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689 lines
31 KiB
Plaintext
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BIP: 38
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Title: Passphrase-protected private key
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Authors: Mike Caldwell
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Aaron Voisine <voisine@gmail.com>
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Status: Draft (Some confusion applies: The announcements for this never made it to the list, so it hasn't had public discussion)
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Type: Standards Track
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Created: 2012-11-20
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----------------------------------------------------------------------------------------------------------------------------------
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[[abstract]]
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Abstract
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~~~~~~~~
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A method is proposed for encrypting and encoding a passphrase-protected
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Bitcoin private key record in the form of a 58-character
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Base58Check-encoded printable string. Encrypted private key records are
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intended for use on paper wallets and physical Bitcoins. Each record
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string contains all the information needed to reconstitute the private
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key except for a passphrase, and the methodology uses salting and
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_scrypt_ to resist brute-force attacks.
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The method provides two encoding methodologies - one permitting any
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known private key to be encrypted with any passphrase, and another
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permitting a shared private key generation scheme where the party
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generating the final key string and its associated Bitcoin address (such
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as a physical bitcoin manufacturer) knows only a string derived from the
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original passphrase, and where the original passphrase is needed in
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order to actually redeem funds sent to the associated Bitcoin address.
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A 32-bit hash of the resulting Bitcoin address is encoded in plaintext
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within each encrypted key, so it can be correlated to a Bitcoin address
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with reasonable probability by someone not knowing the passphrase. The
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complete Bitcoin address can be derived through successful decryption of
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the key record.
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[[motivation]]
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Motivation
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~~~~~~~~~~
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The motivation to make this proposal stems from observations of the way
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physical bitcoins and paper wallets are used.
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An issuer of physical bitcoins must be trustworthy and trusted. Even if
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trustworthy, users are rightful to be skeptical about a third party with
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theoretical access to take their funds. A physical bitcoin that cannot
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be compromised by its issuer is always more intrinsically valuable than
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one that can.
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A two-factor physical bitcoin solution is highly useful to individuals
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and organizations wishing to securely own bitcoins without any risk of
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electronic theft and without the responsibility of climbing the
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technological learning curve necessary to produce such an environment
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themselves. Two-factor physical bitcoins allow a secure storage solution
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to be put in a box and sold on the open market, greatly enlarging the
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number of people who are able to securely store bitcoins.
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Existing methodologies for creating two-factor physical bitcoins are
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limited and cumbersome. At the time of this proposal, a user could
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create their own private key, submit the public key to the physical
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bitcoin issuer, and then receive a physical bitcoin that must be kept
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together with some sort of record of the user-generated private key, and
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finally, must be redeemed through a tool. The fact that the physical
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bitcoin must be kept together with a user-produced private key negates
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much of the benefit of the physical bitcoin - the user may as well just
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print and maintain a private key.
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A standardized password-protected private key format makes acquiring and
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redeeming two-factor physical bitcoins simpler for the user. Instead of
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maintaining a private key that cannot be memorized, the user may choose
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a passphrase of their choice. The passphrase may be much shorter than
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the length of a typical private key, short enough that they could use a
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label or engraver to permanently commit their passphrase to their
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physical Bitcoin piece once they have received it. By adopting a
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standard way to encrypt a private key, we maximize the possibility that
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they'll be able to redeem their funds in the venue of their choice,
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rather than relying on an executable redemption tool they may not wish
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to download.
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Password and passphrase-protected private keys enable new practical use
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cases for sending bitcoins from person to person. Someone wanting to
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send bitcoins through postal mail could send a password-protected paper
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wallet and give the recipient the passphrase over the phone or e-mail,
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making the transfer safe from interception of either channel. A user of
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paper wallets or Bitcoin banknote-style vouchers ("cash") could carry
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funded encrypted private keys while leaving a copy at home as an element
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of protection against accidental loss or theft. A user of paper wallets
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who leaves bitcoins in a bank vault or safety deposit box could keep the
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password at home or share it with trusted associates as protection
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against someone at the bank gaining access to the paper wallets and
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spending from them. The foreseeable and unforeseeable use cases for
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password-protected private keys are numerous.
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[[copyright]]
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Copyright
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~~~~~~~~~
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This proposal is hereby placed in the public domain.
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[[rationale]]
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Rationale
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~~~~~~~~~
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::
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_*User story:* As a Bitcoin user who uses paper wallets, I would like
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the ability to add encryption, so that my Bitcoin paper storage can be
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two factor: something I have plus something I know._
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+
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_*User story:* As a Bitcoin user who would like to pay a person or a
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company with a private key, I do not want to worry that any part of
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the communication path may result in the interception of the key and
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theft of my funds. I would prefer to offer an encrypted private key,
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and then follow it up with the password using a different
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communication channel (e.g. a phone call or SMS)._
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+
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_*User story:* (EC-multiplied keys) As a user of physical bitcoins, I
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would like a third party to be able to create password-protected
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Bitcoin private keys for me, without them knowing the password, so I
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can benefit from the physical bitcoin without the issuer having access
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to the private key. I would like to be able to choose a password whose
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minimum length and required format does not preclude me from
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memorizing it or engraving it on my physical bitcoin, without exposing
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me to an undue risk of password cracking and/or theft by the
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manufacturer of the item._
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+
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'*'User story:* (EC multiplied keys) As a user of paper wallets, I
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would like the ability to generate a large number of Bitcoin addresses
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protected by the same password, while enjoying a high degree of
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security (highly expensive scrypt parameters), but without having to
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incur the scrypt delay for each address I generate.
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[[specification]]
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Specification
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~~~~~~~~~~~~~
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This proposal makes use of the following functions and definitions:
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* *AES256Encrypt, AES256Decrypt*: the simple form of the well-known AES
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block cipher without consideration for initialization vectors or block
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chaining. Each of these functions takes a 256-bit key and 16 bytes of
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input, and deterministically yields 16 bytes of output.
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* *SHA256*, a well-known hashing algorithm that takes an arbitrary
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number of bytes as input and deterministically yields a 32-byte hash.
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* *scrypt*: A well-known key derivation algorithm. It takes the
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following parameters: (string) password, (string) salt, (int) n, (int)
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r, (int) p, (int) length, and deterministically yields an array of bytes
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whose length is equal to the length parameter.
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* *ECMultiply*: Multiplication of an elliptic curve point by a scalar
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integer with respect to the secp256k1 elliptic curve.
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* *G, N*: Constants defined as part of the secp256k1 elliptic curve. G
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is an elliptic curve point, and N is a large positive integer.
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* *Base58Check*: a method for encoding arrays of bytes using 58
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alphanumeric characters commonly used in the Bitcoin ecosystem.
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[[prefix]]
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Prefix
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^^^^^^
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It is proposed that the resulting Base58Check-encoded string start with
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a '6'. The number '6' is intended to represent, from the perspective of
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the user, "a private key that needs something else to be usable" - an
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umbrella definition that could be understood in the future to include
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keys participating in multisig transactions, and was chosen with
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deference to the existing prefix '5' most commonly observed in
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link:Wallet Import Format[Wallet Import Format] which denotes an
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unencrypted private key.
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It is proposed that the second character ought to give a hint as to what
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is needed as a second factor, and for an encrypted key requiring a
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passphrase, the uppercase letter P is proposed.
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To keep the size of the encrypted key down, no initialization vectors
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(IVs) are used in the AES encryption. Rather, suitable values for
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IV-like use are derived using scrypt from the passphrase and from using
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a 32-bit hash of the resulting Bitcoin address as salt.
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[[proposed-specification]]
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Proposed specification
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^^^^^^^^^^^^^^^^^^^^^^
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* Object identifier prefix: 0x0142 (non-EC-multiplied) or 0x0143
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(EC-multiplied). These are constant bytes that appear at the beginning
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of the Base58Check-encoded record, and their presence causes the
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resulting string to have a predictable prefix.
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* How the user sees it: 58 characters always starting with '6P'
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** Visual cues are present in the third character for visually
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identifying the EC-multiply and compress flag.
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* Count of payload bytes (beyond prefix): 37
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** 1 byte (_flagbyte_):
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*** the most significant two bits are set as follows to preserve the
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visibility of the compression flag in the prefix, as well as to keep the
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payload within the range of allowable values that keep the "6P" prefix
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intact. For non-EC-multiplied keys, the bits are 11. For EC-multiplied
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keys, the bits are 00.
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*** the bit with value 0x20 when set indicates the key should be
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converted to a bitcoin address using the compressed public key format.
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*** the bits with values 0x10 and 0x08 are reserved for a future
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specification that contemplates using multisig as a way to combine the
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factors such that parties in possession of the separate factors can
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independently sign a proposed transaction without requiring that any
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party possess both factors. These bits must be 0 to comply with this
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version of the specification.
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*** the bit with value 0x04 indicates whether a lot and sequence number
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are encoded into the first factor, and activates special behavior for
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including them in the decryption process. This applies to EC-multiplied
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keys only. Must be 0 for non-EC-multiplied keys.
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*** remaining bits are reserved for future use and must all be 0 to
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comply with this version of the specification.
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** 4 bytes: SHA256(SHA256(expected_bitcoin_address))[0...3], used both
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for typo checking and as salt
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** 16 bytes: Contents depend on whether EC multiplication is used.
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** 16 bytes: lasthalf: An AES-encrypted key material record (contents
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depend on whether EC multiplication is used)
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* Range in base58check encoding for non-EC-multiplied keys without
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compression (prefix 6PR):
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** Minimum value:
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6PRHv1jg1ytiE4kT2QtrUz8gEjMQghZDWg1FuxjdYDzjUkcJeGdFj9q9Vi (based on 01
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42 C0 plus thirty-six 00's)
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** Maximum value:
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6PRWdmoT1ZursVcr5NiD14p5bHrKVGPG7yeEoEeRb8FVaqYSHnZTLEbYsU (based on 01
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42 C0 plus thirty-six FF's)
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* Range in base58check encoding for non-EC-multiplied keys with
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compression (prefix 6PY):
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** Minimum value:
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6PYJxKpVnkXUsnZAfD2B5ZsZafJYNp4ezQQeCjs39494qUUXLnXijLx6LG (based on 01
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42 E0 plus thirty-six 00's)
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** Maximum value:
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6PYXg5tGnLYdXDRZiAqXbeYxwDoTBNthbi3d61mqBxPpwZQezJTvQHsCnk (based on 01
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42 E0 plus thirty-six FF's)
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* Range in base58check encoding for EC-multiplied keys without
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compression (prefix 6Pf):
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** Minimum value:
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6PfKzduKZXAFXWMtJ19Vg9cSvbFg4va6U8p2VWzSjtHQCCLk3JSBpUvfpf (based on 01
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43 00 plus thirty-six 00's)
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** Maximum value:
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6PfYiPy6Z7BQAwEHLxxrCEHrH9kasVQ95ST1NnuEnnYAJHGsgpNPQ9dTHc (based on 01
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43 00 plus thirty-six FF's)
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* Range in base58check encoding for non-EC-multiplied keys with
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compression (prefix 6Pn):
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** Minimum value:
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6PnM2wz9LHo2BEAbvoGpGjMLGXCom35XwsDQnJ7rLiRjYvCxjpLenmoBsR (based on 01
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43 20 plus thirty-six 00's)
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** Maximum value:
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6PnZki3vKspApf2zym6Anp2jd5hiZbuaZArPfa2ePcgVf196PLGrQNyVUh (based on 01
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43 20 plus thirty-six FF's)
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[[encryption-when-ec-multiply-flag-is-not-used]]
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Encryption when EC multiply flag is not used
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++++++++++++++++++++++++++++++++++++++++++++
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Encrypting a private key without the EC multiplication offers the
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advantage that any known private key can be encrypted. The party
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performing the encryption must know the passphrase.
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Encryption steps:
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1. Compute the Bitcoin address (ASCII), and take the first four bytes
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of SHA256(SHA256()) of it. Let's call this "addresshash".
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2. Derive a key from the passphrase using scrypt
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* Parameters: _passphrase_ is the passphrase itself encoded in UTF-8.
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salt is _addresshash_ from the earlier step, n=16384, r=8, p=8,
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length=64 (n, r, p are provisional and subject to consensus)
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* Let's split the resulting 64 bytes in half, and call them
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_derivedhalf1_ and _derivedhalf2_.
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3. Do AES256Encrypt(bitcoinprivkey[0...15] xor derivedhalf1[0...15],
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derivedhalf2), call the 16-byte result _encryptedhalf1_
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4. Do AES256Encrypt(bitcoinprivkey[16...31] xor derivedhalf1[16...31],
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derivedhalf2), call the 16-byte result _encryptedhalf2_
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The encrypted private key is the Base58Check-encoded concatenation of
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the following, which totals 39 bytes without Base58 checksum:
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* 0x01 0x42 + _flagbyte_ + _salt_ + _encryptedhalf1_ + _encryptedhalf2_
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Decryption steps:
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1. Collect encrypted private key and passphrase from user.
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2. Derive _derivedhalf1_ and _derivedhalf2_ by passing the passphrase
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and _addresshash_ into scrypt function.
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3. Decrypt _encryptedhalf1_ and _encryptedhalf2_ using AES256Decrypt,
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merge them to form the encrypted private key.
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4. Convert that private key into a Bitcoin address, honoring the
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compression preference specified in _flagbyte_ of the encrypted key
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record.
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5. Hash the Bitcoin address, and verify that _addresshash_ from the
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encrypted private key record matches the hash. If not, report that the
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passphrase entry was incorrect.
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[[encryption-when-ec-multiply-mode-is-used]]
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Encryption when EC multiply mode is used
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++++++++++++++++++++++++++++++++++++++++
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Encrypting a private key with EC multiplication offers the ability for
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someone to generate encrypted keys knowing only an EC point derived from
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the original passphrase and some salt generated by the passphrase's
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owner, and without knowing the passphrase itself. Only the person who
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knows the original passphrase can decrypt the private key. A code known
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as an _intermediate code_ conveys the information needed to generate
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such a key without knowledge of the passphrase.
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This methodology does not offer the ability to encrypt a known private
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key - this means that the process of creating encrypted keys is also the
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process of generating new addresses. On the other hand, this serves a
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security benefit for someone possessing an address generated this way:
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if the address can be recreated by decrypting its private key with a
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passphrase, and it's a strong passphrase one can be certain only he
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knows himself, then he can safely conclude that nobody could know the
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private key to that address.
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The person who knows the passphrase and who is the intended beneficiary
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of the private keys is called the _owner_. He will generate one or more
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"intermediate codes", which are the first factor of a two-factor
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redemption system, and will give them to someone else we'll call
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_printer_, who generates a key pair with an intermediate code can know
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the address and encrypted private key, but cannot decrypt the private
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key without the original passphrase.
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An intermediate code should, but is not required to, embed a printable
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"lot" and "sequence" number for the benefit of the user. The proposal
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forces these lot and sequence numbers to be included in any valid
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private keys generated from them. An owner who has requested multiple
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private keys to be generated for him will be advised by applications to
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ensure that each private key has a unique lot and sequence number
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consistent with the intermediate codes he generated. These mainly help
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protect _owner_ from potential mistakes and/or attacks that could be
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made by _printer_.
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The "lot" and "sequence" number are combined into a single 32 bit
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number. 20 bits are used for the lot number and 12 bits are used for the
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sequence number, such that the lot number can be any decimal number
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between 0 and 1048575, and the sequence number can be any decimal number
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between 0 and 4095. For programs that generate batches of intermediate
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codes for an _owner_, it is recommended that lot numbers be chosen at
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random within the range 100000-999999 and that sequence numbers are
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assigned starting with 1.
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Steps performed by _owner_ to generate a single intermediate code, if
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lot and sequence numbers are being included:
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1. Generate 4 random bytes, call them _ownersalt_.
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2. Encode the lot and sequence numbers as a 4 byte quantity
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(big-endian): lotnumber * 4096 + sequencenumber. Call these four bytes
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_lotsequence_.
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3. Concatenate _ownersalt_ + _lotsequence_ and call this
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_ownerentropy_.
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4. Derive a key from the passphrase using scrypt
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* Parameters: _passphrase_ is the passphrase itself encoded in UTF-8.
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salt is _ownersalt_. n=16384, r=8, p=8, length=32.
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* Call the resulting 32 bytes _prefactor_.
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* Take SHA256(SHA256(_prefactor_ + _ownerentropy_)) and call this
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_passfactor_.
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5. Compute the elliptic curve point G * _passfactor_, and convert the
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result to compressed notation (33 bytes). Call this _passpoint_.
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Compressed notation is used for this purpose regardless of whether the
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intent is to create Bitcoin addresses with or without compressed public
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keys.
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6. Convey _ownersalt_ and _passpoint_ to the party generating the keys,
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along with a checksum to ensure integrity.
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* The following Base58Check-encoded format is recommended for this
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purpose: magic bytes "2C E9 B3 E1 FF 39 E2 51" followed by
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_ownerentropy_, and then _passpoint_. The resulting string will start
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with the word "passphrase" due to the constant bytes, will be 72
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characters in length, and encodes 49 bytes (8 bytes constant + 8 bytes
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_ownerentropy_ + 33 bytes _passpoint_). The checksum is handled in the
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Base58Check encoding. The resulting string is called
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_intermediate_passphrase_string_.
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If lot and sequence numbers are not being included, then follow the same
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procedure with the following changes:
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* _ownersalt_ is 8 random bytes instead of 4, and _lotsequence_ is
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omitted. _ownerentropy_ becomes an alias for _ownersalt_.
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* The SHA256 conversion of _prefactor_ to _passfactor_ is omitted.
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Instead, the output of scrypt is used directly as _passfactor_.
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* The magic bytes are "2C E9 B3 E1 FF 39 E2 53" instead (the last byte
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is 0x53 instead of 0x51).
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Steps to create new encrypted private keys given
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_intermediate_passphrase_string_ from _owner_ (so we have
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_ownerentropy_, and _passpoint_, but we do not have _passfactor_ or the
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passphrase):
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1. Set _flagbyte_.
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* Turn on bit 0x20 if the Bitcoin address will be formed by hashing the
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compressed public key (optional, saves space, but many Bitcoin
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implementations aren't compatible with it)
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* Turn on bit 0x04 if _ownerentropy_ contains a value for _lotsequence_.
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(While it has no effect on the keypair generation process, the
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decryption process needs this flag to know how to process
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_ownerentropy_)
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2. Generate 24 random bytes, call this _seedb_. Take
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SHA256(SHA256(_seedb_)) to yield 32 bytes, call this _factorb_.
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3. ECMultiply _passpoint_ by _factorb_. Use the resulting EC point as a
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public key and hash it into a Bitcoin address using either compressed or
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uncompressed public key methodology (specify which methodology is used
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inside _flagbyte_). This is the generated Bitcoin address, call it
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_generatedaddress_.
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4. Take the first four bytes of SHA256(SHA256(_generatedaddress_)) and
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call it _addresshash_.
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5. Now we will encrypt _seedb_. Derive a second key from _passpoint_
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using scrypt
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* Parameters: _passphrase_ is _passpoint_ provided from the first party
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(expressed in binary as 33 bytes). _salt_ is _addresshash_ +
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_ownerentropy_, n=1024, r=1, p=1, length=64. The "+" operator is
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concatenation.
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* Split the result into two 32-byte halves and call them _derivedhalf1_
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and _derivedhalf2_.
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6. Do AES256Encrypt(seedb[0...15] xor derivedhalf1[0...15],
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derivedhalf2), call the 16-byte result _encryptedpart1_
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7. Do AES256Encrypt((encryptedpart1[8...15] + seedb[16...23]) xor
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derivedhalf1[16...31], derivedhalf2), call the 16-byte result
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_encryptedpart2_. The "+" operator is concatenation.
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The encrypted private key is the Base58Check-encoded concatenation of
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the following, which totals 39 bytes without Base58 checksum:
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* 0x01 0x43 + _flagbyte_ + _addresshash_ + _ownerentropy_ +
|
|
_encryptedpart1_[0...7] + _encryptedpart2_
|
|
|
|
[[confirmation-code]]
|
|
Confirmation code
|
|
|
|
The party generating the Bitcoin address has the option to return a
|
|
_confirmation code_ back to _owner_ which allows _owner_ to
|
|
independently verify that he has been given a Bitcoin address that
|
|
actually depends on his passphrase, and to confirm the lot and sequence
|
|
numbers (if applicable). This protects _owner_ from being given a
|
|
Bitcoin address by the second party that is unrelated to the key
|
|
derivation and possibly spendable by the second party. If a Bitcoin
|
|
address given to _owner_ can be successfully regenerated through the
|
|
confirmation process, _owner_ can be reasonably assured that any
|
|
spending without the passphrase is infeasible. This confirmation code is
|
|
75 characters starting with "cfrm38".
|
|
|
|
To generate it, we need _flagbyte_, _ownerentropy_, _factorb_,
|
|
_derivedhalf1_ and _derivedhalf2_ from the original encryption
|
|
operation.
|
|
|
|
1. ECMultiply _factorb_ by G, call the result _pointb_. The result is
|
|
33 bytes.
|
|
2. The first byte is 0x02 or 0x03. XOR it by (derivedhalf2[31] & 0x01),
|
|
call the resulting byte _pointbprefix_.
|
|
3. Do AES256Encrypt(pointb[1...16] xor derivedhalf1[0...15],
|
|
derivedhalf2) and call the result _pointbx1_.
|
|
4. Do AES256Encrypt(pointb[17...32] xor derivedhalf1[16...31],
|
|
derivedhalf2) and call the result _pointbx2_.
|
|
5. Concatenate _pointbprefix_ + _pointbx1_ + _pointbx2_ (total 33
|
|
bytes) and call the result _encryptedpointb_.
|
|
|
|
The result is a Base58Check-encoded concatenation of the following:
|
|
|
|
* 0x64 0x3B 0xF6 0xA8 0x9A + _flagbyte_ + _addresshash_ + _ownerentropy_
|
|
+ _encryptedpointb_
|
|
|
|
A confirmation tool, given a passphrase and a confirmation code, can
|
|
recalculate the address, verify the address hash, and then assert the
|
|
following: "It is confirmed that Bitcoin address _address_ depends on
|
|
this passphrase". If applicable: "The lot number is _lotnumber_ and the
|
|
sequence number is _sequencenumber_."
|
|
|
|
To recalculate the address:
|
|
|
|
1. Derive _passfactor_ using scrypt with _ownerentropy_ and the user's
|
|
passphrase and use it to recompute _passpoint_
|
|
2. Derive decryption key for _pointb_ using scrypt with _passpoint_,
|
|
_addresshash_, and _ownerentropy_
|
|
3. Decrypt _encryptedpointb_ to yield _pointb_
|
|
4. ECMultiply _pointb_ by _passfactor_. Use the resulting EC point as a
|
|
public key and hash it into _address_ using either compressed or
|
|
uncompressed public key methodology as specifid in _flagbyte_.
|
|
|
|
[[decryption]]
|
|
Decryption
|
|
|
|
1. Collect encrypted private key and passphrase from user.
|
|
2. Derive _passfactor_ using scrypt with _ownerentropy_ and the user's
|
|
passphrase and use it to recompute _passpoint_
|
|
3. Derive decryption key for _seedb_ using scrypt with _passpoint_,
|
|
_addresshash_, and _ownersalt_
|
|
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
|
|
~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
Backwards compatibility is minimally applicable since this is a new
|
|
standard that at most extends link:Wallet Import Format[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
|
|
link:Wallet Import Format[Wallet Import Format]); this draft uses a key
|
|
format that cannot be mistaken for any existing one and preserves
|
|
auto-detection capabilities.
|
|
|
|
[[suggestions-for-implementers-of-proposal-with-alt-chains]]
|
|
Suggestions for implementers of proposal with alt-chains
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
If this proposal is accepted into alt-chains, it is requested that the
|
|
unused flag bytes not be used for denoting that the key belongs to an
|
|
alt-chain.
|
|
|
|
Alt-chain implementers should exploit the address hash for this purpose.
|
|
Since each operation in this proposal involves hashing a text
|
|
representation of a coin address which (for Bitcoin) includes the
|
|
leading '1', an alt-chain can easily be denoted simply by using the
|
|
alt-chain's preferred format for representing an address. Alt-chain
|
|
implementers may also change the prefix such that encrypted addresses do
|
|
not start with "6P".
|
|
|
|
[[discussion-item-scrypt-parameters]]
|
|
Discussion item: scrypt parameters
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
This proposal leaves the scrypt parameters up in the air. The following
|
|
items are proposed for consideration:
|
|
|
|
The main goal of scrypt is to reduce the feasibility of brute force
|
|
attacks. It must be assumed that an attacker will be able to use an
|
|
efficient implementation of scrypt. The parameters should force a highly
|
|
efficient implementation of scrypt to wait a decent amount of time to
|
|
slow attacks.
|
|
|
|
On the other hand, an unavoidably likely place where scrypt will be
|
|
implemented is using slow interpreted languages such as javascript. What
|
|
might take milliseconds on an efficient scrypt implementation may take
|
|
seconds in javascript.
|
|
|
|
It is believed, however, that someone using a javascript implementation
|
|
is probably dealing with codes by hand, one at a time, rather than
|
|
generating or processing large batches of codes. Thus, a wait time of
|
|
several seconds is acceptable to a user.
|
|
|
|
A private key redemption process that forces a server to consume several
|
|
seconds of CPU time would discourage implementation by the server owner,
|
|
because they would be opening up a denial of service avenue by inviting
|
|
users to make numerous attempts to invoke the redemption process.
|
|
However, it's also feasible for the server owner to implement his
|
|
redemption process in such a way that the decryption is done by the
|
|
user's browser, offloading the task from his own server (and providing
|
|
another reason why the chosen scrypt parameters should be tolerant of
|
|
javascript-based decryptors).
|
|
|
|
The preliminary values of 16384, 8, and 8 are hoped to offer the
|
|
following properties:
|
|
|
|
* Encryption/decryption in javascript requiring several seconds per
|
|
operation
|
|
* Use of the parallelization parameter provides a modest opportunity for
|
|
speedups in environments where concurrent threading is available - such
|
|
environments would be selected for processes that must handle bulk
|
|
quantities of encryption/decryption operations. Estimated time for an
|
|
operation is in the tens or hundreds of milliseconds.
|
|
|
|
[[reference-implementation]]
|
|
Reference implementation
|
|
~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
Added to alpha version of Casascius Bitcoin Address Utility for Windows
|
|
available at:
|
|
|
|
* via https: https://casascius.com/btcaddress-alpha.zip
|
|
* at github: https://github.com/casascius/Bitcoin-Address-Utility
|
|
|
|
Click "Tools" then "PPEC Keygen" (provisional name)
|
|
|
|
[[test-vectors]]
|
|
Test vectors
|
|
~~~~~~~~~~~~
|
|
|
|
[[no-compression-no-ec-multiply]]
|
|
No compression, no EC multiply
|
|
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
|
|
|
Test 1:
|
|
|
|
* Passphrase: TestingOneTwoThree
|
|
* Encrypted: 6PRVWUbkzzsbcVac2qwfssoUJAN1Xhrg6bNk8J7Nzm5H7kxEbn2Nh2ZoGg
|
|
* Unencrypted (WIF): 5KN7MzqK5wt2TP1fQCYyHBtDrXdJuXbUzm4A9rKAteGu3Qi5CVR
|
|
* Unencrypted (hex):
|
|
CBF4B9F70470856BB4F40F80B87EDB90865997FFEE6DF315AB166D713AF433A5
|
|
|
|
Test 2:
|
|
|
|
* Passphrase: Satoshi
|
|
* Encrypted: 6PRNFFkZc2NZ6dJqFfhRoFNMR9Lnyj7dYGrzdgXXVMXcxoKTePPX1dWByq
|
|
* Unencrypted (WIF): 5HtasZ6ofTHP6HCwTqTkLDuLQisYPah7aUnSKfC7h4hMUVw2gi5
|
|
* Unencrypted (hex):
|
|
09C2686880095B1A4C249EE3AC4EEA8A014F11E6F986D0B5025AC1F39AFBD9AE
|
|
|
|
[[compression-no-ec-multiply]]
|
|
Compression, no EC multiply
|
|
^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
|
|
|
Test 1:
|
|
|
|
* Passphrase: TestingOneTwoThree
|
|
* Encrypted: 6PYNKZ1EAgYgmQfmNVamxyXVWHzK5s6DGhwP4J5o44cvXdoY7sRzhtpUeo
|
|
* Unencrypted (WIF):
|
|
L44B5gGEpqEDRS9vVPz7QT35jcBG2r3CZwSwQ4fCewXAhAhqGVpP
|
|
* Unencrypted (hex):
|
|
CBF4B9F70470856BB4F40F80B87EDB90865997FFEE6DF315AB166D713AF433A5
|
|
|
|
Test 2:
|
|
|
|
* Passphrase: Satoshi
|
|
* Encrypted: 6PYLtMnXvfG3oJde97zRyLYFZCYizPU5T3LwgdYJz1fRhh16bU7u6PPmY7
|
|
* Unencrypted (WIF):
|
|
KwYgW8gcxj1JWJXhPSu4Fqwzfhp5Yfi42mdYmMa4XqK7NJxXUSK7
|
|
* Unencrypted (hex):
|
|
09C2686880095B1A4C249EE3AC4EEA8A014F11E6F986D0B5025AC1F39AFBD9AE
|
|
|
|
[[ec-multiply-no-compression-no-lotsequence-numbers]]
|
|
EC multiply, no compression, no lot/sequence numbers
|
|
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
|
|
|
Test 1:
|
|
|
|
* Passphrase: TestingOneTwoThree
|
|
* Passphrase code:
|
|
passphrasepxFy57B9v8HtUsszJYKReoNDV6VHjUSGt8EVJmux9n1J3Ltf1gRxyDGXqnf9qm
|
|
* Encrypted key:
|
|
6PfQu77ygVyJLZjfvMLyhLMQbYnu5uguoJJ4kMCLqWwPEdfpwANVS76gTX
|
|
* Bitcoin address: 1PE6TQi6HTVNz5DLwB1LcpMBALubfuN2z2
|
|
* Unencrypted private key (WIF):
|
|
5K4caxezwjGCGfnoPTZ8tMcJBLB7Jvyjv4xxeacadhq8nLisLR2
|
|
* Unencrypted private key (hex):
|
|
A43A940577F4E97F5C4D39EB14FF083A98187C64EA7C99EF7CE460833959A519
|
|
|
|
Test 2:
|
|
|
|
* Passphrase: Satoshi
|
|
* Passphrase code:
|
|
passphraseoRDGAXTWzbp72eVbtUDdn1rwpgPUGjNZEc6CGBo8i5EC1FPW8wcnLdq4ThKzAS
|
|
* Encrypted key:
|
|
6PfLGnQs6VZnrNpmVKfjotbnQuaJK4KZoPFrAjx1JMJUa1Ft8gnf5WxfKd
|
|
* Bitcoin address: 1CqzrtZC6mXSAhoxtFwVjz8LtwLJjDYU3V
|
|
* Unencrypted private key (WIF):
|
|
5KJ51SgxWaAYR13zd9ReMhJpwrcX47xTJh2D3fGPG9CM8vkv5sH
|
|
* Unencrypted private key (hex):
|
|
C2C8036DF268F498099350718C4A3EF3984D2BE84618C2650F5171DCC5EB660A
|
|
|
|
[[ec-multiply-no-compression-lotsequence-numbers]]
|
|
EC multiply, no compression, lot/sequence numbers
|
|
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
|
|
|
Test 1:
|
|
|
|
* Passphrase: MOLON LABE
|
|
* Passphrase code:
|
|
passphraseaB8feaLQDENqCgr4gKZpmf4VoaT6qdjJNJiv7fsKvjqavcJxvuR1hy25aTu5sX
|
|
* Encrypted key:
|
|
6PgNBNNzDkKdhkT6uJntUXwwzQV8Rr2tZcbkDcuC9DZRsS6AtHts4Ypo1j
|
|
* Bitcoin address: 1Jscj8ALrYu2y9TD8NrpvDBugPedmbj4Yh
|
|
* Unencrypted private key (WIF):
|
|
5JLdxTtcTHcfYcmJsNVy1v2PMDx432JPoYcBTVVRHpPaxUrdtf8
|
|
* Unencrypted private key (hex):
|
|
44EA95AFBF138356A05EA32110DFD627232D0F2991AD221187BE356F19FA8190
|
|
* Confirmation code:
|
|
cfrm38V8aXBn7JWA1ESmFMUn6erxeBGZGAxJPY4e36S9QWkzZKtaVqLNMgnifETYw7BPwWC9aPD
|
|
* Lot/Sequence: 263183/1
|
|
|
|
Test 2:
|
|
|
|
* Passphrase (all letters are Greek - test UTF-8 compatibility with
|
|
this): ΜΟΛΩΝ ΛΑΒΕ
|
|
* Passphrase code:
|
|
passphrased3z9rQJHSyBkNBwTRPkUGNVEVrUAcfAXDyRU1V28ie6hNFbqDwbFBvsTK7yWVK
|
|
* Encrypted private key:
|
|
6PgGWtx25kUg8QWvwuJAgorN6k9FbE25rv5dMRwu5SKMnfpfVe5mar2ngH
|
|
* Bitcoin address: 1Lurmih3KruL4xDB5FmHof38yawNtP9oGf
|
|
* Unencrypted private key (WIF):
|
|
5KMKKuUmAkiNbA3DazMQiLfDq47qs8MAEThm4yL8R2PhV1ov33D
|
|
* Unencrypted private key (hex):
|
|
CA2759AA4ADB0F96C414F36ABEB8DB59342985BE9FA50FAAC228C8E7D90E3006
|
|
* Confirmation code:
|
|
cfrm38V8G4qq2ywYEFfWLD5Cc6msj9UwsG2Mj4Z6QdGJAFQpdatZLavkgRd1i4iBMdRngDqDs51
|
|
* Lot/Sequence: 806938/1
|
|
|