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/*************************************************
* EAX Mode Source File *
* (C) 1999-2006 The Botan Project *
*************************************************/
#include <botan/eax.h>
#include <botan/lookup.h>
#include <botan/bit_ops.h>
#include <botan/parsing.h>
#include <algorithm>
namespace Botan {
namespace {
/*************************************************
* EAX MAC-based PRF *
*************************************************/
SecureVector<byte> eax_prf(byte tag, u32bit BLOCK_SIZE,
MessageAuthenticationCode* mac,
const byte in[], u32bit length)
{
for(u32bit j = 0; j != BLOCK_SIZE - 1; ++j)
mac->update(0);
mac->update(tag);
mac->update(in, length);
return mac->final();
}
}
/*************************************************
* EAX_Base Constructor *
*************************************************/
EAX_Base::EAX_Base(const std::string& cipher_name,
u32bit tag_size) :
TAG_SIZE(tag_size ? tag_size / 8 : block_size_of(cipher_name)),
BLOCK_SIZE(block_size_of(cipher_name))
{
const std::string mac_name = "CMAC(" + cipher_name + ")";
cipher = get_block_cipher(cipher_name);
mac = get_mac(mac_name);
if(tag_size % 8 != 0 || TAG_SIZE == 0 || TAG_SIZE > mac->OUTPUT_LENGTH)
throw Invalid_Argument(name() + ": Bad tag size " + to_string(tag_size));
state.create(BLOCK_SIZE);
buffer.create(BLOCK_SIZE);
position = 0;
}
/*************************************************
* Check if a keylength is valid for EAX *
*************************************************/
bool EAX_Base::valid_keylength(u32bit n) const
{
if(!cipher->valid_keylength(n))
return false;
if(!mac->valid_keylength(n))
return false;
return true;
}
/*************************************************
* Set the EAX key *
*************************************************/
void EAX_Base::set_key(const SymmetricKey& key)
{
cipher->set_key(key);
mac->set_key(key);
header_mac = eax_prf(1, BLOCK_SIZE, mac, 0, 0);
}
/*************************************************
* Do setup at the start of each message *
*************************************************/
void EAX_Base::start_msg()
{
for(u32bit j = 0; j != BLOCK_SIZE - 1; ++j)
mac->update(0);
mac->update(2);
}
/*************************************************
* Set the EAX nonce *
*************************************************/
void EAX_Base::set_iv(const InitializationVector& iv)
{
nonce_mac = eax_prf(0, BLOCK_SIZE, mac, iv.begin(), iv.length());
state = nonce_mac;
cipher->encrypt(state, buffer);
}
/*************************************************
* Set the EAX header *
*************************************************/
void EAX_Base::set_header(const byte header[], u32bit length)
{
header_mac = eax_prf(1, BLOCK_SIZE, mac, header, length);
}
/*************************************************
* Return the name of this cipher mode *
*************************************************/
std::string EAX_Base::name() const
{
return (cipher->name() + "/EAX");
}
/*************************************************
* Increment the counter and update the buffer *
*************************************************/
void EAX_Base::increment_counter()
{
for(s32bit j = BLOCK_SIZE - 1; j >= 0; --j)
if(++state[j])
break;
cipher->encrypt(state, buffer);
position = 0;
}
/*************************************************
* EAX_Encryption Constructor *
*************************************************/
EAX_Encryption::EAX_Encryption(const std::string& cipher_name,
u32bit tag_size) :
EAX_Base(cipher_name, tag_size)
{
}
/*************************************************
* EAX_Encryption Constructor *
*************************************************/
EAX_Encryption::EAX_Encryption(const std::string& cipher_name,
const SymmetricKey& key,
const InitializationVector& iv,
u32bit tag_size) :
EAX_Base(cipher_name, tag_size)
{
set_key(key);
set_iv(iv);
}
/*************************************************
* Encrypt in EAX mode *
*************************************************/
void EAX_Encryption::write(const byte input[], u32bit length)
{
u32bit copied = std::min(BLOCK_SIZE - position, length);
xor_buf(buffer + position, input, copied);
send(buffer + position, copied);
mac->update(buffer + position, copied);
input += copied;
length -= copied;
position += copied;
if(position == BLOCK_SIZE)
increment_counter();
while(length >= BLOCK_SIZE)
{
xor_buf(buffer, input, BLOCK_SIZE);
send(buffer, BLOCK_SIZE);
mac->update(buffer, BLOCK_SIZE);
input += BLOCK_SIZE;
length -= BLOCK_SIZE;
increment_counter();
}
xor_buf(buffer + position, input, length);
send(buffer + position, length);
mac->update(buffer + position, length);
position += length;
}
/*************************************************
* Finish encrypting in EAX mode *
*************************************************/
void EAX_Encryption::end_msg()
{
SecureVector<byte> data_mac = mac->final();
xor_buf(data_mac, nonce_mac, data_mac.size());
xor_buf(data_mac, header_mac, data_mac.size());
send(data_mac, TAG_SIZE);
state.clear();
buffer.clear();
position = 0;
}
/*************************************************
* EAX_Decryption Constructor *
*************************************************/
EAX_Decryption::EAX_Decryption(const std::string& cipher_name,
u32bit tag_size) :
EAX_Base(cipher_name, tag_size)
{
queue.create(2*TAG_SIZE + DEFAULT_BUFFERSIZE);
queue_start = queue_end = 0;
}
/*************************************************
* EAX_Decryption Constructor *
*************************************************/
EAX_Decryption::EAX_Decryption(const std::string& cipher_name,
const SymmetricKey& key,
const InitializationVector& iv,
u32bit tag_size) :
EAX_Base(cipher_name, tag_size)
{
set_key(key);
set_iv(iv);
queue.create(2*TAG_SIZE + DEFAULT_BUFFERSIZE);
queue_start = queue_end = 0;
}
/*************************************************
* Decrypt in EAX mode *
*************************************************/
void EAX_Decryption::write(const byte input[], u32bit length)
{
while(length)
{
const u32bit copied = std::min(length, queue.size() - queue_end);
queue.copy(queue_end, input, copied);
input += copied;
length -= copied;
queue_end += copied;
SecureVector<byte> block_buf(cipher->BLOCK_SIZE);
while((queue_end - queue_start) > TAG_SIZE)
{
u32bit removed = (queue_end - queue_start) - TAG_SIZE;
do_write(queue + queue_start, removed);
queue_start += removed;
}
if(queue_start + TAG_SIZE == queue_end &&
queue_start >= queue.size() / 2)
{
SecureVector<byte> queue_data(TAG_SIZE);
queue_data.copy(queue + queue_start, TAG_SIZE);
queue.copy(queue_data, TAG_SIZE);
queue_start = 0;
queue_end = TAG_SIZE;
}
}
}
/*************************************************
* Decrypt in EAX mode *
*************************************************/
void EAX_Decryption::do_write(const byte input[], u32bit length)
{
mac->update(input, length);
u32bit copied = std::min(BLOCK_SIZE - position, length);
xor_buf(buffer + position, input, copied);
send(buffer + position, copied);
input += copied;
length -= copied;
position += copied;
if(position == BLOCK_SIZE)
increment_counter();
while(length >= BLOCK_SIZE)
{
xor_buf(buffer, input, BLOCK_SIZE);
send(buffer, BLOCK_SIZE);
input += BLOCK_SIZE;
length -= BLOCK_SIZE;
increment_counter();
}
xor_buf(buffer + position, input, length);
send(buffer + position, length);
position += length;
}
/*************************************************
* Finish decrypting in EAX mode *
*************************************************/
void EAX_Decryption::end_msg()
{
if((queue_end - queue_start) != TAG_SIZE)
throw Integrity_Failure(name() + ": Message authentication failure");
SecureVector<byte> data_mac = mac->final();
for(u32bit j = 0; j != TAG_SIZE; ++j)
if(queue[queue_start+j] != (data_mac[j] ^ nonce_mac[j] ^ header_mac[j]))
throw Integrity_Failure(name() + ": Message authentication failure");
state.clear();
buffer.clear();
position = 0;
queue_start = queue_end = 0;
}
}
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