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/*
* OCB Mode
* (C) 2013 Jack Lloyd
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
#include <botan/ocb.h>
#include <botan/cmac.h>
#include <botan/internal/xor_buf.h>
#include <botan/internal/bit_ops.h>
#include <algorithm>
namespace Botan {
// Has to be in Botan namespace so unique_ptr can reference it
class L_computer
{
public:
L_computer(const BlockCipher& cipher)
{
m_L_star.resize(cipher.block_size());
cipher.encrypt(m_L_star);
m_L_dollar = poly_double(star());
m_L.push_back(poly_double(dollar()));
}
const secure_vector<byte>& star() const { return m_L_star; }
const secure_vector<byte>& dollar() const { return m_L_dollar; }
const secure_vector<byte>& operator()(size_t i) const { return get(i); }
const secure_vector<byte>& compute_offsets(secure_vector<byte>& offset,
size_t block_index,
size_t blocks) const
{
const size_t BS = m_L_star.size();
m_offset_buf.resize(blocks * BS);
for(size_t i = 0; i != blocks; ++i)
{ // could be done in parallel
offset ^= get(ctz(block_index + 1 + i));
copy_mem(&m_offset_buf[BS*i], &offset[0], BS);
}
return m_offset_buf;
}
private:
const secure_vector<byte>& get(size_t i) const
{
while(m_L.size() <= i)
m_L.push_back(poly_double(m_L.back()));
return m_L.at(i);
}
secure_vector<byte> poly_double(const secure_vector<byte>& in) const
{
return CMAC::poly_double(in);
}
secure_vector<byte> m_L_dollar, m_L_star;
mutable std::vector<secure_vector<byte>> m_L;
mutable secure_vector<byte> m_offset_buf;
};
namespace {
/*
* OCB's HASH
*/
secure_vector<byte> ocb_hash(const L_computer& L,
const BlockCipher& cipher,
const byte ad[], size_t ad_len)
{
const size_t BS = cipher.block_size();
secure_vector<byte> sum(BS);
secure_vector<byte> offset(BS);
secure_vector<byte> buf(BS);
const size_t ad_blocks = (ad_len / BS);
const size_t ad_remainder = (ad_len % BS);
for(size_t i = 0; i != ad_blocks; ++i)
{
// this loop could run in parallel
offset ^= L(ctz(i+1));
buf = offset;
xor_buf(&buf[0], &ad[BS*i], BS);
cipher.encrypt(buf);
sum ^= buf;
}
if(ad_remainder)
{
offset ^= L.star();
buf = offset;
xor_buf(&buf[0], &ad[BS*ad_blocks], ad_remainder);
buf[ad_len % BS] ^= 0x80;
cipher.encrypt(buf);
sum ^= buf;
}
return sum;
}
}
OCB_Mode::OCB_Mode(BlockCipher* cipher, size_t tag_size) :
m_cipher(cipher),
m_BS(m_cipher->block_size()),
m_checksum(m_cipher->parallel_bytes()),
m_offset(m_BS),
m_ad_hash(m_BS),
m_tag_size(tag_size)
{
if(BS() != 16)
throw std::invalid_argument("OCB is not compatible with " + m_cipher->name());
if(m_tag_size % 4 != 0 || m_tag_size < 8 || m_tag_size > BS())
throw std::invalid_argument("OCB cannot produce a " + std::to_string(m_tag_size) +
" byte tag");
}
OCB_Mode::~OCB_Mode() { /* for unique_ptr destructor */ }
void OCB_Mode::clear()
{
m_cipher.reset();
m_L.reset();
zeroise(m_ad_hash);
zeroise(m_offset);
zeroise(m_checksum);
}
bool OCB_Mode::valid_nonce_length(size_t length) const
{
return (length > 0 && length < m_cipher->block_size());
}
std::string OCB_Mode::name() const
{
return m_cipher->name() + "/OCB"; // include tag size
}
size_t OCB_Mode::update_granularity() const
{
return m_cipher->parallel_bytes();
}
Key_Length_Specification OCB_Mode::key_spec() const
{
return m_cipher->key_spec();
}
void OCB_Mode::key_schedule(const byte key[], size_t length)
{
m_cipher->set_key(key, length);
m_L.reset(new L_computer(*m_cipher));
}
void OCB_Mode::set_associated_data(const byte ad[], size_t ad_len)
{
BOTAN_ASSERT(m_L, "A key was set");
m_ad_hash = ocb_hash(*m_L, *m_cipher, &ad[0], ad_len);
}
secure_vector<byte>
OCB_Mode::update_nonce(const byte nonce[], size_t nonce_len)
{
BOTAN_ASSERT(nonce_len < BS(), "OCB nonce is less than cipher block size");
secure_vector<byte> nonce_buf(BS());
copy_mem(&nonce_buf[BS() - nonce_len], nonce, nonce_len);
nonce_buf[0] = ((tag_size() * 8) % 128) << 1;
nonce_buf[BS() - nonce_len - 1] = 1;
const byte bottom = nonce_buf[BS()-1] & 0x3F;
nonce_buf[BS()-1] &= 0xC0;
const bool need_new_stretch = (m_last_nonce != nonce_buf);
if(need_new_stretch)
{
m_last_nonce = nonce_buf;
m_cipher->encrypt(nonce_buf);
for(size_t i = 0; i != BS() / 2; ++i)
nonce_buf.push_back(nonce_buf[i] ^ nonce_buf[i+1]);
m_stretch = nonce_buf;
}
// now set the offset from stretch and bottom
const size_t shift_bytes = bottom / 8;
const size_t shift_bits = bottom % 8;
secure_vector<byte> offset(BS());
for(size_t i = 0; i != BS(); ++i)
{
offset[i] = (m_stretch[i+shift_bytes] << shift_bits);
offset[i] |= (m_stretch[i+shift_bytes+1] >> (8-shift_bits));
}
return offset;
}
secure_vector<byte> OCB_Mode::start_raw(const byte nonce[], size_t nonce_len)
{
if(!valid_nonce_length(nonce_len))
throw Invalid_IV_Length(name(), nonce_len);
BOTAN_ASSERT(m_L, "A key was set");
m_offset = update_nonce(nonce, nonce_len);
zeroise(m_checksum);
m_block_index = 0;
return secure_vector<byte>();
}
void OCB_Encryption::encrypt(byte buffer[], size_t blocks)
{
const size_t par_blocks = m_checksum.size() / BS();
while(blocks)
{
const size_t proc_blocks = std::min(blocks, par_blocks);
const size_t proc_bytes = proc_blocks * BS();
const auto& offsets = m_L->compute_offsets(m_offset, m_block_index, proc_blocks);
xor_buf(&m_checksum[0], &buffer[0], proc_bytes);
xor_buf(&buffer[0], &offsets[0], proc_bytes);
m_cipher->encrypt_n(&buffer[0], &buffer[0], proc_blocks);
xor_buf(&buffer[0], &offsets[0], proc_bytes);
buffer += proc_bytes;
blocks -= proc_blocks;
m_block_index += proc_blocks;
}
}
void OCB_Encryption::update(secure_vector<byte>& buffer, size_t offset)
{
BOTAN_ASSERT(buffer.size() >= offset, "Offset is sane");
const size_t sz = buffer.size() - offset;
byte* buf = &buffer[offset];
BOTAN_ASSERT(sz % BS() == 0, "Input length is an even number of blocks");
encrypt(buf, sz / BS());
}
void OCB_Encryption::finish(secure_vector<byte>& buffer, size_t offset)
{
BOTAN_ASSERT(buffer.size() >= offset, "Offset is sane");
const size_t sz = buffer.size() - offset;
byte* buf = &buffer[offset];
if(sz)
{
const size_t final_full_blocks = sz / BS();
const size_t remainder_bytes = sz - (final_full_blocks * BS());
encrypt(buf, final_full_blocks);
if(remainder_bytes)
{
BOTAN_ASSERT(remainder_bytes < BS(), "Only a partial block left");
byte* remainder = &buf[sz - remainder_bytes];
xor_buf(&m_checksum[0], &remainder[0], remainder_bytes);
m_checksum[remainder_bytes] ^= 0x80;
m_offset ^= m_L->star(); // Offset_*
secure_vector<byte> zeros(BS());
m_cipher->encrypt(m_offset, zeros);
xor_buf(&remainder[0], &zeros[0], remainder_bytes);
}
}
secure_vector<byte> checksum(BS());
// fold checksum
for(size_t i = 0; i != m_checksum.size(); ++i)
checksum[i % checksum.size()] ^= m_checksum[i];
// now compute the tag
secure_vector<byte> mac = m_offset;
mac ^= checksum;
mac ^= m_L->dollar();
m_cipher->encrypt(mac);
mac ^= m_ad_hash;
buffer += std::make_pair(&mac[0], tag_size());
zeroise(m_checksum);
zeroise(m_offset);
m_block_index = 0;
}
void OCB_Decryption::decrypt(byte buffer[], size_t blocks)
{
const size_t par_bytes = m_cipher->parallel_bytes();
BOTAN_ASSERT(par_bytes % BS() == 0, "Cipher is parallel in full blocks");
const size_t par_blocks = par_bytes / BS();
while(blocks)
{
const size_t proc_blocks = std::min(blocks, par_blocks);
const size_t proc_bytes = proc_blocks * BS();
const auto& offsets = m_L->compute_offsets(m_offset, m_block_index, proc_blocks);
xor_buf(&buffer[0], &offsets[0], proc_bytes);
m_cipher->decrypt_n(&buffer[0], &buffer[0], proc_blocks);
xor_buf(&buffer[0], &offsets[0], proc_bytes);
xor_buf(&m_checksum[0], &buffer[0], proc_bytes);
buffer += proc_bytes;
blocks -= proc_blocks;
m_block_index += proc_blocks;
}
}
void OCB_Decryption::update(secure_vector<byte>& buffer, size_t offset)
{
BOTAN_ASSERT(buffer.size() >= offset, "Offset is sane");
const size_t sz = buffer.size() - offset;
byte* buf = &buffer[offset];
BOTAN_ASSERT(sz % BS() == 0, "Input length is an even number of blocks");
decrypt(buf, sz / BS());
}
void OCB_Decryption::finish(secure_vector<byte>& buffer, size_t offset)
{
BOTAN_ASSERT(buffer.size() >= offset, "Offset is sane");
const size_t sz = buffer.size() - offset;
byte* buf = &buffer[offset];
BOTAN_ASSERT(sz >= tag_size(), "We have the tag");
const size_t remaining = sz - tag_size();
if(remaining)
{
const size_t final_full_blocks = remaining / BS();
const size_t final_bytes = remaining - (final_full_blocks * BS());
decrypt(&buf[0], final_full_blocks);
if(final_bytes)
{
BOTAN_ASSERT(final_bytes < BS(), "Only a partial block left");
byte* remainder = &buf[remaining - final_bytes];
m_offset ^= m_L->star(); // Offset_*
secure_vector<byte> pad(BS());
m_cipher->encrypt(m_offset, pad); // P_*
xor_buf(&remainder[0], &pad[0], final_bytes);
xor_buf(&m_checksum[0], &remainder[0], final_bytes);
m_checksum[final_bytes] ^= 0x80;
}
}
secure_vector<byte> checksum(BS());
// fold checksum
for(size_t i = 0; i != m_checksum.size(); ++i)
checksum[i % checksum.size()] ^= m_checksum[i];
// compute the mac
secure_vector<byte> mac = m_offset;
mac ^= checksum;
mac ^= m_L->dollar();
m_cipher->encrypt(mac);
mac ^= m_ad_hash;
// reset state
zeroise(m_checksum);
zeroise(m_offset);
m_block_index = 0;
// compare mac
const byte* included_tag = &buf[remaining];
if(!same_mem(&mac[0], included_tag, tag_size()))
throw Integrity_Failure("OCB tag check failed");
// remove tag from end of message
buffer.resize(remaining + offset);
}
}
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