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SUSE:SLE-12-SP2:GA
libgcrypt.4929
cavs_driver.pl
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File cavs_driver.pl of Package libgcrypt.4929
#!/usr/bin/env perl # # $Id: cavs_driver.pl 2242 2011-12-16 09:13:12Z smueller $ # # CAVS test driver (based on the OpenSSL driver) # Written by: Stephan Müller <sm@atsec.com> # Werner Koch <wk@g10code.com> (libgcrypt interface) # Tomas Mraz <tmraz@redhat.com> (addition of DSA2) # Copyright (c) atsec information security corporation # # Permission is hereby granted, free of charge, to any person obtaining a copy # of this software and associated documentation files (the "Software"), to deal # in the Software without restriction, including without limitation the rights # to use, copy, modify, merge, publish, distribute, sublicense, and/or sell # copies of the Software, and to permit persons to whom the Software is # furnished to do so, subject to the following conditions: # # The above copyright notice and this permission notice shall be included in # all copies or substantial portions of the Software. # # NO WARRANTY # # BECAUSE THE PROGRAM IS LICENSED FREE OF CHARGE, THERE IS NO WARRANTY # FOR THE PROGRAM, TO THE EXTENT PERMITTED BY APPLICABLE LAW. EXCEPT WHEN # OTHERWISE STATED IN WRITING THE COPYRIGHT HOLDERS AND/OR OTHER PARTIES # PROVIDE THE PROGRAM "AS IS" WITHOUT WARRANTY OF ANY KIND, EITHER EXPRESSED # OR IMPLIED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF # MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. THE ENTIRE RISK AS # TO THE QUALITY AND PERFORMANCE OF THE PROGRAM IS WITH YOU. SHOULD THE # PROGRAM PROVE DEFECTIVE, YOU ASSUME THE COST OF ALL NECESSARY SERVICING, # REPAIR OR CORRECTION. # # IN NO EVENT UNLESS REQUIRED BY APPLICABLE LAW OR AGREED TO IN WRITING # WILL ANY COPYRIGHT HOLDER, OR ANY OTHER PARTY WHO MAY MODIFY AND/OR # REDISTRIBUTE THE PROGRAM AS PERMITTED ABOVE, BE LIABLE TO YOU FOR DAMAGES, # INCLUDING ANY GENERAL, SPECIAL, INCIDENTAL OR CONSEQUENTIAL DAMAGES ARISING # OUT OF THE USE OR INABILITY TO USE THE PROGRAM (INCLUDING BUT NOT LIMITED # TO LOSS OF DATA OR DATA BEING RENDERED INACCURATE OR LOSSES SUSTAINED BY # YOU OR THIRD PARTIES OR A FAILURE OF THE PROGRAM TO OPERATE WITH ANY OTHER # PROGRAMS), EVEN IF SUCH HOLDER OR OTHER PARTY HAS BEEN ADVISED OF THE # POSSIBILITY OF SUCH DAMAGES. # # # test execution instruction: # 1. get the request files from the lab # 2. call each request file from 1. with this program: # $0 <FILE>.rep # 3. send the resulting file <FILE>.rsp to the lab # # # Test should be easily adoptable to other implementations # See the first functions for this task # # Following tests are covered (others may also be covered # but have not been tested) # # AES # [CBC|CFB128|ECB|OFB]GFSbox[128|192|256] # [CBC|CFB128|ECB|OFB]MCT[128|192|256] # [CBC|CFB128|ECB|OFB]VarKey[128|192|256] # [CBC|CFB128|ECB|OFB]KeySbox[128|192|256] # [CBC|CFB128|ECB|OFB]MMT[128|192|256] # [CBC|CFB128|ECB|OFB]VarTxt[128|192|256] # [XTS] (IV in hex string only) # [GCM with external IV] # [CCM] # # RSA # SigGen[15|RSA] # SigVer15 # (SigVerRSA is not applicable for OpenSSL as X9.31 padding # is not done through openssl dgst) # KeyGen RSA X9.31 # # RSA2 # SigVer15 # # SHA # SHA[1|224|256|384|512]ShortMsg # SHA[1|224|256|384|512]LongMsg # SHA[1|224|256|384|512]Monte # # HMAC (SHA - caveat: we only support hash output equal to the block size of # of the hash - we do not support truncation of the hash; to support # that, we first need to decipher the HMAC.req file - see hmac_kat() ) # HMAC # # CMAC AES and TDES # # TDES # T[CBC|CFB??|ECB|OFB]Monte[1|2|3] # T[CBC|CFB??|ECB|OFB]permop # T[CBC|CFB??|ECB|OFB]MMT[1|2|3] # T[CBC|CFB??|ECB|OFB]subtab # T[CBC|CFB??|ECB|OFB]varkey # T[CBC|CFB??|ECB|OFB]invperm # T[CBC|CFB??|ECB|OFB]vartext # WARNING: TDES in CFB and OFB mode problems see below # # ANSI X9.31 RNG # ANSI931_AES128MCT # ANSI931_AES128VST # # DSA2 # PQGGen # PQGVer # KeyPair # SigGen # SigVer # # ECDSA2 # Key Pair # PKV # SigGen # SigVer # # DRBG: # CTR DRBG # Hash DRBG # HMAC DRBG # with and w/o PR # # RC4 (atsec developed tests) # RC4KeyBD # RC4MCT # RC4PltBD # RC4REGT # # # TDES MCT for CFB and OFB: # ------------------------- # The inner loop cannot be handled by this script. If you want to have tests # for these cipher types, implement your own inner loop and add it to # crypto_mct. # # the value $next_source in crypto_mct is NOT set by the standard implementation # of this script. It would need to be set as follows for these two (code take # from fipsdrv.c from libgcrypt - the value input at the end will contain the # the value for $next_source: # # ... inner loop ... # ... # get_current_iv (hd, last_iv, blocklen); # ... encrypt / decrypt (input is the data to be en/decrypted and output is the # result of operation) ... # if (encrypt_mode && (cipher_mode == GCRY_CIPHER_MODE_CFB)) # memcpy (input, last_iv, blocklen); # else if (cipher_mode == GCRY_CIPHER_MODE_OFB) # memcpy (input, last_iv, blocklen); # else if (!encrypt_mode && cipher_mode == GCRY_CIPHER_MODE_CFB) # { # /* Reconstruct the output vector. */ # int i; # for (i=0; i < blocklen; i++) # input[i] ^= output[i]; # } # ... inner loop ends ... # ==> now, the value of input is to be put into $next_source use strict; use warnings; use IPC::Open2; use Getopt::Std; use MIME::Base64; use Math::BigInt; # Contains the command line options my %opt; ################################################################# ##### Central interface functions to the external ciphers ####### ################################################################# # Only these interface routines should be changed in case of # porting to a new cipher library # # For porting to a new library, create implementation of these functions # and then add pointers to the respective implementation of each # function to the given variables. # common encryption/decryption routine # $1 key in hex form (please note for 3DES: even when ede3 for three # independent ciphers is given with the cipher specification, we hand in # either one key for k1 = k2 = k3, two keys which are concatinated for # k1 = k3, k2 independent, or three keys which are concatinated for # k1, k2, k3 independent) # $2 iv in hex form # $3 cipher - the cipher string is defined as specified in the openssl # enc(1ssl) specification for the option "-ciphername" # (e.g. aes-128-cbc or des-ede3-cbc) # $4 encrypt=1/decrypt=0 # $5 de/encrypted data in hex form # return en/decrypted data in hex form my $encdec; # # Derive an RSA key from the given X9.31 parameters. # $1: modulus size # $2: E in hex form # $3: Xp1 in hex form # $4: Xp2 in hex form # $5: Xp in hex form # $6: Xq1 in hex form # $7: Xq2 in hex form # $8: Xq in hex form # return: string with the calculated values in hex format, where each value # is separated from the previous with a \n in the following order: # P\n # Q\n # N\n # D\n my $rsa_derive; # Sign a message with RSA # $1: data to be signed in hex form # $2: Hash algo # $3: Key file in PEM format with the private key # return: digest in hex format my $rsa_sign; # Verify a message with RSA # $1: data to be verified in hex form # $2: hash algo # $3: file holding the public RSA key in PEM format # $4: file holding the signature in binary form # $5: signature in hex # $6: exponent e in hex # $7: private key n in hex # return: 1 == verified / 0 == not verified my $rsa_verify; # generate a new private RSA key with the following properties: # exponent is 65537 # PEM format # $1 key size in bit # $2 keyfile name # return: nothing, but file created my $gen_rsakey; # Creating a hash # $1: Plaintext in hex form # $2: hash type in the form documented in openssl's dgst(1ssl) - e.g. # sha1, sha224, sha256, sha384, sha512 # return: hash in hex form my $hash; # supplying the call to the external cipher implementation # that is being used to keep STDIN and STDOUT open # to maintain the state of the block chaining # $1: cipher # $2: 1=encryption, 0=decryption # $3: buffersize needed for openssl # $4: encryption key in binary form # $5: IV in binary form # return: command line to execute the application my $state_cipher; # the only difference of the DES version is that it implements the inner loop # of the TDES tests my $state_cipher_des; # supplying the call to the external cipher implementation # that is being used to keep STDIN and STDOUT open # to maintain the state of the RNG with its seed # # input holds seed values # $1: cipher key in hex format # $2: DT value in hex format # $3: V value in hex format # # return: command line to execute the application # # the application is expected to deliver random values on STDOUT - the script # reads 128 bits repeatedly where the state of the RNG must be retained # between the reads. The output of the RNG on STDOUT is assumed to be binary. my $state_rng; # Generate an HMAC based on SHAx # $1: Key to be used for the HMAC in hex format # $2: length of the hash to be calculated in bits # $3: Message for which the HMAC shall be calculated in hex format # $4: hash type (1 - SHA1, 224 - SHA224, and so on) # return: calculated HMAC in hex format my $hmac; # Generate an CMAC # $1: cipher name # $2: Key to be used for the CMAC in hex format (for 3DES, the keys are concatenated) # $3: length of the hash to be calculated in bits # $4: Message for which the HMAC shall be calculated in hex format # return: calculated HMAC in hex format my $cmac; # # Generate the P, Q, G, Seed, counter, h (value used to generate g) values # for DSA # $1: modulus size # $2: q size # $3: seed (might be empty string) # return: string with the calculated values in hex format, where each value # is separated from the previous with a \n in the following order: # P\n # Q\n # G\n # Seed\n # counter\n # h my $dsa_pqggen; # Generate the G value from P and Q # for DSA # $1: modulus size # $2: q size # $3: P in hex form # $4: Q in hex form # return: string with the calculated values in hex format, where each value # is separated from the previous with a \n in the following order: # P\n # Q\n # G\n my $dsa_ggen; # # Generate an DSA public key from the provided parameters: # $1: Name of file to create # $2: P in hex form # $3: Q in hex form # $4: G in hex form # $5: Y in hex form my $dsa_genpubkey; # Verify a message with DSA # $1: data to be verified in hex form # $2: file holding the public DSA key in PEM format # $3: R value of the signature # $4: S value of the signature # return: 1 == verified / 0 == not verified my $dsa_verify; # generate a new DSA key with the following properties: # PEM format # $1: modulus size # $2: q size # $3 keyfile name # return: file created with key, string with values of P, Q, G in hex format my $gen_dsakey; # generate a new DSA private key XY parameters in domain: # PEM format # $1: P in hex form # $2: Q in hex form # $3: G in hex form # return: string with values of X, Y in hex format my $gen_dsakey_domain; # Sign a message with DSA # $1: data to be signed in hex form # $2: Key file in PEM format with the private key # return: hash of digest information in hex format with Y, R, S as keys my $dsa_sign; my $rsa_keygen; my $rsa_keygen_kat; # Generate ECDSA key # $1: NIST curve name # return: hash of key information in hex format with d, Qx, Qy as keys my $ecdsa_keygen; # Verify ECDSA public key # $1: NIST curve name # $2: Qx in hex form # $3: Qy in hex form my $ecdsa_key_verify; my $ecdsa_sign; my $ecdsa_verify; # interface with SP800-90A DRBG # $1 cipher - the sign whether prediction resistance is required is visible on # set additional entropy # $2 expected length of output # $3 entropy in hex # $4 nonce in hex # $5 personalization string in hex - if "z", string was empty # $6 1st additional input in hex - if "z", string was empty # $7 2nd additional input in hex - if "z", string was empty # $8 1st additional entropy in hex - if "z", string was empty # $9 2nd additional entropy in hex - if "z", string was empty # return: random value in hex format my $drbg; # interface with GCM AEAD cipher # Note: the interface function is mandated to format the output string # as follows: # * For encryption: # "CT = <ciphertext>\n" # "Tag = <tag>\n" # * For decryption when authentication fails it generates "FAIL\n" # * For decryption when authentication passes it generates "PT = <plaintext>\n" # $1 cipher name # $2 key in hex format # $3 iv in hex format # $4 tag in hex format (empty for encryption) # $5 tag length in bits (expected tag length for encryption, length of $tag for # decryption) # $6 associated data # $7 flag for encryption (== 1) or decryption (== 0) # $8 plaintext or ciphertext my $gcm; # interface with CCM AEAD cipher # Note: the interface function is mandated to format the output string # as follows: # * For encryption: # "CT = <ciphertext>\n" # * For decryption when authentication fails it generates "Result = Fail\n" # * For decryption when authentication passes it generates # "Result = Pass\n" # "PT = <plaintext>\n" # $1 cipher name # $2 key in hex format # $3 nonce in hex format # $5 tag length in bytes (expected tag length for encryption, length of $tag for # decryption) # $6 associated data # $7 flag for encryption (== 1) or decryption (== 0) # $8 plaintext or ciphertext my $ccm; # hack to distinguish between pkcs1 and pss encoding for RSA signature my $pss = 0; ################################################################ ##### OpenSSL interface functions ################################################################ sub openssl_encdec($$$$$) { my $key=shift; my $iv=shift; my $cipher=shift; my $enc = (shift) ? "-e" : "-d"; my $data=shift; # We only invoke the driver with the IV parameter, if we have # an IV, otherwise, we skip it $iv = "-iv $iv" if ($iv); $data=hex2bin($data); my $program="openssl enc -$cipher -nopad -nosalt -K $key $enc $iv"; $program = "rc4 -k $key" if $opt{'R'}; #for ARCFOUR, no IV must be given $data=pipe_through_program($data,$program); return bin2hex($data); } sub openssl_rsa_sign($$$) { my $data = shift; my $cipher = shift; my $keyfile = shift; $data=hex2bin($data); die "ARCFOUR not available for RSA" if $opt{'R'}; $data=pipe_through_program($data, "openssl dgst -$cipher -binary -sign $keyfile"); return bin2hex($data); } sub openssl_rsa_verify($$$$$$$) { my $data = shift; my $cipher = shift; my $keyfile = shift; my $sigfile = shift; $data = hex2bin($data); die "ARCFOUR not available for RSA" if $opt{'R'}; $data = pipe_through_program($data, "openssl dgst -$cipher -binary -verify $keyfile -signature $sigfile"); # Parse through the OpenSSL output information return ($data =~ /OK/); } sub openssl_gen_rsakey($$) { my $keylen = shift; my $file = shift; die "ARCFOUR not available for RSA" if $opt{'R'}; # generating of a key with exponent 0x10001 my @args = ("openssl", "genrsa", "-F4", "-out", "$file", "$keylen"); system(@args) == 0 or die "system @args failed: $?"; die "system @args failed: file $file not created" if (! -f $file); } sub openssl_hash($$) { my $pt = shift; my $cipher = shift; die "ARCFOUR not available for hashes" if $opt{'R'}; my $hash = hex2bin($pt); #bin2hex not needed as the '-hex' already converts it return pipe_through_program($hash, "openssl dgst -$cipher -hex"); } sub openssl_state_cipher($$$$$) { my $cipher = shift; my $encdec = shift; my $bufsize = shift; my $key = shift; my $iv = shift; my $enc = $encdec ? "-e": "-d"; # We only invoke the driver with the IV parameter, if we have # an IV, otherwise, we skip it $iv = "-iv ".bin2hex($iv) if defined($iv); my $out = "openssl enc -'$cipher' $enc -nopad -nosalt -bufsize $bufsize -K ".bin2hex($key)." $iv"; #for ARCFOUR, no IV must be given $out = "rc4 -k " . bin2hex($key) if $opt{'R'}; return $out; } ###### End of OpenSSL interface implementation ############ ########################################################### ###### libgcrypt implementation ########################################################### sub libgcrypt_encdec($$$$$) { my $key=shift; my $iv=shift; my $cipher=shift; my $enc = (shift) ? "encrypt" : "decrypt"; my $data=shift; # We only invoke the driver with the IV parameter, if we have # an IV, otherwise, we skip it $iv = "--iv $iv" if ($iv); my $program="fipsdrv --key $key $iv --algo $cipher $enc"; return pipe_through_program($data,$program); } sub libgcrypt_rsa_derive($$$$$$$$) { my $n = shift; my $e = shift; my $xp1 = shift; my $xp2 = shift; my $xp = shift; my $xq1 = shift; my $xq2 = shift; my $xq = shift; my $sexp; my @tmp; $n = sprintf ("%u", $n); $e = sprintf ("%u", hex($e)); $sexp = "(genkey(rsa(nbits " . sprintf ("%u:%s", length($n), $n) . ")" . "(rsa-use-e " . sprintf ("%u:%s", length($e), $e) . ")" . "(derive-parms" . "(Xp1 #$xp1#)" . "(Xp2 #$xp2#)" . "(Xp #$xp#)" . "(Xq1 #$xq1#)" . "(Xq2 #$xq2#)" . "(Xq #$xq#))))\n"; return pipe_through_program($sexp, "fipsdrv rsa-derive"); } sub libgcrypt_rsa_keygen($) { my $n = shift; my $sexp; $n = sprintf ("%u", $n); $sexp = "(genkey(rsa(nbits " . sprintf ("%u:%s", length($n), $n) . ")))\n"; return pipe_through_program($sexp, "fipsdrv rsa-keygen"); } sub libgcrypt_rsa_keygen_kat($$$$) { my $n = shift; my $e = shift; my $p = shift; my $q = shift; my $sexp; $n = sprintf ("%u", $n); $sexp = "(genkey(rsa(nbits " . sprintf ("%u:%s", length($n), $n) . ")" . "(test-parms" . "(e #$e#)" . "(p #$p#)" . "(q #$q#))))\n"; return pipe_through_program($sexp, "fipsdrv rsa-keygen-kat"); } sub libgcrypt_rsa_sign($$$) { my $data = shift; my $hashalgo = shift; my $keyfile = shift; my $encoding = "--pkcs1"; die "ARCFOUR not available for RSA" if $opt{'R'}; if ($pss) { $encoding = "--pss"; } return pipe_through_program($data, "fipsdrv $encoding --algo $hashalgo --key $keyfile rsa-sign"); } sub libgcrypt_rsa_verify($$$$$$$) { my $data = shift; my $hashalgo = shift; my $keyfile = shift; my $sigfile = shift; my $encoding = "--pkcs1"; die "ARCFOUR not available for RSA" if $opt{'R'}; if ($pss) { $encoding = "--pss"; } $data = pipe_through_program($data, "fipsdrv $encoding --algo $hashalgo --key $keyfile --signature $sigfile rsa-verify"); # Parse through the output information return ($data =~ /GOOD signature/); } sub libgcrypt_gen_rsakey($$) { my $keylen = shift; my $file = shift; die "ARCFOUR not available for RSA" if $opt{'R'}; my @args = ("fipsdrv --keysize $keylen rsa-gen > $file"); system(@args) == 0 or die "system @args failed: $?"; die "system @args failed: file $file not created" if (! -f $file); } sub libgcrypt_hash($$) { my $pt = shift; my $hashalgo = shift; my $program = "fipsdrv --algo $hashalgo digest"; die "ARCFOUR not available for hashes" if $opt{'R'}; return pipe_through_program($pt, $program); } sub libgcrypt_state_cipher($$$$$) { my $cipher = shift; my $enc = (shift) ? "encrypt": "decrypt"; my $bufsize = shift; my $key = shift; my $iv = shift; # We only invoke the driver with the IV parameter, if we have # an IV, otherwise, we skip it $iv = "--iv ".bin2hex($iv) if ($iv); my $program="fipsdrv --binary --key ".bin2hex($key)." $iv --algo '$cipher' --chunk '$bufsize' $enc"; return $program; } sub libgcrypt_state_cipher_des($$$$$) { my $cipher = shift; my $enc = (shift) ? "encrypt": "decrypt"; my $bufsize = shift; my $key = shift; my $iv = shift; # We only invoke the driver with the IV parameter, if we have # an IV, otherwise, we skip it $iv = "--iv ".bin2hex($iv) if ($iv); my $program="fipsdrv --algo '$cipher' --mct-server $enc"; return $program; } sub libgcrypt_state_rng($$$) { my $key = shift; my $dt = shift; my $v = shift; return "fipsdrv --binary --loop --key $key --iv $v --dt $dt random"; } sub libgcrypt_hmac($$$$) { my $key = shift; my $maclen = shift; my $msg = shift; my $hashtype = shift; my $program = "fipsdrv --key $key --algo $hashtype hmac-sha"; return pipe_through_program($msg, $program); } sub libgcrypt_dsa_pqggen($$$) { my $mod = shift; my $qsize = shift; my $seed = shift; my $program = "fipsdrv --keysize $mod --qsize $qsize dsa-pqg-gen"; return pipe_through_program($seed, $program); } sub libgcrypt_dsa_ggen($$$$) { my $mod = shift; my $qsize = shift; my $p = shift; my $q = shift; my $domain = "(domain (p #$p#)(q #$q#))"; my $program = "fipsdrv --keysize $mod --qsize $qsize --key \'$domain\' dsa-g-gen"; return pipe_through_program("", $program); } sub libgcrypt_gen_dsakey($$$) { my $mod = shift; my $qsize = shift; my $file = shift; my $program = "fipsdrv --keysize $mod --qsize $qsize --key $file dsa-gen"; my $tmp; my %ret; die "ARCFOUR not available for DSA" if $opt{'R'}; $tmp = pipe_through_program("", $program); die "dsa key gen failed: file $file not created" if (! -f $file); @ret{'P', 'Q', 'G'} = split(/\n/, $tmp); return %ret; } sub libgcrypt_gen_dsakey_domain($$$) { my $p = shift; my $q = shift; my $g = shift; my $domain = "(domain (p #$p#)(q #$q#)(g #$g#))"; my $program = "fipsdrv --key '$domain' dsa-gen-key"; return pipe_through_program("", $program); } sub libgcrypt_dsa_genpubkey($$$$$) { my $filename = shift; my $p = shift; my $q = shift; my $g = shift; my $y = shift; my $sexp; $sexp = "(public-key(dsa(p #$p#)(q #$q#)(g #$g#)(y #$y#)))"; open(FH, ">", $filename) or die; print FH $sexp; close FH; } sub libgcrypt_dsa_sign($$) { my $data = shift; my $keyfile = shift; my $tmp; my %ret; die "ARCFOUR not available for DSA" if $opt{'R'}; $tmp = pipe_through_program($data, "fipsdrv --key $keyfile dsa-sign"); @ret{'Y', 'R', 'S'} = split(/\n/, $tmp); return %ret; } sub libgcrypt_dsa_verify($$$$) { my $data = shift; my $keyfile = shift; my $r = shift; my $s = shift; my $ret; die "ARCFOUR not available for DSA" if $opt{'R'}; my $sigfile = "$keyfile.sig"; open(FH, ">$sigfile") or die "Cannot create file $sigfile: $?"; print FH "(sig-val(dsa(r #$r#)(s #$s#)))"; close FH; $ret = pipe_through_program($data, "fipsdrv --key $keyfile --signature $sigfile dsa-verify"); unlink ($sigfile); # Parse through the output information return ($ret =~ /GOOD signature/); } sub libgcrypt_ecdsa_keygen($) { my $curve = "NIST " . shift; my $program = "fipsdrv --curve '$curve' ecdsa-gen-key"; my $tmp = pipe_through_program("", $program); my @fields = split(/\n/, $tmp); my $len = length $fields[1]; my %ret; my %xy = ecc_decode_os($fields[1]); $ret{'d'} = $fields[0]; @ret{'Qx', 'Qy'} = @xy{'x', 'y'}; return %ret; } sub libgcrypt_ecdsa_key_verify($$$) { my $curve = "NIST " . shift; my $qx = shift; my $qy = shift; my $q = ecc_encode_os($qx, $qy); my $keyfile = "ecdsa_keyver.tmp.$$"; open(FH, ">$keyfile") or die "Cannot create file $keyfile: $?"; print FH "(public-key(ecc(curve $curve)(q #$q#)))"; close FH; my $program = "fipsdrv --key $keyfile verify-key"; my $tmp = pipe_through_program("", $program); } sub libgcrypt_ecdsa_sign($$) { } sub libgcrypt_ecdsa_verify($$$$) { } sub libgcrypt_drbg($$$$$$$$$$$) { my $cipher = shift; my $drbg_expectedlen = shift; my $drbg_entropy = shift; my $drbg_nonce = shift; my $drbg_pers = shift; my $drbg_addtla = shift; my $drbg_addtlb = shift; my $drbg_entpra = shift; my $drbg_entprb = shift; my $drbg_reseed = shift; my $drbg_addreseed = shift; my $out = ""; my $parameter = ""; my $flags = 0; $drbg_expectedlen = $drbg_expectedlen / 8; if ($cipher =~ /aes128/) { $flags |= (1 << 0 | 1 << 13); } if ($cipher =~ /aes192/) { $flags |= (1 << 0 | 1 << 14); } if ($cipher =~ /aes256/) { $flags |= (1 << 0 | 1 << 15); } if ($cipher =~ /sha1/) { $flags |= 1 << 4; } if ($cipher =~ /sha256/) { $flags |= 1 << 6; } if ($cipher =~ /sha384/) { $flags |= 1 << 7; } if ($cipher =~ /sha512/) { $flags |= 1 << 8; } if ($cipher =~ /hmac/) { $flags |= 1 << 12; } if ($drbg_entpra ne "" && $drbg_entprb ne "") { $flags |= 1 << 28; } $parameter .= " -f $flags"; # test drvier requires concatenated entropy/nonce $drbg_entropy = $drbg_entropy . $drbg_nonce; $parameter .= " -e $drbg_entropy"; $parameter .= " -l $drbg_expectedlen"; if ($drbg_pers ne "z") { $parameter .= " -p $drbg_pers"; } if ($drbg_addtla ne "z") { $parameter .= " -c $drbg_addtla";} if ($drbg_addtlb ne "z") { $parameter .= " -d $drbg_addtlb";} if ($drbg_entpra ne "z" && $drbg_entpra ne "") { $parameter .= " -y $drbg_entpra"; } if ($drbg_entprb ne "z" && $drbg_entprb ne "") { $parameter .= " -z $drbg_entprb"; } if ($drbg_reseed ne "z" && $drbg_reseed ne "") { $parameter .= " -r $drbg_reseed"; } if ($drbg_addreseed ne "z" && $drbg_addreseed ne "") { $parameter .= " -a $drbg_addreseed"; } $out = pipe_through_program("", "/usr/lib/libgcrypt/cavs/drbg_test $parameter 2>/dev/null"); return $out; } ######### End of libgcrypt implementation ################ ################################################################ ###### Kernel Crypto API interface functions ################################################################ my $DIR = "/sys/kernel/debug/kcapi-cavs/"; my $BLKCIPHER = Math::BigInt->new("0x0000000000000001"); my $SHASH = Math::BigInt->new("0x0000000000000002"); my $X931 = Math::BigInt->new("0x0000000000000004"); my $DRBG = Math::BigInt->new("0x0000000000000008"); my $AEAD = Math::BigInt->new("0x0000000000000010"); my $RSA_SIGVER = Math::BigInt->new("0x0000000000000020"); my $TYPE_KEEP = Math::BigInt->new("0x0100000000000000"); my $TYPE_ENC = Math::BigInt->new("0x0200000000000000"); my $TYPE_DEC = Math::BigInt->new("0x0400000000000000"); sub writedata($$) { my $file=shift; my $data=shift; $file = $DIR . $file; open(FH, ">$file") or die "Cannot open file $file"; my $dlen = length($data); my $len = syswrite(FH, $data, $dlen); if($len != $dlen) { die "Cannot write data of length $dlen"; } close(FH); } sub readdata($$) { my $file=shift; my $bytes=shift; my $out; $file = $DIR . $file; open(FH, "<$file") or die "Cannot open file $file"; my $len = sysread(FH, $out, $bytes); if(!defined($len)) { $out=""; } return $out; } sub cryptoapi_setupencdec($$$$$) { my $key=shift; my $iv=shift; my $cipher=shift; my $enc = shift; my $keep = shift; my $type = $BLKCIPHER; # enc / dec yet unhandled - should not matter anyhow if($cipher eq "des-ede3-cbc") { $cipher = "cbc(des3_ede)"; } elsif($cipher eq "des-ede3") { $cipher = "ecb(des3_ede)"; } elsif($cipher =~ /^aes-\d{3}-cbc$/) { $cipher = "cbc(aes)"; } elsif($cipher =~ /^aes-\d{3}-ecb$/) { $cipher = "ecb(aes)"; } elsif($cipher =~ /^aes-\d{3}-xts$/) { $cipher = "xts(aes)"; } else { die "Unknown cipher $cipher for kernel crypto API"; } if($enc) { $type = $type | $TYPE_ENC; } else { $type = $type | $TYPE_DEC; } if($keep) { $type = $type | $TYPE_KEEP; } $type = $type->as_hex; writedata("name", $cipher); writedata("type", $type); writedata("key", hex2bin($key)); # We only invoke the driver with the IV parameter, if we have # an IV, otherwise, we skip it if(defined($iv)) { writedata("iv", hex2bin($iv)); } } sub cryptoapi_encdec($$$$$) { my $key=shift; my $iv=shift; my $cipher=shift; my $enc = shift; my $data = shift; cryptoapi_setupencdec($key, $iv, $cipher, $enc, 0); writedata("data", hex2bin($data)); my $out; $out = readdata("data", 10000); return bin2hex($out); } sub cryptoapi_state_cipher($$$$$) { my $cipher = shift; my $enc = shift; my $bufsize = shift; my $key = bin2hex(shift); my $iv = shift; $iv = bin2hex($iv) if ($iv); cryptoapi_setupencdec($key, $iv, $cipher, $enc, 1); my $file = $DIR . "data"; return "statewrapper.pl $file $bufsize"; } sub cryptoapi_hash($$) { my $pt = shift; my $hashalgo = shift; my $out; writedata("name", $hashalgo); writedata("type", $SHASH->as_hex); writedata("data", hex2bin($pt)); die "ARCFOUR not available for hashes" if $opt{'R'}; $out = readdata("data", 10000); return bin2hex($out); } sub cryptoapi_cmac($$$$) { my $cipher = shift; my $key = shift; my $maclen = shift; my $msg = shift; my $out; if($cipher =~ /tdes/) { $cipher = "cmac(des3_ede)"; } elsif($cipher =~ /aes/) { $cipher = "cmac(aes)"; } else { die "Unknown hashalgo $cipher for kernel crypto API"; } writedata("name", $cipher); writedata("type", $SHASH->as_hex); writedata("key", hex2bin($key)); writedata("data", hex2bin($msg)); $out = readdata("data", 10000); $out = bin2hex($out); $out = substr($out, 0, $maclen * 2); return $out; } sub cryptoapi_hmac($$$$) { my $key = shift; my $maclen = shift; my $msg = shift; my $hashtype = shift; my $out; if($hashtype eq "1") { $hashtype = "hmac(sha1)"; } elsif($hashtype eq "224") { $hashtype = "hmac(sha224)"; } elsif($hashtype eq "256") { $hashtype = "hmac(sha256)"; } elsif($hashtype eq "384") { $hashtype = "hmac(sha384)"; } elsif($hashtype eq "512") { $hashtype = "hmac(sha512)"; } else { die "Unknown hashalgo $hashtype for kernel crypto API"; } writedata("name", $hashtype); writedata("type", $SHASH->as_hex); writedata("key", hex2bin($key)); writedata("data", hex2bin($msg)); $out = readdata("data", 10000); return bin2hex($out); } sub cryptoapi_state_rng($$$) { my $key = shift; my $dt = shift; my $v = shift; my $seed = $v . $key . $dt; $seed=hex2bin($seed); writedata("name", "fips(ansi_cprng)"); writedata("type", $X931->as_hex); writedata("key", $seed); my $file = $DIR . "data"; return "statewrapper.pl $file"; } sub cryptoapi_drbg($$$$$$$$$) { my $cipher = shift; my $drbg_expectedlen = shift; my $drbg_entropy = shift; my $drbg_nonce = shift; my $drbg_pers = shift; my $drbg_addtla = shift; my $drbg_addtlb = shift; my $drbg_entpra = shift; my $drbg_entprb = shift; my $out = ""; $drbg_expectedlen = $drbg_expectedlen / 8; if ($cipher =~ /hash\s+(\w+)/) { $cipher = $1; } if ($cipher =~ /hmac\s+(\w+)/) { $cipher = "hmac_$1"; } if ($cipher =~ /ctr\s+(\w+)/) { $cipher = "ctr_$1"; } if ($drbg_entpra ne "" && $drbg_entprb ne "") { $cipher = "drbg_pr_$cipher"; } else { $cipher = "drbg_nopr_$cipher"; } # test drvier requires concatenated entropy/nonce $drbg_entropy = $drbg_entropy . $drbg_nonce; writedata("name", $cipher); writedata("type", $DRBG->as_hex); writedata("drbg_entropy", hex2bin($drbg_entropy)); if ($drbg_pers ne "z") { writedata("drbg_pers", hex2bin($drbg_pers)); } if ($drbg_addtla ne "z") { writedata("drbg_addtla", hex2bin($drbg_addtla));} if ($drbg_addtlb ne "z") { writedata("drbg_addtlb", hex2bin($drbg_addtlb));} if ($drbg_entpra ne "z" && $drbg_entpra ne "") { writedata("drbg_entpra", hex2bin($drbg_entpra)); } if ($drbg_entprb ne "z" && $drbg_entprb ne "") { writedata("drbg_entprb", hex2bin($drbg_entprb)); } $out = readdata("data", $drbg_expectedlen); $out = bin2hex($out); return $out; } sub _cryptoapi_aead($$$$$$$$) { my $name = shift; my $type = shift; my $key = shift; my $iv = shift; my $aead_authsize = shift; my $assoc = shift; my $data = shift; my $datalen = shift; my $out; writedata("name", $name); writedata("type", $type); writedata("key", hex2bin($key)); writedata("iv", hex2bin($iv)); if ($aead_authsize) { writedata("aead_authsize", $aead_authsize); } if (defined($assoc)) { writedata("aead_assoc", hex2bin($assoc)); } # Who conceives these damn stupid exceptions? if ($name =~ /ccm/) { writedata("data", hex2bin_ccm($data, $datalen)); } else { writedata("data", hex2bin($data)); } $out = readdata("data", 10000); $out = bin2hex($out); return $out; } sub cryptoapi_gcm($$$$$$$$) { my $name = shift; my $key = shift; my $iv = shift; my $tag = shift; my $taglen = shift; my $assoc = shift; my $enc = shift; my $data = shift; my $out = ""; my $type = $AEAD->as_hex; if($enc) { $type = $type | $TYPE_ENC; } else { $type = $type | $TYPE_DEC; } # Hard code the name for kernel crypto API $name = "gcm(aes)"; # Taglen is provided in bits $taglen = $taglen / 8; # Decryption: append tag if ($type & $TYPE_DEC) { $data = $data . $tag; } $out = _cryptoapi_aead($name, $type, $key, $iv, $taglen, $assoc, $data, undef); # Encryption: strip out tag if ($type & $TYPE_ENC) { $tag = substr($out, (-$taglen * 2)); my $ct = substr($out, 0, (length($out) - $taglen * 2)); $out = "CT = $ct\n"; $out = $out . "Tag = $tag\n"; } else { # Output of deadbeef indicates authentication failure if ($out eq "deadbeef") { $out = "FAIL\n"; } else { $out = "PT = $out\n"; } } return $out; } # IV construction: # 1-byte-flag + #bytes-nonce + #bytes-counter = 16 bytes total, since ccm # indicates its "ivsize" = 16 bytes # For example, rfc3610 test vectors used in kernel, have a 13-bytes # nonce. # The first rfc3610 test vector's nonce is, "00000003020100A0A1A2A3A4A5" # Since 13-byte nonce + 1 byte-flag = 14 bytes, leaves 2 bytes for counter. # L = 2, L' = 2 - 1 # So, entered the ccm "iv" as, 01 00000003020100A0A1A2A3A4A5 0000 ( i # put spaces to indicate the components) # # So, now given your test vector's nonce = 99a789af090798, 7 bytes. # So 7 byte nonce + 1 byte flag = 8 bytes, leaving 8 bytes for counter. # L = 8, L' = 8 - 1 # ccm iv entered in aead = 07 99a789af090798 0000000000000000 sub cryptoapi_ccm($$$$$$$) { my $name = shift; my $key = shift; my $nonce = shift; my $taglen = shift; my $assoc = shift; my $enc = shift; my $data = shift; my $datalen = shift; my $out = ""; my $type = $AEAD->as_hex; if($enc) { $type = $type | $TYPE_ENC; } else { $type = $type | $TYPE_DEC; } # IV generation as indicated above my $iv = $nonce; my $L = 16 - 1 - length($iv)/2; my $Lstr = sprintf("%02x", ($L - 1)); $iv = $Lstr . $iv; while ($L) { $iv = $iv . "00"; $L--; } # Hard code the name for kernel crypto API $name = "ccm(aes)"; $out = _cryptoapi_aead($name, $type, $key, $iv,$taglen, $assoc, $data, $datalen); if ($out eq "") { $out = "00"; } if ($type & $TYPE_ENC) { $out = "CT = $out\n"; } else { # Output of deadbeef indicates authentication failure if ($out eq "deadbeef") { $out = "Result = Fail\n"; } else { $out = "Payload = $out\n"; $out = "Result = Pass\n" . $out; } } return $out; } sub cryptoapi_gen_rsakey($$) { return; } sub cryptoapi_rsa_sigver($$$$$$$) { my $msg = shift; my $hash = shift; my $keyfile_unused = shift; my $sigfile_unused = shift; my $sig = shift; my $e = shift; my $n = shift; my $out; writedata("name", $hash); writedata("type", $RSA_SIGVER); writedata("rsa_sig", hex2bin($sig)); writedata("rsa_n", hex2bin($n)); writedata("rsa_e", hex2bin($e)); writedata("data", hex2bin($msg)); $out = readdata("data", 10000); $out = bin2hex($out); if ($out eq "beefbeef") { return 1; } elsif ($out eq "deadbeef") { return 0; } else { warn "Cannot verify RSA signature result $out"; return -1; } } ################################################################ ###### Vendor1 interface functions ################################################################ sub vendor1_encdec($$$$$) { my $key=shift; my $iv=shift; my $cipher=shift; my $enc = (shift) ? "encrypt" : "decrypt"; my $data=shift; $data=hex2bin($data); my $program = "./aes $enc $key"; $data=pipe_through_program($data,$program); return bin2hex($data); } sub vendor1_state_cipher($$$$$) { my $cipher = shift; my $encdec = shift; my $bufsize = shift; my $key = shift; my $iv = shift; $key = bin2hex($key); my $enc = $encdec ? "encrypt": "decrypt"; my $out = "./aes $enc $key $bufsize"; return $out; } ##### No other interface functions below this point ###### ########################################################## ########################################################## # General helper routines # Executing a program by feeding STDIN and retrieving # STDOUT # $1: data string to be piped to the app on STDIN # rest: program and args # returns: STDOUT of program as string sub pipe_through_program($@) { my $in = shift; my @args = @_; my ($CO, $CI); my $pid = open2($CO, $CI, @args); my $out = ""; my $len = length($in); my $first = 1; while (1) { my $rin = ""; my $win = ""; # Output of prog is FD that we read vec($rin,fileno($CO),1) = 1; # Input of prog is FD that we write # check for $first is needed because we can have NULL input # that is to be written to the app if ( $len > 0 || $first) { (vec($win,fileno($CI),1) = 1); $first=0; } # Let us wait for 100ms my $nfound = select(my $rout=$rin, my $wout=$win, undef, 0.1); if ( $wout ) { my $written = syswrite($CI, $in, $len); die "broken pipe" if !defined $written; $len -= $written; substr($in, 0, $written) = ""; if ($len <= 0) { close $CI or die "broken pipe: $!"; } } if ( $rout ) { my $tmp_out = ""; my $bytes_read = sysread($CO, $tmp_out, 4096); $out .= $tmp_out; last if ($bytes_read == 0); } } close $CO or die "broken pipe: $!"; waitpid $pid, 0; return $out; } # # convert ASCII hex to binary input # $1 ASCII hex # return binary representation sub hex2bin($) { my $in = shift; my $len = length($in); $len = 0 if ($in eq "00"); return pack("H$len", "$in"); } sub hex2bin_ccm($$) { my $in = shift; my $len = shift; if (defined($len) && $len ne "") { $len = $len * 2; } else { $len = length($in); } return pack("H$len", "$in"); } # # convert binary input to ASCII hex # $1 binary value # return ASCII hex representation sub bin2hex($) { my $in = shift; my $len = length($in)*2; return unpack("H$len", "$in"); } # $1: binary byte (character) # returns: binary byte with odd parity using low bit as parity bit sub odd_par($) { my $in = ord(shift); my $odd_count=0; for(my $i=1; $i<8; $i++) { $odd_count++ if ($in & (1<<$i)); } my $out = $in; if ($odd_count & 1) { # check if parity is already odd $out &= ~1; # clear the low bit } else { $out |= 1; # set the low bit } return chr($out); } # DES keys uses only the 7 high bits of a byte, the 8th low bit # is the parity bit # as the new key is calculated from oldkey XOR cipher in the MCT test, # the parity is not really checked and needs to be set to match # expectation (OpenSSL does not really care, but the FIPS # test result is expected that the key has the appropriate parity) # $1: arbitrary binary string # returns: string with odd parity set in low bit of each byte sub fix_key_parity($) { my $in = shift; my $out = ""; for (my $i = 0; $i < length($in); $i++) { $out .= odd_par(substr($in, $i, 1)); } return $out; } # Convert ECC point coordinates from "octet-string" format # to separate x and y coordinates # $1: octet-string formatted ECC point (hex string) # returns: hash with fields x and y as hex strings sub ecc_decode_os($) { my $os = shift; $os =~ /^4/ or die "bad ECC octet-string"; $os = substr $os, 1; length($os) % 2 and die "bad ECC octet-string"; my %res; $res{'x'} = substr $os, 0, length($os) / 2; $res{'y'} = substr $os, length($os) / 2; return %res; } # Convert separate ECC point coordinates into the # "octet-string" format # $1: Qx coordinate # $2: Qy coordinate # returns: octet-string that combines the coordinates sub ecc_encode_os($$) { my $qx = shift; my $qy = shift; return "4" . $qx . $qy; } #################################################### # DER/PEM utility functions # Cf. http://www.columbia.edu/~ariel/ssleay/layman.html # Convert unsigned integer to base256 bigint bytes # $1 integer # returns base256 octet string sub int_base256_unsigned($) { my $n = shift; my $out = chr($n & 255); while ($n>>=8) { $out = chr($n & 255) . $out; } return $out; } # Convert signed integer to base256 bigint bytes # $1 integer # returns base256 octet string sub int_base256_signed($) { my $n = shift; my $negative = ($n < 0); if ($negative) { $n = -$n-1; } my $out = int_base256_unsigned($n); if (ord(substr($out, 0, 1)) & 128) { # it's supposed to be positive but has sign bit set, # add a leading zero $out = chr(0) . $out; } if ($negative) { my $neg = chr(255) x length($out); $out ^= $neg; } return $out; } # Length header for specified DER object length # $1 length as integer # return octet encoding for length sub der_len($) { my $len = shift; if ($len <= 127) { return chr($len); } else { my $blen = int_base256_unsigned($len); return chr(128 | length($blen)) . $blen; } } # Prepend length header to object # $1 object as octet sequence # return length header for object followed by object as octets sub der_len_obj($) { my $x = shift; return der_len(length($x)) . $x; } # DER sequence # $* objects # returns DER sequence consisting of the objects passed as arguments sub der_seq { my $seq = join("", @_); return chr(0x30) . der_len_obj($seq); } # DER bitstring # $1 input octets (must be full octets, fractional octets not supported) # returns input encapsulated as bitstring sub der_bitstring($) { my $x = shift; $x = chr(0) . $x; return chr(0x03) . der_len_obj($x); } # base-128-encoded integer, used for object numbers. # $1 integer # returns octet sequence sub der_base128($) { my $n = shift; my $out = chr($n & 127); while ($n>>=7) { $out = chr(128 | ($n & 127)) . $out; } return $out; } # Generating the PEM certificate string # (base-64-encoded DER string) # $1 DER string # returns octet sequence sub pem_cert($) { my $n = shift; my $out = "-----BEGIN PUBLIC KEY-----\n"; $out .= encode_base64($n); $out .= "-----END PUBLIC KEY-----\n"; return $out; } # DER object identifier # $* sequence of id numbers # returns octets sub der_objectid { my $v1 = shift; my $v2 = shift; my $out = chr(40*$v1 + $v2) . join("", map { der_base128($_) } @_); return chr(0x06) . der_len_obj($out); } # DER signed integer # $1 number as octet string (base 256 representation, high byte first) # returns number in DER integer encoding sub der_bigint($) { my $x = shift; return chr(0x02) . der_len_obj($x); } # DER positive integer with leading zeroes stripped # $1 number as octet string (base 256 representation, high byte first) # returns number in DER integer encoding sub der_pos_bigint($) { my $x = shift; # strip leading zero digits $x =~ s/^[\0]+//; # need to prepend a zero if high bit set, since it would otherwise be # interpreted as a negative number. Also needed for number 0. if (!length($x) || ord(substr($x, 0, 1)) >= 128) { $x = chr(0) . $x; } return der_bigint($x); } # $1 number as signed integer # returns number as signed DER integer encoding sub der_int($) { my $n = shift; return der_bigint(int_base256_signed($n)); } # the NULL object constant sub der_null() { return chr(0x05) . chr(0x00); } # Unit test helper # $1 calculated result # $2 expected result # no return value, dies if results differ, showing caller's line number sub der_test($$) { my $actual = bin2hex(shift); my $expected = shift; my @caller = caller; $actual eq $expected or die "Error:line $caller[2]:assertion failed: " ."$actual != $expected\n"; } # Unit testing for the DER encoding functions # Examples from http://www.columbia.edu/~ariel/ssleay/layman.html # No input, no output. Dies if unit tests fail. sub der_unit_test { ## uncomment these if you want to test the test framework #print STDERR "Unit test running\n"; #der_test chr(0), "42"; der_test der_null, "0500"; # length bytes der_test der_len(1), "01"; der_test der_len(127), "7f"; der_test der_len(128), "8180"; der_test der_len(256), "820100"; der_test der_len(65536), "83010000"; # bigint der_test der_bigint(chr(0)), "020100"; der_test der_bigint(chr(128)), "020180"; # -128 der_test der_pos_bigint(chr(128)), "02020080"; # +128 der_test der_pos_bigint(chr(0).chr(0).chr(1)), "020101"; der_test der_pos_bigint(chr(0)), "020100"; # integers (tests base256 conversion) der_test der_int( 0), "020100"; der_test der_int( 127), "02017f"; der_test der_int( 128), "02020080"; der_test der_int( 256), "02020100"; der_test der_int( -1), "0201ff"; der_test der_int( -128), "020180"; der_test der_int( -129), "0202ff7f"; der_test der_int(-65536), "0203ff0000"; der_test der_int(-65537), "0203feffff"; # object encoding, "RSA Security" der_test der_base128(840), "8648"; der_test der_objectid(1, 2, 840, 113549), "06062a864886f70d"; # Combinations der_test der_bitstring("ABCD"), "03050041424344"; der_test der_bitstring(der_null), "0303000500"; der_test der_seq(der_int(0), der_null), "30050201000500"; # The big picture der_test der_seq(der_seq(der_objectid(1, 2, 840, 113549), der_null), der_bitstring(der_seq(der_pos_bigint(chr(5)), der_pos_bigint(chr(3))))), "3017300a06062a864886f70d05000309003006020105020103"; } #################################################### # OpenSSL missing functionality workarounds ## Format of an RSA public key: # 0:d=0 hl=3 l= 159 cons: SEQUENCE # 3:d=1 hl=2 l= 13 cons: SEQUENCE # 5:d=2 hl=2 l= 9 prim: OBJECT :rsaEncryption # 16:d=2 hl=2 l= 0 prim: NULL # 18:d=1 hl=3 l= 141 prim: BIT STRING # [ sequence: INTEGER (n), INTEGER (e) ] # generate RSA pub key in PEM format # $1: filename where PEM key is to be stored # $2: n of the RSA key in hex # $3: e of the RSA key in hex # return: nothing, but file created sub gen_pubrsakey($$$) { my $filename=shift; my $n = shift; my $e = shift; # make sure the DER encoder works ;-) der_unit_test(); # generate DER encoding of the public key my $rsaEncryption = der_objectid(1, 2, 840, 113549, 1, 1, 1); my $der = der_seq(der_seq($rsaEncryption, der_null), der_bitstring(der_seq(der_pos_bigint(hex2bin($n)), der_pos_bigint(hex2bin($e))))); open(FH, ">", $filename) or die; print FH pem_cert($der); close FH; } # generate RSA pub key in PEM format # # This implementation uses "openssl asn1parse -genconf" which was added # in openssl 0.9.8. It is not available in older openssl versions. # # $1: filename where PEM key is to be stored # $2: n of the RSA key in hex # $3: e of the RSA key in hex # return: nothing, but file created sub gen_pubrsakey_using_openssl($$$) { my $filename=shift; my $n = shift; my $e = shift; my $asn1 = "asn1=SEQUENCE:pubkeyinfo [pubkeyinfo] algorithm=SEQUENCE:rsa_alg pubkey=BITWRAP,SEQUENCE:rsapubkey [rsa_alg] algorithm=OID:rsaEncryption parameter=NULL [rsapubkey] n=INTEGER:0x$n e=INTEGER:0x$e"; open(FH, ">$filename.cnf") or die "Cannot create file $filename.cnf: $?"; print FH $asn1; close FH; my @args = ("openssl", "asn1parse", "-genconf", "$filename.cnf", "-noout", "-out", "$filename.der"); system(@args) == 0 or die "system @args failed: $?"; @args = ("openssl", "rsa", "-inform", "DER", "-in", "$filename.der", "-outform", "PEM", "-pubin", "-pubout", "-out", "$filename"); system(@args) == 0 or die "system @args failed: $?"; die "RSA PEM formatted key file $filename was not created" if (! -f $filename); unlink("$filename.cnf"); unlink("$filename.der"); } ############################################ # Test cases # This is the Known Answer Test # $1: the string that we have to put in front of the key # when printing the key # $2: crypto key1 in hex form # $3: crypto key2 in hex form (TDES, undef otherwise) # $4: crypto key3 in hex form (TDES, undef otherwise) # $5: IV in hex form # $6: Plaintext (enc=1) or Ciphertext (enc=0) in hex form # $7: cipher # $8: encrypt=1/decrypt=0 # return: string formatted as expected by CAVS sub kat($$$$$$$$) { my $keytype = shift; my $key1 = shift; my $key2 = shift; my $key3 = shift; my $iv = shift; my $pt = shift; my $cipher = shift; my $enc = shift; my $out = ""; my $ivstr = "IV"; my $ptstr = "PLAINTEXT"; my $ctstr = "CIPHERTEXT"; if ($cipher =~ /xts/) { $ivstr = "i"; $ptstr = "PT"; $ctstr = "CT"; } $out .= "$keytype = $key1\n"; # this is the concardination of the keys for 3DES if (defined($key2)) { if ($keytype ne "KEYs") { $out .= "KEY2 = $key2\n"; } $key1 = $key1 . $key2; } if (defined($key3)) { if ($keytype ne "KEYs") { $out .= "KEY3 = $key3\n"; } $key1= $key1 . $key3; } $out .= "$ivstr = $iv\n" if (defined($iv) && $iv ne ""); if ($enc) { $out .= "$ptstr = $pt\n"; $out .= "$ctstr = " . lc &$encdec($key1, $iv, $cipher, 1, $pt) . "\n"; } else { $out .= "$ctstr = $pt\n"; $out .= "$ptstr = " . lc &$encdec($key1, $iv, $cipher, 0, $pt) . "\n"; } return $out; } # This is the Known Answer Test for Hashes # $1: Plaintext in hex form # $2: hash # $3: hash length (undef if not applicable) # return: string formatted as expected by CAVS sub hash_kat($$$) { my $pt = shift; my $cipher = shift; my $len = shift; my $out = ""; $out .= "Len = $len\n" if (defined($len)); $out .= "Msg = $pt\n"; $pt = "" if(!$len); $out .= "MD = " . &$hash($pt, $cipher) . "\n"; return $out; } # Known Answer Test for HMAC hash # $1: key length in bytes # $2: MAC length in bytes # $3: key for HMAC in hex form # $4: message to be hashed # return: string formatted as expected by CAVS sub hmac_kat($$$$) { my $klen = shift; my $tlen = shift; my $key = shift; my $msg = shift; # XXX this is a hack - we need to decipher the HMAC REQ files in a more # sane way # # This is a conversion table from the expected hash output size # to the assumed hash type - we only define here the block size of # the underlying hashes and do not allow any truncation my %hashtype = ( 20 => 1, 28 => 224, 32 => 256, 48 => 384, 64 => 512 ); die "Hash output size $tlen is not supported!" if(!defined($hashtype{$tlen})); my $out = ""; $out .= "Klen = $klen\n"; $out .= "Tlen = $tlen\n"; $out .= "Key = $key\n"; $out .= "Msg = $msg\n"; if ($msg eq "00") { $msg = ""; } $out .= "Mac = " . lc(&$hmac($key, $tlen, $msg, $hashtype{$tlen})) . "\n"; return $out; } # Known Answer Test for CMAC hash # $1: cipher name # $2: key length in bytes # $3: MAC length in bytes # $4: keytype # $5 through 7 key parts (see kat) # $8: message to be hashed # $9: expected MAC (for CMACVer, otherwise "" or undef) # return: string formatted as expected by CAVS sub cmac_kat($$$$$$$$$) { my $cipher = shift; my $klen = shift; my $tlen = shift; my $keytype = shift; my $key1 = shift; my $key2 = shift; my $key3 = shift; my $msg = shift; my $mac = shift; my $out = ""; $out .= "Klen = $klen\n"; $out .= "Tlen = $tlen\n"; $out .= "$keytype = $key1\n"; # this is the concardination of the keys for 3DES if (defined($key2) && $key2 ne "") { $out .= "Key2 = $key2\n"; $key1 = $key1 . $key2; } if (defined($key3) && $key3 ne "") { $out .= "Key3 = $key3\n"; $key1= $key1 . $key3; } $out .= "Msg = $msg\n"; if ($msg eq "00") { $msg = ""; } if (!defined($mac) || $mac eq "") { $out .= "Mac = " . lc(&$cmac($cipher, $key1, $tlen, $msg)) . "\n"; } else { $out .= "Mac = $mac\n"; my $tmpres = lc(&$cmac($cipher, $key1, $tlen, $msg)); if ($mac eq $tmpres) { $out .= "Result = P\n"; } else { $out .= "Result = F\n"; } } return $out; } # Cipher Monte Carlo Testing # $1: the string that we have to put in front of the key # when printing the key # $2: crypto key1 in hex form # $3: crypto key2 in hex form (TDES, undef otherwise) # $4: crypto key3 in hex form (TDES, undef otherwise) # $5: IV in hex form # $6: Plaintext (enc=1) or Ciphertext (enc=0) in hex form # $7: cipher # $8: encrypt=1/decrypt=0 # return: string formatted as expected by CAVS sub crypto_mct($$$$$$$$) { my $keytype = shift; my $key1 = hex2bin(shift); my $key2 = shift; my $key3 = shift; my $iv = hex2bin(shift); my $source_data = hex2bin(shift); my $cipher = shift; my $enc = shift; my $out = ""; $key2 = hex2bin($key2) if (defined($key2)); $key3 = hex2bin($key3) if (defined($key3)); my $bufsize = length($source_data); # for AES: outer loop 0-99, inner 0-999 based on FIPS compliance tests # for RC4: outer loop 0-99, inner 0-999 based on atsec compliance tests # for DES: outer loop 0-399, inner 0-9999 based on FIPS compliance tests my $ciph = substr($cipher,0,3); my $oloop=100; my $iloop=1000; if ($ciph =~ /des/) {$oloop=400;$iloop=10000;} for (my $i=0; $i<$oloop; ++$i) { if (not ( $ciph =~ /aes/ && $i == 0)) { $out .= "COUNT = $i\n"; } if (defined($key2)) { $out .= "$keytype = ". bin2hex($key1). "\n"; $out .= "KEY2 = ". bin2hex($key2). "\n"; $key1 = $key1 . $key2; } else { $out .= "$keytype = ". bin2hex($key1). "\n"; } if(defined($key3)) { $out .= "KEY3 = ". bin2hex($key3). "\n"; $key1 = $key1 . $key3; } my $keylen = length($key1); $out .= "IV = ". bin2hex($iv) . "\n" if (defined($iv) && $iv ne ""); if ($enc) { $out .= "PLAINTEXT = ". bin2hex($source_data). "\n"; } else { $out .= "CIPHERTEXT = ". bin2hex($source_data). "\n"; } my ($CO, $CI); my $cipher_imp = &$state_cipher($cipher, $enc, $bufsize, $key1, $iv); $cipher_imp = &$state_cipher_des($cipher, $enc, $bufsize, $key1, $iv) if($cipher =~ /des/ && defined($state_cipher_des)); my $pid = open2($CO, $CI, $cipher_imp); my $calc_data = $iv; # CT[j] my $old_calc_data; # CT[j-1] my $old_old_calc_data; # CT[j-2] my $next_source; # TDES inner loop implements logic within driver of libgcrypt if ($cipher =~ /des/ && $opt{'I'} && $opt{'I'} eq 'libgcrypt' ) { # Need to provide a dummy IV in case of ECB mode. my $iv_arg = (defined($iv) && $iv ne "") ? bin2hex($iv) : "00"x(length($source_data)); print $CI "1\n" .$iloop."\n" .bin2hex($key1)."\n" .$iv_arg."\n" .bin2hex($source_data)."\n\n" or die; chomp(my $line = <$CO>); $calc_data = hex2bin($line); chomp($line = <$CO>); $old_calc_data = hex2bin($line); chomp($line = <$CO>); $old_old_calc_data = hex2bin($line); chomp($line = <$CO>); $iv = hex2bin($line) if (defined($iv) && $iv ne ""); chomp($line = <$CO>); $next_source = hex2bin($line); # Skip over empty line. $line = <$CO>; } else { for (my $j = 0; $j < $iloop; ++$j) { if ($cipher =~ /des-ede3-ofb/ || (!$enc && $cipher =~ /des-ede3-cfb/)) { die "Implementation lacks support for TDES OFB and TDES CFB in encryption mode - the problem is that we would need to extract the IV of the last round of encryption which would be the input for the next round - see comments in this script for implementation requirements"; } $old_old_calc_data = $old_calc_data; $old_calc_data = $calc_data; #print STDERR "source_data=", bin2hex($source_data), "\n"; syswrite $CI, $source_data or die $!; my $len = sysread $CO, $calc_data, $bufsize; #my $a = bin2hex($source_data); #my $b = bin2hex($calc_data); #warn "$a $b"; #sleep 1; #print STDERR "len=$len, bufsize=$bufsize\n"; die if $len ne $bufsize; #print STDERR "calc_data=", bin2hex($calc_data), "\n"; if ( (!$enc && $ciph =~ /des/) || $ciph =~ /rc4/ || $cipher =~ /ecb/ || $cipher eq "des-ede3" ) { #TDES in decryption mode, RC4 and ECB mode #have a special rule $source_data = $calc_data; } else { $source_data = $old_calc_data; } } } close $CO; close $CI; waitpid $pid, 0; if ($enc) { $out .= "CIPHERTEXT = ". bin2hex($calc_data). "\n\n"; } else { $out .= "PLAINTEXT = ". bin2hex($calc_data). "\n\n"; } if ( $ciph =~ /aes/ ) { $key1 ^= substr($old_calc_data . $calc_data, -$keylen); #print STDERR bin2hex($key1)."\n"; } elsif ( $ciph =~ /des/ ) { die "Wrong keylen $keylen" if ($keylen != 24); # $nkey needed as $key holds the concatenation of the # old key atm my $nkey = fix_key_parity(substr($key1,0,8) ^ $calc_data); #print STDERR "KEY1 = ". bin2hex($nkey)."\n"; if (substr($key1,0,8) ne substr($key1,8,8)) { #print STDERR "KEY2 recalc: KEY1==KEY3, KEY2 indep. or all KEYs are indep.\n"; $key2 = fix_key_parity((substr($key1,8,8) ^ $old_calc_data)); } else { #print STDERR "KEY2 recalc: KEY1==KEY2==KEY3\n"; $key2 = fix_key_parity((substr($key1,8,8) ^ $calc_data)); } #print STDERR "KEY2 = ". bin2hex($key2)."\n"; if ( substr($key1,0,8) eq substr($key1,16)) { #print STDERR "KEY3 recalc: KEY1==KEY2==KEY3 or KEY1==KEY3, KEY2 indep.\n"; $key3 = fix_key_parity((substr($key1,16) ^ $calc_data)); } else { #print STDERR "KEY3 recalc: all KEYs are independent\n"; $key3 = fix_key_parity((substr($key1,16) ^ $old_old_calc_data)); } #print STDERR "KEY3 = ". bin2hex($key3)."\n"; # reset the first key - concardination happens at # beginning of loop $key1=$nkey; } elsif ($ciph =~ /rc4/ ) { $key1 ^= substr($calc_data, 0, 16); #print STDERR bin2hex($key1)."\n"; } else { die "Test limitation: cipher '$cipher' not supported in Monte Carlo testing"; } if ($cipher =~ /des-ede3-ofb/) { $source_data = $source_data ^ $next_source; } elsif (!$enc && $cipher =~ /des-ede3-cfb/) { #TDES decryption CFB has a special rule $source_data = $next_source; } elsif ( $ciph =~ /rc4/ || $cipher eq "des-ede3" || $cipher =~ /ecb/) { #No resetting of IV as the IV is all zero set initially (i.e. no IV) $source_data = $calc_data; } elsif (! $enc && $ciph =~ /des/ ) { #TDES in decryption mode has a special rule $iv = $old_calc_data; $source_data = $calc_data; } else { $iv = $calc_data; $source_data = $old_calc_data; } } return $out; } # Hash Monte Carlo Testing # $1: Plaintext in hex form # $2: hash # return: string formatted as expected by CAVS sub hash_mct($$) { my $pt = shift; my $cipher = shift; my $out = ""; $out .= "Seed = $pt\n\n"; for (my $j=0; $j<100; ++$j) { print STDERR "DEBUG: hash_mct ($j/99)\r"; $out .= "COUNT = $j\n"; my $md0=$pt; my $md1=$pt; my $md2=$pt; for (my $i=0; $i<1000; ++$i) { #print STDERR "outer loop $j; inner loop $i\n"; my $mi= $md0 . $md1 . $md2; $md0=$md1; $md1=$md2; $md2 = &$hash($mi, $cipher); $md2 =~ s/\n//; } $out .= "MD = $md2\n\n"; $pt=$md2; } print STDERR "\n"; return $out; } # RSA SigGen test # $1: Message to be signed in hex form # $2: Hash algorithm # $3: file name with RSA key in PEM form # return: string formatted as expected by CAVS sub rsa_siggen($$$) { my $data = shift; my $cipher = shift; my $keyfile = shift; my $out = ""; $out .= "SHAAlg = $cipher\n"; $out .= "Msg = $data\n"; $out .= "S = " . &$rsa_sign($data, lc($cipher), $keyfile) . "\n"; return $out; } # RSA SigVer test # $1: Message to be verified in hex form # $2: Hash algoritm # $3: Signature of message in hex form # $4: n of the RSA key in hex in hex form # $5: e of the RSA key in hex in hex form # return: string formatted as expected by CAVS sub rsa_sigver($$$$$) { my $data = shift; my $cipher = shift; my $signature = shift; my $n = shift; my $e = shift; my $out = ""; $out .= "SHAAlg = $cipher\n"; $out .= "e = $e\n"; $out .= "Msg = $data\n"; $out .= "S = $signature\n"; # XXX maybe a secure temp file name is better here # but since it is not run on a security sensitive # system, I hope that this is fine my $keyfile = "rsa_sigver.tmp.$$"; gen_pubrsakey($keyfile, $n, $e); my $sigfile = "$keyfile.sig"; open(FH, ">$sigfile") or die "Cannot create file $sigfile: $?"; print FH hex2bin($signature); close FH; $out .= "Result = " . (&$rsa_verify($data, lc($cipher), $keyfile, $sigfile, $signature, $e, $n) ? "P\n" : "F\n"); unlink($keyfile); unlink($sigfile); return $out; } # RSA X9.31 key generation test # $1 modulus size # $2 e # $3 xp1 # $4 xp2 # $5 Xp # $6 xq1 # $7 xq2 # $8 Xq # return: string formatted as expected by CAVS sub rsa_keygen($$$$$$$$) { my $modulus = shift; my $e = shift; my $xp1 = shift; my $xp2 = shift; my $Xp = shift; my $xq1 = shift; my $xq2 = shift; my $Xq = shift; my $out = ""; my $ret = &$rsa_derive($modulus, $e, $xp1, $xp2, $Xp, $xq1, $xq2, $Xq); my ($P, $Q, $N, $D) = split(/\n/, $ret); $out .= "e = $e\n"; $out .= "xp1 = $xp1\n"; $out .= "xp2 = $xp2\n"; $out .= "Xp = $Xp\n"; $out .= "p = $P\n"; $out .= "xq1 = $xq1\n"; $out .= "xq2 = $xq2\n"; $out .= "Xq = $Xq\n"; $out .= "q = $Q\n"; $out .= "n = $N\n"; $out .= "d = $D\n\n"; return $out; } # X9.31 RNG test # $1 key for the AES cipher # $2 DT value # $3 V value # $4 type ("VST", "MCT") # return: string formatted as expected by CAVS sub rngx931($$$$) { my $key=shift; my $dt=shift; my $v=shift; my $type=shift; my $out = "Key = $key\n"; $out .= "DT = $dt\n"; $out .= "V = $v\n"; my $count = 1; $count = 10000 if ($type eq "MCT"); my $rnd_val = ""; # we read 16 bytes from RNG my $bufsize = 16; my ($CO, $CI); my $rng_imp = &$state_rng($key, $dt, $v); my $pid = open2($CO, $CI, $rng_imp); for (my $i = 0; $i < $count; ++$i) { my $len = sysread $CO, $rnd_val, $bufsize; #print STDERR "len=$len, bufsize=$bufsize\n"; die "len=$len != bufsize=$bufsize" if $len ne $bufsize; #print STDERR "calc_data=", bin2hex($rnd_val), "\n"; } close $CO; close $CI; waitpid $pid, 0; $out .= "R = " . bin2hex($rnd_val) . "\n\n"; return $out; } sub drbg_kat($$$$$$$$$$$) { my $cipher = shift; my $drbg_expectedlen = shift; my $drbg_entropy = shift; my $drbg_nonce = shift; my $drbg_pers = shift; my $drbg_addtla = shift; my $drbg_addtlb = shift; my $drbg_entpra = shift; my $drbg_entprb = shift; my $drbg_reseed = shift; my $drbg_addreseed = shift; my $out = ""; my $ret = &$drbg($cipher, $drbg_expectedlen, $drbg_entropy, $drbg_nonce, $drbg_pers, $drbg_addtla, $drbg_addtlb, $drbg_entpra, $drbg_entprb, $drbg_reseed, $drbg_addreseed); $out = "ReturnedBits = " . $ret; return $out; } sub gcm_kat($$$$$$$$) { my $name = shift; my $key = shift; my $iv = shift; my $tag = shift; my $taglen = shift; my $assoc = shift; my $enc = shift; my $data = shift; if ($data eq "z") { $data = ""; } if ($assoc eq "z") { $assoc = ""; } my $out = "Key = " . $key . "\n"; $out .= "IV = " . $iv . "\n"; if ($enc) { $out .= "PT = " . $data . "\n"; } else { $out .= "CT = " . $data . "\n"; } $out .= "AAD = " . $assoc . "\n"; if (!$enc) { $out .= "Tag = " . $tag . "\n"; } # the GCM callback function is expected to format the output $out .= &$gcm($name, $key, $iv, $tag, $taglen, $assoc, $enc, $data); return $out; } sub ccm_kat($$$$$$$$$) { my $name = shift; my $key = shift; my $nonce = shift; my $taglen = shift; my $assoc = shift; my $enc = shift; my $ccm_global_nonce = shift; my $data = shift; my $datalen = shift; if ($data eq "z") { $data = ""; } if ($assoc eq "z") { $assoc = ""; } my $out = ""; if (!$ccm_global_nonce) { $out .= "Nonce = " . $nonce . "\n"; } $out .= "Adata = " . $assoc . "\n"; if ($enc) { $out .= "Payload = " . $data . "\n"; } else { $out .= "CT = " . $data . "\n"; } if ($assoc eq "00") { $assoc = ""; } # the GCM callback function is expected to format the output $out .= &$ccm($name, $key, $nonce, $taglen, $assoc, $enc, $data, $datalen); return $out; } # DSA PQGen test # $1 modulus size # $2 q size # $3 number of rounds to perform the test # return: string formatted as expected by CAVS sub dsa_pqgen_driver($$$) { my $mod = shift; my $qsize = shift; my $rounds = shift; my $out = ""; for(my $i=0; $i<$rounds; $i++) { my $ret = &$dsa_pqggen($mod, $qsize, ""); my ($P, $Q, $G, $Seed, $c, $H) = split(/\n/, $ret); die "Return value does not contain all expected values of P, Q, Seed, c for dsa_pqggen" if (!defined($P) || !defined($Q) || !defined($Seed) || !defined($c)); # now change the counter to decimal as CAVS wants decimal # counter value although all other is HEX $c = hex($c); $out .= "P = $P\n"; $out .= "Q = $Q\n"; $out .= "domain_parameter_seed = $Seed\n"; $out .= "counter = $c\n\n"; } return $out; } # DSA GGen test # $1 modulus size # $2 q size # $3 p in hex form # $4 q in hex form # return: string formatted as expected by CAVS sub dsa_ggen_driver($$$$) { my $mod = shift; my $qsize = shift; my $p = shift; my $q = shift; my $out = ""; my $ret = &$dsa_ggen($mod, $qsize, $p, $q); my ($P, $Q, $G) = split(/\n/, $ret); die "Return value does not contain all expected values of P, Q, G for dsa_ggen" if (!defined($P) || !defined($Q) || !defined($G)); $out .= "G = $G\n\n"; return $out; } # DSA PQVer test # $1 modulus size # $2 q size # $3 p in hex form # $4 q in hex form # $5 seed in hex form # $6 c decimal counter # return: string formatted as expected by CAVS sub dsa_pqver_driver($$$$$$) { my $mod = shift; my $qsize = shift; my $p = shift; my $q = shift; my $seed = shift; my $c = shift; my $out = ""; my $ret = &$dsa_pqggen($mod, $qsize, $seed); my ($P, $Q, $G, $seed2, $c2, $h2) = split(/\n/, $ret); die "Return value does not contain all expected values of P, Q, G, seed, c for dsa_pqggen" if (!defined($P) || !defined($Q) || !defined($G) || !defined($seed2) || !defined($c2)); $c2 = hex($c2); $out .= "Seed = $seed\n"; $out .= "c = $c\n"; if ($P eq $p && $Q eq $q && $seed eq lc $seed2 && $c eq $c2) { $out .= "Result = P\n\n"; } else { $out .= "Result = F\n\n"; } return $out; } sub hexcomp($$) { my $a = lc shift; my $b = lc shift; if (length $a < length $b) { my $c = $a; $a = $b; $b = $a; } while (length $b < length $a) { $b = "00$b"; } return $a eq $b; } # DSA PQGVer test # $1 modulus size # $2 q size # $3 p in hex form # $4 q in hex form # $5 g in hex form # $6 seed in hex form # $7 c decimal counter # $8 h in hex form # return: string formatted as expected by CAVS sub dsa_pqgver_driver($$$$$$$$) { my $mod = shift; my $qsize = shift; my $p = shift; my $q = shift; my $g = shift; my $seed = shift; my $c = shift; my $h = shift; my $out = ""; my $ret = &$dsa_pqggen($mod, $qsize, $seed); my ($P, $Q, $G, $seed2, $c2, $h2) = split(/\n/, $ret); die "Return value does not contain all expected values of P, Q, G, seed, c, H for dsa_pqggen" if (!defined($P) || !defined($Q) || !defined($G) || !defined($seed2) || !defined($c2) || !defined($h2)); $out .= "Seed = $seed\n"; $out .= "c = $c\n"; $out .= "H = $h\n"; $c2 = hex($c2); if (hexcomp($P, $p) && hexcomp($Q, $q) && hexcomp($G, $g) && hexcomp($seed, $seed2) && $c == $c2 && hex($h) == hex($h2)) { $out .= "Result = P\n\n"; } else { $out .= "Result = F\n\n"; } return $out; } # DSA Keypair test # $1 modulus size # $2 q size # $3 number of rounds to perform the test # return: string formatted as expected by CAVS sub dsa_keypair_driver($$$) { my $mod = shift; my $qsize = shift; my $rounds = shift; my $out = ""; my $tmpkeyfile = "dsa_siggen.tmp.$$"; my %pqg = &$gen_dsakey($mod, $qsize, $tmpkeyfile); $out .= "P = " . $pqg{'P'} . "\n"; $out .= "Q = " . $pqg{'Q'} . "\n"; $out .= "G = " . $pqg{'G'} . "\n\n"; unlink($tmpkeyfile); for(my $i=0; $i<$rounds; $i++) { my $ret = &$gen_dsakey_domain($pqg{'P'}, $pqg{'Q'}, $pqg{'G'}); my ($X, $Y) = split(/\n/, $ret); die "Return value does not contain all expected values of X, Y for gen_dsakey_domain" if (!defined($X) || !defined($Y)); $out .= "X = $X\n"; $out .= "Y = $Y\n\n"; } return $out; } # DSA SigGen test # $1: Message to be signed in hex form # $2: file name with DSA key in PEM form # return: string formatted as expected by CAVS sub dsa_siggen($$) { my $data = shift; my $keyfile = shift; my $out = ""; my %ret = &$dsa_sign($data, $keyfile); $out .= "Msg = $data\n"; $out .= "Y = " . $ret{'Y'} . "\n"; $out .= "R = " . $ret{'R'} . "\n"; $out .= "S = " . $ret{'S'} . "\n"; return $out; } # DSA signature verification # $1 modulus # $2 P # $3 Q # $4 G # $5 Y - public key # $6 r # $7 s # $8 message to be verified # return: string formatted as expected by CAVS sub dsa_sigver($$$$$$$$) { my $modulus = shift; my $p = shift; my $q = shift; my $g = shift; my $y = shift; my $r = shift; my $s = shift; my $msg = shift; my $out = ""; #PQG are already printed - do not print them here $out .= "Msg = $msg\n"; $out .= "Y = $y\n"; $out .= "R = $r\n"; $out .= "S = $s\n"; # XXX maybe a secure temp file name is better here # but since it is not run on a security sensitive # system, I hope that this is fine my $keyfile = "dsa_sigver.tmp.$$"; &$dsa_genpubkey($keyfile, $p, $q, $g, $y); $out .= "Result = " . (&$dsa_verify($msg, $keyfile, $r, $s) ? "P\n" : "F\n"); unlink($keyfile); return $out; } # RSA Keygen RPP test # $1 modulus size # $2 number of rounds to perform the test # return: string formatted as expected by CAVS sub rsa_keygen_driver($$) { my $mod = shift; my $rounds = shift; my $out = ""; for(my $i=0; $i<$rounds; $i++) { my $ret = &$rsa_keygen($mod); my ($e, $p, $q, $n, $d) = split(/\n/, $ret); die "Return value does not contain all expected values of e, p, q, n, d for rsa_keygen" if (!defined($e) || !defined($p) || !defined($q) || !defined($n) || !defined($d)); $out .= "e = $e\n"; $out .= "p = $p\n"; $out .= "q = $q\n"; $out .= "n = $n\n"; if ( $mod/4 > length($d) ) { my $zeros = $mod/4 - length($d); $out .= "d = " . '0' x $zeros . "$d\n\n"; } else { $out .= "d = $d\n\n"; } } return $out; } # RSA RPP Keygen KAT test # $1 modulus size # $2 p in hex form # $3 q in hex form # return: string formatted as expected by CAVS sub rsa_keygen_kat_driver($$$$) { my $mod = shift; my $e = shift; my $p = shift; my $q = shift; my $out = ""; my $ret = &$rsa_keygen_kat($mod, $e, $p, $q); my ($Result) = split(/\n/, $ret); die "Return value does not contain all expected values of Result for rsa_keygen_kat" if (!defined($Result)); $out .= "Result = $Result\n\n"; return $out; } # ECDSA Keypair test # $1 curve name # $2 number of rounds to perform the test # return: string formatted as expected by CAVS sub ecdsa_keypair_driver($$) { my $curve = shift; my $rounds = shift; my $out = ""; for(my $i=0; $i<$rounds; $i++) { my %dxy = &$ecdsa_keygen($curve); $out .= "d = " . $dxy{'d'} . "\n"; $out .= "Qx = " . $dxy{'Qx'} . "\n"; $out .= "Qy = " . $dxy{'Qy'} . "\n\n"; } return $out; } ############################################################## # Parser of input file and generator of result file # sub usage() { print STDERR "Usage: $0 [-R] [-D] [-I name] <CAVS-test vector file> -R execution of ARCFOUR instead of OpenSSL -I NAME Use interface style NAME: openssl OpenSSL (default) libgcrypt Libgcrypt cryptoapi Kernel -D SigGen and SigVer are executed with DSA Please note that the DSA CAVS vectors do not allow distinguishing them from the RSA vectors. As the RSA test is the default, you have to supply this option to apply the DSA logic"; } # Parser of CAVS test vector file # $1: Test vector file # $2: Output file for test results # return: nothing sub parse($$) { my $infile = shift; my $outfile = shift; my $out = ""; # this is my cipher/hash type my $cipher = ""; # Test type # 1 - cipher known answer test # 2 - cipher Monte Carlo test # 3 - hash known answer test # 4 - hash Monte Carlo test # 5 - RSA signature generation # 6 - RSA signature verification # (....) # 19 - ECDSA Key pair generation # 20 - ECDSA Public key verification my $tt = 0; # Variables for tests my $keytype = ""; # we can have "KEY", "KEYs", "KEY1" my $key1 = ""; my $key2 = undef; #undef needed for allowing my $key3 = undef; #the use of them as input variables my $pt = ""; my $enc = 1; my $iv = ""; my $len = undef; #see key2|3 my $n = ""; my $e = ""; my $signature = ""; my $rsa_keyfile = ""; my $dsa_keyfile = ""; my $dt = ""; my $v = ""; my $klen = ""; my $tlen = ""; my $modulus = ""; my $qsize = ""; my $capital_n = 0; my $num = 0; my $capital_p = ""; my $capital_q = ""; my $capital_g = ""; my $capital_y = ""; my $capital_r = ""; my $capital_h = ""; my $c = ""; my $prandom = ""; my $qrandom = ""; my $xp1 = ""; my $xp2 = ""; my $Xp = ""; my $xq1 = ""; my $xq2 = ""; my $Xq = ""; my $drbg_expectedlen = ""; my $drbg_entropy = ""; my $drbg_nonce = ""; my $drbg_pers = ""; my $drbg_addtla = ""; my $drbg_addtlb = ""; my $drbg_entpra = ""; my $drbg_entprb = ""; my $drbg_reseed = ""; my $drbg_addreseed = ""; my $curve = ""; # selected curve for ECC tests, e.g. [P-256] my $qx = ""; my $qy = ""; my $aead_assoc = ""; my $aead_taglen = ""; my $aead_tag = ""; my $cmac_mac = ""; my $plen = ""; # some CCM test vectors have global nonce, some local nonce my $ccm_global_nonce = 0; my $mode = ""; open(IN, "<$infile"); while(<IN>) { my $line = $_; chomp($line); $line =~ s/\r//; my $keylen = ""; # Mode and type check # consider the following parsed line # '# AESVS MCT test data for CBC' # '# TDES Multi block Message Test for CBC' # '# INVERSE PERMUTATION - KAT for CBC' # '# SUBSTITUTION TABLE - KAT for CBC' # '# TDES Monte Carlo (Modes) Test for CBC' # '# "SHA-1 Monte" information for "IBMRHEL5"' # '# "SigVer PKCS#1 Ver 1.5" information for "IBMRHEL5"' # '# "SigGen PKCS#1 Ver 1.5" information for "IBMRHEL5"' # '#RC4VS MCT test data' # avoid false positives from user specified 'for "PRODUCT"' strings my $tmpline = $line; $tmpline =~ s/ for ".*"//; ##### Extract cipher # XXX there may be more - to be added if ($tmpline =~ /^#.*(CBC|ECB|OFB|CFB|SHA-|SigGen|SigVer|RC4VS|ANSI X9\.31|Hash sizes tested|PQGGen|KeyGen|KeyPair|PQGVer|DRBG|XTS|GCM|CCM|CMAC)/) { if ($tmpline =~ /CBC/) { $mode="cbc"; } elsif ($tmpline =~ /ECB/) { $mode="ecb"; } elsif ($tmpline =~ /OFB/) { $mode="ofb"; } elsif ($tmpline =~ /CFB/) { $mode="cfb"; } elsif ($tmpline =~ /XTS/) { $mode="xts"; } elsif ($tmpline =~ /GCM/) { $mode="gcm"; } elsif ($tmpline =~ /CCM/) { $mode="ccm"; } #we do not need mode as the cipher is already clear elsif ($tmpline =~ /SHA-1/) { $cipher="sha1"; } elsif ($tmpline =~ /SHA-224/) { $cipher="sha224"; } elsif ($tmpline =~ /SHA-256/) { $cipher="sha256"; } elsif ($tmpline =~ /SHA-384/) { $cipher="sha384"; } elsif ($tmpline =~ /SHA-512/) { $cipher="sha512"; } elsif ($tmpline =~ /CMAC/) { $mode="cmac"; } #we do not need mode as the cipher is already clear elsif ($tmpline =~ /RC4VS/) { $cipher="rc4"; } elsif ($tmpline =~ /SigGen|SigVer/) { die "Error: X9.31 is not supported" if ($tmpline =~ /X9/); } if ($tmpline =~ /^#.*AESVS/ || $tmpline =~ /^#.*XTS/ || $mode eq "gcm" | $mode eq "ccm") { # AES cipher (part of it) $cipher="aes"; } if ($tmpline =~ /^#.*(TDES|KAT)/) { # TDES cipher (full definition) # the FIPS-140 test generator tool does not produce # machine readable output! if ($mode eq "cbc") { $cipher="des-ede3-cbc"; } if ($mode eq "ecb") { $cipher="des-ede3"; } if ($mode eq "ofb") { $cipher="des-ede3-ofb"; } if ($mode eq "cfb") { $cipher="des-ede3-cfb"; } } # check for RNG if ($tmpline =~ /ANSI X9\.31/) { # change the tmpline to add the type of the # test which is ONLY visible from the file # name :-( if ($infile =~ /MCT\.req/) { $tmpline .= " MCT"; } elsif ($infile =~ /VST\.req/) { $tmpline .= " VST"; } else { die "Unexpected cipher type with $infile"; } } if ($tt == 0) { ##### Identify the test type if ($tmpline =~ /KeyGen - Random Probably Prime Known Answer Test/) { $tt = 24; die "Interface function rsa_keygen_kat for RSA key generation KAT not defined for tested library" if (!defined($rsa_keygen_kat)); } elsif ($tmpline =~ /KeyGen - Random Probably Prime Test/) { $tt = 23; die "Interface function rsa_keygen for RSA key generation not defined for tested library" if (!defined($rsa_keygen)); } elsif ($tmpline =~ /CMACGen/) { $tt = 22; die "Interface function for CMAC testing not defined for tested library" if (!defined($cmac)); } elsif ($tmpline =~ /CMACVer/) { $tt = 21; die "Interface function for CMAC testing not defined for tested library" if (!defined($cmac)); } elsif ($tmpline =~ /CCM/) { $tt = 20; die "Interface function for AES CCM testing not defined for tested library" if (!defined($ccm)); } elsif ($tmpline =~ /GCM/) { $tt = 19; die "Interface function for AES GCM testing not defined for tested library" if (!defined($gcm)); } elsif ($tmpline =~ /DRBG/) { $tt = 18; die "Interface function for SP800-90A DRBG testing not defined for tested library" if (!defined($drbg)); } elsif ($tmpline =~ /PQGVer/) { $tt = 16; die "Interface function for DSA PQGVer testing not defined for tested library" if (!defined($dsa_pqggen)); } elsif ($tmpline =~ /KeyPair/) { $tt = 14; die "Interface function dsa_keygen for DSA key generation not defined for tested library" if (!defined($gen_dsakey_domain)); } elsif ($tmpline =~ /KeyGen RSA \(X9\.31\)/) { $tt = 13; die "Interface function rsa_derive for RSA key generation not defined for tested library" if (!defined($rsa_derive)); } elsif ($tmpline =~ /SigVer/ && $opt{'D'} ) { $tt = 12; die "Interface function dsa_verify or dsa_genpubkey for DSA verification not defined for tested library" if (!defined($dsa_verify) || !defined($dsa_genpubkey)); } elsif ($tmpline =~ /SigGen/ && $opt{'D'}) { $tt = 11; die "Interface function dsa_sign or gen_dsakey for DSA sign not defined for tested library" if (!defined($dsa_sign) || !defined($gen_dsakey)); } elsif ($tmpline =~ /PQGGen/) { $tt = 10; die "Interface function for DSA PQGGen testing not defined for tested library" if (!defined($dsa_pqggen) || !defined($dsa_ggen)); } elsif ($tmpline =~ /Hash sizes tested/) { $tt = 9; die "Interface function hmac for HMAC testing not defined for tested library" if (!defined($hmac)); } elsif ($tmpline =~ /ANSI X9\.31/ && $tmpline =~ /MCT/) { $tt = 8; die "Interface function state_rng for RNG MCT not defined for tested library" if (!defined($state_rng)); } elsif ($tmpline =~ /ANSI X9\.31/ && $tmpline =~ /VST/) { $tt = 7; die "Interface function state_rng for RNG KAT not defined for tested library" if (!defined($state_rng)); } elsif ($tmpline =~ /SigVer/ ) { $tt = 6; if ($tmpline =~ /RSASSA-PSS/) { $pss = 1; } die "Interface function rsa_verify or gen_rsakey for RSA verification not defined for tested library" if (!defined($rsa_verify) || !defined($gen_rsakey)); } elsif ($tmpline =~ /SigGen/ ) { $tt = 5; if ($tmpline =~ /RSASSA-PSS/) { $pss = 1; } die "Interface function rsa_sign or gen_rsakey for RSA sign not defined for tested library" if (!defined($rsa_sign) || !defined($gen_rsakey)); } elsif ($tmpline =~ /Monte|MCT|Carlo/ && $cipher =~ /^sha/) { $tt = 4; die "Interface function hash for Hashing not defined for tested library" if (!defined($hash)); } elsif ($tmpline =~ /Monte|MCT|Carlo/) { $tt = 2; die "Interface function state_cipher for Stateful Cipher operation defined for tested library" if (!defined($state_cipher) && !defined($state_cipher_des)); } elsif ($cipher =~ /^sha/) { $tt = 3; die "Interface function hash for Hashing not defined for tested library" if (!defined($hash)); } else { $tt = 1; die "Interface function encdec for Encryption/Decryption not defined for tested library" if (!defined($encdec)); } } # CCM madness for inconsistent formats if ($tmpline =~ /VTT/ || $tmpline =~ /VADT/ || $tmpline =~ /VPT/) { $ccm_global_nonce = 1; } } # This is needed as ARCFOUR does not operate with an IV $iv = "00000000000000000000000000000000" if ($cipher eq "rc4" && $iv eq "" ); if ($mode eq "cmac" && $tmpline =~ /TDES/) { $cipher = "cmac-tdes"; } if ($mode eq "cmac" && $tmpline =~ /AES/) { $cipher = "cmac-aes"; } # we are now looking for the string # '# Key Length : 256' found in AES # or '# Key Length: AES128' found in XTS # or '[Keylen = 128]' found in AES GCM # or '# AES Keylen: 128' found in AES CCM if ($tmpline =~ /^#\s*Key Length.*?(128|192|256)/ || $line =~ /\[Keylen\s*=\s*(128|192|256)\]/ || $tmpline =~ /^#\s*AES\s*Keylen.*?(128|192|256)/) { if ($cipher eq "aes") { $cipher="$cipher-$1-$mode"; } else { if (!$cipher =~ /aes/) { die "Error: Key length $1 given for cipher $cipher which is unexpected"; } } } # Get the test data if ($line =~ /^(KEY|KEY1|Key|Key1)\s*=\s*(.*)/) { # found in ciphers and RNG # CCM sets keys globally #die "KEY seen twice - input file crap" if ($key1 ne ""); $keytype=$1; $key1=$2; $key1 =~ s/\s//g; #replace potential white spaces #CCM sets it globally if ($cipher =~ /ccm/) { $out .= $line . "\n"; } } elsif ($line =~ /^(KEYs)\s*=\s*(.*)/) { # found in ciphers and RNG die "KEY seen twice - input file crap" if ($key1 ne ""); $keytype=$1; $key1=$2; $key1 =~ s/\s//g; #replace potential white spaces $key2 = $key1; $key3 = $key1; } elsif ($line =~ /^(KEY2|Key2)\s*=\s*(.*)/) { # found in TDES die "First key not set, but got already second key - input file crap" if ($key1 eq ""); die "KEY2 seen twice - input file crap" if (defined($key2)); $key2=$2; $key2 =~ s/\s//g; #replace potential white spaces } elsif ($line =~ /^(KEY3|Key3)\s*=\s*(.*)/) { # found in TDES die "Second key not set, but got already third key - input file crap" if ($key2 eq ""); die "KEY3 seen twice - input file crap" if (defined($key3)); $key3=$2; $key3 =~ s/\s//g; #replace potential white spaces } elsif ($line =~ /^IV\s*=\s*(.*)/) { # found in ciphers die "IV seen twice - input file crap" if ($iv ne ""); $iv=$1; $iv =~ s/\s//g; #replace potential white spaces } elsif ($line =~ /^i\s*=\s*(.*)/) { # found in XTS (the tweak) die "Tweak seen twice - input file crap" if ($iv ne ""); $iv=$1; $iv =~ s/\s//g; #replace potential white spaces } elsif ($line =~ /^Nonce\s*=\s*(.*)/) { # found in CCM / DRBG my $tmpval = $1; if ($cipher =~ /ccm/) { # some CCM vectors set nonce globally $iv=$tmpval; $iv =~ s/\s//g; #replace potential white spaces if ($ccm_global_nonce) { $out .= $line . "\n"; } } else { $drbg_nonce=$tmpval; $out .= $line . "\n"; } } elsif ($line =~ /^PLAINTEXT\s*=\s*(.*)/ || $line =~ /^PT\s*=\s*(.*)/ || $line =~ /^Payload\s*=\s*(.*)/) { # found in ciphers if ( $1 !~ /\?/ ) { #only use it if there is valid hex data die "PLAINTEXT/CIPHERTEXT seen twice - input file crap" if ($pt ne ""); $pt=$1; $pt =~ s/\s//g; #replace potential white spaces if ($pt eq "") { $pt = "z"; } $enc=1; } } elsif ($line =~ /^CIPHERTEXT\s*=\s*(.*)/ || $line =~ /^CT\s*=\s*(.*)/) { # found in ciphers if ( $1 !~ /\?/ ) { #only use it if there is valid hex data die "PLAINTEXT/CIPHERTEXT seen twice - input file crap" if ($pt ne ""); $pt=$1; $pt =~ s/\s//g; #replace potential white spaces if ($pt eq "") { $pt = "z"; } $enc=0; } } elsif ($line =~ /^Len\s*=\s*(.*)/) { # found in hashs $len=$1; } elsif ($line =~ /^(Msg|Seed)\s*=\s*(.*)/) { # found in hashs die "Msg/Seed seen twice - input file crap" if ($pt ne ""); $pt=$2; } elsif ($line =~ /^Mac\s*=\s*(.*)/) { # found in CMAC die "Mac seen twice - input file crap" if ($cmac_mac ne ""); $cmac_mac = $1; } elsif ($line =~ /^\[A.2.1\s.*\]$/) { # found in DSA2 PQGGen request $out .= $line . "\n"; # print it if ($tt == 10) { # now generate G from PQ $tt = 15; } } elsif ($line =~ /^\[A.2.2\s.*\]$/) { # found in DSA2 PQGVer request $out .= $line . "\n"; # print it if ($tt == 16) { # now verify PQG $tt = 17; } } elsif ($line =~ /^\[mod\s*=\s*L=([0-9]*),\s*N=([0-9]*).*\]$/) { # found in DSA2 requests $modulus = $1; $qsize = $2; $out .= $line . "\n\n"; # print it # clear eventual PQG $capital_p = ""; $capital_q = ""; $capital_g = ""; # generate the private key with given bit length now # as we have the required key length in bit if ($tt == 11) { $dsa_keyfile = "dsa_siggen.tmp.$$"; my %pqg = &$gen_dsakey($modulus, $qsize, $dsa_keyfile); $out .= "P = " . $pqg{'P'} . "\n"; $out .= "Q = " . $pqg{'Q'} . "\n"; $out .= "G = " . $pqg{'G'} . "\n\n"; } } elsif ($line =~ /^\[mod\s*=\s*(.*)\]$/) { # found in RSA requests $modulus = $1; $out .= $line . "\n\n"; # print it # generate the private key with given bit length now # as we have the required key length in bit if ( $tt == 5 ) { # XXX maybe a secure temp file name is better here # but since it is not run on a security sensitive # system, I hope that this is fine $rsa_keyfile = "rsa_siggen.tmp.$$"; &$gen_rsakey($modulus, $rsa_keyfile); my $modulus = pipe_through_program("", "openssl rsa -pubout -modulus -in $rsa_keyfile"); $modulus =~ s/Modulus=(.*?)\s(.|\s)*/$1/; $out .= "n = $modulus\n"; $out .= "\ne = 10001\n" } } elsif ($line =~ /^\[([PKB]-[0-9]+)\]$/) { # curve selection in ECDSA requests $curve = $1; $out .= $line . "\n"; } elsif ($line =~ /^\[([PKB]-[0-9]+),(SHA-[0-9]+)\]$/) { # curve + hash selection in ECDSA requests $curve = $1; $cipher = $2; $out .= $line . "\n"; } elsif ($line =~ /^SHAAlg\s*=\s*(.*)/) { #found in RSA requests $cipher=$1; } elsif($line =~ /^n\s*=\s*(.*)/) { # found in RSA requests $out .= $line . "\n"; $n=$1; } elsif ($line =~ /^e\s*=\s*(.*)/) { # found in RSA requests $e=$1; if ($tt == 24) { $out .= $line . "\n"; # print it } } elsif ($line =~ /^S\s*=\s*(.*)/) { # found in RSA requests die "S seen twice - input file crap" if ($signature ne ""); $signature=$1; } elsif ($line =~ /^DT\s*=\s*(.*)/) { # X9.31 RNG requests die "DT seen twice - check input file" if ($dt ne ""); $dt=$1; } elsif ($line =~ /^V\s*=\s*(.*)/) { # X9.31 RNG requests die "V seen twice - check input file" if ($v ne ""); $v=$1; } elsif ($line =~ /^Klen\s*=\s*(.*)/) { # HMAC requests die "Klen seen twice - check input file" if ($klen ne ""); $klen=$1; } elsif ($line =~ /^Tlen\s*=\s*(\d+)/ || $line =~ /\s+Tlen\s*=\s*(\d+)/ || $line =~ /^\[Tlen\s*=\s*(\d+)/) { # HMAC RNG CCM # CCM sets this globally #die "Tlen seen twice - check input file" if ($tlen ne ""); $tlen=$1; if ($cipher =~ /ccm/) { $out .= $line . "\n"; } } elsif ($line =~ /^\[Plen\s*=\s*(\d+)/) { $out .= $line . "\n"; $plen = $1; } elsif ($line =~ /^N\s*=\s*(.*)/) { #DSA KeyPair die "N seen twice - check input file" if ($capital_n); $capital_n = $1; } elsif ($line =~ /^Num\s*=\s*(.*)/) { #DSA PQGGen die "Num seen twice - check input file" if ($num); $num = $1; } elsif ($line =~ /^P\s*=\s*(.*)/) { #DSA SigVer die "P seen twice - check input file" if ($capital_p); $capital_p = $1; $out .= $line . "\n"; # print it } elsif ($line =~ /^Q\s*=\s*(.*)/) { #DSA SigVer die "Q seen twice - check input file" if ($capital_q); $capital_q = $1; $out .= $line . "\n"; # print it } elsif ($line =~ /^G\s*=\s*(.*)/) { #DSA SigVer die "G seen twice - check input file" if ($capital_g); $capital_g = $1; $out .= $line . "\n"; # print it } elsif ($line =~ /^Y\s*=\s*(.*)/) { #DSA SigVer die "Y seen twice - check input file" if ($capital_y); $capital_y = $1; } elsif ($line =~ /^R\s*=\s*(.*)/) { #DSA SigVer die "R seen twice - check input file" if ($capital_r); $capital_r = $1; } elsif ($line =~ /^H\s*=\s*(.*)/) { #DSA PQGVer die "H seen twice - check input file" if ($capital_h); $capital_h = $1; } elsif ($line =~ /^c\s*=\s*(.*)/) { #DSA PQGVer die "c seen twice - check input file" if ($c); $c = $1; } elsif ($line =~ /^xp1\s*=\s*(.*)/) { #RSA key gen die "xp1 seen twice - check input file" if ($xp1); $xp1 = $1; } elsif ($line =~ /^xp2\s*=\s*(.*)/) { #RSA key gen die "xp2 seen twice - check input file" if ($xp2); $xp2 = $1; } elsif ($line =~ /^Xp\s*=\s*(.*)/) { #RSA key gen die "Xp seen twice - check input file" if ($Xp); $Xp = $1; } elsif ($line =~ /^xq1\s*=\s*(.*)/) { #RSA key gen die "xq1 seen twice - check input file" if ($xq1); $xq1 = $1; } elsif ($line =~ /^xq2\s*=\s*(.*)/) { #RSA key gen die "xq2 seen twice - check input file" if ($xq2); $xq2 = $1; } elsif ($line =~ /^Xq\s*=\s*(.*)/) { #RSA key gen die "Xq seen twice - check input file" if ($Xq); $Xq = $1; } elsif ($line =~ /^prandom\s*=\s*(.*)/) { #RSA key gen KAT die "prandom seen twice - check input file" if ($prandom); $prandom = $1; $out .= $line . "\n"; # print it } elsif ($line =~ /^qrandom\s*=\s*(.*)/) { #RSA key gen KAT die "qrandom seen twice - check input file" if ($qrandom); $qrandom = $1; $out .= $line . "\n"; # print it } elsif ($tt == 24 && $line =~ /^ / && $qrandom eq "") { #RSA key gen KAT $qrandom = "00"; $out .= $line . "\n"; # print it } elsif ($line =~ /^Qx\s*=\s*([a-fA-F0-9]+)/) { # ECDSA public key die "Qx seen twice - check input file" if ($qx); $qx = $1; } elsif ($line =~ /^Qy\s*=\s*([a-fA-F0-9]+)/) { # ECDSA public key die "Qy seen twice - check input file" if ($qy); $qy = $1; } # DRBG types elsif ($line =~ /^\[SHA-1\]/) { $cipher="sha1"; $out .= $line . "\n";} elsif ($line =~ /^\[SHA-224\]/) { $cipher="sha224"; $out .= $line . "\n";} elsif ($line =~ /^\[SHA-256\]/) { $cipher="sha256"; $out .= $line . "\n";} elsif ($line =~ /^\[SHA-384\]/) { $cipher="sha384"; $out .= $line . "\n";} elsif ($line =~ /^\[SHA-512\]/) { $cipher="sha512"; $out .= $line . "\n";} elsif ($line =~ /^\[AES-128/) { $cipher="aes128"; $out .= $line . "\n";} elsif ($line =~ /^\[AES-192/) { $cipher="aes192"; $out .= $line . "\n";} elsif ($line =~ /^\[AES-256/) { $cipher="aes256"; $out .= $line . "\n";} elsif ($line =~ /^\[ReturnedBitsLen\s*=\s*(.*)]/) { $drbg_expectedlen = $1; $out .= $line . "\n";} elsif ($line =~ /^EntropyInput\s*=\s*(.*)/) { $drbg_entropy=$1; $out .= $line . "\n";} elsif ($line =~ /^PersonalizationString\s*=\s*(.*)/) { $drbg_pers=$1; if ($drbg_pers eq "") { $drbg_pers = "z"; } $out .= $line . "\n"; } elsif ($line =~ /^AdditionalInput\s*=\s*(.*)/) { if ($drbg_addtla eq "") { $drbg_addtla=$1; if ($drbg_addtla eq "") { $drbg_addtla = "z"; } } else { $drbg_addtlb=$1; if ($drbg_addtlb eq "") { $drbg_addtlb = "z"; } } $out .= $line . "\n"; } elsif ($line =~ /^EntropyInputPR\s*=\s*(.*)/) { if ($drbg_entpra eq "") { $drbg_entpra=$1; if ($drbg_entpra eq "") { $drbg_entpra = "z"; } } else { $drbg_entprb=$1; if ($drbg_entprb eq "") { $drbg_entprb = "z"; } } $out .= $line . "\n"; } elsif ($line =~ /^EntropyInputReseed\s*=\s*(.*)/) { if ($drbg_reseed eq "") { $drbg_reseed=$1; if ($drbg_reseed eq "") { $drbg_reseed = "z"; } } $out .= $line . "\n"; } elsif ($line =~ /^AdditionalInputReseed\s*=\s*(.*)/) { if ($drbg_addreseed eq "") { $drbg_addreseed=$1; if ($drbg_addreseed eq "") { $drbg_addreseed = "z"; } } $out .= $line . "\n"; } # AEAD GCM / CCM elsif ($line =~ /^AAD\s*=\s*(.*)/ || $line =~ /^Adata\s*=\s*(.*)/) { die "AAD seen twice - check input file" if ($aead_assoc); $aead_assoc = $1; if ($aead_assoc eq "") { $aead_assoc = "z"; } } elsif ($line =~ /^\[Taglen\s*=\s*(.*)\]/) { $aead_taglen = $1; $out .= $line . "\n"; } elsif ($line =~ /^Tag\s*=\s*(.*)/) { die "Tag seen twice - check input file" if ($aead_tag); $aead_tag = $1; if ($aead_tag eq "") { $aead_tag = "z"; } } else { $out .= $line . "\n"; } # call tests if all input data is there if ($tt == 1) { if ($key1 ne "" && $pt ne "" && $cipher ne "") { $out .= kat($keytype, $key1, $key2, $key3, $iv, $pt, $cipher, $enc); $keytype = ""; $key1 = ""; $key2 = undef; $key3 = undef; $iv = ""; $pt = ""; } } elsif ($tt == 2) { if ($key1 ne "" && $pt ne "" && $cipher ne "") { $out .= crypto_mct($keytype, $key1, $key2, $key3, $iv, $pt, $cipher, $enc); $keytype = ""; $key1 = ""; $key2 = undef; $key3 = undef; $iv = ""; $pt = ""; } } elsif ($tt == 3) { if ($pt ne "" && $cipher ne "") { $out .= hash_kat($pt, $cipher, $len); $pt = ""; $len = undef; } } elsif ($tt == 4) { if ($pt ne "" && $cipher ne "") { $out .= hash_mct($pt, $cipher); $pt = ""; } } elsif ($tt == 5) { if ($pt ne "" && $cipher ne "" && $rsa_keyfile ne "") { $out .= rsa_siggen($pt, $cipher, $rsa_keyfile); $pt = ""; } } elsif ($tt == 6) { if ($pt ne "" && $cipher ne "" && $signature ne "" && $n ne "" && $e ne "") { $out .= rsa_sigver($pt, $cipher, $signature, $n, $e); $pt = ""; $signature = ""; } } elsif ($tt == 7 ) { if ($key1 ne "" && $dt ne "" && $v ne "") { $out .= rngx931($key1, $dt, $v, "VST"); $key1 = ""; $dt = ""; $v = ""; } } elsif ($tt == 8 ) { if ($key1 ne "" && $dt ne "" && $v ne "") { $out .= rngx931($key1, $dt, $v, "MCT"); $key1 = ""; $dt = ""; $v = ""; } } elsif ($tt == 9) { if ($klen ne "" && $tlen ne "" && $key1 ne "" && $pt ne "") { $out .= hmac_kat($klen, $tlen, $key1, $pt); $key1 = ""; $tlen = ""; $klen = ""; $pt = ""; } } elsif ($tt == 10) { if ($modulus ne "" && $qsize ne "" && $num > 0) { $out .= dsa_pqgen_driver($modulus, $qsize, $num); $num = 0; } } elsif ($tt == 11) { if ($pt ne "" && $dsa_keyfile ne "") { $out .= dsa_siggen($pt, $dsa_keyfile); $pt = ""; } } elsif ($tt == 12) { if ($modulus ne "" && $capital_p ne "" && $capital_q ne "" && $capital_g ne "" && $capital_y ne "" && $capital_r ne "" && $signature ne "" && $pt ne "") { $out .= dsa_sigver($modulus, $capital_p, $capital_q, $capital_g, $capital_y, $capital_r, $signature, $pt); # We do not clear the domain values PQG and # the modulus value as they # are specified only once in a file # and we do not need to print them as they # are already printed above $capital_y = ""; $capital_r = ""; $signature = ""; $pt = ""; } } elsif ($tt == 13) { if($modulus ne "" && $e ne "" && $xp1 ne "" && $xp2 ne "" && $Xp ne "" && $xq1 ne "" && $xq2 ne "" && $Xq ne "") { $out .= rsa_keygen($modulus, $e, $xp1, $xp2, $Xp, $xq1, $xq2, $Xq); $e = ""; $xp1 = ""; $xp2 = ""; $Xp = ""; $xq1 = ""; $xq2 = ""; $Xq = ""; } } elsif ($tt == 14) { if ($modulus ne "" && $qsize ne "" && $capital_n > 0) { $out .= dsa_keypair_driver($modulus, $qsize, $capital_n); $capital_n = 0; } } elsif ($tt == 15) { if ($modulus ne "" && $qsize ne "" && $capital_p ne "" && $capital_q ne "") { $out .= dsa_ggen_driver($modulus, $qsize, $capital_p, $capital_q); $capital_p = ""; $capital_q = ""; $num--; } } elsif ($tt == 16) { if ($modulus ne "" && $qsize ne "" && $capital_p ne "" && $capital_q ne "" && $pt ne "" && $c ne "") { $out .= dsa_pqver_driver($modulus, $qsize, $capital_p, $capital_q, $pt, $c); $capital_p = ""; $capital_q = ""; $pt = ""; $c = ""; } } elsif ($tt == 17) { if ($modulus ne "" && $qsize ne "" && $capital_p ne "" && $capital_q ne "" && $capital_g ne "" && $pt ne "" && $c ne "" && $capital_h ne "") { $out .= dsa_pqgver_driver($modulus, $qsize, $capital_p, $capital_q, $capital_g, $pt, $c, $capital_h); $capital_p = ""; $capital_q = ""; $capital_g = ""; $pt = ""; $c = ""; $capital_h = ""; } } elsif ($tt == 18) { if ($cipher ne "" && $drbg_expectedlen ne "" && $drbg_entropy ne "" && $drbg_nonce ne "" && $drbg_pers ne "" && $drbg_addtla ne "" && $drbg_addtlb ne "") { if ($drbg_entpra ne "" && $drbg_entprb eq "") { next; } if ($drbg_reseed ne "" && $drbg_addreseed eq "") { next; } my $tmpcipher = $cipher; if ($infile =~ /HMAC_DRBG\.req/) { $tmpcipher = "hmac $tmpcipher"; } elsif ($infile =~ /Hash_DRBG\.req/) { $tmpcipher = "hash $tmpcipher"; } elsif ($infile =~ /CTR_DRBG\.req/) { $tmpcipher = "ctr $tmpcipher"; } else { die "unknown DRBG input file $infile"; } $out .= drbg_kat($tmpcipher, $drbg_expectedlen, $drbg_entropy, $drbg_nonce, $drbg_pers, $drbg_addtla, $drbg_addtlb, $drbg_entpra, $drbg_entprb, $drbg_reseed, $drbg_addreseed); $drbg_entropy = ""; $drbg_nonce = ""; $drbg_pers = ""; $drbg_addtla = ""; $drbg_addtlb = ""; $drbg_entpra = ""; $drbg_entprb = ""; $drbg_reseed = ""; $drbg_addreseed = ""; } } elsif ($tt == 19) { if ($cipher ne "" && $key1 ne "" && $iv ne "" && $pt ne "" && $aead_taglen ne "" && $aead_assoc ne "") { if (!$enc) { if ($aead_tag eq "") { next; } } $out .= gcm_kat($cipher, $key1, $iv, $aead_tag, $aead_taglen, $aead_assoc, $enc, $pt); #taglen is not reset $key1 = ""; $iv = ""; $pt = ""; $aead_assoc = ""; $aead_tag = ""; } } elsif ($tt == 20) { if ($cipher ne "" && $key1 ne "" && $iv ne "" && $pt ne "" && $tlen ne "" && $aead_assoc ne "") { $out .= ccm_kat($cipher, $key1, $iv, $tlen, $aead_assoc, $enc, $ccm_global_nonce, $pt, $plen); #tlen is not reset # key is not reset # the nonce is not reset $pt = ""; $aead_assoc = ""; } } elsif ($tt == 21) { if ($cipher ne "" && $klen ne "" && $tlen ne "" && $keytype ne "" && $key1 ne "" && $pt ne "" && $cmac_mac ne "" ) { $out .= cmac_kat($cipher, $klen, $tlen, $keytype, $key1, $key2, $key3, $pt, $cmac_mac); $klen = ""; $tlen = ""; $keytype = ""; $key1 = ""; $key2 = undef; $key3 = undef; $pt = ""; $cmac_mac = ""; } } elsif ($tt == 22) { if ($cipher ne "" && $klen ne "" && $tlen ne "" && $keytype ne "" && $key1 ne "" && $pt ne "") { $out .= cmac_kat($cipher, $klen, $tlen, $keytype, $key1, $key2, $key3, $pt, undef); $klen = ""; $tlen = ""; $keytype = ""; $key1 = ""; $key2 = undef; $key3 = undef; $pt = ""; } } elsif ($tt == 23) { if ($modulus ne "" && $capital_n > 0) { $out .= rsa_keygen_driver($modulus, $capital_n); $capital_n = 0; } } elsif ($tt == 24) { if ($modulus ne "" && $e ne "" && $prandom ne "" && $qrandom ne "") { $out .= rsa_keygen_kat_driver($modulus, $e, $prandom, $qrandom); $prandom = ""; $qrandom = ""; $e = ""; } } elsif ($tt > 0) { die "Test case $tt not defined"; } } close IN; $out =~ s/\n/\r\n/g; # make it a dos file open(OUT, ">$outfile") or die "Cannot create output file $outfile: $?"; print OUT $out; close OUT; } # Signalhandler sub cleanup() { unlink("rsa_siggen.tmp.$$"); unlink("rsa_sigver.tmp.$$"); unlink("rsa_sigver.tmp.$$.sig"); unlink("rsa_sigver.tmp.$$.der"); unlink("rsa_sigver.tmp.$$.cnf"); unlink("dsa_siggen.tmp.$$"); unlink("dsa_sigver.tmp.$$"); unlink("dsa_sigver.tmp.$$.sig"); exit; } ############################################################ # # let us pretend to be C :-) sub main() { usage() unless @ARGV; getopts("DRI:", \%opt) or die "bad option"; ##### Set library if ( ! defined $opt{'I'} || $opt{'I'} eq 'openssl' ) { print STDERR "Using OpenSSL interface functions\n"; $encdec = \&openssl_encdec; $rsa_sign = \&openssl_rsa_sign; $rsa_verify = \&openssl_rsa_verify; $gen_rsakey = \&openssl_gen_rsakey; $hash = \&openssl_hash; $state_cipher = \&openssl_state_cipher; } elsif ( $opt{'I'} eq 'libgcrypt' ) { print STDERR "Using libgcrypt interface functions\n"; $encdec = \&libgcrypt_encdec; $rsa_sign = \&libgcrypt_rsa_sign; $rsa_verify = \&libgcrypt_rsa_verify; $gen_rsakey = \&libgcrypt_gen_rsakey; $rsa_derive = \&libgcrypt_rsa_derive; $hash = \&libgcrypt_hash; $state_cipher = \&libgcrypt_state_cipher; $state_cipher_des = \&libgcrypt_state_cipher_des; $state_rng = \&libgcrypt_state_rng; $hmac = \&libgcrypt_hmac; $dsa_pqggen = \&libgcrypt_dsa_pqggen; $dsa_ggen = \&libgcrypt_dsa_ggen; $gen_dsakey = \&libgcrypt_gen_dsakey; $gen_dsakey_domain = \&libgcrypt_gen_dsakey_domain; $dsa_sign = \&libgcrypt_dsa_sign; $dsa_verify = \&libgcrypt_dsa_verify; $dsa_genpubkey = \&libgcrypt_dsa_genpubkey; $rsa_keygen = \&libgcrypt_rsa_keygen; $rsa_keygen_kat = \&libgcrypt_rsa_keygen_kat; $ecdsa_keygen = \&libgcrypt_ecdsa_keygen; $ecdsa_key_verify = \&libgcrypt_ecdsa_key_verify; $ecdsa_sign = \&libgcrypt_ecdsa_sign; $ecdsa_verify = \&libgcrypt_ecdsa_verify; $drbg = \&libgcrypt_drbg; } elsif ( $opt{'I'} eq 'cryptoapi' ) { print STDERR "Using cryptoapi interface functions\n"; $encdec = \&cryptoapi_encdec; $hash = \&cryptoapi_hash; $state_cipher = \&cryptoapi_state_cipher; $hmac = \&cryptoapi_hmac; $cmac = \&cryptoapi_cmac; $state_rng = \&cryptoapi_state_rng; $drbg = \&cryptoapi_drbg; $gcm = \&cryptoapi_gcm; $ccm = \&cryptoapi_ccm; $rsa_verify = \&cryptoapi_rsa_sigver; $gen_rsakey = \&cryptoapi_gen_rsakey; } else { die "Invalid interface option given"; } my $infile=$ARGV[0]; die "Error: Test vector file $infile not found" if (! -f $infile); my $outfile = $infile; # let us add .rsp regardless whether we could strip .req $outfile =~ s/\.req$//; if ($opt{'R'}) { $outfile .= ".rc4"; } else { $outfile .= ".rsp"; } if (-f $outfile) { die "Output file $outfile could not be removed: $?" unless unlink($outfile); } print STDERR "Performing tests from source file $infile with results stored in destination file $outfile\n"; #Signal handler $SIG{HUP} = \&cleanup; $SIG{INT} = \&cleanup; $SIG{QUIT} = \&cleanup; $SIG{TERM} = \&cleanup; # Do the job parse($infile, $outfile); cleanup(); } ########################################### # Call it main(); 1;
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