BIP 0038

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  BIP: draft
  Title: Passphrase-protected private key
  Author: Mike Caldwell
  Status: Draft
  Type: Standards Track
  Created: 20-11-2012

Abstract

A method is proposed for encoding a passphrase-protected Bitcoin private key record in the form of a 58-character Base58Check-encoded printable string. Encoded private key records are intended for use on paper wallets and physical Bitcoins. Each record string contains all the information needed to reconstitute the private key except for a passphrase, and the methodology uses salting and scrypt to resist brute-force attacks.

The method provides two encoding methodologies - one permitting any known private key to be encrypted with any passphrase, and another permitting a shared private key generation scheme where the party generating the final key string and its associated Bitcoin address (such as a physical bitcoin manufacturer) knows only a string derived from the original passphrase, and where the original passphrase is needed in order to actually redeem funds sent to the associated Bitcoin address.

A 32-bit hash of the resulting Bitcoin address is encoded in plaintext within each encrypted key, so it can be correlated to a Bitcoin address with reasonable probability by someone not knowing the passphrase. The complete Bitcoin address can be derived through successful decryption of the key record.

Copyright

This proposal is hereby placed in the public domain.

Rationale

User story: As a Bitcoin user who uses paper wallets, I would like the ability to add encryption, so that my Bitcoin paper storage can be two factor: something I have plus something I know.
User story: As a Bitcoin user who would like to pay a person or a company with a private key, I do not want to worry that any part of the communication path may result in the interception of the key and theft of my funds. I would prefer to offer an encrypted private key, and then follow it up with the password using a different communication channel (e.g. a phone call or SMS).
User story: (EC-multiplied keys) As a user of physical bitcoins, I would like a third party to be able to create password-protected Bitcoin private keys for me, without them knowing the password, so I can benefit from the physical bitcoin without the issuer having access to the private key. I would like to be able to choose a password whose minimum length and required format precludes me from memorizing it or engraving it on my physical bitcoin, without exposing me to an undue risk of password cracking and/or theft by the manufacturer of the item.

Specification

This proposal makes use of the following functions and definitions:

  • AES256Encrypt, AES256Decrypt: the simple form of the well-known AES block cipher without consideration for initialization vectors or block chaining. Each of these functions takes a 256-bit key and 16 bytes of input, and deterministically yields 16 bytes of output.
  • SHA256, a well-known hashing algorithm that takes an arbitrary number of bytes as input and deterministically yields a 32-byte hash.
  • scrypt: A well-known key derivation algorithm. It takes the following parameters: (string) password, (string) salt, (int) n, (int) r, (int) p, (int) length, and deterministically yields an array of bytes whose length is equal to the length parameter.
  • ECMultiply: Multiplication of an elliptic curve point by a scalar integer with respect to the secp256k1 elliptic curve.
  • G, N: Constants defined as part of the secp256k1 elliptic curve. G is an elliptic curve point, and N is a large positive integer.
  • Base58Check: a method for encoding arrays of bytes using 58 alphanumeric characters commonly used in the Bitcoin ecosystem.

Prefix

It is proposed that the resulting Base58Check-encoded string start with a '6'. The number '6' is intended to represent, from the perspective of the user, "a private key that needs something else to be usable" - an umbrella definition that could include keys participating in multisig transactions. The second character ought to give a hint as to what is needed, and for an AES256-encoded key based on this proposal, the uppercase letter P is proposed.

To keep the size of the encrypted key down, no initialization vectors (IVs) are used in the AES encryption. Rather, suitable values for IV-like use are derived using scrypt from the passphrase and from using a 32-bit hash of the resulting Bitcoin address as salt.

Proposed specification

  • Object identifier prefix: 0x0142 (non-EC-multiplied) or 0x0143 (EC-multiplied)
  • How the user sees it: 58 characters always starting with '6P'
    • Visual cues are present in the third character for visually identifying the EC-multiply and compress flag.
  • Count of payload bytes (beyond prefix): 37
    • 1 byte (flagbyte):
      • the most significant two bits are set as follows to preserve the visibility of the compression flag in the prefix, as well as to keep the payload within the range of allowable values that keep the "6P" prefix intact. For non-EC-multiplied keys, the bits are 11. For EC-multiplied keys, the bits are 00.
      • the bit with value 0x20 when set indicates the key should be converted to a bitcoin address using the compressed public key format.
      • remaining bits are reserved for future use (such as specifying different scrypt parameters or cryptocurrency systems) and must all be 0 to comply with this specification.
    • 4 bytes: SHA256(SHA256(expected_bitcoin_address))[0...3], used both for typo checking and as salt
    • 16 bytes: firsthalf: An AES-encrypted key material record (contents depend on whether EC multiplication is used)
    • 16 bytes: lasthalf: An AES-encrypted key material record (contents depend on whether EC multiplication is used)
  • Range in base58check encoding for non-EC-multiplied keys without compression (prefix 6PR):
    • Minimum value: 6PRHv1jg1ytiE4kT2QtrUz8gEjMQghZDWg1FuxjdYDzjUkcJeGdFj9q9Vi (based on 01 42 C0 plus thirty-six 00's)
    • Maximum value: 6PRWdmoT1ZursVcr5NiD14p5bHrKVGPG7yeEoEeRb8FVaqYSHnZTLEbYsU (based on 01 42 C0 plus thirty-six FF's)
  • Range in base58check encoding for non-EC-multiplied keys with compression (prefix 6PY):
    • Minimum value: 6PYJxKpVnkXUsnZAfD2B5ZsZafJYNp4ezQQeCjs39494qUUXLnXijLx6LG (based on 01 42 E0 plus thirty-six 00's)
    • Maximum value: 6PYXg5tGnLYdXDRZiAqXbeYxwDoTBNthbi3d61mqBxPpwZQezJTvQHsCnk (based on 01 42 E0 plus thirty-six FF's)
  • Range in base58check encoding for EC-multiplied keys without compression (prefix 6Pf):
    • Minimum value: 6PfKzduKZXAFXWMtJ19Vg9cSvbFg4va6U8p2VWzSjtHQCCLk3JSBpUvfpf (based on 01 43 00 plus thirty-six 00's)
    • Maximum value: 6PfYiPy6Z7BQAwEHLxxrCEHrH9kasVQ95ST1NnuEnnYAJHGsgpNPQ9dTHc (based on 01 43 00 plus thirty-six FF's)
  • Range in base58check encoding for non-EC-multiplied keys with compression (prefix 6Pn):
    • Minimum value: 6PnM2wz9LHo2BEAbvoGpGjMLGXCom35XwsDQnJ7rLiRjYvCxjpLenmoBsR (based on 01 43 20 plus thirty-six 00's)
    • Maximum value: 6PnZki3vKspApf2zym6Anp2jd5hiZbuaZArPfa2ePcgVf196PLGrQNyVUh (based on 01 43 20 plus thirty-six FF's)

Encryption when EC multiply flag is not used

Encrypting a private key without the EC multiplication offers the advantage that any known private key can be encrypted. The party performing the encryption must know the passphrase.

Encryption steps:

  1. Compute the Bitcoin address (ASCII), and take the first four bytes of SHA256(SHA256()) of it. Let's call this "addresshash".
  2. Derive a key from the passphrase using scrypt
    • Parameters: passphrase is the passphrase itself encoded in UTF-8. addresshash came from the earlier step, n=1048576, r=8, p=16, length=64
    • Let's split the resulting 64 bytes in half, and call them derivedhalf1 and derivedhalf2.
  3. Do AES256Encrypt(bitcoinprivkey[0...15] xor derivedhalf1[0...15], derivedhalf2), call the 16-byte result encryptedhalf1
  4. Do AES256Encrypt(bitcoinprivkey[16...31] xor derivedhalf1[16...31], derivedhalf2), call the 16-byte result encryptedhalf2

The encrypted private key is the Base58Check-encoded concatenation of the following:

  • 0x0142 + flagbyte + salt + encryptedhalf1 + encryptedhalf2

Encryption when EC multiply mode is used

Encrypting a private key with EC multiplication offers the ability for someone to generate encrypted keys knowing only an EC point derived from the original passphrase and some salt generated by the passphrase's owner, and without knowing the passphrase itself. Only the person who knows the original passphrase can decrypt the private key. This methodology does not offer the ability to encrypt a known private key - this means that the process of creating encrypted keys is also the process of generating new addresses.

Steps performed by the person with the passphrase (call him the owner):

  1. Generate 8 random bytes, call this ownersalt
  2. Derive a key from the passphrase using scrypt
    • Parameters: passphrase is the passphrase itself encoded in UTF-8. salt is ownersalt. n=1048576, r=8, p=16, length=32.
    • Call the resulting 32 bytes passfactor.
  3. Compute the elliptic curve point G * passfactor, and convert the result to compressed notation (33 bytes). Call this passpoint. Compressed notation is used for this purpose regardless of whether the intent is to create Bitcoin addresses with or without compressed public keys.
  4. Convey ownersalt and passpoint to the party generating the keys, along with a checksum to ensure integrity.
    • The following Base58Check-encoded format is recommended for this purpose: bytes "C6 3C 7B 3D 83 D9 C0" followed by ownersalt and then passpoint. The resulting string will start with the word "password", will be 71 characters in length, and encodes 48 bytes (7 bytes constant + 8 bytes ownersalt + 33 bytes passpoint). The checksum is handled in the Base58Check encoding.

Steps to create new encrypted private keys given an encrypted password string from owner (so we have ownersalt and passpoint, but we do not have passfactor or the passphrase):

  1. Generate 24 random bytes, call this seedb. Take SHA256(SHA256(seedb)) to yield 32 bytes, call this factorb.
  2. ECMultiply passpoint by factorb. Use the resulting EC point as a public key and hash it into a Bitcoin address using either compressed or uncompressed public key methodology (specify which methodology is used inside flagbyte). This is the generated Bitcoin address, call it generatedaddress.
  3. Take the first four bytes of SHA256(SHA256(generatedaddress)) and call it addresshash.
  4. Now we will encrypt seedb. Derive a second key from passpoint using scrypt
    • Parameters: passphrase is passpoint provided from the first party (expressed in binary as 33 bytes). salt is addresshash + ownersalt (concatenation), n=1048576, r=8, p=16, length=64
    • Split the result into two 16-byte halves and call them derivedhalf1 and derivedhalf2.
  5. Do AES256Encrypt(seedb[0...15]] xor derivedhalf1[0...15], derivedhalf2), call the 16-byte result encryptedpart1
  6. Do AES256Encrypt((encryptedpart1[8...15] + seedb[16...23]) xor derivedhalf1[16...31], derivedhalf2), call the 16-byte result encryptedseedb. + is concatenation.

The encrypted private key is the Base58Check-encoded concatenation of the following:

  • 0x0142 + flagbyte + addresshash + ownersalt + encryptedpart1[0...7] + encryptedpart2

Decryption steps:

  1. Collect encrypted private key and passphrase from user.
  2. Recompute passfactor and passpoint using same steps done pre-encryption (using ownersalt and the user's passphrase)
  3. Derive decryption key for factorb by passing passpoint and addresshash+ownersalt into scrypt function.
  4. Decrypt encryptedpart2 using AES256Decrypt to yield the last 8 bytes of seedb and the last 8 bytes of encryptedpart1.
  5. Decrypt encryptedpart1 to yield the remainder of seedb.
  6. Use seedb to compute factorb.
  7. Multiply passfactor by factorb mod N to yield the private key associated with generatedaddress.
  8. Convert that private key into a Bitcoin address, honoring the compression preference specified in the encrypted key.
  9. Hash the Bitcoin address, and verify that addresshash from the encrypted private key record matches the hash. If not, report that the passphrase entry was incorrect.

Backwards compatibility

Backwards compatibility is minimally applicable since this is a new standard that at most extends Wallet Import Format. It is assumed that an entry point for private key data may also accept existing formats of private keys (such as hexadecimal and Wallet Import Format); this draft uses a key format that cannot be mistaken for any existing one and preserves auto-detection capabilities.

Reference implementation

Coming soon as part of Casascius Bitcoin Address Utility