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/*
* (C) 2014,2015 Jack Lloyd
* (C) 2016 Daniel Neus, Rohde & Schwarz Cybersecurity
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
#include "tests.h"
#if defined(BOTAN_HAS_MODES)
#include <botan/cipher_mode.h>
#endif
namespace Botan_Tests {
#if defined(BOTAN_HAS_MODES)
class Cipher_Mode_Tests : public Text_Based_Test
{
public:
Cipher_Mode_Tests() :
Text_Based_Test("modes", "Key,Nonce,In,Out")
{}
std::vector<std::string> possible_providers(const std::string& algo) override
{
return provider_filter(Botan::Cipher_Mode::providers(algo));
}
Test::Result run_one_test(const std::string& algo, const VarMap& vars) override
{
const std::vector<uint8_t> key = get_req_bin(vars, "Key");
const std::vector<uint8_t> nonce = get_opt_bin(vars, "Nonce");
const std::vector<uint8_t> input = get_req_bin(vars, "In");
const std::vector<uint8_t> expected = get_req_bin(vars, "Out");
Test::Result result(algo);
const std::vector<std::string> providers = possible_providers(algo);
if(providers.empty())
{
result.note_missing("cipher mode " + algo);
return result;
}
for(auto&& provider_ask : providers)
{
std::unique_ptr<Botan::Cipher_Mode> enc(Botan::get_cipher_mode(
algo, Botan::ENCRYPTION, provider_ask));
std::unique_ptr<Botan::Cipher_Mode> dec(Botan::get_cipher_mode(
algo, Botan::DECRYPTION, provider_ask));
if(!enc || !dec)
{
result.note_missing(algo);
return result;
}
result.test_is_nonempty("provider", enc->provider());
result.test_eq("name", enc->name(), algo);
result.test_eq("mode not authenticated", enc->authenticated(), false);
// Test to make sure reset() resets what we need it to
enc->set_key(mutate_vec(key));
Botan::secure_vector<uint8_t> garbage = Test::rng().random_vec(enc->update_granularity());
enc->start(mutate_vec(nonce));
enc->update(garbage);
enc->reset();
enc->set_key(key);
enc->start(nonce);
Botan::secure_vector<uint8_t> buf(input.begin(), input.end());
// TODO: should first update if possible
enc->finish(buf);
result.test_eq("encrypt", buf, expected);
// additionally test process() if possible
size_t update_granularity = enc->update_granularity();
size_t input_length = input.size();
size_t min_final_bytes = enc->minimum_final_size();
if(input_length > (update_granularity + min_final_bytes))
{
// reset state first
enc->reset();
enc->start(nonce);
buf.assign(input.begin(), input.end());
// we can process at max input_length
const size_t max_blocks_to_process = (input_length - min_final_bytes) / update_granularity;
const size_t bytes_to_process = max_blocks_to_process * update_granularity;
const size_t bytes_written = enc->process(buf.data(), bytes_to_process);
result.test_eq("correct number of bytes processed", bytes_written, bytes_to_process);
enc->finish(buf, bytes_to_process);
result.test_eq("encrypt", buf, expected);
}
// decryption
buf.assign(expected.begin(), expected.end());
// Test to make sure reset() resets what we need it to
dec->set_key(mutate_vec(key));
garbage = Test::rng().random_vec(dec->update_granularity());
dec->start(mutate_vec(nonce));
dec->update(garbage);
dec->reset();
dec->set_key(key);
dec->start(nonce);
dec->finish(buf);
result.test_eq("decrypt", buf, input);
// additionally test process() if possible
update_granularity = dec->update_granularity();
input_length = expected.size();
min_final_bytes = dec->minimum_final_size();
if(input_length > (update_granularity + min_final_bytes))
{
// reset state first
dec->reset();
dec->start(nonce);
buf.assign(expected.begin(), expected.end());
// we can process at max input_length
const size_t max_blocks_to_process = (input_length - min_final_bytes) / update_granularity;
const size_t bytes_to_process = max_blocks_to_process * update_granularity;
const size_t bytes_written = dec->process(buf.data(), bytes_to_process);
result.test_eq("correct number of bytes processed", bytes_written, bytes_to_process);
dec->finish(buf, bytes_to_process);
result.test_eq("decrypt", buf, input);
}
enc->clear();
dec->clear();
}
return result;
}
};
BOTAN_REGISTER_TEST("modes", Cipher_Mode_Tests);
#endif
}
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