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/*
* PKCS #8
* (C) 1999-2010,2014,2018 Jack Lloyd
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
#include <botan/pkcs8.h>
#include <botan/rng.h>
#include <botan/der_enc.h>
#include <botan/ber_dec.h>
#include <botan/alg_id.h>
#include <botan/oids.h>
#include <botan/pem.h>
#include <botan/scan_name.h>
#include <botan/pk_algs.h>
#if defined(BOTAN_HAS_PKCS5_PBES2)
#include <botan/pbes2.h>
#endif
namespace Botan {
namespace PKCS8 {
namespace {
/*
* Get info from an EncryptedPrivateKeyInfo
*/
secure_vector<uint8_t> PKCS8_extract(DataSource& source,
AlgorithmIdentifier& pbe_alg_id)
{
secure_vector<uint8_t> key_data;
BER_Decoder(source)
.start_cons(SEQUENCE)
.decode(pbe_alg_id)
.decode(key_data, OCTET_STRING)
.verify_end();
return key_data;
}
/*
* PEM decode and/or decrypt a private key
*/
secure_vector<uint8_t> PKCS8_decode(
DataSource& source,
std::function<std::string ()> get_passphrase,
AlgorithmIdentifier& pk_alg_id,
bool is_encrypted)
{
AlgorithmIdentifier pbe_alg_id;
secure_vector<uint8_t> key_data, key;
try {
if(ASN1::maybe_BER(source) && !PEM_Code::matches(source))
{
if(is_encrypted)
{
key_data = PKCS8_extract(source, pbe_alg_id);
}
else
{
// todo read more efficiently
while(!source.end_of_data())
{
uint8_t b;
size_t read = source.read_byte(b);
if(read)
{
key_data.push_back(b);
}
}
}
}
else
{
std::string label;
key_data = PEM_Code::decode(source, label);
// todo remove autodetect for pem as well?
if(label == "PRIVATE KEY")
is_encrypted = false;
else if(label == "ENCRYPTED PRIVATE KEY")
{
DataSource_Memory key_source(key_data);
key_data = PKCS8_extract(key_source, pbe_alg_id);
}
else
throw PKCS8_Exception("Unknown PEM label " + label);
}
if(key_data.empty())
throw PKCS8_Exception("No key data found");
}
catch(Decoding_Error& e)
{
throw Decoding_Error("PKCS #8 private key decoding", e);
}
try
{
if(is_encrypted)
{
if(OIDS::lookup(pbe_alg_id.get_oid()) != "PBE-PKCS5v20")
throw PKCS8_Exception("Unknown PBE type " + pbe_alg_id.get_oid().to_string());
#if defined(BOTAN_HAS_PKCS5_PBES2)
key = pbes2_decrypt(key_data, get_passphrase(), pbe_alg_id.get_parameters());
#else
BOTAN_UNUSED(get_passphrase);
throw Decoding_Error("Private key is encrypted but PBES2 was disabled in build");
#endif
}
else
key = key_data;
BER_Decoder(key)
.start_cons(SEQUENCE)
.decode_and_check<size_t>(0, "Unknown PKCS #8 version number")
.decode(pk_alg_id)
.decode(key, OCTET_STRING)
.discard_remaining()
.end_cons();
}
catch(std::exception& e)
{
throw Decoding_Error("PKCS #8 private key decoding", e);
}
return key;
}
}
/*
* BER encode a PKCS #8 private key, unencrypted
*/
secure_vector<uint8_t> BER_encode(const Private_Key& key)
{
// keeping around for compat
return key.private_key_info();
}
/*
* PEM encode a PKCS #8 private key, unencrypted
*/
std::string PEM_encode(const Private_Key& key)
{
return PEM_Code::encode(PKCS8::BER_encode(key), "PRIVATE KEY");
}
#if defined(BOTAN_HAS_PKCS5_PBES2)
namespace {
std::pair<std::string, std::string>
choose_pbe_params(const std::string& pbe_algo, const std::string& key_algo)
{
if(pbe_algo.empty())
{
/*
* For algorithms where we are using a non-RFC format anyway, default to
* SIV or GCM. For others (RSA, ECDSA, ...) default to something widely
* compatible.
*/
const bool nonstandard_pk = (key_algo == "McEliece" || key_algo == "XMSS");
if(nonstandard_pk)
{
#if defined(BOTAN_HAS_AEAD_SIV) && defined(BOTAN_HAS_SHA2_64)
return std::make_pair("AES-256/SIV", "SHA-512");
#elif defined(BOTAN_HAS_AEAD_GCM) && defined(BOTAN_HAS_SHA2_64)
return std::make_pair("AES-256/GCM", "SHA-512");
#endif
}
// Default is something compatible with everyone else
return std::make_pair("AES-256/CBC", "SHA-256");
}
SCAN_Name request(pbe_algo);
if(request.arg_count() != 2 ||
(request.algo_name() != "PBE-PKCS5v20" && request.algo_name() != "PBES2"))
{
throw Invalid_Argument("Unsupported PBE " + pbe_algo);
}
return std::make_pair(request.arg(0), request.arg(1));
}
}
#endif
/*
* BER encode a PKCS #8 private key, encrypted
*/
std::vector<uint8_t> BER_encode(const Private_Key& key,
RandomNumberGenerator& rng,
const std::string& pass,
std::chrono::milliseconds msec,
const std::string& pbe_algo)
{
#if defined(BOTAN_HAS_PKCS5_PBES2)
const auto pbe_params = choose_pbe_params(pbe_algo, key.algo_name());
const std::pair<AlgorithmIdentifier, std::vector<uint8_t>> pbe_info =
pbes2_encrypt_msec(PKCS8::BER_encode(key), pass, msec, nullptr,
pbe_params.first, pbe_params.second, rng);
std::vector<uint8_t> output;
DER_Encoder der(output);
der.start_cons(SEQUENCE)
.encode(pbe_info.first)
.encode(pbe_info.second, OCTET_STRING)
.end_cons();
return output;
#else
BOTAN_UNUSED(key, rng, pass, msec, pbe_algo);
throw Encoding_Error("PKCS8::BER_encode cannot encrypt because PBES2 was disabled in build");
#endif
}
/*
* PEM encode a PKCS #8 private key, encrypted
*/
std::string PEM_encode(const Private_Key& key,
RandomNumberGenerator& rng,
const std::string& pass,
std::chrono::milliseconds msec,
const std::string& pbe_algo)
{
if(pass.empty())
return PEM_encode(key);
return PEM_Code::encode(PKCS8::BER_encode(key, rng, pass, msec, pbe_algo),
"ENCRYPTED PRIVATE KEY");
}
/*
* BER encode a PKCS #8 private key, encrypted
*/
std::vector<uint8_t> BER_encode_encrypted_pbkdf_iter(const Private_Key& key,
RandomNumberGenerator& rng,
const std::string& pass,
size_t pbkdf_iterations,
const std::string& cipher,
const std::string& pbkdf_hash)
{
#if defined(BOTAN_HAS_PKCS5_PBES2)
const std::pair<AlgorithmIdentifier, std::vector<uint8_t>> pbe_info =
pbes2_encrypt_iter(key.private_key_info(),
pass, pbkdf_iterations,
cipher.empty() ? "AES-256/CBC" : cipher,
pbkdf_hash.empty() ? "SHA-256" : pbkdf_hash,
rng);
std::vector<uint8_t> output;
DER_Encoder der(output);
der.start_cons(SEQUENCE)
.encode(pbe_info.first)
.encode(pbe_info.second, OCTET_STRING)
.end_cons();
return output;
#else
BOTAN_UNUSED(key, rng, pass, pbkdf_iterations, cipher, pbkdf_hash);
throw Encoding_Error("PKCS8::BER_encode_encrypted_pbkdf_iter cannot encrypt because PBES2 disabled in build");
#endif
}
/*
* PEM encode a PKCS #8 private key, encrypted
*/
std::string PEM_encode_encrypted_pbkdf_iter(const Private_Key& key,
RandomNumberGenerator& rng,
const std::string& pass,
size_t pbkdf_iterations,
const std::string& cipher,
const std::string& pbkdf_hash)
{
return PEM_Code::encode(
PKCS8::BER_encode_encrypted_pbkdf_iter(key, rng, pass, pbkdf_iterations, cipher, pbkdf_hash),
"ENCRYPTED PRIVATE KEY");
}
/*
* BER encode a PKCS #8 private key, encrypted
*/
std::vector<uint8_t> BER_encode_encrypted_pbkdf_msec(const Private_Key& key,
RandomNumberGenerator& rng,
const std::string& pass,
std::chrono::milliseconds pbkdf_msec,
size_t* pbkdf_iterations,
const std::string& cipher,
const std::string& pbkdf_hash)
{
#if defined(BOTAN_HAS_PKCS5_PBES2)
const std::pair<AlgorithmIdentifier, std::vector<uint8_t>> pbe_info =
pbes2_encrypt_msec(key.private_key_info(), pass,
pbkdf_msec, pbkdf_iterations,
cipher.empty() ? "AES-256/CBC" : cipher,
pbkdf_hash.empty() ? "SHA-256" : pbkdf_hash,
rng);
std::vector<uint8_t> output;
DER_Encoder(output)
.start_cons(SEQUENCE)
.encode(pbe_info.first)
.encode(pbe_info.second, OCTET_STRING)
.end_cons();
return output;
#else
BOTAN_UNUSED(key, rng, pass, pbkdf_msec, pbkdf_iterations, cipher, pbkdf_hash);
throw Encoding_Error("BER_encode_encrypted_pbkdf_msec cannot encrypt because PBES2 disabled in build");
#endif
}
/*
* PEM encode a PKCS #8 private key, encrypted
*/
std::string PEM_encode_encrypted_pbkdf_msec(const Private_Key& key,
RandomNumberGenerator& rng,
const std::string& pass,
std::chrono::milliseconds pbkdf_msec,
size_t* pbkdf_iterations,
const std::string& cipher,
const std::string& pbkdf_hash)
{
return PEM_Code::encode(
PKCS8::BER_encode_encrypted_pbkdf_msec(key, rng, pass, pbkdf_msec, pbkdf_iterations, cipher, pbkdf_hash),
"ENCRYPTED PRIVATE KEY");
}
namespace {
/*
* Extract a private key (encrypted/unencrypted) and return it
*/
std::unique_ptr<Private_Key>
load_key(DataSource& source,
std::function<std::string ()> get_pass,
bool is_encrypted)
{
AlgorithmIdentifier alg_id;
secure_vector<uint8_t> pkcs8_key = PKCS8_decode(source, get_pass, alg_id, is_encrypted);
const std::string alg_name = OIDS::lookup(alg_id.get_oid());
if(alg_name.empty() || alg_name == alg_id.get_oid().to_string())
throw PKCS8_Exception("Unknown algorithm OID: " +
alg_id.get_oid().to_string());
return load_private_key(alg_id, pkcs8_key);
}
}
/*
* Extract an encrypted private key and return it
*/
std::unique_ptr<Private_Key> load_key(DataSource& source,
std::function<std::string ()> get_pass)
{
return load_key(source, get_pass, true);
}
/*
* Extract an encrypted private key and return it
*/
std::unique_ptr<Private_Key> load_key(DataSource& source,
const std::string& pass)
{
return load_key(source, [pass]() { return pass; }, true);
}
/*
* Extract an unencrypted private key and return it
*/
std::unique_ptr<Private_Key> load_key(DataSource& source)
{
auto fail_fn = []() -> std::string {
throw PKCS8_Exception("Internal error: Attempt to read password for unencrypted key");
};
return load_key(source, fail_fn, false);
}
/*
* Make a copy of this private key
*/
std::unique_ptr<Private_Key> copy_key(const Private_Key& key)
{
DataSource_Memory source(PEM_encode(key));
return PKCS8::load_key(source);
}
/*
* Extract an encrypted private key and return it
*/
Private_Key* load_key(DataSource& source,
RandomNumberGenerator& rng,
std::function<std::string ()> get_pass)
{
BOTAN_UNUSED(rng);
return PKCS8::load_key(source, get_pass).release();
}
/*
* Extract an encrypted private key and return it
*/
Private_Key* load_key(DataSource& source,
RandomNumberGenerator& rng,
const std::string& pass)
{
BOTAN_UNUSED(rng);
return PKCS8::load_key(source, pass).release();
}
/*
* Extract an unencrypted private key and return it
*/
Private_Key* load_key(DataSource& source,
RandomNumberGenerator& rng)
{
BOTAN_UNUSED(rng);
return PKCS8::load_key(source).release();
}
#if defined(BOTAN_TARGET_OS_HAS_FILESYSTEM)
/*
* Extract an encrypted private key and return it
*/
Private_Key* load_key(const std::string& fsname,
RandomNumberGenerator& rng,
std::function<std::string ()> get_pass)
{
BOTAN_UNUSED(rng);
DataSource_Stream in(fsname);
return PKCS8::load_key(in, get_pass).release();
}
/*
* Extract an encrypted private key and return it
*/
Private_Key* load_key(const std::string& fsname,
RandomNumberGenerator& rng,
const std::string& pass)
{
BOTAN_UNUSED(rng);
DataSource_Stream in(fsname);
return PKCS8::load_key(in, [pass]() { return pass; }).release();
}
/*
* Extract an unencrypted private key and return it
*/
Private_Key* load_key(const std::string& fsname,
RandomNumberGenerator& rng)
{
BOTAN_UNUSED(rng);
DataSource_Stream in(fsname);
return PKCS8::load_key(in).release();
}
#endif
/*
* Make a copy of this private key
*/
Private_Key* copy_key(const Private_Key& key,
RandomNumberGenerator& rng)
{
BOTAN_UNUSED(rng);
return PKCS8::copy_key(key).release();
}
}
}
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