Mini private key format: Difference between revisions

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Added Python code
Clark (talk | contribs)
Added length check in Python code CheckShortKey()
Line 100: Line 100:
     Checks for typos in the short key.
     Checks for typos in the short key.
     """
     """
    if len(shortKey) != 22:
        return False
     t = '%s?' % shortKey
     t = '%s?' % shortKey
     tHash = hashlib.sha256(t).digest()
     tHash = hashlib.sha256(t).digest()

Revision as of 18:54, 8 September 2011

The mini private key format is a method of encoding a Bitcoin private key in 22 characters so that it can be embedded in a small space. This private key format was first used in Casascius physical bitcoins, and is also favorable for use in QR codes. The fewer characters encoded in a QR code, the lower dot density can be used, as well as more dots allocated to error correcting codes, and hence a QR code that is easier for a machine to read. The mini private key format offers its own built-in check code as a small margin of protection against typos.

An example key using this encoding is S4b3N3oGqDqR5jNuxEvDwf.

The way it might appear within a physical bitcoin is on a round card printed as follows:

S4b3N
3oGqDq
R5jNux
EvDwf

Decoding

The private key encoding consists of 22 alphanumeric characters from the base58 alphabet used in Bitcoin. The first of the 22 characters is always the uppercase letter S.

To obtain the full 256-bit private key, simply take the SHA256 hash of the entire string. There is no encoding for breaks in the string even if printed that way - the SHA256 should be taken of exactly twenty-two bytes.

SHA256("S4b3N3oGqDqR5jNuxEvDwf") = 0C28FCA386C7A227600B2FE50B7CAE11EC86D3BF1FBE471BE89827E19D72AA1D

Check code

The check code is designed to be simple, but relatively computationally expensive so that it cannot be used to quickly reduce the key space in a brute force attack. It offers seven bits worth of error protection (or, in other words, in the event of a typo, the typo will be caught about 127 out of 128 times, or over 99%).

To determine whether a string passes the check code, follow these steps:

  1. Ensure it is well-formed (22 characters, base58 alphabet, starts with S).
  2. Add a question mark to the end of the string, and take the SHA256 of that. If the SHA256 starts with eight zero bits (hex 00), then the string passes the check code.
  3. If it does not, then with the same string (ending in a question mark), do 717 (seven hundred seventeen) rounds of SHA256 on the string. If the result after the 717th round starts with eight zero bits (hex 00), then the string passes the check code.
  4. If the results of SHA256 after both tests don't start with eight zero bits, then the check fails.

Creating mini private keys

Creating mini private keys is relatively simple. One program which can create such keys is Casascius Bitcoin Utility.

Mini private keys must be created "from scratch", as the conversion from mini private key to full-size private key is one-way. In other words, there is no way to convert an existing full-size private key into a mini private key.

To create mini private keys, simply create random strings that satisfy the well-formedness requirement, and then eliminate the ones that do not pass the typo check. (This means eliminating more than 99% of the candidates.) Then use SHA256 to compute the corresponding private key, and in turn, the matching Bitcoin address. The Bitcoin address can always be computed from just the private key.

In all cases, you should use a secure cryptographic random number generator to eliminate risks of predictability of the random strings. Also, for stronger security, accept only the strings that pass the typo check on the 717th round rather than the first.

Python Code

import random
import hashlib

BASE58 = '123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz'

def Candidate():
    """
    Generate a random, well-formed mini private key.
    """
    return('%s%s' % ('S', ''.join(
        [BASE58[ random.randrange(0,len(BASE58)) ] for i in range(21)])))

def GenerateKeys(numKeys = 10, additionalSecurity = False):
    """
    Generate mini private keys and output the mini key as well as the full
    private key. numKeys is The number of keys to generate, and 
    additionalSecurity controls whether to do 717 rounds of SHA256
    """
    keysGenerated = 0
    totalCandidates = 0
    while keysGenerated < numKeys:
        try:
            cand = Candidate()
            # Do typo check
            t = '%s?' % cand
            # Take one round of SHA256
            candHash = hashlib.sha256(t).digest()
            if additionalSecurity:
                # Do the other 716 rounds for additional security
                for i in range(716):
                    candHash = hashlib.sha256(candHash).digest()
            # Check if the first eight bits of the hash are 0
            if candHash[0] == '\x00':
                privateKey = GetPrivateKey(cand)
                print('\n%s\nSHA256( ): %s\nsha256(?): %s' %
                      (cand, privateKey, candHash.encode('hex_codec')))
                if CheckShortKey(cand):
                    print('Validated.')
                else:
                    print('Invalid!')
                keysGenerated += 1
            totalCandidates += 1
        except KeyboardInterrupt:
            break
    print('\n%s: %i\n%s: %i\n%s: %r\n%s: %.1f' %
          ('Keys Generated', keysGenerated,
           'Total Candidates', totalCandidates,
           'Additional Security', additionalSecurity,
           'Reject Percentage',
           100*(1.0-keysGenerated/float(totalCandidates))))

def GetPrivateKey(shortKey):
    """
    Returns the hexadecimal representation of the private key corresponding
    to the given short key.
    """
    if CheckShortKey(shortKey):
        return hashlib.sha256(shortKey).hexdigest()
    else:
        print('Typo detected in private key!')
        return None

def CheckShortKey(shortKey):
    """
    Checks for typos in the short key.
    """
    if len(shortKey) != 22:
        return False
    t = '%s?' % shortKey
    tHash = hashlib.sha256(t).digest()
    # Check to see that first byte is \x00
    if tHash[0] == '\x00':
        return True
    else:
        # Do an additional 716 rounds
        for i in range(716):
            tHash = hashlib.sha256(tHash).digest()
        # Check again for \x00
        if tHash[0] == '\x00':
            return True
    return False