182 lines
4.2 KiB
V
182 lines
4.2 KiB
V
// algorthim is adapted from https://github.com/mr-tron/base58 under the MIT license
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module base58
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import math
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// encode_int encodes any integer type to base58 string with Bitcoin alphabet
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pub fn encode_int(input int) ?string {
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return encode_int_walpha(input, alphabets['btc'])
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}
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// encode_int_walpha any integer type to base58 string with custom alphabet
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pub fn encode_int_walpha(input int, alphabet Alphabet) ?string {
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if input <= 0 {
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return error(@MOD + '.' + @FN + ': input must be greater than zero')
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}
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mut buffer := []byte{}
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mut i := input
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for i > 0 {
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remainder := i % 58
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buffer << alphabet.encode[i8(remainder)]
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// This needs to be casted so byte inputs can
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// be used. i8 because remainder will never be
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// over 58.
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i = i / 58
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}
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return buffer.reverse().bytestr()
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}
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// encode encodes byte array to base58 with Bitcoin alphabet
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pub fn encode(input string) string {
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return encode_walpha(input, alphabets['btc'])
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}
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// encode_walpha encodes byte array to base58 with custom aplhabet
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pub fn encode_walpha(input string, alphabet Alphabet) string {
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if input.len == 0 {
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return ''
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}
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bin := input.bytes()
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mut sz := bin.len
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mut zcount := 0
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for zcount < sz && bin[zcount] == 0 {
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zcount++
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}
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// It is crucial to make this as short as possible, especially for
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// the usual case of Bitcoin addresses
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sz = zcount + (sz - zcount) * 555 / 406 + 1
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// integer simplification of
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// ceil(log(256)/log(58))
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mut out := []byte{len: sz}
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mut i := 0
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mut high := 0
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mut carry := u32(0)
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high = sz - 1
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for b in bin {
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i = sz - 1
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for carry = u32(b); i > high || carry != 0; i-- {
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carry = carry + 256 * u32(out[i])
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out[i] = u8(carry % 58)
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carry /= 58
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}
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high = 1
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}
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// determine additional "zero-gap" in the buffer, aside from zcount
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for i = zcount; i < sz && out[i] == 0; i++ {}
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// now encode the values with actual alphabet in-place
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val := out[i - zcount..]
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sz = val.len
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for i = 0; i < sz; i++ {
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out[i] = alphabet.encode[val[i]]
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}
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return out[..sz].bytestr()
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}
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// decode_int decodes base58 string to an integer with Bitcoin alphabet
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pub fn decode_int(input string) ?int {
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return decode_int_walpha(input, alphabets['btc'])
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}
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// decode_int_walpha decodes base58 string to an integer with custom alphabet
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pub fn decode_int_walpha(input string, alphabet Alphabet) ?int {
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mut total := 0 // to hold the results
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b58 := input.reverse()
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for i, ch in b58 {
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ch_i := alphabet.encode.bytestr().index_u8(ch)
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if ch_i == -1 {
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return error(@MOD + '.' + @FN +
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': input string contains values not found in the provided alphabet')
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}
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val := ch_i * math.pow(58, i)
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total += int(val)
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}
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return total
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}
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// decode decodes base58 string using the Bitcoin alphabet
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pub fn decode(str string) ?string {
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return decode_walpha(str, alphabets['btc'])
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}
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// decode_walpha decodes base58 string using custom alphabet
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pub fn decode_walpha(str string, alphabet Alphabet) ?string {
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if str.len == 0 {
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return ''
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}
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zero := alphabet.encode[0]
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b58sz := str.len
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mut zcount := 0
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for i := 0; i < b58sz && str[i] == zero; i++ {
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zcount++
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}
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mut t := u64(0)
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mut c := u64(0)
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// the 32-bit algorithm stretches the result up to 2x
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mut binu := []byte{len: 2 * ((b58sz * 406 / 555) + 1)}
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mut outi := []u32{len: (b58sz + 3) / 4}
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for _, r in str {
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if r > 127 {
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panic(@MOD + '.' + @FN +
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': high-bit set on invalid digit; outside of ascii range ($r). This should never happen.')
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}
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if alphabet.decode[r] == -1 {
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return error(@MOD + '.' + @FN + ': invalid base58 digit ($r)')
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}
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c = u64(alphabet.decode[r])
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for j := outi.len - 1; j >= 0; j-- {
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t = u64(outi[j]) * 58 + c
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c = t >> 32
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outi[j] = u32(t & 0xffffffff)
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}
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}
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// initial mask depend on b58sz, on further loops it always starts at 24 bits
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mut mask := (u32(b58sz % 4) * 8)
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if mask == 0 {
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mask = 32
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}
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mask -= 8
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mut out_len := 0
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for j := 0; j < outi.len; j++ {
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for mask < 32 {
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binu[out_len] = u8(outi[j] >> mask)
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mask -= 8
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out_len++
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}
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mask = 24
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}
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// find the most significant byte post-decode, if any
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for msb := zcount; msb < binu.len; msb++ { // loop relies on u32 overflow
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if binu[msb] > 0 {
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return binu[msb - zcount..out_len].bytestr()
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}
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}
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// it's all zeroes
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return binu[..out_len].bytestr()
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}
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