// Copyright (c) 2019-2023 Alexander Medvednikov. All rights reserved. // Use of this source code is governed by an MIT license // that can be found in the LICENSE file. // Package md5 implements the MD5 hash algorithm as defined in RFC 1321. // MD5 is cryptographically broken and should not be used for secure // applications. // Based off: https://github.com/golang/go/blob/master/src/crypto/md5 // Last commit: https://github.com/golang/go/commit/ed7f323c8f4f6bc61a75146bf34f5b8f73063a17 module md5 import encoding.binary pub const ( // The size of an MD5 checksum in bytes. size = 16 // The blocksize of MD5 in bytes. block_size = 64 ) const ( init0 = 0x67452301 init1 = u32(0xEFCDAB89) init2 = u32(0x98BADCFE) init3 = 0x10325476 ) // Digest represents the partial evaluation of a checksum. struct Digest { mut: s []u32 x []u8 nx int len u64 } // free the resources taken by the Digest `d` [unsafe] pub fn (mut d Digest) free() { $if prealloc { return } unsafe { d.x.free() } } fn (mut d Digest) init() { d.s = []u32{len: (4)} d.x = []u8{len: md5.block_size} d.reset() } // reset the state of the Digest `d` pub fn (mut d Digest) reset() { d.s[0] = u32(md5.init0) d.s[1] = u32(md5.init1) d.s[2] = u32(md5.init2) d.s[3] = u32(md5.init3) d.nx = 0 d.len = 0 } // new returns a new Digest (implementing hash.Hash) computing the MD5 checksum. pub fn new() &Digest { mut d := &Digest{} d.init() return d } // write writes the contents of `p_` to the internal hash representation. pub fn (mut d Digest) write(p_ []u8) ?int { unsafe { mut p := p_ nn := p.len d.len += u64(nn) if d.nx > 0 { n := copy(mut d.x[d.nx..], p) d.nx += n if d.nx == md5.block_size { block(mut d, d.x) d.nx = 0 } if n >= p.len { p = [] } else { p = p[n..] } } if p.len >= md5.block_size { n := p.len & ~(md5.block_size - 1) block(mut d, p[..n]) if n >= p.len { p = [] } else { p = p[n..] } } if p.len > 0 { d.nx = copy(mut d.x, p) } return nn } } // sum returns the md5 sum of the bytes in `b_in`. pub fn (d &Digest) sum(b_in []u8) []u8 { // Make a copy of d so that caller can keep writing and summing. mut d0 := *d hash := d0.checksum() mut b_out := b_in.clone() for b in hash { b_out << b } return b_out } // checksum returns the byte checksum of the `Digest`. pub fn (mut d Digest) checksum() []u8 { // Append 0x80 to the end of the message and then append zeros // until the length is a multiple of 56 bytes. Finally append // 8 bytes representing the message length in bits. // // 1 byte end marker :: 0-63 padding bytes :: 8 byte length // tmp := [1 + 63 + 8]u8{0x80} mut tmp := []u8{len: (1 + 63 + 8)} tmp[0] = 0x80 pad := ((55 - d.len) % 64) // calculate number of padding bytes binary.little_endian_put_u64(mut tmp[1 + pad..], d.len << 3) // append length in bits d.write(tmp[..1 + pad + 8]) or { panic(err) } // The previous write ensures that a whole number of // blocks (i.e. a multiple of 64 bytes) have been hashed. if d.nx != 0 { panic('d.nx != 0') } mut digest := []u8{len: md5.size} binary.little_endian_put_u32(mut digest, d.s[0]) binary.little_endian_put_u32(mut digest[4..], d.s[1]) binary.little_endian_put_u32(mut digest[8..], d.s[2]) binary.little_endian_put_u32(mut digest[12..], d.s[3]) return digest } // sum returns the MD5 checksum of the data. pub fn sum(data []u8) []u8 { mut d := new() d.write(data) or { panic(err) } return d.checksum() } fn block(mut dig Digest, p []u8) { // For now just use block_generic until we have specific // architecture optimized versions block_generic(mut dig, p) } // size returns the size of the checksum in bytes. pub fn (d &Digest) size() int { return md5.size } // block_size returns the block size of the checksum in bytes. pub fn (d &Digest) block_size() int { return md5.block_size } // hexhash returns a hexadecimal MD5 hash sum `string` of `s`. // Example: assert md5.hexhash('V') == '5206560a306a2e085a437fd258eb57ce' pub fn hexhash(s string) string { return sum(s.bytes()).hex() }