Difference between revisions of "R-Puzzles"

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An R-Puzzle is a new type of script that allows for the spending party to sign the input UTXO using any valid Bitcoin keypair. This can be used to sign Metanet node addresses or addresses that hold tokens, or be randomly generated.
 
An R-Puzzle is a new type of script that allows for the spending party to sign the input UTXO using any valid Bitcoin keypair. This can be used to sign Metanet node addresses or addresses that hold tokens, or be randomly generated.
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In an R-puzzle, a knowledge proof of a value called 'k' is used to allow coins to be spent. 'k' is from the same mathematical set as Bitcoin [[Private Keys]] and must be known to the spender and used to generate 'r', which is the x-coordinate of k multiplied by the [[G|Generator point]]. 'r' is extracted from the signature used in the transaction and tested against a hash stored in the ScriptPubKey. k-chains can be managed using the same deterministic techniques as Bitcoin keychains.
 
In an R-puzzle, a knowledge proof of a value called 'k' is used to allow coins to be spent. 'k' is from the same mathematical set as Bitcoin [[Private Keys]] and must be known to the spender and used to generate 'r', which is the x-coordinate of k multiplied by the [[G|Generator point]]. 'r' is extracted from the signature used in the transaction and tested against a hash stored in the ScriptPubKey. k-chains can be managed using the same deterministic techniques as Bitcoin keychains.
  

Revision as of 06:24, 13 December 2019

An R-Puzzle is a new type of script that allows for the spending party to sign the input UTXO using any valid Bitcoin keypair. This can be used to sign Metanet node addresses or addresses that hold tokens, or be randomly generated.

In an R-puzzle, a knowledge proof of a value called 'k' is used to allow coins to be spent. 'k' is from the same mathematical set as Bitcoin Private Keys and must be known to the spender and used to generate 'r', which is the x-coordinate of k multiplied by the Generator point. 'r' is extracted from the signature used in the transaction and tested against a hash stored in the ScriptPubKey. k-chains can be managed using the same deterministic techniques as Bitcoin keychains.

Generating an ECDSA signature involves a few steps.

Inputs to the signature:

  1. k value 'k'
  2. keypair 'P1' = 'S1' · G
  3. Message 'm'

Method:

  1. Calculate R = k · G
  2. Define r = x-coordinate of R
  3. Calculate s = k-1(H(m) + S1 * r)mod n

Signature is (r, s) plus 5 bytes of formatting and a SIGHASH type

Signature Structure

Data Structure Length Data (hex)
Sequence Identifier 1 30
Length of Sequence 1 46
Integer Identifier 1 02
Byte-length of r 1 21
Needed when left(r, 1) > 7f 1 00 NOTE: This byte is not always needed
r 32 e9d34347e597e8b335745c6f8353580f4cbdb4bcde2794ef7aab915d996642
Integer identifier 1 02
Byte-length of s 1 21
Needed when left(s, 1) > 7f 1 00
s df2ccb52c7243c55bde34934bd55efbdac21c74a20bb7b438d1b6de3311f
Sighash type 1 01

When serialised the signature looks like this:

3046022100e9d34347e597e8b335745c6f8353580f4cbdb4bcde2794ef7aab915d996642022100df2ccb52c7243c55bde34934bd55efbdac21c74a20bb7b438d1b6de3311f01

Extracting R

The following piece of script pulls R out of the signature string by extracting first the length of R which is the 4th byte of the packet, and then using it to split R from the signature.

OP_3 OP_SPLIT OP_NIP OP_1 OP_SPLIT OP_SWAP OP_SPLIT OP_DROP

Stack Script Description
<sig> OP_3 OP_SPLIT OP_NIP OP_1 OP_SPLIT OP_SWAP OP_SPLIT OP_DROP scriptSig is loaded, signature on the stack
<3 bytes> <sig'> OP_NIP OP_1 OP_SPLIT OP_SWAP OP_SPLIT OP_DROP First 3 bytes of signature are split
<sig'> OP_1 OP_SPLIT OP_SWAP OP_SPLIT OP_DROP 3 byte data item is removed
<R Length> <sig"> OP_SWAP OP_SPLIT OP_DROP 1 byte containing R length is split from sig'
<sig"> <R Length> OP_SPLIT OP_DROP R Length parameter is moved to top of stack
<R> <sig'"> OP_DROP R is split from sig"
<R> sig'"== is dropped from stack, leaving R

P2RPH

Packaging this subscript into the following gives a Pay to R-Puzzle Hash script: OP_OVER OP_3 OP_SPLIT OP_NIP OP_1 OP_SPLIT OP_SWAP OP_SPLIT OP_DROP OP_HASH160 <Hash(r)> OP_EQUALVERIFY OP_CHECKSIG

R-Puzzle Use Cases

  • Delegation of authority
  • Tokens
  • Multi-signature schemes (with advanced scripting)