and closed arbitrarily.
- Payment channels can be opened directly with the participating peers, without needing a third party.
- It is possible to open a payment channel with or without an on-chain action.
- Payment channels can be private or public.
- You can have many peers in a channel.
- You can add and remove peers from a channel.
- Payment channels are data conduits.
- Channels are typically closed with an on-chain payment, however an on-chain payment can be made outside the channel which causes it to update.
Overview of the Mechanism
A payment channel uses a transaction that has an nSequence that is less than 0xFFFFFFFF, and a nLocktime set to a time or block height in the future. The transaction can be updated many times between the peers until either, the nLocktime is reached, or nSequence is finalised and one of the parties transmits the transaction to the blockchain.
Example - Streaming Movie
The following goes through the sequence of opening, using, and closing a payment channel for the purposes of serving streamed content.
STEP 1
User browses catalog for titles to watch. Content can be on-chain or off-chain.
Step 2
User selects the content. At this point, there can be a few ways to manage the channel:
- In public via mining network.
- In private with pre-funded UTXO per channel.
- In private with separate channels for content purchase and service delivery per user.
Step 3
In this example, peers will use a timelocked UTXO in a public channel managed by Miners to serve the content. For the sake of this example we will assume a single UTXO is being used. This UTXO goes into a double spend monitoring pool.
The viewer sends a transaction with the following output script to the provider to initiate the channel:
Where:
- Svn is the Viewer's nth iteration of the channel signature.
- Pv is the Viewer's pubkey.
- Hv is the Viewer's PKH.
- Spn is the service provider's nth iteration of the channel signature.
- Pp is the service provider's pubkey.
- Hp is the service provider's PKH.
- Hc0 is the hash of the merkle root of the content being selected.
- Hcn is the hash of each content frame with Hc1 being the hash of the first frame.
- Cn is the content frame with C1 being the first frame data.
- Hfm is the hash of a message the user can trigger to prematurely end or pause the stream.
- Fm is a message that the provider uses to end the stream.
The sequence no. for the input being spent is still 1.
The transaction iterates between the two scripts as as follows:
Iteration 1
The user signs the inputs they want to spend in, as payment using SIGHASH_ALL with the following outputs:
Script No. | Purpose | Script | Amount |
---|---|---|---|
1 | Iteration 1: Content Request | Hc0 DROP DUP HASH160 Hp EQUALVERIFY CHECKSIGVERIFY EQUALVERIFY DUP HASH160 Hv EQUALVERIFY CHECKSIG | Price of first frame |
2 | Change | Viewer's change script | Change amount |
The Viewer also supplies the following data allowing the content provider to spend the payment channel output if the payment channel is closed:
- Sv0 Pv where the signature is signed as SIGHASH_ANYONECANPAY | SIGHASH_NONE. The user can do this as the payment channel's current TXID can be generated allowing the user to sign the output against the most recent revision of the payment channel.
This would allow the service provider to close the channel by countersigning the tx and settling on the network, guaranteeing payment for the first frame.
The transaction pays out the price of the first frame to the service provider and the remainder is returned to the viewer as change. If the viewer cancels their session without watching, the transaction can still be processed on the network, and using the provided second signature the service provider can claim their money.
Step 4
The provider responds with a new version of the transaction that modifies the output as shown:
Script No. | Purpose | Script | Amount |
---|---|---|---|
1 | Iteration 2: First frame | SHA256 Hc1 EQUALVERIFY DUP HASH160 Hp EQUALVERIFY CHECKSIGVERIFY EQUALVERIFY DUP HASH160 Hv EQUALVERIFY CHECKSIG | Price of second frame |
2 | Change | Viewer's change script | Change amount |
They also provide a new signature Sp0 for this output, allowing the user to countersign and broadcast the previous iteration should they wish to close the channel.
When the user receives this new output, they sign the inputs against the updated content to indicate they have received the first frame and provide the streaming service with payment for the second frame. The amounts can be optimised for the service provider's fee model.
If the payment channel were closed, this output could be subsequently spent by providing the second packet of movie data as part of the input. This is not the ideal way for the output to be created on-chain, as there are higher transaction fees involved, but is done this way to allow both parties to acknowledge the progression through the content.
Step 5
The viewer completes the transaction as shown:
Script No. | Purpose | Script | Amount |
---|---|---|---|
1 | Iteration 3: Second frame | SHA256 Hc2 EQUALVERIFY DUP HASH160 Hp EQUALVERIFY CHECKSIGVERIFY EQUALVERIFY DUP HASH160 Hv EQUALVERIFY CHECKSIG | Price of second frame |
2 | Change | Viewer's change script | Change amount |
As in the previous iteration, they sign to indicate they have received the frame and provide the streaming service with payment for the next frame. This can be optimised for each service provider's fee model.
They also provide a new signature for this output, Sv1, allowing the service provider to countersign should they need to close the channel. In this example, the keypairs being used don't need to change for each iteration, but they could.
Step N
The user can request that the provider close the channel. Streams can also be paused, or take place at any framerate, or even use larger transactions to move chunks at a time. In this case the user is deciding to close it.
Script No. | Purpose | Script | Amount |
---|---|---|---|
1 | Iteration N: Final frame | SHA256 Hfm EQUALVERIFY DUP HASH160 Hp EQUALVERIFY CHECKSIGVERIFY EQUALVERIFY DUP HASH160 Hv EQUALVERIFY CHECKSIG | Price of second frame |
2 | Change | Viewer's change script | Change amount |
The user puts the finish message hash at the front of the output. The streaming provider sees this and knows the customer wants to close the channel. The user provides a new signature for this output, Svn. This allows the streaming service provider to finalise the channel.
Step N+1
The provider broadcasts the final transaction and spends their payment with the following script:
Svn Pv Spn Pp Fm
In this way, rather than closing the transaction with a potentially large blob of content data at the front, just a short code need be used.