Your keys, your Bitcoin. Not your keys, not your Bitcoin.
—Andreas Antonopoulos
The python-slip39 project (and the SLIP-39 macOS/win32 App) exists to assist in the safe creation, backup and documentation of Hierarchical Deterministic (HD) Wallet seeds and derived accounts, with various SLIP-39 sharing parameters. It generates the new random wallet seed, and generates the expected standard Ethereum account(s) (at derivation path m/44’/60’/0’/0/0 by default) and Bitcoin accounts (at Bech32 derivation path m/84’/0’/0’/0/0 by default), with wallet address and QR code (compatible with Trezor and Ledger derivations). It produces the required SLIP-39 phrases, and outputs a single PDF containing all the required printable cards to document the seed (and the specified derived accounts).
On an secure (ideally air-gapped) computer, new seeds can safely be generated (without trusting
this program) and the PDF saved to a USB drive for printing (or directly printed without the file
being saved to disk.). Presently, slip39
can output example ETH, BTC, LTC, DOGE, BSC, and XRP
addresses derived from the seed, to illustrate what accounts are associated with the backed-up
seed. Recovery of the seed to a Trezor Safe 3 is simple, by entering the mnemonics right on the
device.
We also support the backup of existing insecure and unreliable 12- or 24-word BIP-39 Mnemonic Phrases as SLIP-39 Mnemonic cards, for existing BIP-39 hardware wallets like the Ledger Nano, etc.! Recover from your existing BIP-39 Seed Phrase Mnemonic, select “Using BIP-39” (and enter your BIP-39 passphrase), and generate a set of SLIP-39 Mnemonic cards. Later, use the SLIP-39 App to recover from your SLIP-39 Mnemonic cards, click “Using BIP-39” to get your BIP-39 Mnemonic back, and use it (and your passphrase) to recover your accounts to your Ledger (or other) hardware wallet.
Output of BIP-38 or JSON encrypted Paper Wallets is also supported, for import into standard software cryptocurrency wallets.
Here’s a full round-trip demonstration of:
- Creating new (or “Backing Up” existing) Seed Entropy as a BIP-39 Mnemonic
- Recovering the Seed Entropy from SLIP-39 (via https://iancoleman.io/slip39/)
- Recovering the original BIP-39 (via https://iancoleman.io/bip39/)
First, we generate SLIP-39 Cards representing a BIP-39 Mnemonic seed. Remember, your BIP-39 Mnemonic simply encodes your 128- or 256-bit Seed Entropy. So, we’re not backing up your Mnemonic phrase – we’re backing up the raw seed data that is encoded into your BIP-39 Mnemonic.
# python3 -m pip install slip39; slip39 -q --using-bip39 # to generate one from scratch, or
slip39 --secret "seven replace great luggage fox rent general tower guess inside smile sing"
If you look at the generated SLIP39 PDF, you’ll see that the cover page contains the original BIP-39 Mnemonic phrase (for confirmation), and generates a number of SLIP-39 Mnemonic cards. These cards encode the original Seed Entropy, and are what you use to recover the BIP-39 Mnemonic whenever you need it.
I recommend that you tear off and destroy the BIP-39 Mnemonic from the cover sheet, once you’ve confirmed you can recover it anytime you want, and you’ve set up your hardware wallet, and confirmed that it contains the same cryptocurrency addresses displayed in the PDF.
Practice this full round-trip several times with a bad BIP-39 Mnemonic like “zoo zoo … wrong”. This is the only way to become comfortable with your ability to recover your original seed data, and (hence) your BIP-39 Mnemonic.
Later, when you need to recover your BIP-39 Seed Entropy and Mnemonic, use this SLIP-39 App or https://iancoleman.io/slip39/ and enter some of your SLIP-39 Mnemonic Cards. These may need to be collected from friends and family.
In this case, we’re using the First and Second cards, intended for you to secure, separately from each other; for example, in two safes or other secure locations like locked filing cabinets, at 2 locations known to you and your partner(s):
Finally, convert the recovered Seed Entropy back to your BIP-39 Mnemonic. This requires 2 steps if you use https://iancoleman.io/bip39/
In this step, we’re simply converting the recovered Seed Entropy back into its BIP-39 Mnemonic. You need to select the “[X] show entropy details” checkbox in order to enter the raw Seed Entropy we’ve recovered in the last step:
Alternatively, you can use the SLIP-39 App or the slip39-recovery
command-line tool, and do it
all in one step. This illustrates recovering your BIP-39 Mnemonic from the SLIP-39 Cards
generated in the first step:
python3 -m slip39.recovery --using-bip39 \
-m "pitch negative acrobat romp desert usual negative darkness friar artist estimate aluminum beard crowd email season guard hybrid kidney cards" \
-m "pitch negative beard romp diagnose timely ruler emission acrobat adult stilt dress typical blue inmate lilac pajamas trend duration endless"
For both BIP-39 and SLIP-39, a 128- or 256-bit random “seed” is the source of an unlimited sequence of Ethereum and Bitcoin Heirarchical Deterministic (HD) derived Wallet accounts. Anyone who can obtain this seed gains control of all Ethereum, Bitcoin (and other) accounts derived from it, so it must be securely stored.
Losing this seed means that all of the HD Wallet accounts are permanently lost. It must be both backed up securely, and be readily accessible.
Therefore, we must:
- Ensure that nobody untrustworthy can recover the seed, but
- Store the seed in many places, probably with several (some perhaps untrustworthy) people.
How can we address these conflicting requirements?
Satoshi Lab’s (Trezor) SLIP-39 uses SSSS to distribute the ability to recover the key to 1 or more “groups”. Collecting the mnemonics from the required number of groups allows recovery of the seed.
For BIP-39, the number of groups is always 1, and the number of mnemonics required for that group is always 1. This selection is both insecure (easy to accidentally disclose) and unreliable (easy to accidentally lose), but since most hardware wallets only accept BIP-39 phrases, we also provide a way to backup your BIP-39 phrase using SLIP-39!
For SLIP-39, you specify a “group_threshold” of how many of your groups must be successfully collected, to recover the seed; this seed is (conceptually) split between 1 or more groups (though not in reality – each group’s data alone gives away no information about the seed).
For example, you might have First, Second, Fam and Frens groups, and decide that any 2 groups can be combined to recover the seed. Each group has members with varying levels of trust and persistence, so have different number of Members, and differing numbers Required to recover that group’s data:
Group | Required | Members | Description | |
---|---|---|---|---|
<r> | <l> | |||
First | 1 | / | 1 | Stored at home |
Second | 1 | / | 1 | Stored in office safe |
Fam | 2 | / | 4 | Distributed to family members |
Frens | 3 | / | 6 | Distributed to friends and associates |
The account owner might store their First and Second group data in their home and office safes. These are 1/1 groups (1 required, and only 1 member, so each of these are 1-card groups.)
If the Seed needs to be recovered, collecting the First and Second cards from the home and office safe is sufficient to recover the Seed, and re-generate all of the HD Wallet accounts.
Only 2 Fam group member’s cards must be collected to recover the Fam group’s data. So, if the HD Wallet owner loses their home (and the one and only First group card) in a fire, they could get the one Second group card from the office safe, and also 2 cards from Fam group members, and recover the Seed and all of their wallets.
If catastrophe strikes and the wallet owner dies, and the heirs don’t have access to either the First (at home) or Second (at the office) cards, they can collect 2 Fam cards and 3 Frens cards (at the funeral, for example), completing the Fam and Frens groups’ data, and recover the Seed, and all derived HD Wallet accounts.
Since Frens are less likely to persist long term, we’ll produce more (6) of these cards. Depending on how trustworthy the group is, adjust the Fren group’s Required number higher (less trustworthy, more likely to know each-other, need to collect more to recover the group), or lower (more trustworthy, less likely to collude, need less to recover).
Generating a new SLIP-39 encoded Seed is easy, with results available as PDF and text. Any number of derived HD wallet account addresses can be generated from this Seed, and the Seed (and all derived HD wallets, for all cryptocurrencies) can be recovered by collecting the desired groups of recover card phrases. The default recovery groups are as described above.
This is what the first page of the output SLIP-39 mnemonic cards PDF looks like:
Run the following to obtain a PDF file containing business cards with the default SLIP-39 groups for a new account Seed named “Personal” (usable with any hardware wallet with SLIP-39 support, such as the Trezor Safe) ; insert a USB drive to collect the output, and run:
$ python3 -m pip install slip39 # Install slip39 in Python3 $ cd /Volumes/USBDRIVE/ # Change current directory to USB $ python3 -m slip39 Personal # Or just run "slip39 Personal" 2022-11-22 05:35:21 slip39.layout ETH m/44'/60'/0'/0/0 : 0x0F04cab1855CE275bd098c918075373EB3944Ba3 2022-11-22 05:35:21 slip39.layout BTC m/84'/0'/0'/0/0 : bc1qszvts5vyxy265er6ngk3ew4utx5sll2ck2m7m2 2022-11-22 05:35:22 slip39.layout Writing SLIP39-encoded wallet for 'Personal' to:\ Personal-2022-11-22+05.35.22-ETH-0x0F04cab1855CE275bd098c918075373EB3944Ba3.pdf
The resultant PDF will be output into the designated file.
This PDF file contains business card sized SLIP-39 Mnemonic cards, and will print on a single
page of 8-1/2”x11” paper or card stock, and the cards can be cut out (--card index
, credit
,
half
(page), third
and quarter
are also available, as well as 4x6 photo
and custom
"(<h>,<w>),<margin>"
).
To get the data printed on the terminal as in this example (so you could write it down on cards
instead), add a -v
(to see it logged in a tabular format), or --text
to have it printed to
stdout in full lines (ie. for pipelining to other programs).
To obtain the Seed in BIP-39 format, with its original “entropy” backed up using SLIP-39
(supporting any BIP-39 hardware wallet, and recoverable from the Mnemonic cards using SLIP-39),
use the --using-bip39
option:
$ slip39 --using-bip39 Personal-BIP-39 2022-11-22 05:47:13 slip39.layout ETH m/44'/60'/0'/0/0 : 0x927232296120343A89DeAb15F108a420087a2Ef3 2022-11-22 05:47:13 slip39.layout BTC m/84'/0'/0'/0/0 : bc1qgs6xg5kvrrxp4579y22a4tf0d8me4dslwxjr9x 2022-11-22 05:47:15 slip39.layout Writing SLIP39 backup for BIP-39-encoded wallet for 'Personal-BIP-39' to:\ Personal-BIP-39-2022-11-22+05.47.15-ETH-0x927232296120343A89DeAb15F108a420087a2Ef3.pdf
This is the best approach, if you want a new Seed and need to support a BIP-39-only Hardware Wallet. (If you already have a BIP-39 Mnemonic Phrase, see <a href=”Pipelining Backup of a BIP-39 Mnemonic Phrase”>Pipelining Backup of a BIP-39 Mnemonic Phrase)
The Trezor hardware wallet natively supports the input of SLIP-39 Mnemonics. However, most software wallets do not (yet) support SLIP-39. So, how do we load the Crypto wallets produced from our Seed into software wallets such as the Metamask plugin or the Brave browser, for example?
The slip39.gui
(and the macOS/win32 SLIP-39.App) support output of standard BIP-38 encrypted wallets
for Bitcoin-like cryptocurrencies such as BTC, LTC and DOGE. It also outputs encrypted Ethereum
JSON wallets for ETH. Here is how to produce them (from a test secret Seed; exclude --secret
ffff...
for yours!):
slip39 -c ETH -c BTC -c DOGE -c LTC --secret ffffffffffffffffffffffffffffffff \
--no-card --wallet password --wallet-hint 'bad:pass...' 2>&1
2024-11-15 16:10:30 slip39 It is recommended to not use '-s|--secret <hex>'; specify '-' to read from input 2024-11-15 16:10:30 slip39 It is recommended to not use '-w|--wallet <password>'; specify '-' to read from input 2024-11-15 16:10:30 slip39 Generated 128-bit SLIP-39 Mnemonics w/ identifier 24706 requiring 2 of 4 (extendable) groups to recover 2024-11-15 16:10:30 slip39.layout ETH m/44'/60'/0'/0/0 : 0x824b174803e688dE39aF5B3D7Cd39bE6515A19a1 2024-11-15 16:10:30 slip39.layout BTC m/84'/0'/0'/0/0 : bc1q9yscq3l2yfxlvnlk3cszpqefparrv7tk24u6pl 2024-11-15 16:10:30 slip39.layout DOGE m/44'/3'/0'/0/0 : DN8PNN3dipSJpLmyxtGe4EJH38EhqF8Sfy 2024-11-15 16:10:30 slip39.layout LTC m/84'/2'/0'/0/0 : ltc1qe5m2mst9kjcqtfpapaanaty40qe8xtusmq4ake 2024-11-15 16:10:36 slip39.layout Writing SLIP39-encoded wallet for 'SLIP39' to: SLIP39-2024-11-15+16.10.33-ETH-0x824b174803e688dE39aF5B3D7Cd39bE6515A19a1.pdf
And what they look like:
To recover your real SLIP-39 Seed Entropy and print wallets, use the SLIP-39 App’s “Recover”
Controls, or to do so on the command-line, use slip39-recover
:
slip39-recovery -v \
--mnemonic "material leaf acrobat romp charity capital omit skunk change firm eclipse crush fancy best tracks flip grownup plastic chew peanut" \
--mnemonic "material leaf beard romp disaster duke flame uncover group slice guest blue gums duckling total suitable trust guitar payment platform" \
2>&1
2024-11-15 16:12:43 slip39.recovery Recovered 128-bit Encrypted SLIP-39 Seed Entropy using 2 groups comprising 2 mnemonics 2024-11-15 16:12:43 slip39.recovery Seed decoded from SLIP-39 Mnemonics w/ no passphrase 2024-11-15 16:12:43 slip39.recovery Recovered SLIP-39 secret; To re-generate SLIP-39 wallet, send it to: python3 -m slip39 --secret - ffffffffffffffffffffffffffffffff
You can run this as a command-line pipeline. Here, we use some SLIP-39 Mnemonics that encode the ffff...
Seed Entropy;
note that the wallets match those output above:
slip39-recovery \
--mnemonic "material leaf acrobat romp charity capital omit skunk change firm eclipse crush fancy best tracks flip grownup plastic chew peanut" \
--mnemonic "material leaf beard romp disaster duke flame uncover group slice guest blue gums duckling total suitable trust guitar payment platform" \
| slip39 -c ETH -c BTC -c DOGE -c LTC --secret - \
--no-card --wallet password --wallet-hint 'bad:pass...' \
2>&1
2024-11-15 16:13:26 slip39 It is recommended to not use '-w|--wallet <password>'; specify '-' to read from input 2024-11-15 16:13:26 slip39 Generated 128-bit SLIP-39 Mnemonics w/ identifier 14481 requiring 2 of 4 (extendable) groups to recover 2024-11-15 16:13:26 slip39.layout ETH m/44'/60'/0'/0/0 : 0x824b174803e688dE39aF5B3D7Cd39bE6515A19a1 2024-11-15 16:13:26 slip39.layout BTC m/84'/0'/0'/0/0 : bc1q9yscq3l2yfxlvnlk3cszpqefparrv7tk24u6pl 2024-11-15 16:13:26 slip39.layout DOGE m/44'/3'/0'/0/0 : DN8PNN3dipSJpLmyxtGe4EJH38EhqF8Sfy 2024-11-15 16:13:26 slip39.layout LTC m/84'/2'/0'/0/0 : ltc1qe5m2mst9kjcqtfpapaanaty40qe8xtusmq4ake 2024-11-15 16:13:31 slip39.layout Writing SLIP39-encoded wallet for 'SLIP39' to: SLIP39-2024-11-15+16.13.29-ETH-0x824b174803e688dE39aF5B3D7Cd39bE6515A19a1.pdf
While the SLIP-39 Seed is not cryptocurrency-specific (any wallet for any cryptocurrency can be
derived from it), each type of cryptocurrency has its own standard derivation path
(eg. m/44'/3'/0'/0/0
for DOGE), and its own address representation (eg. Bech32 at
m/84'/0'/0'/0/0
for BTC eg. bc1qcupw7k8enymvvsa7w35j5hq4ergtvus3zk8a8s
).
When you import your SLIP-39 Seed into a Trezor, you gain access to all derived HD cryptocurrency wallets supported directly by that hardware wallet, and indirectly, to any coin and/or blockchain network supported by any wallet software (eg. Metamask).
Crypto | Semantic | Path | Address | Support |
---|---|---|---|---|
ETH | Legacy | m/44’/60’/0’/0/0 | 0x… | |
BSC | Legacy | m/44’/60’/0’/0/0 | 0x… | Beta |
BTC | Legacy | m/44’/ 0’/0’/0/0 | 1… | |
SegWit | m/49’/ 0’/0’/0/0 | 3… | ||
Bech32 | m/84’/ 0’/0’/0/0 | bc1… | ||
LTC | Legacy | m/44’/ 2’/0’/0/0 | L… | |
SegWit | m/49’/ 2’/0’/0/0 | M… | ||
Bech32 | m/84’/ 2’/0’/0/0 | ltc1… | ||
DOGE | Legacy | m/44’/ 3’/0’/0/0 | D… |
These coins are natively supported both directly by the Trezor hardware wallet, and by most
software wallets and “web3” platforms that interact with the Trezor, or can import the BIP-38
or Ethereum JSON Paper Wallets produced by python-slip39
.
The Binance Smart Chain uses standard Ethereum addresses; support for the BSC is added directly
to the wallet software; here are the instructions for adding BSC support for the Trezor
hardware wallet, using the Metamask software wallet. In python-slip39
, BSC is simply an alias for
ETH, since the wallet addresses and Ethereum JSON Paper Wallets are identical.
If you prefer a graphical user-interface, try the macOS/win32 SLIP-39.App. You can run it directly if
you install Python 3.9+ from python.org/downloads or using homebrew brew install
python-tk@3.10
. Then, start the GUI in a variety of ways:
slip39-gui python3 -m slip39.gui
Alternatively, download and install the macOS/win32 GUI App .zip, .pkg or .dmg installer from github.com/pjkundert/python-slip-39/releases.
From the command line, you can create SLIP-39 Seed Mnemonic card PDFs.
The full command-line argument synopsis for slip39
is:
slip39 --help 2>&1 | sed 's/^/: /' # (just for output formatting)
usage: slip39 [-h] [-v] [-q] [-o OUTPUT] [-t THRESHOLD] [-g GROUP] [-f FORMAT] [-c CRYPTOCURRENCY] [-p PATH] [-j JSON] [-w WALLET] [--wallet-hint WALLET_HINT] [--wallet-format WALLET_FORMAT] [-s SECRET] [-e ENTROPY] [--show] [--no-show] [--bits BITS] [--using-bip39] [--passphrase PASSPHRASE] [-C CARD] [--no-card] [--paper PAPER] [--cover] [--no-cover] [--text] [--watermark WATERMARK] [--double-sided] [--no-double-sided] [--single-sided] [names ...] Create and output SLIP-39 encoded Seeds and Paper Wallets to a PDF file. positional arguments: names Account names to produce; if --secret Entropy is supplied, only one is allowed. options: -h, --help show this help message and exit -v, --verbose Display logging information. -q, --quiet Reduce logging output. -o OUTPUT, --output OUTPUT Output PDF to file or '-' (stdout); formatting w/ name, date, time, crypto, path, address allowed -t THRESHOLD, --threshold THRESHOLD Number of groups required for recovery (default: half of groups, rounded up) -g GROUP, --group GROUP A group name[[<require>/]<size>] (default: <size> = 1, <require> = half of <size>, rounded up, eg. 'Frens(3/5)' ). -f FORMAT, --format FORMAT Specify crypto address formats: legacy, segwit, bech32; default: ETH:legacy, BTC:bech32, LTC:bech32, DOGE:legacy, BSC:legacy, XRP:legacy -c CRYPTOCURRENCY, --cryptocurrency CRYPTOCURRENCY A crypto name and optional derivation path (eg. '../<range>/<range>'); defaults: ETH:m/44'/60'/0'/0/0, BTC:m/84'/0'/0'/0/0, LTC:m/84'/2'/0'/0/0, DOGE:m/44'/3'/0'/0/0, BSC:m/44'/60'/0'/0/0, XRP:m/44'/144'/0'/0/0 -p PATH, --path PATH Modify all derivation paths by replacing the final segment(s) w/ the supplied range(s), eg. '.../1/-' means .../1/[0,...) -j JSON, --json JSON Save an encrypted JSON wallet for each Ethereum address w/ this password, '-' reads it from stdin (default: None) -w WALLET, --wallet WALLET Produce paper wallets in output PDF; each wallet private key is encrypted this password (use --wallet="" for empty password) --wallet-hint WALLET_HINT Paper wallets password hint --wallet-format WALLET_FORMAT Paper wallet size; half, third, quarter or '(<h>,<w>),<margin>' (default: quarter) -s SECRET, --secret SECRET Use the supplied BIP-39 Mnemonic or 128-, 256- or 512-bit hex value as the secret seed; '-' reads it from stdin (eg. output from slip39.recover) -e ENTROPY, --entropy ENTROPY Additional entropy; if 0x... hex, used directly; otherwise, UTF-8 stretched via SHA-512 --show Show derivation of master seed --no-show Disable showing derivation of master seed --bits BITS Ensure that the seed is of the specified bit length; 128, 256, 512 supported. --using-bip39 Generate Seed from secret Entropy using BIP-39 generation algorithm (encode as BIP-39 Mnemonics, encrypted using --passphrase) --passphrase PASSPHRASE Encrypt the master secret w/ this passphrase, '-' reads it from stdin (default: None/'') -C CARD, --card CARD Card size; business, credit, index, half, third, quarter, photo or '(<h>,<w>),<margin>' (default: business) --no-card Disable PDF SLIP-39 mnemonic card output --paper PAPER Paper size (default: Letter) --cover Produce PDF SLIP-39 cover page --no-cover Disable PDF SLIP-39 cover page --text Enable textual SLIP-39 mnemonic output to stdout --watermark WATERMARK Include a watermark on the output SLIP-39 mnemonic cards --double-sided Enable double-sided PDF (default) --no-double-sided Disable double-sided PDF --single-sided Enable single-sided PDF
Later, if you need to recover the wallet seed, keep entering SLIP-39 mnemonics into
slip39-recovery
until the secret is recovered (invalid/duplicate mnemonics will be ignored):
$ python3 -m slip39.recovery # (or just "slip39-recovery") Enter 1st SLIP-39 mnemonic: ab c Enter 2nd SLIP-39 mnemonic: veteran guilt acrobat romp burden campus purple webcam uncover ... Enter 3rd SLIP-39 mnemonic: veteran guilt acrobat romp burden campus purple webcam uncover ... Enter 4th SLIP-39 mnemonic: veteran guilt beard romp dragon island merit burden aluminum worthy ... 2021-12-25 11:03:33 slip39.recovery Recovered SLIP-39 secret; Use: python3 -m slip39 --secret ... 383597fd63547e7c9525575decd413f7
Finally, re-create the wallet seed, perhaps including an encrypted JSON Paper Wallet for import of
some accounts into a software wallet (use --json password
to output encrypted Ethereum JSON
wallet files):
slip39 --secret 383597fd63547e7c9525575decd413f7 --wallet password --wallet-hint bad:pass... 2>&1
2024-11-15 16:14:05 slip39 It is recommended to not use '-s|--secret <hex>'; specify '-' to read from input 2024-11-15 16:14:05 slip39 It is recommended to not use '-w|--wallet <password>'; specify '-' to read from input 2024-11-15 16:14:05 slip39 Generated 128-bit SLIP-39 Mnemonics w/ identifier 25812 requiring 2 of 4 (extendable) groups to recover 2024-11-15 16:14:05 slip39.layout ETH m/44'/60'/0'/0/0 : 0xb44A2011A99596671d5952CdC22816089f142FB3 2024-11-15 16:14:05 slip39.layout BTC m/84'/0'/0'/0/0 : bc1qcupw7k8enymvvsa7w35j5hq4ergtvus3zk8a8s 2024-11-15 16:14:10 slip39.layout Writing SLIP39-encoded wallet for 'SLIP39' to: SLIP39-2024-11-15+16.14.09-ETH-0xb44A2011A99596671d5952CdC22816089f142FB3.pdf SLIP39-2024-11-15+16.14.09-ETH-0xb44A2011A99596671d5952CdC22816089f142FB3.pdf
python3 -m slip39.recovery --help 2>&1 | sed 's/^/: /' # (just for output formatting)
usage: __main__.py [-h] [-v] [-q] [-m MNEMONIC] [-e] [--no-entropy] [-b] [-u] [--binary] [--language LANGUAGE] [-p PASSPHRASE] Recover and output secret Seed from SLIP-39 or BIP-39 Mnemonics options: -h, --help show this help message and exit -v, --verbose Display logging information. -q, --quiet Reduce logging output. -m MNEMONIC, --mnemonic MNEMONIC Supply another SLIP-39 (or a BIP-39) mnemonic phrase -e, --entropy Return the BIP-39 Mnemonic Seed Entropy instead of the generated Seed (default: True if --using-bip39 w/o passphrase) --no-entropy Return the BIP-39 Mnemonic generated Seed -b, --bip39 Recover Entropy and generate 512-bit secret Seed from BIP-39 Mnemonic + passphrase -u, --using-bip39 Recover Entropy from SLIP-39, generate 512-bit secret Seed using BIP-39 Mnemonic + passphrase --binary Output seed in binary instead of hex --language LANGUAGE BIP-39 Mnemonic language (default: english) -p PASSPHRASE, --passphrase PASSPHRASE Decrypt the SLIP-39 or BIP-39 master secret w/ this passphrase, '-' reads it from stdin (default: None/'') If you obtain a threshold number of SLIP-39 mnemonics, you can recover the original secret Seed Entropy, and then re-generate one or more wallets from it. Enter the mnemonics when prompted and/or via the command line with -m |--mnemonic "...". The secret Seed Entropy can then be used to generate a new SLIP-39 encoded wallet: python3 -m slip39 --secret = "ab04...7f" SLIP-39 Mnemonics may be encrypted with a passphrase; this is *not* Ledger-compatible, so it rarely recommended! Typically, on a Trezor, you recover using your SLIP-39 Mnemonics, and then use the "Hidden wallet" feature (passwords entered on the device) to produce alternative sets of accounts. BIP-39 Mnemonics can be backed up as SLIP-39 Mnemonics, in two ways: 1) The actual BIP-39 standard 512-bit Seed can be generated by supplying --passphrase, but only at the cost of 59-word SLIP-39 mnemonics. This is because the *output* 512-bit BIP-39 Seed must be stored in SLIP-39 -- not the *input* 128-, 160-, 192-, 224-, or 256-bit entropy used to create the original BIP-39 mnemonic phrase. 2) The original BIP-39 12- or 24-word, 128- to 256-bit Seed Entropy can be recovered by supplying --entropy. This modifies the BIP-39 recovery to return the original BIP-39 Mnemonic Entropy, before decryption and seed generation. It has no effect for SLIP-39 recovery.
The tools can be used in a pipeline to avoid printing the secret. Here we generate some mnemonics, sorting them in reverse order so we need more than just the first couple to recover. Observe the Ethereum wallet address generated.
Then, we recover the master secret seed in hex with slip39-recovery
, and finally send it to
slip39 --secret -
to re-generate the same wallet as we originally created.
( python3 -m slip39 --text --no-card \
| ( sort -r ; echo "...later, after recovering SLIP-39 mnemonics..." 1>&2 ) \
| python3 -m slip39.recovery \
| python3 -m slip39 --secret - --no-card \
) 2>&1
2024-11-15 16:14:29 slip39 Generated 128-bit SLIP-39 Mnemonics w/ identifier 26257 requiring 2 of 4 (extendable) groups to recover 2024-11-15 16:14:29 slip39.layout ETH m/44'/60'/0'/0/0 : 0xa82995161ef5bf7647F224D3b83140b31787F078 2024-11-15 16:14:29 slip39.layout BTC m/84'/0'/0'/0/0 : bc1qyefnnngkel3ee4sahd62ccucmpdmx02laryk4y ...later, after recovering SLIP-39 mnemonics... 2024-11-15 16:14:29 slip39 Generated 128-bit SLIP-39 Mnemonics w/ identifier 1514 requiring 2 of 4 (extendable) groups to recover 2024-11-15 16:14:29 slip39.layout ETH m/44'/60'/0'/0/0 : 0xa82995161ef5bf7647F224D3b83140b31787F078 2024-11-15 16:14:29 slip39.layout BTC m/84'/0'/0'/0/0 : bc1qyefnnngkel3ee4sahd62ccucmpdmx02laryk4y
A primary use case for python-slip39
will be to backup an existing BIP-39 Mnemonic Phrase to
SLIP-39 cards, so here it is. Suppose you have some (arbitrary) way to recover (or generate)
some Entropy; for example, by recovering the original seed entropy used to generate a BIP-39
Mhemonic:
( python3 -m slip39.recovery --bip39 --entropy \
--mnemonic "zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong" \
| python3 -m slip39 --using-bip39 --secret - \
) 2>&1
2024-11-15 16:21:43 slip39 Assuming BIP-39 seed entropy: Ensure you recover and use via a BIP-39 Mnemonic 2024-11-15 16:21:43 slip39 Generated 128-bit SLIP-39 Mnemonics w/ identifier 31496 requiring 2 of 4 (extendable) groups to recover 2024-11-15 16:21:43 slip39.layout ETH m/44'/60'/0'/0/0 : 0xfc2077CA7F403cBECA41B1B0F62D91B5EA631B5E 2024-11-15 16:21:43 slip39.layout BTC m/84'/0'/0'/0/0 : bc1qk0a9hr7wjfxeenz9nwenw9flhq0tmsf6vsgnn2 2024-11-15 16:21:46 slip39.layout Writing SLIP39 backup for BIP-39-encoded wallet for 'SLIP39' to: SLIP39-2024-11-15+16.21.46-ETH-0xfc2077CA7F403cBECA41B1B0F62D91B5EA631B5E.pdf SLIP39-2024-11-15+16.21.46-ETH-0xfc2077CA7F403cBECA41B1B0F62D91B5EA631B5E.pdf
Better yet, if you already have a BIP-39 Mnemonic, you can just use that directly (we’ll use a bit of “wrapping” around the filename output, so the first page shows up here):
echo -n "[[./$( \
python3 -m slip39 --secret "zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong" --output SLIP39-Example.pdf \
)]]"
Note the presence of the BIP-39 recovery phrase on the cover sheet; this is recovered by round-tripping the original BIP-39 seed entropy, through SLIP-39, and re-encoding back to BIP-39.
For systems that require a stream of groups of wallet Addresses (eg. for preparing invoices for
clients, with a choice of cryptocurrency payment options), slip-generator
can produce a stream
of groups of addresses.
slip39-generator --help --version | sed 's/^/: /' # (just for output formatting)
usage: slip39-generator [-h] [-v] [-q] [-s SECRET] [-f FORMAT] [--xpub] [--no-xpub] [-c CRYPTOCURRENCY] [--path PATH] [-d DEVICE] [--baudrate BAUDRATE] [-e ENCRYPT] [--decrypt ENCRYPT] [--enumerated] [--no-enumerate] [--receive] [--corrupt CORRUPT] Generate public wallet address(es) from a secret seed options: -h, --help show this help message and exit -v, --verbose Display logging information. -q, --quiet Reduce logging output. -s SECRET, --secret SECRET Use the supplied 128-, 256- or 512-bit hex value as the secret seed; '-' (default) reads it from stdin (eg. output from slip39.recover) -f FORMAT, --format FORMAT Specify crypto address formats: legacy, segwit, bech32; default: ETH:legacy, BTC:bech32, LTC:bech32, DOGE:legacy, BSC:legacy, XRP:legacy --xpub Output xpub... instead of cryptocurrency wallet address (and trim non-hardened default path segments) --no-xpub Inhibit output of xpub (compatible w/ pre-v10.0.0) -c CRYPTOCURRENCY, --cryptocurrency CRYPTOCURRENCY A crypto name and optional derivation path (default: "ETH:{Account.path_default('ETH')}"), optionally w/ ranges, eg: ETH:../0/- --path PATH Modify all derivation paths by replacing the final segment(s) w/ the supplied range(s), eg. '.../1/-' means .../1/[0,...) -d DEVICE, --device DEVICE Use this serial device to transmit (or --receive) records --baudrate BAUDRATE Set the baud rate of the serial device (default: 115200) -e ENCRYPT, --encrypt ENCRYPT Secure the channel from errors and/or prying eyes with ChaCha20Poly1305 encryption w/ this password; '-' reads from stdin --decrypt ENCRYPT --enumerated Include an enumeration in each record output (required for --encrypt) --no-enumerate Disable enumeration of output records --receive Receive a stream of slip.generator output --corrupt CORRUPT Corrupt a percentage of output symbols Once you have a secret seed (eg. from slip39.recovery), you can generate a sequence of HD wallet addresses from it. Emits rows in the form: <enumeration> [<address group(s)>] If the output is to be transmitted by an insecure channel (eg. a serial port), which may insert errors or allow leakage, it is recommended that the records be encrypted with a cryptographic function that includes a message authentication code. We use ChaCha20Poly1305 with a password and a random nonce generated at program start time. This nonce is incremented for each record output. Since the receiver requires the nonce to decrypt, and we do not want to separately transmit the nonce and supply it to the receiver, the first record emitted when --encrypt is specified is the random nonce, encrypted with the password, itself with a known nonce of all 0 bytes. The plaintext data is random, while the nonce is not, but since this construction is only used once, it should be satisfactory. This first nonce record is transmitted with an enumeration prefix of "nonce".
Addresses can be produced in plaintext or encrypted, and output to stdout or to a serial port.
echo ffffffffffffffffffffffffffffffff | slip39-generator --secret - --path '../-3' 2>&1
0: [["ETH", "m/44'/60'/0'/0/0", "0x824b174803e688dE39aF5B3D7Cd39bE6515A19a1"], ["BTC", "m/84'/0'/0'/0/0", "bc1q9yscq3l2yfxlvnlk3cszpqefparrv7tk24u6pl"]] 1: [["ETH", "m/44'/60'/0'/0/1", "0x8D342083549C635C0494d3c77567860ee7456963"], ["BTC", "m/84'/0'/0'/0/1", "bc1qnec684yvuhfrmy3q856gydllsc54p2tx9w955c"]] 2: [["ETH", "m/44'/60'/0'/0/2", "0x52787E24965E1aBd691df77827A3CfA90f0166AA"], ["BTC", "m/84'/0'/0'/0/2", "bc1q2snj0zcg23dvjpw7m9lxtu0ap0hfl5tlddq07j"]] 3: [["ETH", "m/44'/60'/0'/0/3", "0xc2442382Ae70c77d6B6840EC6637dB2422E1D44e"], ["BTC", "m/84'/0'/0'/0/3", "bc1qxwekjd46aa5n0s3dtsynvtsjwsne7c5f5w5dsd"]]
To produce accounts from a BIP-39 or SLIP-39 seed, recover it using slip39-recovery.
Here’s an example of recovering a test BIP-39 seed; note that it yields the well-known ETH
0xfc20...1B5E
and BTC bc1qk0...gnn2
accounts associated with this test Mnemonic:
( python3 -m slip39.recovery --bip39 --mnemonic 'zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong' \
| python3 -m slip39.generator --secret - --path '../-3' --format 'BTC:segwit' --crypto 'DOGE' ) 2>&1
0: [["DOGE", "m/44'/3'/0'/0/0", "DTMaJd8wqye1fymnjxZ5Cc5QkN1w4pMgXT"], ["BTC", "m/49'/0'/0'/0/0", "3CfyLSjYFFV6MUAMh3auTK9kfpPscPCHth"]] 1: [["DOGE", "m/44'/3'/0'/0/1", "DGkL2LD5FfccAaKtx8G7TST5iZwrNkecTY"], ["BTC", "m/49'/0'/0'/0/1", "31nD3MEioUDchu7bVaHUCdCa4vxxsqDYwu"]] 2: [["DOGE", "m/44'/3'/0'/0/2", "DQa3SpFZH3fFpEFAJHTXZjam4hWiv9muJX"], ["BTC", "m/49'/0'/0'/0/2", "32pqj8rgW1BdXK2Cygwn2JVYPnVRknfTE4"]] 3: [["DOGE", "m/44'/3'/0'/0/3", "DTW5tqLwspMY3NpW3RrgMfjWs5gnpXtfwe"], ["BTC", "m/49'/0'/0'/0/3", "3CimS2PfrNykKtJe1uxM4QtaDopaFHdVN1"]]
We can encrypt the output, to secure the sequence (and due to integrated MACs, ensures no errors occur over an insecure channel like a serial cable):
( slip39-recovery --bip39 --mnemonic 'zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong' \
| slip39-generator --secret - --path '../-3' --encrypt 'password' ) 2>&1 \
| sed -E 's/^(.{100})(.{1,})$/\1.../' # (shorten output)
nonce: bcfdddcb62fdfec1fb6cae6e44018a3281d290e5db44893be66513c2 0: f7a1e078b97b61fb12837ae38ff8185d1c3446aa24065731b24472d6b7bbdcda5493cf48175900751703792f52233... 1: 647cfe57ef7d2f236ec57eb9ed02fa699b1c3cec5c9f704fc792ff75cb0cbfee007a5082ade596f2a4dc62f94044a... 2: 46af8608026a4046ca4727bfa66dabcd5491a11939e1ebd9d5aeeef17873d9c3bab4f8656b6379208ebab59a18429... 3: 5e7c304d4555a2259d8ef4aaeb45ff3f1102c6d89fea0446aee4b6061bd9fe7631010721546774bb82cf6918fae1e...
On the receiving computer, we can decrypt and recover the stream of accounts from the wallet seed; any rows with errors are ignored:
( slip39-recovery --bip39 --mnemonic 'zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong' \
| slip39-generator --secret - --path '../-3' --encrypt 'password' \
| slip39-generator --receive --decrypt 'password' ) 2>&1
0: [["ETH", "m/44'/60'/0'/0/0", "0xfc2077CA7F403cBECA41B1B0F62D91B5EA631B5E"], ["BTC", "m/84'/0'/0'/0/0", "bc1qk0a9hr7wjfxeenz9nwenw9flhq0tmsf6vsgnn2"]] 1: [["ETH", "m/44'/60'/0'/0/1", "0xd1a7451beB6FE0326b4B78e3909310880B781d66"], ["BTC", "m/84'/0'/0'/0/1", "bc1qkd33yck74lg0kaq4tdcmu3hk4yruhjayxpe9ug"]] 2: [["ETH", "m/44'/60'/0'/0/2", "0x578270B5E5B53336baC354756b763b309eCA90Ef"], ["BTC", "m/84'/0'/0'/0/2", "bc1qvr7e5aytd0hpmtaz2d443k364hprvqpm3lxr8w"]] 3: [["ETH", "m/44'/60'/0'/0/3", "0x909f59835A5a120EafE1c60742485b7ff0e305da"], ["BTC", "m/84'/0'/0'/0/3", "bc1q6t9vhestkcfgw4nutnm8y2z49n30uhc0kyjl0d"]]
If you prefer, you can output “xpub…” format public keys, instead of account addresses. By default, this will elide the non-hardened portion of the default addresses – use the “xpub…” keys to produce the remaining non-hardened portion of the HD wallet paths locally.
For example, assume you must produce a sequence of accounts for each client client of your company to deposit into. Your highly secure serial-connected “key enclave” system (which must know your HD wallet seed) emits a sequence of xpubkeys for each new client over a serial cable, to your accounting system:
( echo 'zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong' \
| python3 -m slip39.generator --secret - --xpub --path "../-2'" --encrypt 'password' \
| python3 -m slip39.generator -v --receive --decrypt 'password' ) 2>&1
2024-11-15 16:22:52 slip39.generator Decrypting accountgroups with nonce: 54ef8298808e20661a0e3f98 0: [["ETH", "m/44'/60'/0'", "xpub6C2y6te3rtGg9SspDDFbjGEgn7yxc5ZzzkBk62yz3GRKvuqdaMDS7NUbesTJ44FprxAE7hvm5ZQjDMbYWehdJQsyBCP3mL87nnB4cB47HGS"], ["BTC", "m/84'/0'/0'", "zpub6rD5AGSXPTDMSnpmczjENMT3NvVF7q5MySww6uxitUsBYgkZLeBywrcwUWhW5YkeY2aS7xc45APPgfA6s6wWfG2gnfABq6TDz9zqeMu2JCY"]] 1: [["ETH", "m/44'/60'/1'", "xpub6C2y6te3rtGgCPb4Gi89Qin7Da2dvnnHSuR9rLQV6bWQKiyfKyjtVzr2n9mKmTEHzr4rzK78LmdSXLSzvpZqVs4ussUU8NyXpt9nWWbKG3C"], ["BTC", "m/84'/0'/1'", "zpub6rD5AGSXPTDMUaSe3aGDqWk4uMTwcrFwytkKuDGmi3ofUkJ4dQxXHZwiXWbHHrELJAor8xGs61F8sbKS2JdQkLZRnu5PGktmr6F32nEBUBb"]] 2: [["ETH", "m/44'/60'/2'", "xpub6C2y6te3rtGgENnaK62SyPawqKvbde17wc2ndMGFWi2yAkk3piwEY9QK8egtE9ye9uoqiqs5WV3MTNCCP2qjUNDb8cmSg4ZsVnwQnkziXVh"], ["BTC", "m/84'/0'/2'", "zpub6rD5AGSXPTDMYx2sQPuZgceniniRXDK5tELiREjxfSGJENNxuQD3u2yfpRqnNE1JeH14Pa7MVGrofDJtyXw252ws9HgRcd82X2M4KzkUfpZ"]]
As required (throttled by hardward the serial cable RTS/CTS signals) your accounting system receives these “xpub…” addresses:
( echo 'zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong' \
| python3 -m slip39.generator --secret - --xpub --path "../-2'" --encrypt 'password' \
| python3 -m slip39.generator -v --receive --decrypt 'password' \
| while IFS=':' read num json; do \
echo "--- $(( num ))"; \
echo "$json" | jq -c '.[]'; \
done \
) 2>&1
2024-11-15 16:22:56 slip39.generator Decrypting accountgroups with nonce: 72a74241ac0c7ad80848c735 --- 0 ["ETH","m/44'/60'/0'","xpub6C2y6te3rtGg9SspDDFbjGEgn7yxc5ZzzkBk62yz3GRKvuqdaMDS7NUbesTJ44FprxAE7hvm5ZQjDMbYWehdJQsyBCP3mL87nnB4cB47HGS"] ["BTC","m/84'/0'/0'","zpub6rD5AGSXPTDMSnpmczjENMT3NvVF7q5MySww6uxitUsBYgkZLeBywrcwUWhW5YkeY2aS7xc45APPgfA6s6wWfG2gnfABq6TDz9zqeMu2JCY"] --- 1 ["ETH","m/44'/60'/1'","xpub6C2y6te3rtGgCPb4Gi89Qin7Da2dvnnHSuR9rLQV6bWQKiyfKyjtVzr2n9mKmTEHzr4rzK78LmdSXLSzvpZqVs4ussUU8NyXpt9nWWbKG3C"] ["BTC","m/84'/0'/1'","zpub6rD5AGSXPTDMUaSe3aGDqWk4uMTwcrFwytkKuDGmi3ofUkJ4dQxXHZwiXWbHHrELJAor8xGs61F8sbKS2JdQkLZRnu5PGktmr6F32nEBUBb"] --- 2 ["ETH","m/44'/60'/2'","xpub6C2y6te3rtGgENnaK62SyPawqKvbde17wc2ndMGFWi2yAkk3piwEY9QK8egtE9ye9uoqiqs5WV3MTNCCP2qjUNDb8cmSg4ZsVnwQnkziXVh"] ["BTC","m/84'/0'/2'","zpub6rD5AGSXPTDMYx2sQPuZgceniniRXDK5tELiREjxfSGJENNxuQD3u2yfpRqnNE1JeH14Pa7MVGrofDJtyXw252ws9HgRcd82X2M4KzkUfpZ"]
Then, it generates each client’s sequence of addresses locally: you are creating HD wallet accounts from each “xpub…” key, and adding the remaining non-hardened HD wallet path segments:
( echo 'zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong' \
| python3 -m slip39.generator --secret - --xpub --path "../-2'" --encrypt 'password' \
| python3 -m slip39.generator -v --receive --decrypt 'password' \
| while IFS=':' read num json; do \
echo "--- $(( num ))"; \
echo "$json" | jq -cr '.[]|"--crypto " + .[0] + " --secret " + .[2]' | while read command; do \
python3 -m slip39.cli -v --no-json addresses $command --paths m/0/-2; \
done; \
done \
) 2>&1
2024-11-15 16:23:16 slip39.generator Decrypting accountgroups with nonce: c9b8956d2cada2aa42bb7524 --- 0 ETH m/0/0 0xfc2077CA7F403cBECA41B1B0F62D91B5EA631B5E ETH m/0/1 0xd1a7451beB6FE0326b4B78e3909310880B781d66 ETH m/0/2 0x578270B5E5B53336baC354756b763b309eCA90Ef BTC m/0/0 bc1qk0a9hr7wjfxeenz9nwenw9flhq0tmsf6vsgnn2 BTC m/0/1 bc1qkd33yck74lg0kaq4tdcmu3hk4yruhjayxpe9ug BTC m/0/2 bc1qvr7e5aytd0hpmtaz2d443k364hprvqpm3lxr8w --- 1 ETH m/0/0 0x9176A747BA67C1d7F80AaDC930180b4183AfB5c4 ETH m/0/1 0xa1409B655aC3e09eF261de00BAa4e85bD2820AA4 ETH m/0/2 0xae22C13Ef5891Ed835C24Ed5090542DFa748c21F BTC m/0/0 bc1q8pqnqs573vx3qdp0xp6qdqzvnvy8px24rxh9lp BTC m/0/1 bc1qwtc58u4mmnxa29u8j07e6lmqpnrs38vefy3y24 BTC m/0/2 bc1qg9s8qzm0lcetfv6umhlm3evtca5zsqv7elqd5s --- 2 ETH m/0/0 0x32A8b066c5dbD37147766491A32A612d313fda25 ETH m/0/1 0xff8b88b975f9C296531C1E93d5e4f28757b4571A ETH m/0/2 0xc95Bdf50CA542E1B689f5C06e2D8bAd0625Dfa23 BTC m/0/0 bc1q09zpchmkcnny90ghkg76gd69dvaf57qwcsrhes BTC m/0/1 bc1qjytdyw6zramwt4nvvpte93hfry2d4xhhqn0xg4 BTC m/0/2 bc1qcummre0pxv5xj4gvyut0t84vfwjd6eu7r387v4
You’ll notice that, after this elaborate exercise of generating xpubkeys, encrypted transmission and recovery, generating accounts from the xpubkeys, and producing multiples addresses using the remainder of the original HD wallet paths: the output addresses are identical to those generated directly from the BIP-39 Mnemonic Phrase:
secret='zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong'
for crypto in BTC ETH; do
python3 -m slip39.cli -v --no-json addresses --secret "$secret" --crypto $crypto --paths "../-2"
done
BTC m/84'/0'/0'/0/0 bc1qk0a9hr7wjfxeenz9nwenw9flhq0tmsf6vsgnn2 BTC m/84'/0'/0'/0/1 bc1qkd33yck74lg0kaq4tdcmu3hk4yruhjayxpe9ug BTC m/84'/0'/0'/0/2 bc1qvr7e5aytd0hpmtaz2d443k364hprvqpm3lxr8w ETH m/44'/60'/0'/0/0 0xfc2077CA7F403cBECA41B1B0F62D91B5EA631B5E ETH m/44'/60'/0'/0/1 0xd1a7451beB6FE0326b4B78e3909310880B781d66 ETH m/44'/60'/0'/0/2 0x578270B5E5B53336baC354756b763b309eCA90Ef
What if you or your company wants to accept Crypto payments, and needs to generate a sequence of wallets unique to each client? You can use an xpubkey and then generate a sequence of unique addresses from that, which doesn’t disclose any of your private key material:
( python3 -m slip39.generator -q --secret 'zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong' \
--xpub --path "../-2'" --crypto BTC
) 2>&1
0: [["BTC", "m/84'/0'/0'", "zpub6rD5AGSXPTDMSnpmczjENMT3NvVF7q5MySww6uxitUsBYgkZLeBywrcwUWhW5YkeY2aS7xc45APPgfA6s6wWfG2gnfABq6TDz9zqeMu2JCY"]] 1: [["BTC", "m/84'/0'/1'", "zpub6rD5AGSXPTDMUaSe3aGDqWk4uMTwcrFwytkKuDGmi3ofUkJ4dQxXHZwiXWbHHrELJAor8xGs61F8sbKS2JdQkLZRnu5PGktmr6F32nEBUBb"]] 2: [["BTC", "m/84'/0'/2'", "zpub6rD5AGSXPTDMYx2sQPuZgceniniRXDK5tELiREjxfSGJENNxuQD3u2yfpRqnNE1JeH14Pa7MVGrofDJtyXw252ws9HgRcd82X2M4KzkUfpZ"]]
Since you have to generate such an xpubkey from a “hardened” path, such as with slip39.generate
--xpub ...
, you still need to run that tool chain on some secure “air gapped” computer. So,
how do you do that safely, knowing that you need to input your SLIP-39 or BIP-39 Mnemonics on
that computer? Especially, if you want to do this under any kind of automation, and deliver the
output xpubkey to your insecure business computer systems?
One solution is to have the computer hosting your Seed or Mnemonic private key material only connected to your business computer systems with a guaranteed safe mechanism. Definitely not with any kind of general purpose network system!
The solution: The RS-232 Serial Port
With USB to DB-9 female to DB-9 male serial adapters, any small computer with USB ports (such as the Raspberry Pi 400) can be connected serially and serve as your “secure” computer, storing your Seed Mnemonic.
Remember to disable all other wired and wireless networking!
The RS-232 port on the “secure” computer can be protected from all incoming data transmissions, make an exploit effectively impossible, while still allowing outgoing data (the generated xpubkeys).
A DB-9 serial breakout board or custom serial adapter be easily constructed that disconnects pin 3 (TXD) on the “business” side from pin 2 (RXD) on the “secure” side, eliminating any chance of data being sent to the “secure” side. The only electronic connection that transmits data to the “secure” side is the hardware flow control pin 7 (RTS) to pin 8 (CTS). An exploit using this single-bit approach vector is … unlikely. :)
Provide SLIP-39 Mnemonic set creation from a 128-bit master secret, and recovery of the secret from a subset of the provided Mnemonic set.
Creates a set of SLIP-39 groups and their mnemonics.
Key | Description |
---|---|
name | Who/what the account is for |
group_threshold | How many groups’ data is required to recover the account(s) |
groups | Each group’s description, as {“<group>”:(<required>, <members>), …} |
master_secret | 128-bit secret (default: from secrets.token_bytes) |
passphrase | An optional additional passphrase required to recover secret (default: “”) |
using_bip39 | Produce wallet Seed from master_secret Entropy using BIP-39 generation |
iteration_exponent | For encrypted secret, exponentially increase PBKDF2 rounds (default: 1) |
cryptopaths | A number of crypto names, and their derivation paths ] |
strength | Desired master_secret strength, in bits (default: 128) |
Outputs a slip39.Details
namedtuple containing:
Key | Description |
---|---|
name | (same) |
group_threshold | (same) |
groups | Like groups, w/ <members> = [“<mnemonics>”, …] |
accounts | Resultant list of groups of accounts |
using_bip39 | Seed produced from entropy using BIP-39 generation |
This is immediately usable to pass to slip39.output
.
import codecs
import random
from tabulate import tabulate
#
# NOTE:
#
# We turn off randomness here during SLIP-39 generation to get deterministic phrases;
# during normal operation, secure entropy is used during mnemonic generation, yielding
# random phrases, even when the same seed is used multiple times.
#
import shamir_mnemonic
shamir_mnemonic.shamir.RANDOM_BYTES = lambda n: b'\00' * n
import slip39
cryptopaths = [("ETH","../-2"), ("BTC","../-2")]
master_secret = b'\xFF' * 16
master_secret = 'zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong'
passphrase = b""
create_details = slip39.create(
"Test", 2, { "Mine": (1,1), "Fam": (2,3) },
master_secret=master_secret, passphrase=passphrase, cryptopaths=cryptopaths )
[
[
"Card", "Mnemonics 1 ", "Mnemonics 2", "Mnemonics 3"
],
None,
] + [
[
f"{g_name}({g_of}/{len(g_mnems)}) #{g_n+1}:" if l_n == 0 else ""
] + words
for g_name,(g_of,g_mnems) in create_details.groups.items()
for g_n,mnem in enumerate( g_mnems )
for l_n,(line,words) in enumerate(slip39.organize_mnemonic(
mnem, label=f"{g_name}({g_of}/{len(g_mnems)}) #{g_n+1}:" ))
]
Card | Mnemonics 1 | Mnemonics 2 | Mnemonics 3 |
---|---|---|---|
Mine(1/1) #1: | 1 academic | 8 umbrella | 15 moment |
2 agency | 9 darkness | 16 segment | |
3 acrobat | 10 salt | 17 privacy | |
4 easy | 11 bishop | 18 loan | |
5 course | 12 impact | 19 tricycle | |
6 prune | 13 vanish | 20 sister | |
7 deadline | 14 squeeze | ||
Fam(2/3) #1: | 1 academic | 8 bumpy | 15 greatest |
2 agency | 9 undergo | 16 luxury | |
3 beard | 10 easel | 17 grill | |
4 echo | 11 smug | 18 task | |
5 drift | 12 oral | 19 plastic | |
6 campus | 13 briefing | 20 auction | |
7 group | 14 luck | ||
Fam(2/3) #2: | 1 academic | 8 saver | 15 fridge |
2 agency | 9 flip | 16 fatal | |
3 beard | 10 fluff | 17 scramble | |
4 email | 11 cleanup | 18 alto | |
5 cover | 12 prevent | 19 inmate | |
6 become | 13 cubic | 20 invasion | |
7 width | 14 multiple | ||
Fam(2/3) #3: | 1 academic | 8 resident | 15 jacket |
2 agency | 9 activity | 16 database | |
3 beard | 10 verify | 17 picture | |
4 entrance | 11 fawn | 18 elegant | |
5 both | 12 yoga | 19 device | |
6 airport | 13 devote | 20 webcam | |
7 decent | 14 perfect |
Add the resultant HD Wallet addresses:
[
[ account.path, account.address ]
for group in create_details.accounts
for account in group
]
Key | Description |
---|---|
name | (same as slip39.create ) |
group_threshold | (same as slip39.create ) |
groups | Like groups, w/ <members> = [“<mnemonics>”, …] |
accounts | Resultant { “path”: Account, …} |
using_bip39 | Generate Seed from Entropy via BIP-39 generation algorithm |
card_format | ‘index’, ‘(<h>,<w>),<margin>’, … |
paper_format | ‘Letter’, … |
orientation | Force an orientation (default: portrait, landscape) |
cover_text | Produce a cover page w/ the text (and BIP-39 Phrase if using_bip39) |
Layout and produce a PDF containing all the SLIP-39 details on cards for the crypto accounts, on the paper_format provided. Returns the paper (orientation,format) used, the FPDF, and passes through the supplied cryptocurrency accounts derived.
(paper_format,orientation),pdf,accounts = slip39.produce_pdf( *create_details )
pdf_binary = pdf.output()
[
[ "Orientation:", orientation ],
[ "Paper:", paper_format ],
[ "PDF Pages:", pdf.pages_count ],
[ "PDF Size:", len( pdf_binary )],
]
Key | Description |
---|---|
names | A sequence of Seed names, or a dict of { name: <details> } (from slip39.create) |
master_secret | A Seed secret (only appropriate if exactly one name supplied) |
passphrase | A SLIP-39 passphrase (not Trezor compatible; use “hidden wallet” phrase on device instead) |
using_bip39 | Generate Seed from Entropy via BIP-39 generation algorithm |
group | A dict of {“<group>”:(<required>, <members>), …} |
group_threshold | How many groups are required to recover the Seed |
cryptocurrency | A sequence of [ “<crypto>”, “<crypto>:<derivation>”, … ] w/ optional ranges |
edit | Derivation range(s) for each cryptocurrency, eg. “../0-4/-9” is 9 accounts first 5 change addresses |
card_format | Card size (eg. “credit”); False specifies no SLIP-39 cards (ie. only BIP-39 or JSON paper wallets) |
paper_format | Paper size (eg. “letter”) |
filename | A filename; may contain “…{name}…” formatting, for name, date, time, crypto path and address |
filepath | A file path, if PDF output to file is desired; empty implies current dir. |
printer | A printer name (or True for default), if output to printer is desired |
json_pwd | If password supplied, encrypted Ethereum JSON wallet files will be saved, and produced into PDF |
text | If True, outputs SLIP-39 phrases to stdout |
wallet_pwd | If password supplied, produces encrypted BIP-38 or JSON Paper Wallets to PDF (preferred vs. json_pwd) |
wallet_pwd_hint | An optional passphrase hint, printed on paper wallet |
wallet_format | Paper wallet size, (eg. “third”); the default is 1/3 letter size |
wallet_paper | Other paper format (default: Letter) |
cover_page | A bool indicating whether to produce a cover page (default: True) |
For each of the names provided, produces a separate PDF containing all the SLIP-39 details and optionally encrypted BIP-38 paper wallets and Ethereum JSON wallets for the specified cryptocurrency accounts derived from the seed, and writes the PDF and JSON wallets to the specified file name(s).
slip39.write_pdfs( ... )
Takes a number of SLIP-39 mnemonics, and if sufficient group_threshold
groups’ mnemonics are
present (and the options passphrase
is supplied), the master_secret
is recovered. This can
be used with slip39.accounts
to directly obtain any Account
data.
Note that the SLIP-39 passphrase is not checked; entering a different passphrase for the same set of mnemonics will recover a different wallet! This is by design; it allows the holder of the SLIP-39 mnemonic phrases to recover a “decoy” wallet by supplying a specific passphrase, while protecting the “primary” wallet.
Therefore, it is essential to remember any non-default (non-empty) passphrase used, separately and securely. Take great care in deciding if you wish to use a passphrase with your SLIP-39 wallet!
Key | Description |
---|---|
mnemonics | [“<mnemonics>”, …] |
passphrase | Optional passphrase to decrypt secret Seed Entropy |
using_bip39 | Use BIP-39 Seed generation from recover Entropy |
# Recover with the wrong password (on purpose, as a decoy wallet w/ a small amount)
recoverydecoy = slip39.recover(
create_details.groups['Mine'][1][:] + create_details.groups['Fam'][1][:2],
passphrase=b"wrong!"
)
recoverydecoy_hex = codecs.encode( recoverydecoy, 'hex_codec' ).decode( 'ascii' )
# But, recovering w/ correct passphrase yields our original Seed Entropy
recoveryvalid = slip39.recover(
create_details.groups['Mine'][1][:] + create_details.groups['Fam'][1][:2],
passphrase=passphrase
)
recoveryvalid_hex = codecs.encode( recoveryvalid, 'hex_codec' ).decode( 'ascii' )
[
[ f"{len(recoverydecoy)*8}-bit secret (decoy):", f"{recoverydecoy_hex}" ],
[ f"{len(recoveryvalid)*8}-bit secret recovered:", f"{recoveryvalid_hex}" ]
]
Generate the 512-bit Seed from a BIP-39 Mnemonic + passphrase. Or, return the original 128- to
256-bit Seed Entropy, if as_entropy
is specified.
Key | Description |
---|---|
mnemonic | “<mnemonic>” |
passphrase | Optional passphrase to decrypt secret Seed Entropy |
as_entropy | Return the BIP-39 Seed Entropy, not the generated Seed |
Produce a BIP-39 Mnemonic from the supplied 128- to 256-bit Seed Entropy.
Key | Description |
---|---|
entropy | The bytes of Seed Entropy |
strength | Or, the number of bits of Entropy to produce (Default: 128) |
language | Default is “english” |
If we already have a BIP-39 wallet, it would certainly be nice to be able to create nice, safe SLIP-39 mnemonics for it, and discard the unsafe BIP-39 mnemonics we have lying around, just waiting to be accidentally discovered and the account compromised!
Fortunately, we can do this! It takes a bit of practice to become comfortable with the process, but once you do – you can confidently discard your original insecure and unreliable BIP-39 Mnemonic backups.
Unfortunately, it is not possible to cleanly convert a BIP-39 generated wallet Seed into a SLIP-39 wallet. Both BIP-39 and SLIP-39 preserve the original 128- to 256-bit Seed Entropy (random) bits, but these bits are used very differently – and incompatibly – to generate the resultant wallet Seed.
In native SLIP-39, the original, recovered Seed Entropy (128- or 256-bits) is used directly by the BIP-44 wallet derivation. In BIP-39, the Seed entropy is not directly used at all! It is only indirectly used; the BIP-39 Seed Phrase (which contains the exact, original entropy) is used, as normalized text, as input to a hashing function, along with some other fixed text, to produce a 512-bit Seed, which is then fed into the BIP-44 wallet derivation process.
The least desirable method is to preserve the 512-bit output of the BIP-39 mnemonic phrase as a set of 512-bit (59-word) SLIP-39 Mnemonics. But first, lets review how BIP-39 works.
BIP-39 uses a single set of 12, 15, 18, 21 or 24 BIP-39 words to carefully preserve a specific
128 to 256 bits of initial Seed Entropy. Here’s a 128-bit (12-word) example using some fixed
“entropy” 0xFFFF..FFFF
. You’ll note that, from the BIP-39 Mnemonic, we can either recover the
original 128-bit Seed Entropy, or we can generate the resultant 512-bit Seed w/ the correct
passphrase:
from mnemonic import Mnemonic
bip39_english = Mnemonic("english")
entropy = b'\xFF' * 16
entropy_hex = codecs.encode( entropy, 'hex_codec' ).decode( 'ascii' )
entropy_mnemonic = bip39_english.to_mnemonic( entropy )
recovered = slip39.recover_bip39( entropy_mnemonic, as_entropy=True )
recovered_hex = codecs.encode( recovered, 'hex_codec' ).decode( 'ascii' )
recovered_seed = slip39.recover_bip39( entropy_mnemonic, passphrase=passphrase )
recovered_seed_hex= codecs.encode( recovered_seed, 'hex_codec' ).decode( 'ascii' )
[
[ "Original Entropy", entropy_hex ],
[ "BIP-39 Mnemonic", entropy_mnemonic ],
[ "Recovered Entropy", recovered_hex ],
[ "Recovered Seed", f"{recovered_seed_hex:.50}..." ],
]
Each word is one of a corpus of 2048 words; therefore, each word encodes 11 bits (2048 = 2**11) of entropy. So, we provided 128 bits, but 12*11 = 132. So where does the extra 4 bits of data come from?
It comes from the first few bits of a SHA256 hash of the entropy, which is added to the end of the supplied 128 bits, to reach the required 132 bits: 132 / 11 = 12 words.
This last 4 bits (up to 8 bits, for a 256-bit 24-word BIP-39) is checked, when validating the BIP-39 mnemonic. Therefore, making up a random BIP-39 mnemonic will succeed only 1 / 16 times on average, due to an incorrect checksum 4-bit (16 = 2**4) . Lets check:
def random_words( n, count=100 ):
for _ in range( count ):
yield ' '.join( random.choice( bip39_english.wordlist ) for _ in range( n ))
successes = sum(
bip39_english.check( m )
for i,m in enumerate( random_words( 12, 10000 ))) / 100
[
[ "Valid random 12-word mnemonics:", f"{successes}%" ],
[ "Or, about: ", f"1 / {100/successes:.3}" ],
]
Sure enough, about 1/16 random 12-word phrases are valid BIP-39 mnemonics. OK, we’ve got the contents of the BIP-39 phrase dialed in. How is it used to generate accounts?
Unfortunately, BIP-39 does not use the carefully preserved 128-bit entropy to generate the wallet! Nope, it is stretched to a 512-bit seed using PBKDF2 HMAC SHA512. The normalized text (not the Entropy bytes) of the 12-word mnemonic is then used (with a salt of “mnemonic” plus an optional passphrase, “” by default), to obtain the 512-bit seed:
seed = bip39_english.to_seed( entropy_mnemonic )
seed_hex = codecs.encode( seed, 'hex_codec' ).decode( 'ascii' )
[
[ f"{len(seed)*8}-bit seed:", f"{seed_hex:.50}..." ]
]
Finally, this 512-bit seed is used to derive HD wallet(s). The HD Wallet key derivation process consumes whatever seed entropy is provided (512 bits in the case of BIP-39), and uses HMAC SHA512 with a prefix of b”Bitcoin seed” to stretch the supplied seed entropy to 64 bytes (512 bits). Then, the HD Wallet path segments are iterated through, permuting the first 32 bytes of this material as the key with the second 32 bytes of material as the chain node, until finally the 32-byte (256-bit) Ethereum account private key is produced. We then use this private key to compute the rest of the Ethereum account details, such as its public address.
path = "m/44'/60'/0'/0/0"
bip39_eth_hd = slip39.account( seed, 'ETH', path )
[
[ f"{len(bip39_eth_hd.key)*4}-bit derived key path:", f"{path}" ],
[ "Produces private key: ", f"{bip39_eth_hd.key}" ],
[ "Yields Ethereum address:", f"{bip39_eth_hd.address}" ],
]
Thus, we see that while the 12-word BIP-39 mnemonic careful preserves the original 128-bit entropy, this data is not directly used to derive the wallet private key and address. Also, since an irreversible hash is used to derive the Seed from the Mnemonic, we can’t reverse the process on the seed to arrive back at the BIP-39 mnemonic phrase.
Just like BIP-39 carefully preserves the original 128-bit Seed Entropy bytes in a single 12-word mnemonic phrase, SLIP-39 preserves the original 128- or 256-bit Seed Entropy in a set of 20- or 33-word Mnemonic phrases.
name,thrs,grps,acct,ub39 = slip39.create(
"Test", 2, { "Mine": (1,1), "Fam": (2,3) }, entropy )
[
[ f"{g_name}({g_of}/{len(g_mnems)}) #{g_n+1}:" if l_n == 0 else "" ] + words
for g_name,(g_of,g_mnems) in grps.items()
for g_n,mnem in enumerate( g_mnems )
for l_n,(line,words) in enumerate(slip39.organize_mnemonic(
mnem, rows=7, cols=3, label=f"{g_name}({g_of}/{len(g_mnems)}) #{g_n+1}:" ))
]
Since there is some randomness used in the SLIP-39 mnemonics generation process, we would get a
different set of words each time for the fixed “entropy” 0xFFFF..FF
used in this example (if
we hadn’t manually disabled entropy for shamir_mnemonic
, above), but we will always derive
the same Ethereum account 0x824b..19a1
at the specified HD Wallet derivation path.
[
[ "Crypto", "HD Wallet Path:", "Ethereum Address:" ],
None,
] + [
[ account.crypto, account.path, account.address ]
for group in create_details.accounts
for account in group
]
Crypto | HD Wallet Path: | Ethereum Address: |
---|---|---|
ETH | m/44’/60’/0’/0/0 | 0xfc2077CA7F403cBECA41B1B0F62D91B5EA631B5E |
BTC | m/84’/0’/0’/0/0 | bc1qk0a9hr7wjfxeenz9nwenw9flhq0tmsf6vsgnn2 |
ETH | m/44’/60’/0’/0/1 | 0xd1a7451beB6FE0326b4B78e3909310880B781d66 |
BTC | m/84’/0’/0’/0/1 | bc1qkd33yck74lg0kaq4tdcmu3hk4yruhjayxpe9ug |
ETH | m/44’/60’/0’/0/2 | 0x578270B5E5B53336baC354756b763b309eCA90Ef |
BTC | m/84’/0’/0’/0/2 | bc1qvr7e5aytd0hpmtaz2d443k364hprvqpm3lxr8w |
Lets prove that we can actually recover the original Seed Entropy from the SLIP-39 recovery Mnemonics; in this case, we’ve specified a SLIP-39 group_threshold of 2 groups, so we’ll use 1 Mnemonic from Mine, and 2 from the Fam group:
_,mnem_mine = grps['Mine']
_,mnem_fam = grps['Fam']
recseed = slip39.recover( mnem_mine + mnem_fam[:2] )
recseed_hex = codecs.encode( recseed, 'hex_codec' ).decode( 'ascii' )
[
[ f"{len(recseed)*8}-bit Seed:", f"{recseed_hex}" ]
]
And we’ll use the same style of code as for the BIP-39 example above, to derive the Ethereum address directly from this recovered 128-bit seed:
slip39_eth_hd = slip39.account( recseed, 'ETH', path )
[
[ f"{len(slip39_eth_hd.key)*4}-bit derived key path:", f"{path}" ],
[ "Produces private key: ", f"{slip39_eth_hd.key}" ],
[ "Yields Ethereum address:", f"{slip39_eth_hd.address}" ],
]
And we see that we obtain the same Ethereum address 0x824b..1a2b
as we originally got from
slip39.create
above. However, this is not the same Ethereum wallet address obtained from
BIP-39 with exactly the same 0xFFFF...FF
Seed Entropy, which was 0xfc20..1B5E
!
This is due to the fact that BIP-39 does not use the recovered Seed Entropy to produce the seed like SLIP-39 does, but applies additional one-way hashing of the Mnemonic to produce a 512-bit Seed.
At no time in BIP-39 account derivation is the original 128-bit Seed Entropy used (directly) in the derivation of the wallet key. This differs from SLIP-39, which directly uses the 128-bit Seed Entropy recovered from the SLIP-39 Shamir’s Secret Sharing System recovery process to generate each HD Wallet account’s private key.
Furthermore, there is no point in the BIP-39 Seed Entropy to account generation where we could introduce a known 128-bit seed and produce a known Ethereum wallet from it, other than at the very beginning.
Therefore, our BIP-39 Backup via SLIP-39 strategy must focus on backing up the original 128- to 256-bit Seed Entropy, not the output Seed data!
Here are the two available methods for backing up insecure and unreliable BIP-39 Mnemonic phrases, using SLIP-39.
The first “Emergency Recovery” method allows you to recover your BIP-39 generated wallets without the passphrase, but does not support recovery using hardware wallets; you must output “Paper Wallets” and use them to recover the Cryptocurrency funds.
The second “Best Recovery: Using Recovered BIP-39 Mnemonic Phrase” allows us to recover the accounts to any standard BIP-39 hardware wallet! However, the SLIP-39 Mnemonics are not compatible with standard SLIP-39 wallets like the Trezor – you have to use the recovered BIP-39 Mnemonic phrase to recover the hardware wallet.
There is one approach which can preserve an original BIP-39 generated wallet addresses, using SLIP-39 mnemonics.
It is clumsy, as it preserves the BIP-39 output 512-bit stretched seed, and the resultant 59-word SLIP-39 mnemonics cannot be used (at present) with the Trezor hardware wallet. They can, however, be used to recover the HD wallet private keys without access to the original BIP-39 Mnemonic phrase or passphrase – you could generate and distribute a set of more secure SLIP-39 Mnemonic phrases, instead of trying to secure the original BIP-39 mnemonic + passphrase – without abandoning your existing BIP-39 wallets.
We’ll use slip39.recovery --bip39 ...
to recover the 512-bit stretched seed from BIP-39:
( python3 -m slip39.recovery --bip39 -v \
--mnemonic "zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong"
) 2>&1
2024-11-15 16:28:16 slip39.recovery BIP-39 Language detected: english 2024-11-15 16:28:16 slip39.recovery Recovered 512-bit BIP-39 secret from english mnemonic 2024-11-15 16:28:16 slip39.recovery Recovered BIP-39 secret; To re-generate SLIP-39 wallet, send it to: python3 -m slip39 --secret - b6a6d8921942dd9806607ebc2750416b289adea669198769f2e15ed926c3aa92bf88ece232317b4ea463e84b0fcd3b53577812ee449ccc448eb45e6f544e25b6
Then we can generate a 59-word SLIP-39 mnemonic set from the 512-bit secret:
( python3 -m slip39.recovery --bip39 \
--mnemonic "zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong" \
| python3 -m slip39 --secret - --no-card -v
) 2>&1 | tail -20
2024-11-15 16:28:24 slip39 7 identify 19 easel 31 stay 43 dough 55 extra 2024-11-15 16:28:24 slip39 8 garbage 20 moisture 32 dining 44 energy 56 desktop 2024-11-15 16:28:24 slip39 9 avoid 21 wisdom 33 alto 45 goat 57 exercise 2024-11-15 16:28:24 slip39 10 velvet 22 mixture 34 inmate 46 costume 58 sugar 2024-11-15 16:28:24 slip39 11 fawn 23 fluff 35 froth 47 knife 59 drink 2024-11-15 16:28:24 slip39 12 retailer 24 snake 36 round 48 flash 2024-11-15 16:28:24 slip39 6th 1 charity 13 space 25 safari 37 hairy 49 detailed 2024-11-15 16:28:24 slip39 2 penalty 14 wits 26 prepare 38 golden 50 skunk 2024-11-15 16:28:24 slip39 3 decision 15 ounce 27 liberty 39 scroll 51 mineral 2024-11-15 16:28:24 slip39 4 spider 16 leader 28 expect 40 unknown 52 plunge 2024-11-15 16:28:24 slip39 5 acne 17 exchange 29 join 41 chubby 53 square 2024-11-15 16:28:24 slip39 6 alien 18 tenant 30 display 42 memory 54 adjust 2024-11-15 16:28:24 slip39 7 estate 19 coastal 31 group 43 spill 55 vanish 2024-11-15 16:28:24 slip39 8 leader 20 amazing 32 snake 44 helpful 56 unwrap 2024-11-15 16:28:24 slip39 9 decision 21 retreat 33 trial 45 oven 57 tolerate 2024-11-15 16:28:24 slip39 10 wireless 22 indicate 34 alpha 46 crisis 58 rival 2024-11-15 16:28:24 slip39 11 phrase 23 acquire 35 harvest 47 intend 59 work 2024-11-15 16:28:24 slip39 12 plastic 24 grill 36 custody 48 glen 2024-11-15 16:28:24 slip39.layout ETH m/44'/60'/0'/0/0 : 0xfc2077CA7F403cBECA41B1B0F62D91B5EA631B5E 2024-11-15 16:28:24 slip39.layout BTC m/84'/0'/0'/0/0 : bc1qk0a9hr7wjfxeenz9nwenw9flhq0tmsf6vsgnn2
This 0xfc20..1B5E
address is the same Ethereum address as is recovered on a Trezor using this
BIP-39 mnemonic phrase. Thus, we can generate “Paper Wallets” for the desired Cryptocurrency
accounts, and recover the funds.
So, this does the job:
- Uses our original BIP-39 Mnemonic
- Does not require remembering the BIP-39 passphrase
- Preserves all of the original wallets
But:
- The 59-word SLIP-39 Mnemonics cannot (yet) be imported into the Trezor
- The original BIP-39 Mnemonic phrase cannot be recovered, for any hardware wallet
- Must use the SLIP-39 App to generate “Paper Wallets”, to recover the funds
So, this is a good “emergency backup” solution; you or your heirs would be able to recover the funds with a very high level of security and reliability.
The best solution is to use SLIP-39 to back up the original BIP-39 Seed Entropy (not the generated Seed), and then later recover that Seed Entropy and re-generate the BIP-39 Mnemonic phrase. You will continue to need to remember and use your original BIP-39 passphrase:
First, observe that we can recover the 128-bit Seed Entropy from the BIP-39 Mnemonic phrase (not the 512-bit generated Seed):
( python3 -m slip39.recovery --bip39 --entropy -v \
--mnemonic "zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong"
) 2>&1
2024-11-15 16:28:29 slip39.recovery BIP-39 Language detected: english 2024-11-15 16:28:29 slip39.recovery Recovered 128-bit BIP-39 entropy from english mnemonic (no passphrase supported) 2024-11-15 16:28:29 slip39.recovery Recovered BIP-39 secret; To re-generate SLIP-39 wallet, send it to: python3 -m slip39 --secret - ffffffffffffffffffffffffffffffff
Now we generate SLIP-39 Mnemonics to recover the 128-bit Seed Entropy. Note that these are
20-word Mnemonics. However, these are NOT the wallets we expected! These are the well-known
native SLIP-39 wallets from the 0xFFFF...FF
Seed Entropy; not the well-known native BIP-39
wallets from that Seed Entropy, which generate the Ethereum wallet address 0xfc20..1B5E
! Why
not?
( python3 -m slip39.recovery --bip39 --entropy \
--mnemonic 'zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong' \
| python3 -m slip39 --secret - --no-card -v
) 2>&1 | tail -20
2024-11-15 16:28:50 slip39 4 skin 11 smear 18 volume 2024-11-15 16:28:50 slip39 5 artwork 12 usher 19 arcade 2024-11-15 16:28:50 slip39 6 season 13 raisin 20 training 2024-11-15 16:28:50 slip39 7 exchange 14 uncover 2024-11-15 16:28:50 slip39 5th 1 ceramic 8 scared 15 champion 2024-11-15 16:28:50 slip39 2 industry 9 deal 16 literary 2024-11-15 16:28:50 slip39 3 decision 10 hobo 17 dragon 2024-11-15 16:28:50 slip39 4 snake 11 scene 18 axis 2024-11-15 16:28:50 slip39 5 detailed 12 losing 19 result 2024-11-15 16:28:50 slip39 6 shrimp 13 unfold 20 saver 2024-11-15 16:28:50 slip39 7 hearing 14 slice 2024-11-15 16:28:50 slip39 6th 1 ceramic 8 gray 15 judicial 2024-11-15 16:28:50 slip39 2 industry 9 union 16 picture 2024-11-15 16:28:50 slip39 3 decision 10 capture 17 frozen 2024-11-15 16:28:50 slip39 4 spider 11 closet 18 spill 2024-11-15 16:28:50 slip39 5 diagnose 12 quiet 19 either 2024-11-15 16:28:50 slip39 6 width 13 extra 20 flip 2024-11-15 16:28:50 slip39 7 fishing 14 wireless 2024-11-15 16:28:50 slip39.layout ETH m/44'/60'/0'/0/0 : 0x824b174803e688dE39aF5B3D7Cd39bE6515A19a1 2024-11-15 16:28:50 slip39.layout BTC m/84'/0'/0'/0/0 : bc1q9yscq3l2yfxlvnlk3cszpqefparrv7tk24u6pl
Because we must tell slip39
to that we’re using the BIP-39 Mnemonic and Seed generation
process to derived the wallet addresses from the Seed Entropy (not the SLIP-39 standard). So,
we add the -using-bip39
option:
( python3 -m slip39.recovery --bip39 --entropy \
--mnemonic "zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo zoo wrong" \
| python3 -m slip39 --secret - --no-card -v --using-bip39
) 2>&1 | tail -20
2024-11-15 16:29:06 slip39 4 skin 11 arena 18 warmth 2024-11-15 16:29:06 slip39 5 debris 12 advocate 19 heat 2024-11-15 16:29:06 slip39 6 client 13 taught 20 hush 2024-11-15 16:29:06 slip39 7 expand 14 minister 2024-11-15 16:29:06 slip39 5th 1 argue 8 reunion 15 detailed 2024-11-15 16:29:06 slip39 2 withdraw 9 penalty 16 starting 2024-11-15 16:29:06 slip39 3 decision 10 false 17 excuse 2024-11-15 16:29:06 slip39 4 snake 11 ting 18 sheriff 2024-11-15 16:29:06 slip39 5 depart 12 petition 19 dragon 2024-11-15 16:29:06 slip39 6 papa 13 submit 20 browser 2024-11-15 16:29:06 slip39 7 march 14 order 2024-11-15 16:29:06 slip39 6th 1 argue 8 union 15 coding 2024-11-15 16:29:06 slip39 2 withdraw 9 texture 16 bumpy 2024-11-15 16:29:06 slip39 3 decision 10 equip 17 idle 2024-11-15 16:29:06 slip39 4 spider 11 platform 18 slush 2024-11-15 16:29:06 slip39 5 arena 12 party 19 theory 2024-11-15 16:29:06 slip39 6 decrease 13 award 20 violence 2024-11-15 16:29:06 slip39 7 pacific 14 nuclear 2024-11-15 16:29:06 slip39.layout ETH m/44'/60'/0'/0/0 : 0xfc2077CA7F403cBECA41B1B0F62D91B5EA631B5E 2024-11-15 16:29:06 slip39.layout BTC m/84'/0'/0'/0/0 : bc1qk0a9hr7wjfxeenz9nwenw9flhq0tmsf6vsgnn2
And, there we have it – we’ve recovered exactly the same Ethereum and Bitcoin wallets as would a native BIP-39 hardware wallet like a Ledger Nano.
In the SLIP-39 App, the default Controls presented are to “Backup” a BIP-39 recovery phrase.
In “Seed Source”, enter your existing BIP-39 recovery phrase. In “Seed Secret”, make sure “Using BIP-39” is selected, and enter your BIP-39 passphrase. This allows us to display the proper wallet addresses – we do not store your password, or save it as part of the SLIP-39 cards! You will need to remember and use your passphrase whenever you use your BIP-39 phrase to initialize a hardware wallet.
Check that the Recovery needs … Mnemonic Card Groups are correct for your application, and hit Save!
Later, use the “Recover” Controls to get your BIP-39 recovery phrase back, from your SLIP-39 cards, whenever you need it.
Practice this a few times (using the “zoo zoo … wrong” 12-word or “zoo zoo … vote” 24-word phrase) until you’re confident. Then, back up your real BIP-39 recovery phrase.
Once you’re convinced you can securely and reliably recover your BIP-39 phrase any time you need it, we recommend that you destroy your original BIP-39 recovery phrase backup(s). They are dangerous and unreliable, and only serve to make your Cryptocurrency accounts less secure!
A valuable use of Cryptocurrency accounts is to send or receive payments for goods, services or remittances/donations. The global monetary system makes this very difficult (or even impossible), especially if any of the corporations or governments involved in the transaction are hostile to you or any of the other individuals attempting to transact business.
Worse yet, your business or family can be arbitrarily ejected from the financial system by an of the many intermediary banking industry and government parties involved in any traditional financial transaction, even if you are not convicted of a crime.
Even if such payments are allowed, and none of the counterparties are actively hostile to you, the complexity and expense of quoting a price, signing a client, invoicing for payment, confirming the validity of the invoice and making the payment, monitoring for incoming payments and associating them with the correct invoices, conforming amounts paid are correct, issuing a receipt, book-keeping the incoming payment, converting currencies, retaining the correct taxes for each counterparty jurisdiction, reconciling books, and finally preparing and filing taxes, and then (perhaps years later) defending your accounting decisions against a hostile tax inspector with infinite funds to prosecute – all this makes it virtually impossible for a small business to survive. Furthermore, you must accomplish all this, without error, while attempting to defend yourself against business adversaries with preferential tax treatment, office-towers full of lawyers and accountants, for whom the total percentage of gross revenues paid to accomplish compliance is less than 1%, while the small business is likely to spend 10% to 25% of their entire gross revenue just to financial and regulatory compliance overheads.
Fortunately, DeFi (Decentralized Finance) provides you with the capability to receive payments, quickly and efficiently, from anyone on the planet who wishes to pay you for your services.
Your software can use a variety of means to verify payment, and then license use of the various functionality of your software.
If your needs are simple, you can securely generate an xpub...
key using a unique HD Wallet
derivation path for each separate enterprise you wish to receive funds for. If this is done in a
secure (ie. air-gapped) environment, then this xpub...
key can safely be used to generate a
sequence of HD Wallet addresses for each “client” you wish to charge.
The client deposits cryptocurrency, and you (later) transfer or aggregate it as you wish – using your normal, secure (ie. Hardware Wallet) transfer process.
This is simplest for the client, as they can buy Cryptocurrency on any exchange, and simply “withdraw” the correct amount of Cryptocurrency to the given account. However, these is no other information attached to the transaction – all “licensing” verification takes place manually, outside the cryptocurrency system.
So, generating a sequence of plain (Externally Owned Account, or EOA) client addresses from an
xpub...
is a worthwhile solution to consider. However, it does have some drawbacks:
Collecting up all the clients’ payments later is a manual process. If you wish to distribute the payments (say, to pay partners, or a licensor whose software you sub-licensed, or to ensure that you get paid should someone license your software), this must all be done manually.
If ERC-20 tokens are accepted into the generated EOA addresses, then you must transfer Ethereum into the account first, before transferring out the ERC-20 tokens. This requires at least one additional transfer fee, and since Gas fees are now variable, may result in a small amount of Ethereum abandoned in the account.
In any payment system with many clients paying for product(s), and fees being distributed to various payees, there are normally many trusted partners involved, and many manual (or automated) processes that can fail.
For example, what if a piece of software is created and distributed by some organization, and this software uses your licensed module? If the organization fails, or is deplatformed by a hostile government or corporation, or the software is abandoned, then clients who find the software and install it and want to pay for a license will probably not be able to pay the organization for it – and your license fees also will go unpaid.
Surely, there must be a way to deploy a sequence of interconnected Smart Contracts that can ensure that:
- Any new client can uniquely allocate (and optionally store some data with) a “Forwarder” address and pay for the product,
- Payment into that account address (and perhaps validation of its unique data) constitutes proof of licensing,
- Payees (direct and indirect) can flush any such payments through to themselves (and others)
These goals can be achieved using per-client “Forwarder” account addresses.
The solution to this problem is to use accounts that nobody has “private key” access to – including you (the software issuer), or any client.
These accounts host an Ethereum Smart Contract (the account address is actually the pre-computed address of a future instance of a “Forwarder” contract). They are not Externally Owned Account (EOA) addresses, and have no Private Key; they can only do what their Smart Contract defines.
The only function of these “Forwarder” Contracts is to collect the address’ Ethereum and ERC-20
tokens into the product’s “Fee Distribution” MultiPayoutERC20
Contract account, optionally
storing an immutable value associated with the “salt” value from which the “Forwarder” account
address is derived.
Once the product’s MultiPayoutERC20
“Fee Distribution” contract address is identified, the act
of obtaining a unique client payee “Forwarder” address is simple.
- A “salt” value unique to the client is deduced, usually consisting of “something they know” (eg. a Public Key) plus “something they have” (eg. a Machine ID, or a User Name).
- The salt is used to deduce the client’s unique “Forwarder” address
The creation of a MultiPayoutERC20
contract is very simple.
The product owner must know the Ethereum addresses of the payees, and each payee’s proportion of the product revenue. A payee may be another MultiPayoutERC20 contract (eg. for a product module sub-license), which may in turn have its own payees.
An Ethereum account containing sufficient funds to establish the MultiPayoutERC20 contract must be available. Here’s an example, using the Ethereum “Goerli” testnet.
Since contract creation is expensive, we’ll determine if we’ve already deployed a
MultiPayoutERC20 contract, so we don’t need to spend funds to executed this example.
We’ll use any GOERLI_SEED
or GOERLI_XPRVKEY
defined in your environment, as
well as ALCHEMY_API_TOKEN
and ETHERSCAN_API_TOKEN
available.
First, lets get the Ethereum account private key details, and see if we’ve already deployed a MultiPayoutERC20:
#
# To create a new MultiPayoutERC20contract:
#
# Provide yourself with a Goerli testnet account under your control;
# provide an "xpub..." key for it, or the BIP-39 Mnemonic phrase to
# derive its HD wallet. Use the https://goerlifaucet.com to fund the
# account with some Goerli test Ethereum; requires you to set up an
# https://alchemy.com account, and put your API token in the
# ALCHEMY_API_TOKEN environment variable.
#
# If you have an Etherscan API token, put it in ETHERSCAN_API_TOKEN.
# This will be used to scan for any existing contracts already deployed by
# your Goerli testnet Ethernet address.
#
import os
import logging
from web3 import Web3
import slip39
from slip39.invoice import MultiPayoutERC20, ethereum, Chain
goerli_xprvkey = os.getenv( 'GOERLI_XPRVKEY' )
if not goerli_xprvkey:
goerli_seed = os.getenv( 'GOERLI_SEED' )
print(f"Using Ethereum seed: {goerli_seed}")
if goerli_seed:
try:
# why m/44'/1'/... instead of m/44'/60'/...? Dunno;
# That's the derivation path that Trezor Suite uses for
# Goerli testnet wallets...
goerli_xprvkey = slip39.account(
goerli_seed, crypto="ETH", path="m/44'/1'/0'"
).xprvkey
except Exception as exc:
print(f"Failed to deduce XPRVKEY from seed: {exc}")
contract = None
mp_found = None
if goerli_xprvkey:
# We have the means to authorize a transaction on an Ethereum account!
# Get the Account.address public from the xprvkey
goerli_src = slip39.account(
goerli_xprvkey, crypto='ETH', path="m/0/0"
)
print(f"Using Ethereum address: {goerli_src}")
# eg. f"wss://eth-goerli.g.alchemy.com/v2/{os.getenv( 'ALCHEMY_API_TOKEN' )}"
provider_url = ethereum.alchemy_url( ethereum.Chain.Goerli )
provider = Web3.WebsocketProvider( provider_url )
# Lets scan the address's transactions for any existing contract creations,
# and see if any match our MultiPayoutERC20 API. Will automatically use the
# ETHERSCAN_API_TOKEN environment variable, if defined.
try:
for tx in reversed(ethereum.ethertx( chain=Chain.Goerli, address=goerli_src.address )):
if not ( contract := tx.get( 'contractAddress' )):
continue
try:
mp_found = MultiPayoutERC20(
provider,
address = Web3.to_checksum_address( contract ),
)
except Exception as exc:
print( f"Contract {contract} is not a MultiPayoutERC20: {exc}" )
else:
print( f"Contract {contract} IS a MultiPayoutERC20" )
break
else:
print( f"No MultiPayoutERC20 contracts found for Goerli address {goerli_src}" )
except Exception as exc:
print( f"Failed to scan {goerli_src!r} for contracts: {exc}" )
f"MultiPayoutERC20 found: {contract}\n\n{mp_found}"
MultiPayoutERC20 Payees:
| 0x7Fc431B8FC8250A992567E3D7Da20EE68C155109 | 1881679017/4294967296 | 43.8113 | 0 | 0 | 43.8113 | 0 | ERC-20s:If we didn’t find a MultiPayoutERC20, and have the means to deploy and have not already, do so! We’ll always send the same proportion to the next 3 accounts in our HD wallet for this example.
#
# Deploy a new MultiPayoutERC20, if necessary
#
mp_created = None
if goerli_xprvkey and not contract:
destination = tuple(
a.address
for a in slip39.accounts( goerli_xprvkey, crypto="ETH", paths=f"m/0/1-3" )
)
payees = {
address: share + 1
for share,address in enumerate(destination)
}
tokens = list(
ethereum.tokeninfo(
t,
chain = ethereum.Chain.Goerli,
w3_url = provider_url,
use_provider = Web3.WebsocketProvider
)
for t in (
"0xe802376580c10fE23F027e1E19Ed9D54d4C9311e", # USDT
"0xde637d4C445cA2aae8F782FFAc8d2971b93A4998", # USDC
"0xaFF4481D10270F50f203E0763e2597776068CBc5", # WEENUS
"0x1f9061B953bBa0E36BF50F21876132DcF276fC6e", # ZEENUS
)
)
# print( tabulate( [
# [
# [ "Token", "Decimals", "Contract"]
# ] + [
# [ t.name, t.decimals, t.contract ]
# for t in tokens
# ]
# ], tablefmt='orgtbl' ))
erc20s = list(
t.contract
for t in tokens
)
try:
mp_created = MultiPayoutERC20(
provider,
agent = goerli_src.address,
agent_prvkey= goerli_src.prvkey,
payees = payees,
erc20s = erc20s,
)
except Exception as exc:
print( f"Failed to deploy a new MultiPayoutERC20: {exc}" )
else:
print( f"Success deploying a new MultiPayoutERC20: {mp_created}" )
contract = mp_created._address
print("MultiPayoutERC20 Newly Deployed Contract Details:")
f"MultiPayoutERC20 deployed: {mp_created}"
Finally, if we found or deployed a MultiPayoutERC20 contract, lets generate a “Forwarder” for some unique user-identifying data (we’ll use a pre-existing contract, if necessary).
if not contract:
# We haven't been able to create a contract; just show a pre-defined one.
contract = "0xbE69793974Fc55cD8B94Dac6b410827740Cc6d68"
#
# To examine an existing MultiPayoutERC20 contract, use:
# https://goerli.etherscan.io/address/<contract>
mp = MultiPayoutERC20(
provider,
address = Web3.to_checksum_address( contract ),
)
import hashlib
import uuid
username = "perry@kundert.ca"
machine_id = uuid.uuid4()
salt = hashlib.sha256(
f"{username}-{machine_id}".encode()
)
salt_int = int.from_bytes( salt.digest(), byteorder='big' )
forwarder = mp.forwarder_address( salt_int )
(
f"MultiPayoutERC20 Contract & Forwarder Details:\n\n{mp}\n\n"
+ tabulate( [
[ "MultiPayoutERC20 Contract:", f"{contract}" ],
[ "Unique Client Salt:", f"{salt.hexdigest()}" ],
[ "Their Forwarder Contract:", f"{forwarder}" ],
], tablefmt='orgtbl' ))
MultiPayoutERC20 Payees:
Payee | Share | Frac. % | Reserve | Reserve/2^16 | Frac.Rec. % | Error % |
---|---|---|---|---|---|---|
0xE5714055437154E812d451aF86239087E0829fA8 | 11323/65536 | 17.2775 | 54213 | 54213 | 17.2775 | 0 |
0xEeC2b464c2f50706E3364f5893c659edC9E4153A | 1671224151/4294967296 | 38.9112 | 34709 | 34709 | 38.9112 | 0 |
Token | Symbol | Digits | ||||
0xe802376580c10fE23F027e1E19Ed9D54d4C9311e | USDT | 6 | ||||
0xde637d4C445cA2aae8F782FFAc8d2971b93A4998 | USDC | 6 | ||||
0xaFF4481D10270F50f203E0763e2597776068CBc5 | WEENUS | 18 | ||||
0x1f9061B953bBa0E36BF50F21876132DcF276fC6e | ZEENUS | 0 |
Payee | Share | Frac. % | Reserve | Reserve/2^16 | Frac.Rec. % | Error % |
---|---|---|---|---|---|---|
0xE5714055437154E812d451aF86239087E0829fA8 | 11323/65536 | 17.2775 | 54213 | 54213 | 17.2775 | 0 |
0xEeC2b464c2f50706E3364f5893c659edC9E4153A | 1671224151/4294967296 | 38.9112 | 34709 | 34709 | 38.9112 | 0 |
Token | Symbol | Digits | ||||
0xe802376580c10fE23F027e1E19Ed9D54d4C9311e | USDT | 6 | ||||
0xde637d4C445cA2aae8F782FFAc8d2971b93A4998 | USDC | 6 | ||||
0xaFF4481D10270F50f203E0763e2597776068CBc5 | WEENUS | 18 | ||||
0x1f9061B953bBa0E36BF50F21876132DcF276fC6e | ZEENUS | 0 |
MultiPayoutERC20 Contract: | 0x1714d39d6803ca0b5ad35eb558ea5e32a0a2b8f1 |
Unique Client Salt: | ea1cf51156cb99dfba2ca02655404c9317d76ba26e062d287cd70a4d4e99cc4a |
Their Forwarder Contract: | 0x4bCEd5Aa541299e2086440F6af45f22B32fA7d97 |
One (or more) Smart Contracts move the funds from this account, into the payees’ accounts/Contracts.
If multiple independent parties must be paid out of the proceeds from each client, receiving payments to a plain Account (for which you hold the private key) may not be acceptable to all parties involved. A product owner providing a licensee the capability to sub-licensing their product may, for example, charge a much better fee, if the licensee can prove that payments will automatically flow back to the license owner, every time the licensee sells their product which contains the sub-license.
There are ways to ensure that each client payment must be distributed to each payee, as agreed, using cryptocurrencies which implement Smart Contracts.
A Smart Contract can be created which guarantees that Cryptocurrency funds from a source address are distributed in a fixed proportion to several destination addresses.
A Contract is created that is unique to each set of payee accounts and (fractional) distribution of assets, containing a function something like this (in Solidity):
function payout_internal() private nonReentrant { move_but_x10000_to( 9310, payable( address( 0x7F7458EF9A583B95DFD90C048d4B2d2F09f6dA5b ))); // 6.900% move_but_x10000_to( 5703, payable( address( 0x94Da50738E09e2f9EA0d4c15cf8DaDfb4CfC672B ))); // 40.000% move_but_x10000_to( 0, payable( address( 0xa29618aBa937D2B3eeAF8aBc0bc6877ACE0a1955 ))); // 53.100% }
(you can see the remaining Smart Contract code in the slip-39 source.)
This function can be executed in various ways.
The most expensive and least flexible method constructs, executes and selfdestructs this
payout_internal
Smart Contract function.
constructor() payable { payout_internal(); selfdestruc }
Guaranteeing that each client’s payments always flow through to the designated tree of payees is
the responsibility of the MultiPayoutERC20Forwarder
(client “Forwarder” account) and
MultiPayoutERC20
(product’s “Fee Distribution”) Smart Contracts.
Confirmation of Licensing is the responsibility of the client software. At software runtime, some checks are completed. At minimum, two pieces of data are loaded from storage:
- The Machine ID, and
- A Public Key and a Signature of the Machine ID (previously generated), or
- A Private Key (from which the Machine ID Signature can be generated)
Then, assuming:
- Accounts can be created uniquely for some pseudo-random client-specific identifying key
- A public key for example
- Some data can be stored and later retrieved using that client key
- The signature of some License text or the client-unique Machine ID (or a significant portion of it)
- Payments to the account can be queried from on the blockchain
The client software can check the blockchain to confirm payment to the account, and the saved data (eg. Signature) can be checked to confirm that this client is indeed the licensee. For example, the client’s Private Key generates the Public Key, and the retrieved signature matches the Sgnature of the Machine ID.
If all of these tests pass, then the client software has confirmed that it is licensed.
If not, a licensing offer (invoice) can be generated, to allow the client to obtain a license.
An attacker can attempt to re-use some pre-existing license payment; it can inspect the blockchain history to obtain the prior allocation of a paid “Forwarder” account, and recover the client key (the client’s public key), and the associated data stored for that key (the signature). However, when the software attempts to confirm that the public key signs the machine ID, it will fail, because the attacker doesn’t have the original payee’s machine ID – which was not included in the original blockchain transaction.
Only if the client software is also under the control of the attacker can this attack succeed; but, in that case, the attacker can simply remove the entire license check from the software.
One tempting (but ultimately fragile) solution is to use Ethereum “transfer” transactions that you don’t actually have the private key to sign.
One artifact of how Ethereum (and similar) Cryptocurrency systems create and validate transactions, is that the “source” address may be deduced from the transaction and its accompanying signature. Normally, one already “has” a source address (and its private key) containing funds, and then creates a transaction moving some of those funds (or executing a Smart Contract call) to some destination, and finally signs it using their private key. However, one can create the exact same transaction performing the same actions – and then provide a random signature, and deduce what Ethereum Account it must have originated from. This will be a pseudo-random (unpredictable) source Address, assuming that some bit(s) in the transaction and/or signature differ.
This “signed” transaction from this random Ethereum account may do anything – so long as (when it’s finally executed) there is sufficient Ethereum available to pay the “Gas” fees, and to supply whatever value (in ETH, ERC-20 tokens, etc.) is required by the transaction.
A number of failure modes exist that can result in cryptocurrency lost in this client address:
- Only ETH supported at reasonable cost
- If an ERC-20 token transfer is invoked, the exact token must be known in advance.
- Any other token or Ethereum deposited would be lost
- If the exact correct amount of Ethereum to pay for Gas is not deposited, the transaction will fail and will not be re-executable, resulting in loss of all funds at the address.
This idea is not possible using Bitcoin, due to its lack of general-purpose smart contracts, and the fact that one cannot “sign” transactions in advance to generate the “source” Account address: the transaction must contain specific information about the source UTXOs (Unspent TransaXion Outputs) being spent, which is of course unavailable in advance.
Put some TGOR (Test Goerli Ethereum) tokens into the “zoo zoo … wrong” Ethereum account on the Goerli testnet. This is (of course) a well-known account, and the funds will disappear pretty quickly, but should give you time to run the tests successfully.
You can mint TGOR for free, at:
https://faucet.quicknode.com/ethereum/goerli https://goerlifaucet.com/
Transfer about 0.1 TGOR to the “zoo zoo … wrong” test account:
0x667AcC3Fc27A8EbcDA66E7E01ceCA179d407ce00
Then, run:
make test # or: make unit-test_multipayout_ERC20_web3_tester
If you git clone git@github.com:pjkundert/python-slip39.git
and have the source code, you can use
the supplied GNU make
targets to create a venv Virtual Environment and build then install.
The python-slip39
project is tested under both homebrew:
$ brew install python-tk@3.12 $ PY3=python3.12 make venv ... (python-slip39-13.0.0-usr-darwin-cpython-312) bash-3.2$
and using the official python.org/downloads installer.
It is also supported under Nix (optionally prefixed with eg. TARGET\=py310
):
$ make nix-venv ... *** Activating /Users/perry/src/python-slip39-13.0.0-nix-darwin-cpython-312 VirtualEnv for Interactive /bin/bash (python-slip39-13.0.0-nix-darwin-cpython-312) Perrys-MBP:python-slip39 perry$
The Nix installation is probably the recommended approach for macOS and Linux.
Either of these methods will get you a python3
executable running version 3.12+, usable for
running the slip39
module, and the slip39.gui
GUI.
To manually create your own venv and install from pypi using the Python 3.9 to 3.12 (+ TK if using the GUI) you have at hand:
$ python3.12 -m venv python-slip39-venv $ . ./python-slip39-venv/bin/activate (python-slip39-venv) [you@yourhost src]$ python3 -m pip install slip39[gui] ... (python-slip39-venv) [you@yourhost src]$ python3 -m slip39.gui
To build the wheel and install slip39
manually:
$ git clone git@github.com:pjkundert/python-slip39.git $ make -C python-slip39 install
To install from Pypi, including the optional requirements to run the PySimpleGUI/tkinter GUI, support serial I/O, and to support creating encrypted BIP-38 and Ethereum JSON Paper Wallets:
$ python3 -m pip install slip39[gui,wallet,serial]
To install from Pypi, including the optional requirements to run the PySimpleGUI/tkinter GUI:
$ python3 -m pip install slip39[gui]
Then, there are several ways to run the GUI:
$ python3 -m slip39.gui # Execute the python slip39.gui module main method $ slip39-gui # Run the main function provided by the slip39.gui module
You can build the native macOS and win32 SLIP-39.app
App.
This requires the official python.org/downloads installer; the homebrew python-tk@3.9 will not
work for building the native app using either PyInstaller
. (The py2app
approach doesn’t work
in either version of Python).
$ git clone git@github.com:pjkundert/python-slip39.git $ make -C python-slip39 app
Install Python from https://python.org/downloads, and the Microsoft C++ Build Tools via the
Visual Studio Installer (required for installing some slip39
package dependencies).
To run the GUI, just install slip39
package from Pypi using pip, including the gui
and
wallet
options. Building the Windows SLIP-39
executable GUI application requires the dev
option.
PS C:\Users\IEUser> pip install slip39[gui,wallet,dev]
To work with the python-slip39 Git repo on Github, you’ll also need to install Git from git-scm.com. Once installed, run “Git bash”, and
$ ssh-keygen.exe -t ed25519
to create an id_ed25519.pub
SSH identity, and import it into your Git Settings SSH keys. Then,
$ mkdir src $ cd src $ git clone git@github.com:pjkundert/python-slip39.git
The MMC (Microsoft Management Console) is used to store your code-signing certificates. See stackoverflow.com for how to enable its Certificate management.
Each installation of the SLIP-39 App requires an Ed25519 “Agent” identity, and cryptographically signed license(s) to activate various python-slip39 features. No license is required to use basic features; advanced features require a license.
The Ed25519 signing “Agent” identity is loaded at start-up, and (if necessary) is created
automatically on first execution. This is similar to the ssh-keygen -t ed25519
procedure.
Each separate installation must have a ~/.crypto-licensing/python-slip39.crypto-keypair. This contains the licensing “Agent” credentials: a passphrase-encrypted Ed25519 private key, and a self-signed public key. This shows that we actually had access to the private key and used it to create a signature for the claimed public key and the supplied encrypted private key – proving that the public key is valid, and associated with the encrypted private key.
When an advanced feature is used, all available python-slip39.crypto-license
files are loaded.
They are examined, and if a license is found that is:
- Assigned to this Agent and Machine-ID
- Contains the required license authorizations
then the functionality is allowed to proceed.
If no license is found, instructions on how to obtain a license for this Agent on this Machine-ID will be displayed.
If you’ve already obtained a “master” license on your primary machine’s SLIP-39 installation, you can use it to issue a sub-license to this installation (eg. for your air-gapped cryptocurrency management machine).
Otherwise, a URL is displayed at which the required “master” license can be issued.
Typically, you’ll be using python-slip39’s advanced features on an air-gapped computer. You do not want to visit websites from this computer. So, you obtain a sub-license from your primary computer’s python-slip39 installation, and place it on your secure air-gapped computer (eg. using a USB stick).
Take note of the secondary machine’s Agent ID (pubkey) and Machine ID. On your primary computer (with the “master” license), run:
python3 -m slip39.sublicense <agent-pubkey> <machine-id>
Take the output, and place it in the file ~/.crypto-licensing/python-slip39.crypto-license
on
your air-gapped computer.
On your primary computer, open the provided URL in a browser. The URL contains the details of the advanced feature desired.
This URL’s web page will request an Ed25519 “Agent” public key to issue your “master” license to. This should be your primary user account’s Ed25519 “Agent” public key – this master “Agent” will be issuing sub-licenses to any of your other SLIP-39 installations. You will be redirected to a URL that is unique to the advanced feature plus your Agent ID.
An invoice will be generated with unique Bitcoin, Ethereum and perhaps other cryptocurrency addresses. Pay the required amount of cryptocurrency to one of the provided wallet addresses. Within a few seconds, the cryptocurrency transfer will be confirmed.
Once the payment for the advanced feature is confirmed, the URL including your agent ID will always allow you to re-download the license. It is only usable by your Agent ID to issue sub-licenses to your python-slip39 installations on your machines.
Internally, python-slip39 project uses Trezor’s python-shamir-mnemonic to encode the seed data to SLIP-39 phrases, python-hdwallet to convert seeds to ETH, BTC, LTC and DOGE wallets, and the Ethereum project’s eth-account to produce encrypted JSON wallets for specified Ethereum accounts.
To use it directly, obtain , and install it, or run python3 -m pip install shamir-mnemonic
.
$ shamir create custom --group-threshold 2 --group 1 1 --group 1 1 --group 2 5 --group 3 6 Using master secret: 87e39270d1d1976e9ade9cc15a084c62 Group 1 of 4 - 1 of 1 shares required: merit aluminum acrobat romp capacity leader gray dining thank rhyme escape genre havoc furl breathe class pitch location render beard Group 2 of 4 - 1 of 1 shares required: merit aluminum beard romp briefing email member flavor disaster exercise cinema subject perfect facility genius bike include says ugly package Group 3 of 4 - 2 of 5 shares required: merit aluminum ceramic roster already cinema knit cultural agency intimate result ivory makeup lobe jerky theory garlic ending symbolic endorse merit aluminum ceramic scared beam findings expand broken smear cleanup enlarge coding says destroy agency emperor hairy device rhythm reunion merit aluminum ceramic shadow cover smith idle vintage mixture source dish squeeze stay wireless likely privacy impulse toxic mountain medal merit aluminum ceramic sister duke relate elite ruler focus leader skin machine mild envelope wrote amazing justice morning vocal injury merit aluminum ceramic smug buyer taxi amazing marathon treat clinic rainbow destroy unusual keyboard thumb story literary weapon away move Group 4 of 4 - 3 of 6 shares required: merit aluminum decision round bishop wrote belong anatomy spew hour index fishing lecture disease cage thank fantasy extra often nail merit aluminum decision scatter carpet spine ruin location forward priest cage security careful emerald screw adult jerky flame blanket plot merit aluminum decision shaft arcade infant argue elevator imply obesity oral venture afraid slice raisin born nervous universe usual racism merit aluminum decision skin already fused tactics skunk work floral very gesture organize puny hunting voice python trial lawsuit machine merit aluminum decision snake cage premium aide wealthy viral chemical pharmacy smoking inform work cubic ancestor clay genius forward exotic merit aluminum decision spider boundary lunar staff inside junior tendency sharp editor trouble legal visual tricycle auction grin spit index