nhyatt/putty-source
1
0
Fork 0
mirror of https://git.tartarus.org/simon/putty.git synced 2025-01-09 09:27:59 +00:00
Code Issues Projects Releases Wiki Activity
20d1c47484
putty-source/testcrypt.h
Simon Tatham 844e766b03 RSA generation: option to generate strong primes. 
A 'strong' prime, as defined by the Handbook of Applied Cryptography,
is a prime p such that each of p-1 and p+1 has a large prime factor,
and that the large factor q of p-1 is such that q-1 in turn _also_ has
a large prime factor.

HoAC says that making your RSA key using primes of this form defeats
some factoring algorithms - but there are other faster algorithms to
which it makes no difference. So this is probably not a useful
precaution in practice. However, it has been recommended in the past
by some official standards, and it's easy to implement given the new
general facility in PrimeCandidateSource that lets you ask for your
prime to satisfy an arbitrary modular congruence. (And HoAC also says
there's no particular reason _not_ to use strong primes.) So I provide
it as an option, just in case anyone wants to select it.

The change to the key generation algorithm is entirely in sshrsag.c,
and is neatly independent of the prime-generation system in use. If
you're using Maurer provable prime generation, then the known factor q
of p-1 can be used to help certify p, and the one for q-1 to help with
q in turn; if you switch to probabilistic prime generation then you
still get an RSA key with the right structure, except that every time
the definition says 'prime factor' you just append '(probably)'.

(The probabilistic version of this procedure is described as 'Gordon's
algorithm' in HoAC section 4.4.2.)
2020-03-07 11:37:31 +00:00

317 lines
15 KiB
C
Raw Blame History

/*
* mpint.h functions.
*/
FUNC1(val_mpint, mp_new, uint)
FUNC1(void, mp_clear, val_mpint)
FUNC1(val_mpint, mp_from_bytes_le, val_string_ptrlen)
FUNC1(val_mpint, mp_from_bytes_be, val_string_ptrlen)
FUNC1(val_mpint, mp_from_integer, uint)
FUNC1(val_mpint, mp_from_decimal_pl, val_string_ptrlen)
FUNC1(val_mpint, mp_from_decimal, val_string_asciz)
FUNC1(val_mpint, mp_from_hex_pl, val_string_ptrlen)
FUNC1(val_mpint, mp_from_hex, val_string_asciz)
FUNC1(val_mpint, mp_copy, val_mpint)
FUNC1(val_mpint, mp_power_2, uint)
FUNC2(uint, mp_get_byte, val_mpint, uint)
FUNC2(uint, mp_get_bit, val_mpint, uint)
FUNC3(void, mp_set_bit, val_mpint, uint, uint)
FUNC1(uint, mp_max_bytes, val_mpint)
FUNC1(uint, mp_max_bits, val_mpint)
FUNC1(uint, mp_get_nbits, val_mpint)
FUNC1(val_string_asciz, mp_get_decimal, val_mpint)
FUNC1(val_string_asciz, mp_get_hex, val_mpint)
FUNC1(val_string_asciz, mp_get_hex_uppercase, val_mpint)
FUNC2(uint, mp_cmp_hs, val_mpint, val_mpint)
FUNC2(uint, mp_cmp_eq, val_mpint, val_mpint)
FUNC2(uint, mp_hs_integer, val_mpint, uint)
FUNC2(uint, mp_eq_integer, val_mpint, uint)
FUNC3(void, mp_min_into, val_mpint, val_mpint, val_mpint)
FUNC3(void, mp_max_into, val_mpint, val_mpint, val_mpint)
FUNC2(val_mpint, mp_min, val_mpint, val_mpint)
FUNC2(val_mpint, mp_max, val_mpint, val_mpint)
FUNC2(void, mp_copy_into, val_mpint, val_mpint)
FUNC4(void, mp_select_into, val_mpint, val_mpint, val_mpint, uint)
FUNC3(void, mp_add_into, val_mpint, val_mpint, val_mpint)
FUNC3(void, mp_sub_into, val_mpint, val_mpint, val_mpint)
FUNC3(void, mp_mul_into, val_mpint, val_mpint, val_mpint)
FUNC2(val_mpint, mp_add, val_mpint, val_mpint)
FUNC2(val_mpint, mp_sub, val_mpint, val_mpint)
FUNC2(val_mpint, mp_mul, val_mpint, val_mpint)
FUNC3(void, mp_and_into, val_mpint, val_mpint, val_mpint)
FUNC3(void, mp_or_into, val_mpint, val_mpint, val_mpint)
FUNC3(void, mp_xor_into, val_mpint, val_mpint, val_mpint)
FUNC3(void, mp_bic_into, val_mpint, val_mpint, val_mpint)
FUNC2(void, mp_copy_integer_into, val_mpint, uint)
FUNC3(void, mp_add_integer_into, val_mpint, val_mpint, uint)
FUNC3(void, mp_sub_integer_into, val_mpint, val_mpint, uint)
FUNC3(void, mp_mul_integer_into, val_mpint, val_mpint, uint)
FUNC4(void, mp_cond_add_into, val_mpint, val_mpint, val_mpint, uint)
FUNC4(void, mp_cond_sub_into, val_mpint, val_mpint, val_mpint, uint)
FUNC3(void, mp_cond_swap, val_mpint, val_mpint, uint)
FUNC2(void, mp_cond_clear, val_mpint, uint)
FUNC4(void, mp_divmod_into, val_mpint, val_mpint, opt_val_mpint, opt_val_mpint)
FUNC2(val_mpint, mp_div, val_mpint, val_mpint)
FUNC2(val_mpint, mp_mod, val_mpint, val_mpint)
FUNC3(val_mpint, mp_nthroot, val_mpint, uint, opt_val_mpint)
FUNC2(void, mp_reduce_mod_2to, val_mpint, uint)
FUNC2(val_mpint, mp_invert_mod_2to, val_mpint, uint)
FUNC2(val_mpint, mp_invert, val_mpint, val_mpint)
FUNC5(void, mp_gcd_into, val_mpint, val_mpint, opt_val_mpint, opt_val_mpint, opt_val_mpint)
FUNC2(val_mpint, mp_gcd, val_mpint, val_mpint)
FUNC2(uint, mp_coprime, val_mpint, val_mpint)
FUNC2(val_modsqrt, modsqrt_new, val_mpint, val_mpint)
/* The modsqrt functions' 'success' pointer becomes a second return value */
FUNC3(val_mpint, mp_modsqrt, val_modsqrt, val_mpint, out_uint)
FUNC1(val_monty, monty_new, val_mpint)
FUNC1(val_mpint, monty_modulus, val_monty)
FUNC1(val_mpint, monty_identity, val_monty)
FUNC3(void, monty_import_into, val_monty, val_mpint, val_mpint)
FUNC2(val_mpint, monty_import, val_monty, val_mpint)
FUNC3(void, monty_export_into, val_monty, val_mpint, val_mpint)
FUNC2(val_mpint, monty_export, val_monty, val_mpint)
FUNC4(void, monty_mul_into, val_monty, val_mpint, val_mpint, val_mpint)
FUNC3(val_mpint, monty_add, val_monty, val_mpint, val_mpint)
FUNC3(val_mpint, monty_sub, val_monty, val_mpint, val_mpint)
FUNC3(val_mpint, monty_mul, val_monty, val_mpint, val_mpint)
FUNC3(val_mpint, monty_pow, val_monty, val_mpint, val_mpint)
FUNC2(val_mpint, monty_invert, val_monty, val_mpint)
FUNC3(val_mpint, monty_modsqrt, val_modsqrt, val_mpint, out_uint)
FUNC3(val_mpint, mp_modpow, val_mpint, val_mpint, val_mpint)
FUNC3(val_mpint, mp_modmul, val_mpint, val_mpint, val_mpint)
FUNC3(val_mpint, mp_modadd, val_mpint, val_mpint, val_mpint)
FUNC3(val_mpint, mp_modsub, val_mpint, val_mpint, val_mpint)
FUNC3(void, mp_lshift_safe_into, val_mpint, val_mpint, uint)
FUNC3(void, mp_rshift_safe_into, val_mpint, val_mpint, uint)
FUNC2(val_mpint, mp_rshift_safe, val_mpint, uint)
FUNC3(void, mp_lshift_fixed_into, val_mpint, val_mpint, uint)
FUNC3(void, mp_rshift_fixed_into, val_mpint, val_mpint, uint)
FUNC2(val_mpint, mp_rshift_fixed, val_mpint, uint)
FUNC1(val_mpint, mp_random_bits, uint)
FUNC2(val_mpint, mp_random_in_range, val_mpint, val_mpint)
/*
* ecc.h functions.
*/
FUNC4(val_wcurve, ecc_weierstrass_curve, val_mpint, val_mpint, val_mpint, opt_val_mpint)
FUNC1(val_wpoint, ecc_weierstrass_point_new_identity, val_wcurve)
FUNC3(val_wpoint, ecc_weierstrass_point_new, val_wcurve, val_mpint, val_mpint)
FUNC3(val_wpoint, ecc_weierstrass_point_new_from_x, val_wcurve, val_mpint, uint)
FUNC1(val_wpoint, ecc_weierstrass_point_copy, val_wpoint)
FUNC1(uint, ecc_weierstrass_point_valid, val_wpoint)
FUNC2(val_wpoint, ecc_weierstrass_add_general, val_wpoint, val_wpoint)
FUNC2(val_wpoint, ecc_weierstrass_add, val_wpoint, val_wpoint)
FUNC1(val_wpoint, ecc_weierstrass_double, val_wpoint)
FUNC2(val_wpoint, ecc_weierstrass_multiply, val_wpoint, val_mpint)
FUNC1(uint, ecc_weierstrass_is_identity, val_wpoint)
/* The output pointers in get_affine all become extra output values */
FUNC3(void, ecc_weierstrass_get_affine, val_wpoint, out_val_mpint, out_val_mpint)
FUNC3(val_mcurve, ecc_montgomery_curve, val_mpint, val_mpint, val_mpint)
FUNC2(val_mpoint, ecc_montgomery_point_new, val_mcurve, val_mpint)
FUNC1(val_mpoint, ecc_montgomery_point_copy, val_mpoint)
FUNC3(val_mpoint, ecc_montgomery_diff_add, val_mpoint, val_mpoint, val_mpoint)
FUNC1(val_mpoint, ecc_montgomery_double, val_mpoint)
FUNC2(val_mpoint, ecc_montgomery_multiply, val_mpoint, val_mpint)
FUNC2(void, ecc_montgomery_get_affine, val_mpoint, out_val_mpint)
FUNC1(boolean, ecc_montgomery_is_identity, val_mpoint)
FUNC4(val_ecurve, ecc_edwards_curve, val_mpint, val_mpint, val_mpint, opt_val_mpint)
FUNC3(val_epoint, ecc_edwards_point_new, val_ecurve, val_mpint, val_mpint)
FUNC3(val_epoint, ecc_edwards_point_new_from_y, val_ecurve, val_mpint, uint)
FUNC1(val_epoint, ecc_edwards_point_copy, val_epoint)
FUNC2(val_epoint, ecc_edwards_add, val_epoint, val_epoint)
FUNC2(val_epoint, ecc_edwards_multiply, val_epoint, val_mpint)
FUNC2(uint, ecc_edwards_eq, val_epoint, val_epoint)
FUNC3(void, ecc_edwards_get_affine, val_epoint, out_val_mpint, out_val_mpint)
/*
* The ssh_hash abstraction. Note the 'consumed', indicating that
* ssh_hash_final puts its input ssh_hash beyond use.
*
* ssh_hash_update is an invention of testcrypt, handled in the real C
* API by the hash object also functioning as a BinarySink.
*/
FUNC1(opt_val_hash, ssh_hash_new, hashalg)
FUNC1(void, ssh_hash_reset, val_hash)
FUNC1(val_hash, ssh_hash_copy, val_hash)
FUNC1(val_string, ssh_hash_digest, val_hash)
FUNC1(val_string, ssh_hash_final, consumed_val_hash)
FUNC2(void, ssh_hash_update, val_hash, val_string_ptrlen)
/*
* The ssh2_mac abstraction. Note the optional ssh_cipher parameter
* to ssh2_mac_new. Also, again, I've invented an ssh2_mac_update so
* you can put data into the MAC.
*/
FUNC2(val_mac, ssh2_mac_new, macalg, opt_val_cipher)
FUNC2(void, ssh2_mac_setkey, val_mac, val_string_ptrlen)
FUNC1(void, ssh2_mac_start, val_mac)
FUNC2(void, ssh2_mac_update, val_mac, val_string_ptrlen)
FUNC1(val_string, ssh2_mac_genresult, val_mac)
FUNC1(val_string_asciz_const, ssh2_mac_text_name, val_mac)
/*
* The ssh_key abstraction. All the uses of BinarySink and
* BinarySource in parameters are replaced with ordinary strings for
* the testing API: new_priv_openssh just takes a string input, and
* all the functions that output key and signature blobs do it by
* returning a string.
*/
FUNC2(val_key, ssh_key_new_pub, keyalg, val_string_ptrlen)
FUNC3(opt_val_key, ssh_key_new_priv, keyalg, val_string_ptrlen, val_string_ptrlen)
FUNC2(opt_val_key, ssh_key_new_priv_openssh, keyalg, val_string_binarysource)
FUNC2(opt_val_string_asciz, ssh_key_invalid, val_key, uint)
FUNC4(void, ssh_key_sign, val_key, val_string_ptrlen, uint, out_val_string_binarysink)
FUNC3(boolean, ssh_key_verify, val_key, val_string_ptrlen, val_string_ptrlen)
FUNC2(void, ssh_key_public_blob, val_key, out_val_string_binarysink)
FUNC2(void, ssh_key_private_blob, val_key, out_val_string_binarysink)
FUNC2(void, ssh_key_openssh_blob, val_key, out_val_string_binarysink)
FUNC1(val_string_asciz, ssh_key_cache_str, val_key)
FUNC1(val_keycomponents, ssh_key_components, val_key)
FUNC2(uint, ssh_key_public_bits, keyalg, val_string_ptrlen)
/*
* Accessors to retrieve the innards of a 'key_components'.
*/
FUNC1(uint, key_components_count, val_keycomponents)
FUNC2(opt_val_string_asciz_const, key_components_nth_name, val_keycomponents, uint)
FUNC2(opt_val_string_asciz_const, key_components_nth_str, val_keycomponents, uint)
FUNC2(opt_val_mpint, key_components_nth_mp, val_keycomponents, uint)
/*
* The ssh_cipher abstraction. The in-place encrypt and decrypt
* functions are wrapped to replace them with versions that take one
* string and return a separate string.
*/
FUNC1(opt_val_cipher, ssh_cipher_new, cipheralg)
FUNC2(void, ssh_cipher_setiv, val_cipher, val_string_ptrlen)
FUNC2(void, ssh_cipher_setkey, val_cipher, val_string_ptrlen)
FUNC2(val_string, ssh_cipher_encrypt, val_cipher, val_string_ptrlen)
FUNC2(val_string, ssh_cipher_decrypt, val_cipher, val_string_ptrlen)
FUNC3(val_string, ssh_cipher_encrypt_length, val_cipher, val_string_ptrlen, uint)
FUNC3(val_string, ssh_cipher_decrypt_length, val_cipher, val_string_ptrlen, uint)
/*
* Integer Diffie-Hellman.
*/
FUNC1(val_dh, dh_setup_group, dh_group)
FUNC2(val_dh, dh_setup_gex, val_mpint, val_mpint)
FUNC1(uint, dh_modulus_bit_size, val_dh)
FUNC2(val_mpint, dh_create_e, val_dh, uint)
FUNC2(boolean, dh_validate_f, val_dh, val_mpint)
FUNC2(val_mpint, dh_find_K, val_dh, val_mpint)
/*
* Elliptic-curve Diffie-Hellman.
*/
FUNC1(val_ecdh, ssh_ecdhkex_newkey, ecdh_alg)
FUNC2(void, ssh_ecdhkex_getpublic, val_ecdh, out_val_string_binarysink)
FUNC2(opt_val_mpint, ssh_ecdhkex_getkey, val_ecdh, val_string_ptrlen)
/*
* RSA key exchange, and also the BinarySource get function
* get_ssh1_rsa_priv_agent, which is a convenient way to make an
* RSAKey for RSA kex testing purposes.
*/
FUNC1(val_rsakex, ssh_rsakex_newkey, val_string_ptrlen)
FUNC1(uint, ssh_rsakex_klen, val_rsakex)
FUNC3(val_string, ssh_rsakex_encrypt, val_rsakex, hashalg, val_string_ptrlen)
FUNC3(opt_val_mpint, ssh_rsakex_decrypt, val_rsakex, hashalg, val_string_ptrlen)
FUNC1(val_rsakex, get_rsa_ssh1_priv_agent, val_string_binarysource)
/*
* Bare RSA keys as used in SSH-1. The construction API functions
* write into an existing RSAKey object, so I've invented an 'rsa_new'
* function to make one in the first place.
*/
FUNC0(val_rsa, rsa_new)
FUNC3(void, get_rsa_ssh1_pub, val_string_binarysource, val_rsa, rsaorder)
FUNC2(void, get_rsa_ssh1_priv, val_string_binarysource, val_rsa)
FUNC2(opt_val_string, rsa_ssh1_encrypt, val_string_ptrlen, val_rsa)
FUNC2(val_mpint, rsa_ssh1_decrypt, val_mpint, val_rsa)
FUNC2(val_string, rsa_ssh1_decrypt_pkcs1, val_mpint, val_rsa)
FUNC1(val_string_asciz, rsastr_fmt, val_rsa)
FUNC1(val_string_asciz, rsa_ssh1_fingerprint, val_rsa)
FUNC3(void, rsa_ssh1_public_blob, out_val_string_binarysink, val_rsa, rsaorder)
FUNC1(int, rsa_ssh1_public_blob_len, val_string_ptrlen)
FUNC2(void, rsa_ssh1_private_blob_agent, out_val_string_binarysink, val_rsa)
/*
* The PRNG type. Similarly to hashes and MACs, I've invented an extra
* function prng_seed_update for putting seed data into the PRNG's
* exposed BinarySink.
*/
FUNC1(val_prng, prng_new, hashalg)
FUNC1(void, prng_seed_begin, val_prng)
FUNC2(void, prng_seed_update, val_prng, val_string_ptrlen)
FUNC1(void, prng_seed_finish, val_prng)
FUNC2(val_string, prng_read, val_prng, uint)
FUNC3(void, prng_add_entropy, val_prng, uint, val_string_ptrlen)
/*
* Key load/save functions, or rather, the BinarySource / strbuf API
* that sits just inside the file I/O versions.
*/
FUNC2(boolean, ppk_encrypted_s, val_string_binarysource, out_opt_val_string_asciz)
FUNC2(boolean, rsa1_encrypted_s, val_string_binarysource, out_opt_val_string_asciz)
FUNC5(boolean, ppk_loadpub_s, val_string_binarysource, out_opt_val_string_asciz, out_val_string_binarysink, out_opt_val_string_asciz, out_opt_val_string_asciz_const)
FUNC4(int, rsa1_loadpub_s, val_string_binarysource, out_val_string_binarysink, out_opt_val_string_asciz, out_opt_val_string_asciz_const)
FUNC4(opt_val_key, ppk_load_s, val_string_binarysource, out_opt_val_string_asciz, opt_val_string_asciz, out_opt_val_string_asciz_const)
FUNC5(int, rsa1_load_s, val_string_binarysource, val_rsa, out_opt_val_string_asciz, opt_val_string_asciz, out_opt_val_string_asciz_const)
FUNC3(val_string, ppk_save_sb, val_key, opt_val_string_asciz, opt_val_string_asciz)
FUNC3(val_string, rsa1_save_sb, val_rsa, opt_val_string_asciz, opt_val_string_asciz)
/*
* Key generation functions.
*/
FUNC3(val_key, rsa_generate, uint, boolean, val_pgc)
FUNC2(val_key, dsa_generate, uint, val_pgc)
FUNC1(opt_val_key, ecdsa_generate, uint)
FUNC1(opt_val_key, eddsa_generate, uint)
FUNC3(val_rsa, rsa1_generate, uint, boolean, val_pgc)
FUNC1(val_pgc, primegen_new_context, primegenpolicy)
FUNC2(opt_val_mpint, primegen_generate, val_pgc, consumed_val_pcs)
FUNC2(val_string, primegen_mpu_certificate, val_pgc, val_mpint)
FUNC1(val_pcs, pcs_new, uint)
FUNC3(val_pcs, pcs_new_with_firstbits, uint, uint, uint)
FUNC3(void, pcs_require_residue, val_pcs, val_mpint, val_mpint)
FUNC2(void, pcs_require_residue_1, val_pcs, val_mpint)
FUNC2(void, pcs_require_residue_1_mod_prime, val_pcs, val_mpint)
FUNC3(void, pcs_avoid_residue_small, val_pcs, uint, uint)
FUNC1(void, pcs_try_sophie_germain, val_pcs)
FUNC1(void, pcs_set_oneshot, val_pcs)
FUNC1(void, pcs_ready, val_pcs)
FUNC4(void, pcs_inspect, val_pcs, out_val_mpint, out_val_mpint, out_val_mpint)
FUNC1(val_mpint, pcs_generate, val_pcs)
FUNC0(val_pockle, pockle_new)
FUNC1(uint, pockle_mark, val_pockle)
FUNC2(void, pockle_release, val_pockle, uint)
FUNC2(pocklestatus, pockle_add_small_prime, val_pockle, val_mpint)
FUNC4(pocklestatus, pockle_add_prime, val_pockle, val_mpint, mpint_list, val_mpint)
FUNC2(val_string, pockle_mpu, val_pockle, val_mpint)
/*
* Miscellaneous.
*/
FUNC2(val_wpoint, ecdsa_public, val_mpint, keyalg)
FUNC2(val_epoint, eddsa_public, val_mpint, keyalg)
FUNC2(val_string, des_encrypt_xdmauth, val_string_ptrlen, val_string_ptrlen)
FUNC2(val_string, des_decrypt_xdmauth, val_string_ptrlen, val_string_ptrlen)
FUNC2(val_string, des3_encrypt_pubkey, val_string_ptrlen, val_string_ptrlen)
FUNC2(val_string, des3_decrypt_pubkey, val_string_ptrlen, val_string_ptrlen)
FUNC3(val_string, des3_encrypt_pubkey_ossh, val_string_ptrlen, val_string_ptrlen, val_string_ptrlen)
FUNC3(val_string, des3_decrypt_pubkey_ossh, val_string_ptrlen, val_string_ptrlen, val_string_ptrlen)
FUNC2(val_string, aes256_encrypt_pubkey, val_string_ptrlen, val_string_ptrlen)
FUNC2(val_string, aes256_decrypt_pubkey, val_string_ptrlen, val_string_ptrlen)
FUNC1(uint, crc32_rfc1662, val_string_ptrlen)
FUNC1(uint, crc32_ssh1, val_string_ptrlen)
FUNC2(uint, crc32_update, uint, val_string_ptrlen)
FUNC2(boolean, crcda_detect, val_string_ptrlen, val_string_ptrlen)
/*
* These functions aren't part of PuTTY's own API, but are additions
* by testcrypt itself for administrative purposes.
*/
FUNC1(void, random_queue, val_string_ptrlen)
FUNC0(uint, random_queue_len)
FUNC2(void, random_make_prng, hashalg, val_string_ptrlen)
FUNC0(void, random_clear)
Reference in New Issue View Git Blame Copy Permalink