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zig/lib/std/crypto/pbkdf2.zig
Andrew Kelley d29871977f remove redundant license headers from zig standard library 
We already have a LICENSE file that covers the Zig Standard Library. We
no longer need to remind everyone that the license is MIT in every single
file.

Previously this was introduced to clarify the situation for a fork of
Zig that made Zig's LICENSE file harder to find, and replaced it with
their own license that required annual payments to their company.
However that fork now appears to be dead. So there is no need to
reinforce the copyright notice in every single file.
2021-08-24 12:25:09 -07:00

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const std = @import("std");
const mem = std.mem;
const maxInt = std.math.maxInt;
const OutputTooLongError = std.crypto.errors.OutputTooLongError;
const WeakParametersError = std.crypto.errors.WeakParametersError;
// RFC 2898 Section 5.2
//
// FromSpec:
//
// PBKDF2 applies a pseudorandom function (see Appendix B.1 for an
// example) to derive keys. The length of the derived key is essentially
// unbounded. (However, the maximum effective search space for the
// derived key may be limited by the structure of the underlying
// pseudorandom function. See Appendix B.1 for further discussion.)
// PBKDF2 is recommended for new applications.
//
// PBKDF2 (P, S, c, dk_len)
//
// Options: PRF underlying pseudorandom function (h_len
// denotes the length in octets of the
// pseudorandom function output)
//
// Input: P password, an octet string
// S salt, an octet string
// c iteration count, a positive integer
// dk_len intended length in octets of the derived
// key, a positive integer, at most
// (2^32 - 1) * h_len
//
// Output: DK derived key, a dk_len-octet string
// Based on Apple's CommonKeyDerivation, based originally on code by Damien Bergamini.
/// Apply PBKDF2 to generate a key from a password.
///
/// PBKDF2 is defined in RFC 2898, and is a recommendation of NIST SP 800-132.
///
/// dk: Slice of appropriate size for generated key. Generally 16 or 32 bytes in length.
/// May be uninitialized. All bytes will be overwritten.
/// Maximum size is `maxInt(u32) * Hash.digest_length`
/// It is a programming error to pass buffer longer than the maximum size.
///
/// password: Arbitrary sequence of bytes of any length, including empty.
///
/// salt: Arbitrary sequence of bytes of any length, including empty. A common length is 8 bytes.
///
/// rounds: Iteration count. Must be greater than 0. Common values range from 1,000 to 100,000.
/// Larger iteration counts improve security by increasing the time required to compute
/// the dk. It is common to tune this parameter to achieve approximately 100ms.
///
/// Prf: Pseudo-random function to use. A common choice is `std.crypto.auth.hmac.HmacSha256`.
pub fn pbkdf2(dk: []u8, password: []const u8, salt: []const u8, rounds: u32, comptime Prf: type) (WeakParametersError || OutputTooLongError)!void {
if (rounds < 1) return error.WeakParameters;
const dk_len = dk.len;
const h_len = Prf.mac_length;
comptime std.debug.assert(h_len >= 1);
// FromSpec:
//
// 1. If dk_len > maxInt(u32) * h_len, output "derived key too long" and
// stop.
//
if (dk_len / h_len >= maxInt(u32)) {
// Counter starts at 1 and is 32 bit, so if we have to return more blocks, we would overflow
return error.OutputTooLong;
}
// FromSpec:
//
// 2. Let l be the number of h_len-long blocks of bytes in the derived key,
// rounding up, and let r be the number of bytes in the last
// block
//
const blocks_count = @intCast(u32, std.math.divCeil(usize, dk_len, h_len) catch unreachable);
var r = dk_len % h_len;
if (r == 0) {
r = h_len;
}
// FromSpec:
//
// 3. For each block of the derived key apply the function F defined
// below to the password P, the salt S, the iteration count c, and
// the block index to compute the block:
//
// T_1 = F (P, S, c, 1) ,
// T_2 = F (P, S, c, 2) ,
// ...
// T_l = F (P, S, c, l) ,
//
// where the function F is defined as the exclusive-or sum of the
// first c iterates of the underlying pseudorandom function PRF
// applied to the password P and the concatenation of the salt S
// and the block index i:
//
// F (P, S, c, i) = U_1 \xor U_2 \xor ... \xor U_c
//
// where
//
// U_1 = PRF (P, S || INT (i)) ,
// U_2 = PRF (P, U_1) ,
// ...
// U_c = PRF (P, U_{c-1}) .
//
// Here, INT (i) is a four-octet encoding of the integer i, most
// significant octet first.
//
// 4. Concatenate the blocks and extract the first dk_len octets to
// produce a derived key DK:
//
// DK = T_1 || T_2 || ... || T_l<0..r-1>
var block: u32 = 0;
while (block < blocks_count) : (block += 1) {
var prev_block: [h_len]u8 = undefined;
var new_block: [h_len]u8 = undefined;
// U_1 = PRF (P, S || INT (i))
const block_index = mem.toBytes(mem.nativeToBig(u32, block + 1)); // Block index starts at 0001
var ctx = Prf.init(password);
ctx.update(salt);
ctx.update(block_index[0..]);
ctx.final(prev_block[0..]);
// Choose portion of DK to write into (T_n) and initialize
const offset = block * h_len;
const block_len = if (block != blocks_count - 1) h_len else r;
const dk_block: []u8 = dk[offset..][0..block_len];
mem.copy(u8, dk_block, prev_block[0..dk_block.len]);
var i: u32 = 1;
while (i < rounds) : (i += 1) {
// U_c = PRF (P, U_{c-1})
Prf.create(&new_block, prev_block[0..], password);
mem.copy(u8, prev_block[0..], new_block[0..]);
// F (P, S, c, i) = U_1 \xor U_2 \xor ... \xor U_c
for (dk_block) |_, j| {
dk_block[j] ^= new_block[j];
}
}
}
}
const htest = @import("test.zig");
const HmacSha1 = std.crypto.auth.hmac.HmacSha1;
// RFC 6070 PBKDF2 HMAC-SHA1 Test Vectors
test "RFC 6070 one iteration" {
const p = "password";
const s = "salt";
const c = 1;
const dk_len = 20;
var dk: [dk_len]u8 = undefined;
try pbkdf2(&dk, p, s, c, HmacSha1);
const expected = "0c60c80f961f0e71f3a9b524af6012062fe037a6";
try htest.assertEqual(expected, dk[0..]);
}
test "RFC 6070 two iterations" {
const p = "password";
const s = "salt";
const c = 2;
const dk_len = 20;
var dk: [dk_len]u8 = undefined;
try pbkdf2(&dk, p, s, c, HmacSha1);
const expected = "ea6c014dc72d6f8ccd1ed92ace1d41f0d8de8957";
try htest.assertEqual(expected, dk[0..]);
}
test "RFC 6070 4096 iterations" {
const p = "password";
const s = "salt";
const c = 4096;
const dk_len = 20;
var dk: [dk_len]u8 = undefined;
try pbkdf2(&dk, p, s, c, HmacSha1);
const expected = "4b007901b765489abead49d926f721d065a429c1";
try htest.assertEqual(expected, dk[0..]);
}
test "RFC 6070 16,777,216 iterations" {
// These iteration tests are slow so we always skip them. Results have been verified.
if (true) {
return error.SkipZigTest;
}
const p = "password";
const s = "salt";
const c = 16777216;
const dk_len = 20;
var dk = [_]u8{0} ** dk_len;
try pbkdf2(&dk, p, s, c, HmacSha1);
const expected = "eefe3d61cd4da4e4e9945b3d6ba2158c2634e984";
try htest.assertEqual(expected, dk[0..]);
}
test "RFC 6070 multi-block salt and password" {
const p = "passwordPASSWORDpassword";
const s = "saltSALTsaltSALTsaltSALTsaltSALTsalt";
const c = 4096;
const dk_len = 25;
var dk: [dk_len]u8 = undefined;
try pbkdf2(&dk, p, s, c, HmacSha1);
const expected = "3d2eec4fe41c849b80c8d83662c0e44a8b291a964cf2f07038";
try htest.assertEqual(expected, dk[0..]);
}
test "RFC 6070 embedded NUL" {
const p = "pass\x00word";
const s = "sa\x00lt";
const c = 4096;
const dk_len = 16;
var dk: [dk_len]u8 = undefined;
try pbkdf2(&dk, p, s, c, HmacSha1);
const expected = "56fa6aa75548099dcc37d7f03425e0c3";
try htest.assertEqual(expected, dk[0..]);
}
test "Very large dk_len" {
// This test allocates 8GB of memory and is expected to take several hours to run.
if (true) {
return error.SkipZigTest;
}
const p = "password";
const s = "salt";
const c = 1;
const dk_len = 1 << 33;
var dk = try std.testing.allocator.alloc(u8, dk_len);
defer {
std.testing.allocator.free(dk);
}
// Just verify this doesn't crash with an overflow
try pbkdf2(dk, p, s, c, HmacSha1);
}
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