Bitcoin CLI tools: Haskell port of Sx using Haskoin
List of supported commands:
# ADDRESSES
hx addr
hx validaddr [<ADDRESS>]
hx decode-addr
hx encode-addr
hx encode-addr --script [0]
# KEYS
hx pubkey [--compressed|--uncompressed]
hx wif-to-secret
hx secret-to-wif
hx brainwallet <PASSPHRASE>
hx compress [0]
hx uncompress [0]
# SCRIPTS
hx rawscript <SCRIPT_OP>*
hx showscript
# TRANSACTIONS
hx mktx <TXFILE> --input <TXHASH>:<INDEX> ... --output <ADDR>:<AMOUNT>
hx showtx [-j|--json] <TXFILE> [1]
hx sign-input <TXFILE> <INDEX> <SCRIPT_CODE>
hx set-input <TXFILE> <INDEX> <SIGNATURE_AND_PUBKEY_SCRIPT>
hx validsig <TXFILE> <INDEX> <SCRIPT_CODE> <SIGNATURE>
# HD WALLET (BIP32)
hx hd-priv [0]
hx hd-priv <INDEX>
hx hd-priv --hard <INDEX>
hx hd-pub [0]
hx hd-pub <INDEX>
hx hd-path <PATH> [0]
hx hd-to-wif
hx hd-to-address
hx hd-to-pubkey [0]
# ELECTRUM DETERMINISTIC WALLET [2]
hx electrum-mpk
hx electrum-priv <INDEX> [<CHANGE-0|1>] [<RANGE-STOP>]
hx electrum-pub <INDEX> [<CHANGE-0|1>] [<RANGE-STOP>]
hx electrum-addr <INDEX> [<CHANGE-0|1>] [<RANGE-STOP>]
hx electrum-seq <INDEX> [<CHANGE-0|1>] [<RANGE-STOP>]
hx electrum-stretch-seed
# ELLIPTIC CURVE MATHS
hx ec-multiply <HEX-FIELDN> <HEX-POINT>
hx ec-tweak-add <HEX-FIELDN> <HEX-POINT>
hx ec-add-modp <HEX-FIELDP> <HEX-FIELDP>
hx ec-add-modn <HEX-FIELDN> <HEX-FIELDN> [0]
hx ec-add <HEX-POINT> <HEX-POINT> [0]
hx ec-double <HEX-POINT> [0]
hx ec-g [0]
hx ec-p [0]
hx ec-n [0]
hx ec-a [0]
hx ec-b [0]
hx ec-inf [0]
hx ec-int-modp <DECIMAL-INTEGER> [0]
hx ec-int-modn <DECIMAL-INTEGER> [0]
hx ec-x <HEX-POINT> [0]
hx ec-y <HEX-POINT> [0]
# MNEMONICS AND SEED FORMATS
hx mnemonic
hx bip39-mnemonic [0]
hx bip39-hex [0]
hx bip39-seed <PASSPHRASE> [0]
hx rfc1751-key [0]
hx rfc1751-mnemonic [0]
# BASIC ENCODINGS AND CONVERSIONS
hx btc [<SATOSHIS>] [3]
hx satoshi [<BTCS>] [3]
hx integer [0]
hx hex-encode [0]
hx hex-decode [0]
# BASE58 ENCODING
hx base58-encode
hx base58-decode
hx base58check-encode [<VERSION-BYTE>]
hx base58check-decode
# CHECKSUM32 (first 32bits of double sha256) [0]
hx chksum32 <HEX>*
hx chksum32-encode <HEX>*
hx chksum32-decode <HEX>*
# HASHING
hx ripemd-hash [4]
hx sha256 [<HEX-INPUT>]
hx ripemd160 [<HEX-INPUT>] [0]
hx sha1 [<HEX-INPUT>] [0]
hx hash160 [<HEX-INPUT>] [0]
hx hash256 [0]
# HASH BASED MACs
hx hmac-sha224 <KEY> [<HEX-NPUT>] [0]
hx hmac-sha256 <KEY> [<HEX-NPUT>] [0]
hx hmac-sha384 <KEY> [<HEX-NPUT>] [0]
hx hmac-sha512 <KEY> [<HEX-NPUT>] [0]
[0]: Not available in sx
[1]: `hx showtx` is always using JSON output,
`-j` and `--json` are ignored.
[2]: The compatibility has been checked with electrum and with `sx`.
However if your `sx mpk` returns a hex representation of `64` digits,
then you *miss* half of it.
Moreover subsequent commands (genpub/genaddr) might behave
non-deterministically.
Finally they have different names:
mpk -> electrum-mpk
genpub -> electrum-pub
genpriv -> electrum-priv
genaddr -> electrum-addr
The commands electrum-seq and electrum-stretch-seed expose
the inner workings of the key derivation process.
[3]: Rounding is done upward in `hx` and downard in `sx`.
So they agree `btc 1.4` and `btc 1.9` but on `btc 1.5`,
`hx` returns `0.00000002` and `sx` returns `0.00000001`.
[4]: The `ripemd-hash` command is taking raw-bytes as input,
while the other hashing commands are taking hexadecimal encoded inputs.
This is for this reason that `hash160` has been added
(`hx ripemd-hash` is equivalent to `hx encode-hex | hx hash160`
and `hx hash160` is equivalent to `hx decode-hex | hx ripemd-hash`).
PATH ::= <PATH-HEAD> <PATH-CONT>
PATH-HEAD ::= 'A' [address (compressed)]
| 'M' [extended public key]
| 'm' [extended private key]
| 'P' [public key (compressed)]
| 'p' [private key (compressed)]
| 'U' [uncompressed public key]
| 'u' [uncompressed private key]
PATH-CONT ::= [empty]
| '/' <INDEX> <PATH-CONT> [child key]
| '/' <INDEX> '\'' <PATH-CONT> [hardened child key]