module bcrypt import encoding.base64 import crypto.rand import crypto.blowfish pub const ( min_cost = 4 max_cost = 31 default_cost = 10 salt_length = 16 max_crypted_hash_size = 23 encoded_salt_size = 22 encoded_hash_size = 31 min_hash_size = 59 major_version = '2' minor_version = 'a' ) pub struct Hashed { mut: hash []byte salt []byte cost int major string minor string } const magic_cipher_data = [byte(0x4f), 0x72, 0x70, 0x68, 0x65, 0x61, 0x6e, 0x42, 0x65, 0x68, 0x6f, 0x6c, 0x64, 0x65, 0x72, 0x53, 0x63, 0x72, 0x79, 0x44, 0x6f, 0x75, 0x62, 0x74] // generate_from_password return a bcrypt string from Hashed struct. pub fn generate_from_password(password []byte, cost int) ?string { mut p := new_from_password(password, cost) or { return error('Error: $err') } x := p.hash_byte() return x.bytestr() } // compare_hash_and_password compares a bcrypt hashed password with its possible hashed version. pub fn compare_hash_and_password(password []byte, hashed_password []byte) ? { mut p := new_from_hash(hashed_password) or { return error('Error: $err') } p.salt << `=` p.salt << `=` other_hash := bcrypt(password, p.cost, p.salt) or { return error('err') } mut other_p := Hashed{ hash: other_hash salt: p.salt cost: p.cost major: p.major minor: p.minor } if p.hash_byte() != other_p.hash_byte() { return error('mismatched hash and password') } } // generate_salt generate a string to be treated as a salt. pub fn generate_salt() string { randbytes := rand.read(bcrypt.salt_length) or { panic(err) } return randbytes.bytestr() } // new_from_password converting from password to a Hashed struct with bcrypt. fn new_from_password(password []byte, cost int) ?&Hashed { mut cost_ := cost if cost < bcrypt.min_cost { cost_ = bcrypt.default_cost } mut p := &Hashed{} p.major = bcrypt.major_version p.minor = bcrypt.minor_version if cost_ < bcrypt.min_cost || cost_ > bcrypt.max_cost { return error('invalid cost') } p.cost = cost_ salt := generate_salt().bytes() p.salt = base64.encode(salt).bytes() hash := bcrypt(password, p.cost, p.salt) or { return err } p.hash = hash return p } // new_from_hash converting from hashed data to a Hashed struct. fn new_from_hash(hashed_secret []byte) ?&Hashed { mut tmp := hashed_secret.clone() if tmp.len < bcrypt.min_hash_size { return error('hash to short') } mut p := &Hashed{} mut n := p.decode_version(tmp) or { return err } tmp = tmp[n..].clone() n = p.decode_cost(tmp) or { return err } tmp = tmp[n..].clone() p.salt = tmp[..bcrypt.encoded_salt_size].clone() p.hash = tmp[bcrypt.encoded_salt_size..].clone() return p } // bcrypt hashing passwords. fn bcrypt(password []byte, cost int, salt []byte) ?[]byte { mut cipher_data := []byte{len: 72 - bcrypt.magic_cipher_data.len, init: 0} cipher_data << bcrypt.magic_cipher_data mut bf := expensive_blowfish_setup(password, u32(cost), salt) or { return err } for i := 0; i < 24; i += 8 { for j := 0; j < 64; j++ { bf.encrypt(mut cipher_data[i..i + 8], cipher_data[i..i + 8]) } } hash := base64.encode(cipher_data[..bcrypt.max_crypted_hash_size]) return hash.bytes() } // expensive_blowfish_setup generate a Blowfish cipher, given key, cost and salt. fn expensive_blowfish_setup(key []byte, cost u32, salt []byte) ?&blowfish.Blowfish { csalt := base64.decode(salt.bytestr()) mut bf := blowfish.new_salted_cipher(key, csalt) or { return err } mut i := u64(0) mut rounds := u64(0) rounds = 1 << cost for i = 0; i < rounds; i++ { blowfish.expand_key(key, mut bf) blowfish.expand_key(csalt, mut bf) } return &bf } // hash_byte converts the hash value to a byte array. fn (mut h Hashed) hash_byte() []byte { mut arr := []byte{len: 65, init: 0} arr[0] = `$` arr[1] = h.major[0] mut n := 2 if h.minor != '0' { arr[2] = h.minor[0] n = 3 } arr[n] = `$` n++ copy(arr[n..], '${int(h.cost):02}'.bytes()) n += 2 arr[n] = `$` n++ copy(arr[n..], h.salt) n += bcrypt.encoded_salt_size copy(arr[n..], h.hash) n += bcrypt.encoded_hash_size res := arr[..n].clone() return res } // decode_version decode bcrypt version. fn (mut h Hashed) decode_version(sbytes []byte) ?int { if sbytes[0] != `$` { return error("bcrypt hashes must start with '$'") } if sbytes[1] != bcrypt.major_version[0] { return error('bcrypt algorithm version $bcrypt.major_version') } h.major = sbytes[1].ascii_str() mut n := 3 if sbytes[2] != `$` { h.minor = sbytes[2].ascii_str() n++ } return n } // decode_cost extracts the value of cost and returns the next index in the array. fn (mut h Hashed) decode_cost(sbytes []byte) ?int { cost := sbytes[0..2].bytestr().int() check_cost(cost) or { return err } h.cost = cost return 3 } // check_cost check for reasonable quantities. fn check_cost(cost int) ? { if cost < bcrypt.min_cost || cost > bcrypt.max_cost { return error('invalid cost') } }