1
0
mirror of https://github.com/bitcoinbook/bitcoinbook synced 2024-11-18 06:08:18 +00:00
bitcoinbook/selected BIPs/bip-0038.asciidoc

689 lines
31 KiB
Plaintext
Raw Normal View History

----------------------------------------------------------------------------------------------------------------------------------
BIP: 38
Title: Passphrase-protected private key
Authors: Mike Caldwell
Aaron Voisine <voisine@gmail.com>
Status: Draft (Some confusion applies: The announcements for this never made it to the list, so it hasn't had public discussion)
Type: Standards Track
Created: 2012-11-20
----------------------------------------------------------------------------------------------------------------------------------
[[abstract]]
Abstract
~~~~~~~~
A method is proposed for encrypting and encoding a passphrase-protected
Bitcoin private key record in the form of a 58-character
Base58Check-encoded printable string. Encrypted 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.
[[motivation]]
Motivation
~~~~~~~~~~
The motivation to make this proposal stems from observations of the way
physical bitcoins and paper wallets are used.
An issuer of physical bitcoins must be trustworthy and trusted. Even if
trustworthy, users are rightful to be skeptical about a third party with
theoretical access to take their funds. A physical bitcoin that cannot
be compromised by its issuer is always more intrinsically valuable than
one that can.
A two-factor physical bitcoin solution is highly useful to individuals
and organizations wishing to securely own bitcoins without any risk of
electronic theft and without the responsibility of climbing the
technological learning curve necessary to produce such an environment
themselves. Two-factor physical bitcoins allow a secure storage solution
to be put in a box and sold on the open market, greatly enlarging the
number of people who are able to securely store bitcoins.
Existing methodologies for creating two-factor physical bitcoins are
limited and cumbersome. At the time of this proposal, a user could
create their own private key, submit the public key to the physical
bitcoin issuer, and then receive a physical bitcoin that must be kept
together with some sort of record of the user-generated private key, and
finally, must be redeemed through a tool. The fact that the physical
bitcoin must be kept together with a user-produced private key negates
much of the benefit of the physical bitcoin - the user may as well just
print and maintain a private key.
A standardized password-protected private key format makes acquiring and
redeeming two-factor physical bitcoins simpler for the user. Instead of
maintaining a private key that cannot be memorized, the user may choose
a passphrase of their choice. The passphrase may be much shorter than
the length of a typical private key, short enough that they could use a
label or engraver to permanently commit their passphrase to their
physical Bitcoin piece once they have received it. By adopting a
standard way to encrypt a private key, we maximize the possibility that
they'll be able to redeem their funds in the venue of their choice,
rather than relying on an executable redemption tool they may not wish
to download.
Password and passphrase-protected private keys enable new practical use
cases for sending bitcoins from person to person. Someone wanting to
send bitcoins through postal mail could send a password-protected paper
wallet and give the recipient the passphrase over the phone or e-mail,
making the transfer safe from interception of either channel. A user of
paper wallets or Bitcoin banknote-style vouchers ("cash") could carry
funded encrypted private keys while leaving a copy at home as an element
of protection against accidental loss or theft. A user of paper wallets
who leaves bitcoins in a bank vault or safety deposit box could keep the
password at home or share it with trusted associates as protection
against someone at the bank gaining access to the paper wallets and
spending from them. The foreseeable and unforeseeable use cases for
password-protected private keys are numerous.
[[copyright]]
Copyright
~~~~~~~~~
This proposal is hereby placed in the public domain.
[[rationale]]
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 does not preclude 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._
+
'*'User story:* (EC multiplied keys) As a user of paper wallets, I
would like the ability to generate a large number of Bitcoin addresses
protected by the same password, while enjoying a high degree of
security (highly expensive scrypt parameters), but without having to
incur the scrypt delay for each address I generate.
[[specification]]
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]]
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 be understood in the future to include
keys participating in multisig transactions, and was chosen with
deference to the existing prefix '5' most commonly observed in
link:Wallet Import Format[Wallet Import Format] which denotes an
unencrypted private key.
It is proposed that the second character ought to give a hint as to what
is needed as a second factor, and for an encrypted key requiring a
passphrase, 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]]
Proposed specification
^^^^^^^^^^^^^^^^^^^^^^
* Object identifier prefix: 0x0142 (non-EC-multiplied) or 0x0143
(EC-multiplied). These are constant bytes that appear at the beginning
of the Base58Check-encoded record, and their presence causes the
resulting string to have a predictable prefix.
* 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.
*** the bits with values 0x10 and 0x08 are reserved for a future
specification that contemplates using multisig as a way to combine the
factors such that parties in possession of the separate factors can
independently sign a proposed transaction without requiring that any
party possess both factors. These bits must be 0 to comply with this
version of the specification.
*** the bit with value 0x04 indicates whether a lot and sequence number
are encoded into the first factor, and activates special behavior for
including them in the decryption process. This applies to EC-multiplied
keys only. Must be 0 for non-EC-multiplied keys.
*** remaining bits are reserved for future use and must all be 0 to
comply with this version of the specification.
** 4 bytes: SHA256(SHA256(expected_bitcoin_address))[0...3], used both
for typo checking and as salt
** 16 bytes: 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]]
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.
salt is _addresshash_ from the earlier step, n=16384, r=8, p=8,
length=64 (n, r, p are provisional and subject to consensus)
* 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, which totals 39 bytes without Base58 checksum:
* 0x01 0x42 + _flagbyte_ + _salt_ + _encryptedhalf1_ + _encryptedhalf2_
Decryption steps:
1. Collect encrypted private key and passphrase from user.
2. Derive _derivedhalf1_ and _derivedhalf2_ by passing the passphrase
and _addresshash_ into scrypt function.
3. Decrypt _encryptedhalf1_ and _encryptedhalf2_ using AES256Decrypt,
merge them to form the encrypted private key.
4. Convert that private key into a Bitcoin address, honoring the
compression preference specified in _flagbyte_ of the encrypted key
record.
5. 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.
[[encryption-when-ec-multiply-mode-is-used]]
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. A code known
as an _intermediate code_ conveys the information needed to generate
such a key without knowledge of the passphrase.
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. On the other hand, this serves a
security benefit for someone possessing an address generated this way:
if the address can be recreated by decrypting its private key with a
passphrase, and it's a strong passphrase one can be certain only he
knows himself, then he can safely conclude that nobody could know the
private key to that address.
The person who knows the passphrase and who is the intended beneficiary
of the private keys is called the _owner_. He will generate one or more
"intermediate codes", which are the first factor of a two-factor
redemption system, and will give them to someone else we'll call
_printer_, who generates a key pair with an intermediate code can know
the address and encrypted private key, but cannot decrypt the private
key without the original passphrase.
An intermediate code should, but is not required to, embed a printable
"lot" and "sequence" number for the benefit of the user. The proposal
forces these lot and sequence numbers to be included in any valid
private keys generated from them. An owner who has requested multiple
private keys to be generated for him will be advised by applications to
ensure that each private key has a unique lot and sequence number
consistent with the intermediate codes he generated. These mainly help
protect _owner_ from potential mistakes and/or attacks that could be
made by _printer_.
The "lot" and "sequence" number are combined into a single 32 bit
number. 20 bits are used for the lot number and 12 bits are used for the
sequence number, such that the lot number can be any decimal number
between 0 and 1048575, and the sequence number can be any decimal number
between 0 and 4095. For programs that generate batches of intermediate
codes for an _owner_, it is recommended that lot numbers be chosen at
random within the range 100000-999999 and that sequence numbers are
assigned starting with 1.
Steps performed by _owner_ to generate a single intermediate code, if
lot and sequence numbers are being included:
1. Generate 4 random bytes, call them _ownersalt_.
2. Encode the lot and sequence numbers as a 4 byte quantity
(big-endian): lotnumber * 4096 + sequencenumber. Call these four bytes
_lotsequence_.
3. Concatenate _ownersalt_ + _lotsequence_ and call this
_ownerentropy_.
4. Derive a key from the passphrase using scrypt
* Parameters: _passphrase_ is the passphrase itself encoded in UTF-8.
salt is _ownersalt_. n=16384, r=8, p=8, length=32.
* Call the resulting 32 bytes _prefactor_.
* Take SHA256(SHA256(_prefactor_ + _ownerentropy_)) and call this
_passfactor_.
5. 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.
6. 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: magic bytes "2C E9 B3 E1 FF 39 E2 51" followed by
_ownerentropy_, and then _passpoint_. The resulting string will start
with the word "passphrase" due to the constant bytes, will be 72
characters in length, and encodes 49 bytes (8 bytes constant + 8 bytes
_ownerentropy_ + 33 bytes _passpoint_). The checksum is handled in the
Base58Check encoding. The resulting string is called
_intermediate_passphrase_string_.
If lot and sequence numbers are not being included, then follow the same
procedure with the following changes:
* _ownersalt_ is 8 random bytes instead of 4, and _lotsequence_ is
omitted. _ownerentropy_ becomes an alias for _ownersalt_.
* The SHA256 conversion of _prefactor_ to _passfactor_ is omitted.
Instead, the output of scrypt is used directly as _passfactor_.
* The magic bytes are "2C E9 B3 E1 FF 39 E2 53" instead (the last byte
is 0x53 instead of 0x51).
Steps to create new encrypted private keys given
_intermediate_passphrase_string_ from _owner_ (so we have
_ownerentropy_, and _passpoint_, but we do not have _passfactor_ or the
passphrase):
1. Set _flagbyte_.
* Turn on bit 0x20 if the Bitcoin address will be formed by hashing the
compressed public key (optional, saves space, but many Bitcoin
implementations aren't compatible with it)
* Turn on bit 0x04 if _ownerentropy_ contains a value for _lotsequence_.
(While it has no effect on the keypair generation process, the
decryption process needs this flag to know how to process
_ownerentropy_)
2. Generate 24 random bytes, call this _seedb_. Take
SHA256(SHA256(_seedb_)) to yield 32 bytes, call this _factorb_.
3. 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_.
4. Take the first four bytes of SHA256(SHA256(_generatedaddress_)) and
call it _addresshash_.
5. 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_ +
_ownerentropy_, n=1024, r=1, p=1, length=64. The "+" operator is
concatenation.
* Split the result into two 32-byte halves and call them _derivedhalf1_
and _derivedhalf2_.
6. Do AES256Encrypt(seedb[0...15] xor derivedhalf1[0...15],
derivedhalf2), call the 16-byte result _encryptedpart1_
7. Do AES256Encrypt((encryptedpart1[8...15] + seedb[16...23]) xor
derivedhalf1[16...31], derivedhalf2), call the 16-byte result
_encryptedpart2_. The "+" operator is concatenation.
The encrypted private key is the Base58Check-encoded concatenation of
the following, which totals 39 bytes without Base58 checksum:
* 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