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/**
* (C) 2018,2019 Jack Lloyd
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
#include <botan/argon2.h>
#include <botan/hash.h>
#include <botan/mem_ops.h>
#include <botan/rotate.h>
#include <botan/exceptn.h>
namespace Botan {
namespace {
static const size_t SYNC_POINTS = 4;
secure_vector<uint8_t> argon2_H0(HashFunction& blake2b,
size_t output_len,
const char* password, size_t password_len,
const uint8_t salt[], size_t salt_len,
const uint8_t key[], size_t key_len,
const uint8_t ad[], size_t ad_len,
size_t y, size_t p, size_t M, size_t t)
{
const uint8_t v = 19; // Argon2 version code
blake2b.update_le<uint32_t>(static_cast<uint32_t>(p));
blake2b.update_le<uint32_t>(static_cast<uint32_t>(output_len));
blake2b.update_le<uint32_t>(static_cast<uint32_t>(M));
blake2b.update_le<uint32_t>(static_cast<uint32_t>(t));
blake2b.update_le<uint32_t>(static_cast<uint32_t>(v));
blake2b.update_le<uint32_t>(static_cast<uint32_t>(y));
blake2b.update_le<uint32_t>(static_cast<uint32_t>(password_len));
blake2b.update(cast_char_ptr_to_uint8(password), password_len);
blake2b.update_le<uint32_t>(static_cast<uint32_t>(salt_len));
blake2b.update(salt, salt_len);
blake2b.update_le<uint32_t>(static_cast<uint32_t>(key_len));
blake2b.update(key, key_len);
blake2b.update_le<uint32_t>(static_cast<uint32_t>(ad_len));
blake2b.update(ad, ad_len);
return blake2b.final();
}
void Htick(secure_vector<uint8_t>& T,
uint8_t output[],
size_t output_len,
HashFunction& blake2b,
const secure_vector<uint8_t>& H0,
size_t p0, size_t p1)
{
BOTAN_ASSERT_NOMSG(output_len % 64 == 0);
blake2b.update_le<uint32_t>(static_cast<uint32_t>(output_len));
blake2b.update(H0);
blake2b.update_le<uint32_t>(static_cast<uint32_t>(p0));
blake2b.update_le<uint32_t>(static_cast<uint32_t>(p1));
blake2b.final(&T[0]);
while(output_len > 64)
{
copy_mem(output, &T[0], 32);
output_len -= 32;
output += 32;
blake2b.update(T);
blake2b.final(&T[0]);
}
if(output_len > 0)
copy_mem(output, &T[0], output_len);
}
void extract_key(uint8_t output[], size_t output_len,
const secure_vector<uint64_t>& B,
size_t memory, size_t threads)
{
const size_t lanes = memory / threads;
secure_vector<uint64_t> sum(128);
for(size_t lane = 0; lane != threads; ++lane)
{
size_t start = 128*(lane * lanes + lanes - 1);
size_t end = 128*(lane * lanes + lanes);
for(size_t j = start; j != end; ++j)
{
sum[j % 128] ^= B[j];
}
}
secure_vector<uint8_t> sum8(1024);
copy_out_le(sum8.data(), 1024, sum.data());
if(output_len <= 64)
{
std::unique_ptr<HashFunction> blake2b = HashFunction::create_or_throw("BLAKE2b(" + std::to_string(output_len*8) + ")");
blake2b->update_le(static_cast<uint32_t>(output_len));
blake2b->update(sum8.data(), sum8.size());
blake2b->final(output);
}
else
{
secure_vector<uint8_t> T(64);
std::unique_ptr<HashFunction> blake2b = HashFunction::create_or_throw("BLAKE2b(512)");
blake2b->update_le(static_cast<uint32_t>(output_len));
blake2b->update(sum8.data(), sum8.size());
blake2b->final(&T[0]);
while(output_len > 64)
{
copy_mem(output, &T[0], 32);
output_len -= 32;
output += 32;
if(output_len > 64)
{
blake2b->update(T);
blake2b->final(&T[0]);
}
}
if(output_len == 64)
{
blake2b->update(T);
blake2b->final(output);
}
else
{
std::unique_ptr<HashFunction> blake2b_f = HashFunction::create_or_throw("BLAKE2b(" + std::to_string(output_len*8) + ")");
blake2b_f->update(T);
blake2b_f->final(output);
}
}
}
void init_blocks(secure_vector<uint64_t>& B,
HashFunction& blake2b,
const secure_vector<uint8_t>& H0,
size_t memory,
size_t threads)
{
BOTAN_ASSERT_NOMSG(B.size() >= threads*256);
secure_vector<uint8_t> H(1024);
secure_vector<uint8_t> T(blake2b.output_length());
for(size_t i = 0; i != threads; ++i)
{
const size_t B_off = i * (memory / threads);
BOTAN_ASSERT_NOMSG(B.size() >= 128*(B_off+2));
Htick(T, &H[0], H.size(), blake2b, H0, 0, i);
for(size_t j = 0; j != 128; ++j)
{
B[128*B_off+j] = load_le<uint64_t>(H.data(), j);
}
Htick(T, &H[0], H.size(), blake2b, H0, 1, i);
for(size_t j = 0; j != 128; ++j)
{
B[128*(B_off+1)+j] = load_le<uint64_t>(H.data(), j);
}
}
}
inline void blamka_G(uint64_t& A, uint64_t& B, uint64_t& C, uint64_t& D)
{
A += B + (static_cast<uint64_t>(2) * static_cast<uint32_t>(A)) * static_cast<uint32_t>(B);
D = rotr<32>(A ^ D);
C += D + (static_cast<uint64_t>(2) * static_cast<uint32_t>(C)) * static_cast<uint32_t>(D);
B = rotr<24>(B ^ C);
A += B + (static_cast<uint64_t>(2) * static_cast<uint32_t>(A)) * static_cast<uint32_t>(B);
D = rotr<16>(A ^ D);
C += D + (static_cast<uint64_t>(2) * static_cast<uint32_t>(C)) * static_cast<uint32_t>(D);
B = rotr<63>(B ^ C);
}
inline void blamka(uint64_t& V0, uint64_t& V1, uint64_t& V2, uint64_t& V3,
uint64_t& V4, uint64_t& V5, uint64_t& V6, uint64_t& V7,
uint64_t& V8, uint64_t& V9, uint64_t& VA, uint64_t& VB,
uint64_t& VC, uint64_t& VD, uint64_t& VE, uint64_t& VF)
{
blamka_G(V0, V4, V8, VC);
blamka_G(V1, V5, V9, VD);
blamka_G(V2, V6, VA, VE);
blamka_G(V3, V7, VB, VF);
blamka_G(V0, V5, VA, VF);
blamka_G(V1, V6, VB, VC);
blamka_G(V2, V7, V8, VD);
blamka_G(V3, V4, V9, VE);
}
void process_block_xor(secure_vector<uint64_t>& T,
secure_vector<uint64_t>& B,
size_t offset,
size_t prev,
size_t new_offset)
{
for(size_t i = 0; i != 128; ++i)
T[i] = B[128*prev+i] ^ B[128*new_offset+i];
for(size_t i = 0; i != 128; i += 16)
{
blamka(T[i+ 0], T[i+ 1], T[i+ 2], T[i+ 3],
T[i+ 4], T[i+ 5], T[i+ 6], T[i+ 7],
T[i+ 8], T[i+ 9], T[i+10], T[i+11],
T[i+12], T[i+13], T[i+14], T[i+15]);
}
for(size_t i = 0; i != 128 / 8; i += 2)
{
blamka(T[ i], T[ i+1], T[ 16+i], T[ 16+i+1],
T[ 32+i], T[ 32+i+1], T[ 48+i], T[ 48+i+1],
T[ 64+i], T[ 64+i+1], T[ 80+i], T[ 80+i+1],
T[ 96+i], T[ 96+i+1], T[112+i], T[112+i+1]);
}
for(size_t i = 0; i != 128; ++i)
B[128*offset + i] ^= T[i] ^ B[128*prev+i] ^ B[128*new_offset+i];
}
void gen_2i_addresses(secure_vector<uint64_t>& T, secure_vector<uint64_t>& B,
size_t n, size_t lane, size_t slice, size_t memory,
size_t time, size_t mode, size_t cnt)
{
BOTAN_ASSERT_NOMSG(B.size() == 128);
BOTAN_ASSERT_NOMSG(T.size() == 128);
clear_mem(B.data(), B.size());
B[0] = n;
B[1] = lane;
B[2] = slice;
B[3] = memory;
B[4] = time;
B[5] = mode;
B[6] = cnt;
for(size_t r = 0; r != 2; ++r)
{
copy_mem(T.data(), B.data(), B.size());
for(size_t i = 0; i != 128; i += 16)
{
blamka(T[i+ 0], T[i+ 1], T[i+ 2], T[i+ 3],
T[i+ 4], T[i+ 5], T[i+ 6], T[i+ 7],
T[i+ 8], T[i+ 9], T[i+10], T[i+11],
T[i+12], T[i+13], T[i+14], T[i+15]);
}
for(size_t i = 0; i != 128 / 8; i += 2)
{
blamka(T[ i], T[ i+1], T[ 16+i], T[ 16+i+1],
T[ 32+i], T[ 32+i+1], T[ 48+i], T[ 48+i+1],
T[ 64+i], T[ 64+i+1], T[ 80+i], T[ 80+i+1],
T[ 96+i], T[ 96+i+1], T[112+i], T[112+i+1]);
}
for(size_t i = 0; i != 128; ++i)
B[i] ^= T[i];
}
}
uint32_t index_alpha(uint64_t random,
size_t lanes,
size_t segments,
size_t threads,
size_t n,
size_t slice,
size_t lane,
size_t index)
{
size_t ref_lane = static_cast<uint32_t>(random >> 32) % threads;
if(n == 0 && slice == 0)
ref_lane = lane;
size_t m = 3*segments;
size_t s = ((slice+1) % 4)*segments;
if(lane == ref_lane)
m += index;
if(n == 0) {
m = slice*segments;
s = 0;
if(slice == 0 || lane == ref_lane)
m += index;
}
if(index == 0 || lane == ref_lane)
m -= 1;
uint64_t p = static_cast<uint32_t>(random);
p = (p * p) >> 32;
p = (p * m) >> 32;
return static_cast<uint32_t>(ref_lane*lanes + (s + m - (p+1)) % lanes);
}
void process_block_argon2d(secure_vector<uint64_t>& T,
secure_vector<uint64_t>& B,
size_t n, size_t slice, size_t lane,
size_t lanes, size_t segments, size_t threads)
{
size_t index = 0;
if(n == 0 && slice == 0)
index = 2;
while(index < segments)
{
const size_t offset = lane*lanes + slice*segments + index;
size_t prev = offset - 1;
if(index == 0 && slice == 0)
prev += lanes;
const uint64_t random = B.at(128*prev);
const size_t new_offset = index_alpha(random, lanes, segments, threads, n, slice, lane, index);
process_block_xor(T, B, offset, prev, new_offset);
index += 1;
}
}
void process_block_argon2i(secure_vector<uint64_t>& T,
secure_vector<uint64_t>& B,
size_t n, size_t slice, size_t lane,
size_t lanes, size_t segments, size_t threads, uint8_t mode,
size_t memory, size_t time)
{
size_t index = 0;
if(n == 0 && slice == 0)
index = 2;
secure_vector<uint64_t> addresses(128);
size_t address_counter = 1;
gen_2i_addresses(T, addresses, n, lane, slice, memory, time, mode, address_counter);
while(index < segments)
{
const size_t offset = lane*lanes + slice*segments + index;
size_t prev = offset - 1;
if(index == 0 && slice == 0)
prev += lanes;
if(index > 0 && index % 128 == 0)
{
address_counter += 1;
gen_2i_addresses(T, addresses, n, lane, slice, memory, time, mode, address_counter);
}
const uint64_t random = addresses[index % 128];
const size_t new_offset = index_alpha(random, lanes, segments, threads, n, slice, lane, index);
process_block_xor(T, B, offset, prev, new_offset);
index += 1;
}
}
void process_blocks(secure_vector<uint64_t>& B,
size_t t,
size_t memory,
size_t threads,
uint8_t mode)
{
const size_t lanes = memory / threads;
const size_t segments = lanes / SYNC_POINTS;
secure_vector<uint64_t> T(128);
for(size_t n = 0; n != t; ++n)
{
for(size_t slice = 0; slice != SYNC_POINTS; ++slice)
{
// TODO can run this in Thread_Pool
for(size_t lane = 0; lane != threads; ++lane)
{
if(mode == 1 || (mode == 2 && n == 0 && slice < SYNC_POINTS/2))
process_block_argon2i(T, B, n, slice, lane, lanes, segments, threads, mode, memory, t);
else
process_block_argon2d(T, B, n, slice, lane, lanes, segments, threads);
}
}
}
}
}
void argon2(uint8_t output[], size_t output_len,
const char* password, size_t password_len,
const uint8_t salt[], size_t salt_len,
const uint8_t key[], size_t key_len,
const uint8_t ad[], size_t ad_len,
uint8_t mode, size_t threads, size_t M, size_t t)
{
BOTAN_ARG_CHECK(mode == 0 || mode == 1 || mode == 2, "Unknown Argon2 mode parameter");
BOTAN_ARG_CHECK(output_len >= 4, "Invalid Argon2 output length");
BOTAN_ARG_CHECK(threads >= 1 && threads <= 128, "Invalid Argon2 threads parameter");
BOTAN_ARG_CHECK(M >= 8*threads && M <= 8192*1024, "Invalid Argon2 M parameter");
BOTAN_ARG_CHECK(t >= 1, "Invalid Argon2 t parameter");
std::unique_ptr<HashFunction> blake2 = HashFunction::create_or_throw("BLAKE2b");
const auto H0 = argon2_H0(*blake2, output_len,
password, password_len,
salt, salt_len,
key, key_len,
ad, ad_len,
mode, threads, M, t);
const size_t memory = (M / (SYNC_POINTS*threads)) * (SYNC_POINTS*threads);
secure_vector<uint64_t> B(memory * 1024/8);
init_blocks(B, *blake2, H0, memory, threads);
process_blocks(B, t, memory, threads, mode);
clear_mem(output, output_len);
extract_key(output, output_len, B, memory, threads);
}
}
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