```
BIP: 127 source
Layer: Applications
Title: Simple Proof-of-Reserves Transactions
Author: Steven Roose <steven@stevenroose.org>
Comments-Summary: No comments yet.
Comments-URI: https://github.com/bitcoin/bips/wiki/Comments:BIP-0127
Status: Draft
Type: Standards Track
Created: 2019-01-28
License: CC0-1.0
```

## Table of Contents |

## Abstract

This BIP describes a simple way to construct proof-of-reserves transactions. This proposal formalizes a standard format for constructing such proofs, easing their construction with existing wallet infrastructure and enabling general proof-verification software. It relies on existing standards such as regular Bitcoin transaction serialization/validation and the BIP 174 PSBT format. The proposal also includes the description of a PSBT extension for a better user experience.

## Copyright

This BIP is licensed under the Creative Commons CC0 1.0 Universal license.

## Motivation

From the very early days in the history of Bitcoin, there have been companies managing bitcoins for their users. These users give up control over their coins in return for a certain service. Inevitably, there have been many cases of companies losing their users' bitcoins without timely disclosing such events to the public. Proofs of Reserves are a way for companies managing large amounts of bitcoins to prove ownership over a given amount of funds. The regular proof of control helps to ensure that no significant loss has occurred.

While the term proof-of-reserves is not new by any means, the procedure is not very common among high-value custodian companies. One of the reasons for this is that every company that wants to perform a proof-of-reserves has to construct its own way to do so. Accordingly, their users have to understand the construction of the proof in order to be able to verify it. This raises the bar of entry both for custodians and for users.

### What this BIP is not doing

The proof-of-reserve construction described in this document has some known
shortcomings, mostly with regards to its privacy properties. While there exists
research about improved proof-of-reserves mechanisms that have much better
privacy properties^{[1]}, this BIP intentionally only formalizes
the de-facto existing method.

## Specification

Our specification consists of two parts:

- the format for the actual proofs
- a file format used to package a set of proofs and relevant metadata

- flexible proof construction to support complex wallet infrastructures
- easy integration with existing wallet solutions (both hardware and software wallets)
- support for verification via a standard procedure, regardless of publisher of the proof
- proof prevents reuse of proofs by other parties by committing to a message
- allow validating that the issuer had the funds under his control at a certain block, regardless of what happened after that block

### Proof Format

To allow for maximal compatibility with existing systems, proofs are formatted as regular Bitcoin transactions. However, one small adaptation to the transaction is made that has two functions:

- make the transaction unspendable to avoid putting funds at risk
- link the proof to the issuer of the proof to prevent copying proofs from other custodians

- The first input (the "commitment input")
- MUST have the txid part of the previous outpoint set to the SHA-256 hash of the commitment message prefixed with "Proof-of-Reserves: "
^{[2]}and index 0.

- MUST have the txid part of the previous outpoint set to the SHA-256 hash of the commitment message prefixed with "Proof-of-Reserves: "
- The remaining inputs
- MUST have signatures that commit to the commitment input (e.g. using
`SIGHASH_ALL`).

- MUST have signatures that commit to the commitment input (e.g. using
- The transaction MUST have a single output that is the exact sum of all the inputs, assuming the commitment input to have 0 value; this means the transaction has no miner fee.

### Proof File Format

In theory, the first part of the specification would be sufficient as a minimum viable standard. However, there are a number of motivations to extend the standard with an extra layer of metadata:

- constructing and combining multiple proofs
- Having thousands of UTXOs spread across different offline and online wallets could make it difficult to construct a single proof transaction with all UTXOs. Allowing multiple proof transactions with the same commitment message and block number gives extra flexibility to custodians with complex wallet infrastructure without making the combined proof less secure.

- metadata for verification
- Not all systems that will be used for verification have access to a full index of all transactions. However, proofs should be easily verifiable even after some of the UTXOs used in the proof are no longer unspent. Metadata present in the proof allows for relatively efficient verification of proofs even if no transaction index is available.

- potential future improvements
- The extensible metadata format allows for amending the standard in the future. One potential improvement would be having UTXO set commitments. These would allow the proofs-of-reserves to come with accompanying proofs-of-inclusion of all used UTXOs in the UTXO set at the block of proof construction (making validation even more efficient).

^{[3]}format.

syntax = "proto3"; import "google/protobuf/any.proto"; message OutputMeta { // Identify the outpoint. bytes txid = 1; uint32 vout = 2; // The block hash of the block where this output was created. bytes block_hash = 3; } message FinalProof { // The proof transaction. Should be able to be parsed like a regular // Bitcoin transaction. bytes proof_tx = 1; // The metadata of the ouputs used in the proof transaction. repeated OutputMeta output_metadata = 2; } message ProofOfReserves { // A version number for this format to enable extending it with // additional fields. uint32 version = 1; // The network magic for the network in which the proofs are valid. // 0xD9B4BEF9 for mainnet, 0x0709110B for testnet //TODO consider BIP44 coin type ids instead: // https://github.com/satoshilabs/slips/blob/master/slip-0044.md uint32 network_magic = 2; // The commitment message for this proof-of-reserves. // This message is global for all the proofs. string message = 3; // The block at which this proof is supposed to be validated. // Verification should take into account unspentness of outputs at this // block height. bytes block_hash = 4; // The set of final proof transactions with their output metadata. repeated FinalProof final_proofs = 5; // Reserved field that can potentially be used by proof-construction tools. // It can be ignored for verification. repeated google.protobuf.Any pending_proofs = 6; }

The last field, `pending_proofs`, leaves open some space in the same
file that can be used by proof-construction tools. This allows them to
construct different proofs incrementally without having to switch between file
formats.

### PSBT (BIP 174) extension

The "commitment input" detailed in the proof format section does not spend an
existing UTXO and thus shouldn't be signed (empty `scriptSig` and
witness). This can cause some problems when signing this type of transactions.
For example, hardware wallets often require the signer to provide information
about all inputs of transactions they are signing, such as the previous output
or previous transaction; this data obviously doesn't exist for the commitment
inputs.

For most existing devices, it's possible to circumvent these requirements by providing dummy data or by instructing the device to ignore this specific input. However, there is still a UX problem. Because the hardware wallet device doesn't recognize the transaction as a proof-of-reserves transaction it will think it is signing a regular transaction that is spending all the money in the UTXOs. Most devices will ask for confirmation with a message along the lines of "Are you sure you want to send XXX BTC to address [...]?". This is not the best user experience.

An addition to the BIP 174 PSBT format could help signing devices to recognize proof-of-reserve transactions.
The following field is added to the BIP 174 `INPUT` map:

- Type: Proof-of-reserves commitment
`PSBT_IN_POR_COMMITMENT = 0x09`- Key: None. The key must only contain the 1 byte type.
`{0x09}`

- Value: The UTF-8 encoded commitment message string for the proof-of-reserves.
`{porCommitment}`

- Key: None. The key must only contain the 1 byte type.

- MUST make sure the txid of the previous outpoint is set to the SHA-256 hash of the prefixed commitment message string, as detailed above;
- MUST assume the input value to be 0 (without requiring the previous output or transaction to be provided);
- SHOULD display the commitment message to ask the user for confirmation before signing any inputs;
- SHOULD only provide signatures with a signature hash that commits to this input;
- SHOULD accept an empty
`scriptSig`for this input (as if the`scriptPubKey`was`OP_TRUE`).

## Compatibility

The proof transaction specification is based on the Bitcoin transaction serialization protocol and will thus always be compatible with serializers that can interpret Bitcoin transactions. The protobuf file format is custom to this BIP and has a version byte to enable updates while attempting to remain backwards compatible.

## Implementations

A proof-of-concept implementation of the PSBT extension in the
rust-bitcoin project can be
found in the `psbt-por` branch here:
https://github.com/stevenroose/rust-bitcoin/tree/psbt-por

A work-in-progress implementation of a tool that produces and verifies proofs in the described format can be found here: https://github.com/stevenroose/reserves

An implementation of the custom proof PSBTs is part of the BDK, and can be found here: https://crates.io/crates/bdk-reserves

## Footnotes

**^**Dagher, Gaby G., Benedikt Bünz, Joseph Bonneau, Jeremy Clark, and Dan Boneh. "Provisions: Privacy-preserving proofs of solvency for Bitcoin exchanges." (2015).**^**If the message is "Some Message", the txid part should be`SHA-256("Proof-of-Reserves: Some Message")`with the string encoded as UTF-8.**^**https://github.com/protocolbuffers/protobuf/