// Berkeley Open Infrastructure for Network Computing // http://boinc.berkeley.edu // Copyright (C) 2005 University of California // // This is free software; you can redistribute it and/or // modify it under the terms of the GNU Lesser General Public // License as published by the Free Software Foundation; // either version 2.1 of the License, or (at your option) any later version. // // This software is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. // See the GNU Lesser General Public License for more details. // // To view the GNU Lesser General Public License visit // http://www.gnu.org/copyleft/lesser.html // or write to the Free Software Foundation, Inc., // 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA #ifdef _WIN32 #include "boinc_win.h" #endif #ifndef _WIN32 #include "config.h" #include #include #include #include #endif #include "md5_file.h" #include "error_numbers.h" #include "crypt.h" #ifdef _USING_FCGI_ #include "fcgi_stdio.h" #endif // NOTE: the fast CGI I/O library doesn't have fscanf(), // so some of the following have been modified to use // fgets() and sscanf() instead // write some data in hex notation. // NOTE: since length may not be known to the reader, // we follow the data with a non-hex character '.' // int print_hex_data(FILE* f, DATA_BLOCK& x) { unsigned int i; for (i=0; ibits); len = size - sizeof(key->bits); x.data = key->data; x.len = len; return print_hex_data(f, x); } int scan_key_hex(FILE* f, KEY* key, int size) { int len, i, n; int num_bits; #if _USING_FCGI_ char *p, buf[256]; int j = 0, b; fgets(buf, 256, f); sscanf(buf, "%d", &num_bits); key->bits = num_bits; len = size - sizeof(key->bits); while (1) { p = fgets(buf, 256, f); if (!p) break; n = (strlen(p)-1)/2; if (n == 0) break; for (i=0; idata[j++] = b; } } if (j != len) return ERR_NULL; #else fscanf(f, "%d", &num_bits); key->bits = num_bits; len = size - sizeof(key->bits); for (i=0; idata[i] = n; } fscanf(f, "."); #endif return 0; } // parse a text-encoded key from a memory buffer // int sscan_key_hex(const char* buf, KEY* key, int size) { int n, retval,num_bits; DATA_BLOCK db; //fprintf(stderr, "buf = %s\n", buf); n = sscanf(buf, "%d", &num_bits); key->bits = num_bits; //key->bits is a short //fprintf(stderr, "key->bits = %d\n", key->bits); if (n != 1) return ERR_XML_PARSE; buf = strchr(buf, '\n'); if (!buf) return ERR_XML_PARSE; buf += 1; db.data = key->data; db.len = size - sizeof(key->bits); //huh??? retval = sscan_hex_data(buf, db); return retval; } // encrypt some data. // The amount encrypted may be less than what's supplied. // The output buffer must be at least MIN_OUT_BUFFER_SIZE. // The output block must be decrypted in its entirety. // int encrypt_private(R_RSA_PRIVATE_KEY& key, DATA_BLOCK& in, DATA_BLOCK& out) { int n, modulus_len; modulus_len = (key.bits+7)/8; n = in.len; if (n >= modulus_len-11) { n = modulus_len-11; } RSA* rp = RSA_new(); private_to_openssl(key, rp); RSA_private_encrypt(n, in.data, out.data, rp, RSA_PKCS1_PADDING); out.len = RSA_size(rp); RSA_free(rp); return 0; } int decrypt_public(R_RSA_PUBLIC_KEY& key, DATA_BLOCK& in, DATA_BLOCK& out) { RSA* rp = RSA_new(); public_to_openssl(key, rp); RSA_public_decrypt(in.len, in.data, out.data, rp, RSA_PKCS1_PADDING); out.len = RSA_size(rp); return 0; } int sign_file(const char* path, R_RSA_PRIVATE_KEY& key, DATA_BLOCK& signature) { char md5_buf[MD5_LEN]; double file_length; DATA_BLOCK in_block; int retval; retval = md5_file(path, md5_buf, file_length); if (retval) return retval; in_block.data = (unsigned char*)md5_buf; in_block.len = (unsigned int)strlen(md5_buf); retval = encrypt_private(key, in_block, signature); if (retval) return retval; return 0; } int sign_block(DATA_BLOCK& data_block, R_RSA_PRIVATE_KEY& key, DATA_BLOCK& signature) { char md5_buf[MD5_LEN]; int retval; DATA_BLOCK in_block; md5_block(data_block.data, data_block.len, md5_buf); in_block.data = (unsigned char*)md5_buf; in_block.len = (unsigned int)strlen(md5_buf); retval = encrypt_private(key, in_block, signature); if (retval) { printf("sign_block: encrypt_private returned %d\n", retval); return retval; } return 0; } // compute an XML signature element for some text // int generate_signature( char* text_to_sign, char* signature_hex, R_RSA_PRIVATE_KEY& key ) { DATA_BLOCK block, signature_data; unsigned char signature_buf[SIGNATURE_SIZE_BINARY]; int retval; block.data = (unsigned char*)text_to_sign; block.len = strlen(text_to_sign); signature_data.data = signature_buf; signature_data.len = SIGNATURE_SIZE_BINARY; retval = sign_block(block, key, signature_data); if (retval) return retval; sprint_hex_data(signature_hex, signature_data); return 0; } int verify_file( const char* path, R_RSA_PUBLIC_KEY& key, DATA_BLOCK& signature, bool& answer ) { char md5_buf[MD5_LEN], clear_buf[MD5_LEN]; double file_length; int n, retval; DATA_BLOCK clear_signature; retval = md5_file(path, md5_buf, file_length); if (retval) { fprintf(stderr, "error: verify_file: md5_file error %d\n", retval); return retval; } n = (int)strlen(md5_buf); clear_signature.data = (unsigned char*)clear_buf; clear_signature.len = MD5_LEN; retval = decrypt_public(key, signature, clear_signature); if (retval) { fprintf(stderr, "error: verify_file: decrypt_public error %d\n", retval); return retval; } answer = !strncmp(md5_buf, clear_buf, n); return 0; } int verify_file2( const char* path, const char* signature_text, const char* key_text, bool& answer ) { R_RSA_PUBLIC_KEY key; unsigned char signature_buf[SIGNATURE_SIZE_BINARY]; int retval; DATA_BLOCK signature; retval = sscan_key_hex(key_text, (KEY*)&key, sizeof(key)); if (retval) { fprintf(stderr, "error: verify_file2: sscan_key_hex did not work\n"); return retval; } signature.data = signature_buf; signature.len = sizeof(signature_buf); retval = sscan_hex_data(signature_text, signature); if (retval) return retval; return verify_file(path, key, signature, answer); } // verify, where both text and signature are char strings // int verify_string( const char* text, const char* signature_text, R_RSA_PUBLIC_KEY& key, bool& answer ) { char md5_buf[MD5_LEN]; unsigned char signature_buf[SIGNATURE_SIZE_BINARY]; char clear_buf[MD5_LEN]; int retval, n; DATA_BLOCK signature, clear_signature; retval = md5_block((const unsigned char*)text, (int)strlen(text), md5_buf); if (retval) return retval; n = (int)strlen(md5_buf); signature.data = signature_buf; signature.len = sizeof(signature_buf); retval = sscan_hex_data(signature_text, signature); if (retval) return retval; clear_signature.data = (unsigned char*)clear_buf; clear_signature.len = 256; retval = decrypt_public(key, signature, clear_signature); if (retval) return retval; answer = !strncmp(md5_buf, clear_buf, n); return 0; } // Same, where public key is also encoded as text // int verify_string2( const char* text, const char* signature_text, const char* key_text, bool& answer ) { R_RSA_PUBLIC_KEY key; int retval; retval = sscan_key_hex(key_text, (KEY*)&key, sizeof(key)); if (retval) return retval; return verify_string(text, signature_text, key, answer); } int read_key_file(const char* keyfile, R_RSA_PRIVATE_KEY& key) { int retval; FILE* fkey = fopen(keyfile, "r"); if (!fkey) { fprintf(stderr, "can't open key file (%s)\n", keyfile); return ERR_FOPEN; } retval = scan_key_hex(fkey, (KEY*)&key, sizeof(key)); fclose(fkey); if (retval) { fprintf(stderr, "can't parse key\n"); return retval; } return 0; } #ifdef USE_OPENSSL static void bn_to_bin(BIGNUM* bn, unsigned char* bin, int n) { memset(bin, 0, n); int m = BN_num_bytes(bn); BN_bn2bin(bn, bin+n-m); } void openssl_to_keys( RSA* rp, int nbits, R_RSA_PRIVATE_KEY& priv, R_RSA_PUBLIC_KEY& pub ) { pub.bits = nbits; bn_to_bin(rp->n, pub.modulus, sizeof(pub.modulus)); bn_to_bin(rp->e, pub.exponent, sizeof(pub.exponent)); memset(&priv, 0, sizeof(priv)); priv.bits = nbits; bn_to_bin(rp->n, priv.modulus, sizeof(priv.modulus)); bn_to_bin(rp->e, priv.publicExponent, sizeof(priv.publicExponent)); bn_to_bin(rp->d, priv.exponent, sizeof(priv.exponent)); bn_to_bin(rp->p, priv.prime[0], sizeof(priv.prime[0])); bn_to_bin(rp->q, priv.prime[1], sizeof(priv.prime[1])); bn_to_bin(rp->dmp1, priv.primeExponent[0], sizeof(priv.primeExponent[0])); bn_to_bin(rp->dmq1, priv.primeExponent[1], sizeof(priv.primeExponent[1])); bn_to_bin(rp->iqmp, priv.coefficient, sizeof(priv.coefficient)); } void private_to_openssl(R_RSA_PRIVATE_KEY& priv, RSA* rp) { rp->n = BN_bin2bn(priv.modulus, sizeof(priv.modulus), 0); rp->e = BN_bin2bn(priv.publicExponent, sizeof(priv.publicExponent), 0); rp->d = BN_bin2bn(priv.exponent, sizeof(priv.exponent), 0); rp->p = BN_bin2bn(priv.prime[0], sizeof(priv.prime[0]), 0); rp->q = BN_bin2bn(priv.prime[1], sizeof(priv.prime[1]), 0); rp->dmp1 = BN_bin2bn(priv.primeExponent[0], sizeof(priv.primeExponent[0]), 0); rp->dmq1 = BN_bin2bn(priv.primeExponent[1], sizeof(priv.primeExponent[1]), 0); rp->iqmp = BN_bin2bn(priv.coefficient, sizeof(priv.coefficient), 0); } void public_to_openssl(R_RSA_PUBLIC_KEY& pub, RSA* rp) { rp->n = BN_bin2bn(pub.modulus, sizeof(pub.modulus), 0); rp->e = BN_bin2bn(pub.exponent, sizeof(pub.exponent), 0); } #endif const char *BOINC_RCSID_4f0c2e42ea = "$Id$";