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<pre>
  BIP: 85
  Layer: Applications
  Title: Deterministic Entropy From BIP32 Keychains
  Author: Ethan Kosakovsky <ethankosakovsky@protonmail.com>
          Aneesh Karve <dowsing.seaport0d@icloud.com>
  Comments-Summary: No comments yet.
  Comments-URI: https://github.com/bitcoin/bips/wiki/Comments:BIP-0085
  Status: Final
  Type: Informational
  Created: 2020-03-20
  License: BSD-2-Clause
           OPL
</pre>

==Abstract==

''"One Seed to rule them all,''<br>
''One Key to find them,''<br>
''One Path to bring them all,''<br>
''And in cryptography bind them."''

It is not possible to maintain one single (mnemonic) seed backup for all keychains used across various wallets because there are a variety of incompatible standards. Sharing of seeds across multiple wallets is not desirable for security reasons. Physical storage of multiple seeds is difficult depending on the security and redundancy required.

As HD keychains are essentially derived from initial entropy, this proposal provides a way to derive entropy from the keychain which can be fed into whatever method a wallet uses to derive the initial mnemonic seed or root key.

==Copyright==

This BIP is dual-licensed under the Open Publication License and BSD 2-clause license.

==Definitions==

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED",  "MAY", and "OPTIONAL" in this document are to be interpreted as described in RFC 2119.

The terminology related to keychains used in the wild varies widely, for example `seed` has various different meanings. In this document we define the terms

# '''BIP32 root key''' is the root extended private key that is represented as the top root of the keychain in BIP32.
# '''BIP39 mnemonic''' is the mnemonic phrase that is calculated from the entropy used before hashing of the mnemonic in BIP39.
# '''BIP39 seed''' is the result of hashing the BIP39 mnemonic seed.

When in doubt, assume big endian byte serialization, such that the leftmost
byte is the most significant.

==Motivation==

Most wallets implement BIP32 which defines how a BIP32 root key can be used to derive keychains. As a consequence, a backup of just the BIP32 root key is sufficient to include all keys derived from it. BIP32 does not have a human-friendly serialization of the BIP32 root key (or BIP32 extended keys in general), which makes paper backups or manually restoring the key more error-prone. BIP39 was designed to solve this problem, but rather than serialize the BIP32 root key, it takes some entropy, encoded to a "seed mnemonic", which is then hashed to derive the BIP39 seed, which can be turned into the BIP32 root key. Saving the BIP39 mnemonic is enough to reconstruct the entire BIP32 keychain, but a BIP32 root key cannot be reversed back to the BIP39 mnemonic.

Most wallets implement BIP39, so on initialization or restoration, the user must interact with a BIP39 mnemonic. Most wallets do not support BIP32 extended private keys, so each wallet must either share the same BIP39 mnemonic, or have a separate BIP39 mnemonic entirely. Neither scenario is particularly satisfactory for security reasons. For example, some wallets may be inherently less secure, like hot wallets on smartphones, JoinMarket servers, or Lightning Network nodes. Having multiple seeds is far from desirable, especially for those who rely on split key or redundancy backups in different geological locations. Adding keys is necessarily difficult and may result in users being more lazy with subsequent keys, resulting in compromised security or loss of keys.

There is an added complication with wallets that implement other standards, or no standards at all. The Bitcoin Core wallet uses a WIF as the ''hdseed'', and yet other wallets, like Electrum, use different mnemonic schemes to derive the BIP32 root key. Other cryptocurrencies, like Monero, use an entirely different mnemonic scheme.

Ultimately, all of the mnemonic/seed schemes start with some "initial entropy" to derive a mnemonic/seed, and then process the mnemonic into a BIP32 key, or private key. We can use BIP32 itself to derive the "initial entropy" to then recreate the same mnemonic or seed according to the specific application standard of the target wallet. We can use a BIP44-like categorization to ensure uniform derivation according to the target application type.

==Specification==

We assume a single BIP32 master root key. This specification is not concerned with how this was derived (e.g. directly or via a mnemonic scheme such as BIP39).

For each application that requires its own wallet, a unique private key is derived from the BIP32 master root key using a fully hardened derivation path. The resulting private key (k) is then processed with HMAC-SHA512, where the key is "bip-entropy-from-k", and the message payload is the private key k: <code>HMAC-SHA512(key="bip-entropy-from-k", msg=k)</code>
<ref name="hmac-sha512">
The reason for running the derived key through HMAC-SHA512 and truncating the result as necessary is to prevent leakage of the parent tree should the derived key (''k'') be compromised. While the specification requires the use of hardended key derivation which would prevent this, we cannot enforce hardened derivation, so this method ensures the derived entropy is hardened. Also, from a semantic point of view, since the purpose is to derive entropy and not a private key, we are required to transform the child key. This is done out of an abundance of caution, in order to ward off unwanted side effects should ''k'' be used for a dual purpose, including as a nonce ''hash(k)'', where undesirable and unforeseen interactions could occur.
</ref>.
The result produces 512 bits of entropy. Each application SHOULD use up to the required number of bits necessary for their operation, and truncate the rest.

The HMAC-SHA512 function is specified in [https://tools.ietf.org/html/rfc4231 RFC 4231].

===Test vectors===

====Test case 1====
INPUT:
* MASTER BIP32 ROOT KEY: xprv9s21ZrQH143K2LBWUUQRFXhucrQqBpKdRRxNVq2zBqsx8HVqFk2uYo8kmbaLLHRdqtQpUm98uKfu3vca1LqdGhUtyoFnCNkfmXRyPXLjbKb
* PATH: m/83696968'/0'/0'

OUTPUT:
* DERIVED KEY=cca20ccb0e9a90feb0912870c3323b24874b0ca3d8018c4b96d0b97c0e82ded0
* DERIVED ENTROPY=efecfbccffea313214232d29e71563d941229afb4338c21f9517c41aaa0d16f00b83d2a09ef747e7a64e8e2bd5a14869e693da66ce94ac2da570ab7ee48618f7

====Test case 2====
INPUT:
* MASTER BIP32 ROOT KEY: xprv9s21ZrQH143K2LBWUUQRFXhucrQqBpKdRRxNVq2zBqsx8HVqFk2uYo8kmbaLLHRdqtQpUm98uKfu3vca1LqdGhUtyoFnCNkfmXRyPXLjbKb
*PATH: m/83696968'/0'/1'

OUTPUT
* DERIVED KEY=503776919131758bb7de7beb6c0ae24894f4ec042c26032890c29359216e21ba
* DERIVED ENTROPY=70c6e3e8ebee8dc4c0dbba66076819bb8c09672527c4277ca8729532ad711872218f826919f6b67218adde99018a6df9095ab2b58d803b5b93ec9802085a690e

==BIP85-DRNG==

BIP85-DRNG-SHAKE256 is a deterministic random number generator for cryptographic functions that require deterministic outputs, but where the input to that function requires more than the 64 bytes provided by BIP85's HMAC output. BIP85-DRNG-SHAKE256 uses BIP85 to seed a SHAKE256 stream (from the SHA-3 standard). The input must be exactly 64 bytes long (from the BIP85 HMAC output).

RSA key generation is an example of a function that requires orders of magnitude more than 64 bytes of random input. Further, it is not possible to precalculate the amount of random input required until the function has completed.

    drng_reader = BIP85DRNG.new(bip85_entropy)
    rsa_key = RSA.generate_key(4096, drng_reader.read)

===Test Vectors===
INPUT:
xprv9s21ZrQH143K2LBWUUQRFXhucrQqBpKdRRxNVq2zBqsx8HVqFk2uYo8kmbaLLHRdqtQpUm98uKfu3vca1LqdGhUtyoFnCNkfmXRyPXLjbKb
* MASTER BIP32 ROOT KEY: m/83696968'/0'/0'

OUTPUT
* DERIVED KEY=cca20ccb0e9a90feb0912870c3323b24874b0ca3d8018c4b96d0b97c0e82ded0
* DERIVED ENTROPY=efecfbccffea313214232d29e71563d941229afb4338c21f9517c41aaa0d16f00b83d2a09ef747e7a64e8e2bd5a14869e693da66ce94ac2da570ab7ee48618f7

* DRNG(80 bytes)=b78b1ee6b345eae6836c2d53d33c64cdaf9a696487be81b03e822dc84b3f1cd883d7559e53d175f243e4c349e822a957bbff9224bc5dde9492ef54e8a439f6bc8c7355b87a925a37ee405a7502991111

==Applications==

The Application number defines how entropy will be used post processing. Some basic examples follow:

Derivation paths follow the format <code>m/83696968'/{app_no}'/{index}'</code>, where ''{app_no}'' is the path for the application, and ''{index}'' is the index.

Application numbers should be semantic in some way, such as a BIP number or ASCII character code sequence.

===BIP39===
Application number: 39'

Truncate trailing (least significant) bytes of the entropy to the number of bits required to map to the relevant word length: 128 bits for 12 words, 256 bits for 24 words.

The derivation path format is: <code>m/83696968'/39'/{language}'/{words}'/{index}'</code>

Example: a BIP39 mnemonic with 12 English words (first index) would have the path <code>m/83696968'/39'/0'/12'/0'</code>, the next key would be <code>m/83696968'/39'/0'/12'/1'</code> etc.

Language Table

{|
!Wordlist
!Code
|-
| English
| 0'
|-
| Japanese
| 1'
|-
| Korean
| 2'
|-
| Spanish
| 3'
|-
| Chinese (Simplified)
| 4'
|-
| Chinese (Traditional)
| 5'
|-
| French
| 6'
|-
| Italian
| 7'
|-
| Czech
| 8'
|-
| Portuguese
| 9'
|-
|}

Words Table

{|
!Words
!Entropy
!Code
|-
| 12 words
| 128 bits
| 12'
|-
| 15 words
| 160 bits
| 15'
|-
| 18 words
| 192 bits
| 18'
|-
| 21 words
| 224 bits
| 21'
|-
| 24 words
| 256 bits
| 24'
|}

====12 English words====
BIP39 English 12 word mnemonic seed

128 bits of entropy as input to BIP39 to derive 12 word mnemonic

INPUT:
* MASTER BIP32 ROOT KEY: xprv9s21ZrQH143K2LBWUUQRFXhucrQqBpKdRRxNVq2zBqsx8HVqFk2uYo8kmbaLLHRdqtQpUm98uKfu3vca1LqdGhUtyoFnCNkfmXRyPXLjbKb
* PATH: m/83696968'/39'/0'/12'/0'

OUTPUT:
* DERIVED ENTROPY=6250b68daf746d12a24d58b4787a714b
* DERIVED BIP39 MNEMONIC=girl mad pet galaxy egg matter matrix prison refuse sense ordinary nose

====18 English words====
BIP39 English 18 word mnemonic seed

196 bits of entropy as input to BIP39 to derive 18 word mnemonic

INPUT:
* MASTER BIP32 ROOT KEY: xprv9s21ZrQH143K2LBWUUQRFXhucrQqBpKdRRxNVq2zBqsx8HVqFk2uYo8kmbaLLHRdqtQpUm98uKfu3vca1LqdGhUtyoFnCNkfmXRyPXLjbKb
* PATH: m/83696968'/39'/0'/18'/0'

OUTPUT:
* DERIVED ENTROPY=938033ed8b12698449d4bbca3c853c66b293ea1b1ce9d9dc
* DERIVED BIP39 MNEMONIC=near account window bike charge season chef number sketch tomorrow excuse sniff circle vital hockey outdoor supply token

====24 English words====
Derives 24 word BIP39 mnemonic seed

256 bits of entropy as input to BIP39 to derive 24 word mnemonic

INPUT:
* MASTER BIP32 ROOT KEY: xprv9s21ZrQH143K2LBWUUQRFXhucrQqBpKdRRxNVq2zBqsx8HVqFk2uYo8kmbaLLHRdqtQpUm98uKfu3vca1LqdGhUtyoFnCNkfmXRyPXLjbKb
* PATH: m/83696968'/39'/0'/24'/0'

OUTPUT:
* DERIVED ENTROPY=ae131e2312cdc61331542efe0d1077bac5ea803adf24b313a4f0e48e9c51f37f
* DERIVED BIP39 MNEMONIC=puppy ocean match cereal symbol another shed magic wrap hammer bulb intact gadget divorce twin tonight reason outdoor destroy simple truth cigar social volcano

===HD-Seed WIF===
Application number: 2'

Uses the most significant 256 bits<ref name="curve-order">
There is a very small chance that you'll make an invalid
key that is zero or larger than the order of the curve. If this occurs, software
should hard fail (forcing users to iterate to the next index). From BIP32:
<blockquote>
In case parse<sub>256</sub>(I<sub>L</sub>) ≥ n or k<sub>i</sub> = 0, the resulting key is invalid, and one should proceed with the next value for i. (Note: this has probability lower than 1 in 2<sup>127</sup>.)
</blockquote>
</ref>
of entropy as the secret exponent to derive a private key and encode as a compressed
WIF that will be used as the hdseed for Bitcoin Core wallets.

Path format is <code>m/83696968'/2'/{index}'</code>

INPUT:
* MASTER BIP32 ROOT KEY: xprv9s21ZrQH143K2LBWUUQRFXhucrQqBpKdRRxNVq2zBqsx8HVqFk2uYo8kmbaLLHRdqtQpUm98uKfu3vca1LqdGhUtyoFnCNkfmXRyPXLjbKb
* PATH: m/83696968'/2'/0'

OUTPUT
* DERIVED ENTROPY=7040bb53104f27367f317558e78a994ada7296c6fde36a364e5baf206e502bb1
* DERIVED WIF=Kzyv4uF39d4Jrw2W7UryTHwZr1zQVNk4dAFyqE6BuMrMh1Za7uhp

===XPRV===
Application number: 32'

Taking 64 bytes of the HMAC digest, the first 32 bytes are the chain code, and the second 32 bytes<ref name="curve-order" /> are the private key for the BIP32 XPRV value. Child number, depth, and parent fingerprint are forced to zero.

''Warning'': The above order reverses the order of BIP32, which takes the first 32 bytes as the private key, and the second 32 bytes as the chain code.

Applications may support Testnet by emitting TPRV keys if and only if the input root key is a Testnet key.

Path format is <code>m/83696968'/32'/{index}'</code>

INPUT:
* MASTER BIP32 ROOT KEY: xprv9s21ZrQH143K2LBWUUQRFXhucrQqBpKdRRxNVq2zBqsx8HVqFk2uYo8kmbaLLHRdqtQpUm98uKfu3vca1LqdGhUtyoFnCNkfmXRyPXLjbKb
* PATH: m/83696968'/32'/0'

OUTPUT
* DERIVED ENTROPY=ead0b33988a616cf6a497f1c169d9e92562604e38305ccd3fc96f2252c177682
* DERIVED XPRV=xprv9s21ZrQH143K2srSbCSg4m4kLvPMzcWydgmKEnMmoZUurYuBuYG46c6P71UGXMzmriLzCCBvKQWBUv3vPB3m1SATMhp3uEjXHJ42jFg7myX

===HEX===
Application number: 128169'

The derivation path format is: <code>m/83696968'/128169'/{num_bytes}'/{index}'</code>

`16 <= num_bytes <= 64`

Truncate trailing (least significant) bytes of the entropy after `num_bytes`.

INPUT:
* MASTER BIP32 ROOT KEY: xprv9s21ZrQH143K2LBWUUQRFXhucrQqBpKdRRxNVq2zBqsx8HVqFk2uYo8kmbaLLHRdqtQpUm98uKfu3vca1LqdGhUtyoFnCNkfmXRyPXLjbKb
* PATH: m/83696968'/128169'/64'/0'

OUTPUT
* DERIVED ENTROPY=492db4698cf3b73a5a24998aa3e9d7fa96275d85724a91e71aa2d645442f878555d078fd1f1f67e368976f04137b1f7a0d19232136ca50c44614af72b5582a5c

===PWD BASE64===
Application number: 707764'

The derivation path format is: <code>m/83696968'/707764'/{pwd_len}'/{index}'</code>

`20 <= pwd_len <= 86`

[https://datatracker.ietf.org/doc/html/rfc4648 Base64] encode all 64 bytes of entropy.
Remove any spaces or new lines inserted by Base64 encoding process. Slice base64 result string
on index 0 to `pwd_len`. This slice is the password. As `pwd_len` is limited to 86, passwords will not contain padding.

Entropy calculation:<br>
R = 64  (base64 - do not count padding)<br>
L = pwd_len<br>
Entropy = log2(R ** L)<br>

{| class="wikitable" style="margin:auto"
! pwd_length !! (cca) entropy
|-
| 20 || 120.0
|-
| 24 || 144.0
|-
| 32 || 192.0
|-
| 64 || 384.0
|-
| 86 || 516.0
|}

INPUT:
* MASTER BIP32 ROOT KEY: xprv9s21ZrQH143K2LBWUUQRFXhucrQqBpKdRRxNVq2zBqsx8HVqFk2uYo8kmbaLLHRdqtQpUm98uKfu3vca1LqdGhUtyoFnCNkfmXRyPXLjbKb
* PATH: m/83696968'/707764'/21'/0'

OUTPUT
* DERIVED ENTROPY=74a2e87a9ba0cdd549bdd2f9ea880d554c6c355b08ed25088cfa88f3f1c4f74632b652fd4a8f5fda43074c6f6964a3753b08bb5210c8f5e75c07a4c2a20bf6e9
* DERIVED PWD=dKLoepugzdVJvdL56ogNV

===PWD BASE85===
Application number: 707785'

The derivation path format is: <code>m/83696968'/707785'/{pwd_len}'/{index}'</code>

`10 <= pwd_len <= 80`

Base85 encode all 64 bytes of entropy.
Remove any spaces or new lines inserted by Base64 encoding process. Slice base85 result string
on index 0 to `pwd_len`. This slice is the password. `pwd_len` is limited to 80 characters.

Entropy calculation:<br>
R = 85<br>
L = pwd_len<br>
Entropy = log2(R ** L)<br>

{| class="wikitable" style="margin:auto"
! pwd_length !! (cca) entropy
|-
| 10 || 64.0
|-
| 15 || 96.0
|-
| 20 || 128.0
|-
| 30 || 192.0
|-
| 80 || 512.0
|}

INPUT:
* MASTER BIP32 ROOT KEY: xprv9s21ZrQH143K2LBWUUQRFXhucrQqBpKdRRxNVq2zBqsx8HVqFk2uYo8kmbaLLHRdqtQpUm98uKfu3vca1LqdGhUtyoFnCNkfmXRyPXLjbKb
* PATH: m/83696968'/707785'/12'/0'

OUTPUT
* DERIVED ENTROPY=f7cfe56f63dca2490f65fcbf9ee63dcd85d18f751b6b5e1c1b8733af6459c904a75e82b4a22efff9b9e69de2144b293aa8714319a054b6cb55826a8e51425209
* DERIVED PWD=_s`{TW89)i4`

===RSA===

Application number: 828365'

The derivation path format is: <code>m/83696968'/828365'/{key_bits}'/{key_index}'</code>

The RSA key generator should use BIP85-DRNG as the input RNG function.

===RSA GPG===

Keys allocated for RSA-GPG purposes use the following scheme:

 - Main key <code>m/83696968'/828365'/{key_bits}'/{key_index}'</code>
 - Sub keys:  <code>m/83696968'/828365'/{key_bits}'/{key_index}'/{sub_key}'</code>

    - key_index is the parent key for CERTIFY capability
    - sub_key <code>0'</code> is used as the ENCRYPTION key
    - sub_key <code>1'</code> is used as the AUTHENTICATION key
    - sub_key <code>2'</code> is usually used as SIGNATURE key

Note on timestamps:

The resulting RSA key can be used to create a GPG key where the creation date MUST be fixed to unix Epoch timestamp 1231006505 (the Bitcoin genesis block time <code>'2009-01-03 18:05:05'</code> UTC) because the key fingerprint is affected by the creation date (Epoch timestamp 0 was not chosen because of legacy behavior in GNUPG implementations for older keys). Additionally, when importing sub-keys under a key in GNUPG, the system time must be frozen to the same timestamp before importing (e.g. by use of <code>faketime</code>).

Note on GPG key capabilities on smartcard/hardware devices:

GPG capable smart-cards SHOULD be loaded as follows: The encryption slot SHOULD be loaded with the ENCRYPTION capable key; the authentication slot SHOULD be loaded with the AUTHENTICATION capable key. The signature capable slot SHOULD be loaded with the SIGNATURE capable key.

However, depending on available slots on the smart-card, and preferred policy, the CERTIFY capable key MAY be flagged with CERTIFY and SIGNATURE capabilities and loaded into the SIGNATURE capable slot (for example where the smart-card has only three slots and the CERTIFY capability is required on the same card). In this case, the SIGNATURE capable sub-key would be disregarded because the CERTIFY capable key serves a dual purpose.

===DICE===

Application number: 89101'

The derivation path format is: <code>m/83696968'/89101'/{sides}'/{rolls}'/{index}'</code>

    2 <= sides <= 2^32 - 1
    1 <= rolls <= 2^32 - 1

Use this application to generate PIN numbers, numeric secrets, and secrets over custom alphabets.
For example, applications could generate alphanumeric passwords from a 62-sided die (26 + 26 + 10).

Roll values are zero-indexed, such that an N-sided die produces values in the range
<code>[0, N-1]</code>, inclusive. Applications should separate printed rolls by a comma or similar.

Create a BIP85 DRNG whose seed is the derived entropy.

Calculate the following integers:

    bits_per_roll = ceil(log_2(sides))
    bytes_per_roll = ceil(bits_per_roll / 8)

Read <code>bytes_per_roll</code> bytes from the DRNG.
Trim any bits in excess of <code>bits_per_roll</code> (retain the most
significant bits). The resulting integer represents a single roll or trial.
If the trial is greater than or equal to the number of sides, skip it and
move on to the next one. Repeat as needed until all rolls are complete.

INPUT:
* MASTER BIP32 ROOT KEY: xprv9s21ZrQH143K2LBWUUQRFXhucrQqBpKdRRxNVq2zBqsx8HVqFk2uYo8kmbaLLHRdqtQpUm98uKfu3vca1LqdGhUtyoFnCNkfmXRyPXLjbKb
* PATH: m/83696968'/89101'/6'/10'/0'
OUTPUT
* DERIVED ENTROPY=5e41f8f5d5d9ac09a20b8a5797a3172b28c806aead00d27e36609e2dd116a59176a738804236586f668da8a51b90c708a4226d7f92259c69f64c51124b6f6cd2
* DERIVED ROLLS=1,0,0,2,0,1,5,5,2,4

==Backwards Compatibility==

This specification is not backwards compatible with any other existing specification.

This specification relies on BIP32 but is agnostic to how the BIP32 root key is derived. As such, this standard is able to derive wallets with initialization schemes like BIP39 or Electrum wallet style mnemonics.

==References==

BIP32, BIP39

==Reference Implementations==

* 1.3.0 Python 3.x library implementation: [https://github.com/akarve/bipsea]
* 1.1.0 Python 2.x library implementation: [https://github.com/ethankosakovsky/bip85]
* 1.0.0 JavaScript library implementation: [https://github.com/hoganri/bip85-js]

==Changelog==

===1.3.0 (2024-10-22)===

====Added====

* Dice application 89101'
* Czech language code to application 39'
* TPRV guidance for application 32'
* Warning on application 32' key and chain code ordering

===1.2.0 (2022-12-04)===

====Added====

* Base64 application 707764'
* Base85 application 707785'

===1.1.0 (2020-11-19)===

====Added====

* BIP85-DRNG-SHAKE256
* RSA application 828365'

===1.0.0 (2020-06-11)===

* Initial version

==Footnotes==

<references />

==Acknowledgements==

Many thanks to Peter Gray and Christopher Allen for their input, and to Peter for suggesting extra application use cases.