/* * libretroshare/src/pqi: authxpgp.cc * * 3P/PQI network interface for RetroShare. * * Copyright 2004-2008 by Robert Fernie. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License Version 2 as published by the Free Software Foundation. * * This library 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 * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 * USA. * * Please report all bugs and problems to "retroshare@lunamutt.com". * */ #include "authxpgp.h" #include "cleanupxpgp.h" #include "pqinetwork.h" /******************** notify of new Cert **************************/ #include "pqinotify.h" #include #include #include #include #include /******************************** TRUST LVLS xPGP_vfy.h:#define TRUST_SIGN_OWN 6 xPGP_vfy.h:#define TRUST_SIGN_TRSTED 5 xPGP_vfy.h:#define TRUST_SIGN_AUTHEN 4 xPGP_vfy.h:#define TRUST_SIGN_BASIC 3 xPGP_vfy.h:#define TRUST_SIGN_UNTRUSTED 2 xPGP_vfy.h:#define TRUST_SIGN_UNKNOWN 1 xPGP_vfy.h:#define TRUST_SIGN_NONE 0 xPGP_vfy.h:#define TRUST_SIGN_BAD -1 ******************************************************/ /********************************************************************************/ /********************************************************************************/ /********************************************************************************/ /*********** ** #define AUTHXPGP_DEBUG 1 **********/ // the single instance of this. static AuthXPGP instance_xpgproot; p3AuthMgr *getAuthMgr() { return &instance_xpgproot; } xpgpcert::xpgpcert(XPGP *xpgp, std::string pid) { certificate = xpgp; id = pid; name = getX509CNString(xpgp->subject -> subject); org = getX509OrgString(xpgp->subject -> subject); location = getX509LocString(xpgp->subject -> subject); email = ""; /* These should be filled in afterwards */ fpr = pid; trustLvl = 0; ownsign = false; trusted = false; } AuthXPGP::AuthXPGP() :init(0), sslctx(NULL), pkey(NULL), mToSaveCerts(false), mConfigSaveActive(true) { } bool AuthXPGP::active() { return init; } // args: server cert, server private key, trusted certificates. int AuthXPGP::InitAuth(const char *cert_file, const char *priv_key_file, const char *passwd) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::InitAuth()"; std::cerr << std::endl; #endif static int initLib = 0; if (!initLib) { initLib = 1; SSL_load_error_strings(); SSL_library_init(); } if (init == 1) { return 1; } if ((cert_file == NULL) || (priv_key_file == NULL) || (passwd == NULL)) { fprintf(stderr, "sslroot::initssl() missing parameters!\n"); return 0; } // XXX TODO // actions_to_seed_PRNG(); std::cerr << "SSL Library Init!" << std::endl; // setup connection method sslctx = SSL_CTX_new(PGPv1_method()); // setup cipher lists. SSL_CTX_set_cipher_list(sslctx, "DEFAULT"); // setup flag against read errors // SSL_CTX_set_mode(sslctx,SSL_MODE_AUTO_RETRY); // SSL_CTX_set_mode(sslctx,SSL_MODE_ENABLE_PARTIAL_WRITE) ; // certificates (Set Local Server Certificate). FILE *ownfp = fopen(cert_file, "r"); if (ownfp == NULL) { std::cerr << "Couldn't open Own Certificate!" << std::endl; return -1; } // get xPGP certificate. XPGP *xpgp = PEM_read_XPGP(ownfp, NULL, NULL, NULL); fclose(ownfp); if (xpgp == NULL) { return -1; } SSL_CTX_use_pgp_certificate(sslctx, xpgp); // get private key FILE *pkfp = fopen(priv_key_file, "rb"); if (pkfp == NULL) { std::cerr << "Couldn't Open PrivKey File!" << std::endl; CloseAuth(); return -1; } pkey = PEM_read_PrivateKey(pkfp, NULL, NULL, (void *) passwd); fclose(pkfp); if (pkey == NULL) { return -1; } SSL_CTX_use_pgp_PrivateKey(sslctx, pkey); if (1 != SSL_CTX_check_pgp_private_key(sslctx)) { std::cerr << "Issues With Private Key! - Doesn't match your Cert" << std::endl; std::cerr << "Check your input key/certificate:" << std::endl; std::cerr << priv_key_file << " & " << cert_file; std::cerr << std::endl; CloseAuth(); return -1; } // make keyring. pgp_keyring = createPGPContext(xpgp, pkey); SSL_CTX_set_XPGP_KEYRING(sslctx, pgp_keyring); // Setup the certificate. (after keyring is made!). if (!XPGP_check_valid_certificate(xpgp)) { /* bad certificate */ CloseAuth(); return -1; } if (!getXPGPid(xpgp, mOwnId)) { /* bad certificate */ CloseAuth(); return -1; } // enable verification of certificates (PEER) SSL_CTX_set_verify(sslctx, SSL_VERIFY_PEER | SSL_VERIFY_FAIL_IF_NO_PEER_CERT, NULL); std::cerr << "SSL Verification Set" << std::endl; mOwnCert = new xpgpcert(xpgp, mOwnId); /* add to keyring */ XPGP_add_certificate(pgp_keyring, mOwnCert->certificate); mOwnCert->trustLvl = XPGP_auth_certificate(pgp_keyring, mOwnCert->certificate); mOwnCert->trusted = true; mOwnCert->ownsign = true; init = 1; return 1; } bool AuthXPGP::CloseAuth() { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::CloseAuth()"; std::cerr << std::endl; #endif SSL_CTX_free(sslctx); // clean up private key.... // remove certificates etc -> opposite of initssl. init = 0; return 1; } /* Context handling */ SSL_CTX *AuthXPGP::getCTX() { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::getCTX()"; std::cerr << std::endl; #endif return sslctx; } int AuthXPGP::setConfigDirectories(std::string configfile, std::string neighdir) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::setConfigDirectories()"; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ mCertConfigFile = configfile; mNeighDir = neighdir; xpgpMtx.unlock(); /**** UNLOCK ****/ return 1; } bool AuthXPGP::isTrustingMe(std::string id) { xpgpMtx.lock(); /***** LOCK *****/ bool res = false ; for(std::list::const_iterator it(_trusting_peers.begin());it!=_trusting_peers.end() && !res;++it) if( *it == id ) res = true ; xpgpMtx.unlock(); /**** UNLOCK ****/ return res ; } void AuthXPGP::addTrustingPeer(std::string id) { if( !isTrustingMe(id) ) { xpgpMtx.lock(); /***** LOCK *****/ _trusting_peers.push_back(id) ; xpgpMtx.unlock(); /**** UNLOCK ****/ } } std::string AuthXPGP::OwnId() { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::OwnId()"; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ std::string id = mOwnId; xpgpMtx.unlock(); /**** UNLOCK ****/ return id; } bool AuthXPGP::getAllList(std::list &ids) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::getAllList()"; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ /* iterate through both lists */ std::map::iterator it; for(it = mCerts.begin(); it != mCerts.end(); it++) { ids.push_back(it->first); } xpgpMtx.unlock(); /**** UNLOCK ****/ return true; } bool AuthXPGP::getAuthenticatedList(std::list &ids) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::getAuthenticatedList()"; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ /* iterate through both lists */ std::map::iterator it; for(it = mCerts.begin(); it != mCerts.end(); it++) { if (it->second->trustLvl > TRUST_SIGN_BASIC) { ids.push_back(it->first); } } xpgpMtx.unlock(); /**** UNLOCK ****/ return true; } bool AuthXPGP::getUnknownList(std::list &ids) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::getUnknownList()"; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ /* iterate through both lists */ std::map::iterator it; for(it = mCerts.begin(); it != mCerts.end(); it++) { if (it->second->trustLvl <= TRUST_SIGN_BASIC) { ids.push_back(it->first); } } xpgpMtx.unlock(); /**** UNLOCK ****/ return true; } /* silly question really - only valid certs get saved to map * so if in map its okay */ bool AuthXPGP::isValid(std::string id) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::isValid() " << id; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ bool valid = false; if (id == mOwnId) { valid = true; } else { valid = (mCerts.end() != mCerts.find(id)); } xpgpMtx.unlock(); /**** UNLOCK ****/ return valid; } bool AuthXPGP::isAuthenticated(std::string id) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::isAuthenticated() " << id; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ xpgpcert *cert = NULL; bool auth = false; if (locked_FindCert(id, &cert)) { auth = (cert->trustLvl > TRUST_SIGN_BASIC); } xpgpMtx.unlock(); /**** UNLOCK ****/ return auth; } std::string AuthXPGP::getName(std::string id) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::getName() " << id; std::cerr << std::endl; #endif std::string name; xpgpMtx.lock(); /***** LOCK *****/ xpgpcert *cert = NULL; if (id == mOwnId) { name = mOwnCert->name; } else if (locked_FindCert(id, &cert)) { name = cert->name; } xpgpMtx.unlock(); /**** UNLOCK ****/ return name; } bool AuthXPGP::getDetails(std::string id, pqiAuthDetails &details) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::getDetails() " << id; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ bool valid = false; xpgpcert *cert = NULL; if (id == mOwnId) { cert = mOwnCert; valid = true; } else if (locked_FindCert(id, &cert)) { valid = true; } if (valid) { /* fill details */ details.id = cert->id; details.name = cert->name; details.email = cert->email; details.location= cert->location; details.org = cert->org; details.fpr = cert->fpr; details.signers = cert->signers; details.trustLvl= cert->trustLvl; details.ownsign = cert->ownsign; details.trusted = cert->trusted; } xpgpMtx.unlock(); /**** UNLOCK ****/ return valid; } /* Load/Save certificates */ bool AuthXPGP::LoadCertificateFromString(std::string pem, std::string &id) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::LoadCertificateFromString() " << id; std::cerr << std::endl; #endif #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::LoadCertificateFromString() Cleaning up Certificate First!"; std::cerr << std::endl; #endif std::string cleancert = cleanUpCertificate(pem); XPGP *xpgp = loadXPGPFromPEM(cleancert); if (!xpgp) return false; return ProcessXPGP(xpgp, id); } std::string AuthXPGP::SaveCertificateToString(std::string id) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::SaveCertificateToString() " << id; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ /* get the cert first */ std::string certstr; xpgpcert *cert = NULL; bool valid = false; if (id == mOwnId) { cert = mOwnCert; valid = true; } else if (locked_FindCert(id, &cert)) { valid = true; } if (valid) { BIO *bp = BIO_new(BIO_s_mem()); PEM_write_bio_XPGP(bp, cert->certificate); /* translate the bp data to a string */ char *data; int len = BIO_get_mem_data(bp, &data); for(int i = 0; i < len; i++) { certstr += data[i]; } BIO_free(bp); } xpgpMtx.unlock(); /**** UNLOCK ****/ return certstr; } bool AuthXPGP::LoadCertificateFromFile(std::string filename, std::string &id) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::LoadCertificateFromFile() " << id; std::cerr << std::endl; #endif std::string nullhash; XPGP *xpgp = loadXPGPFromFile(filename.c_str(), nullhash); if (!xpgp) return false; return ProcessXPGP(xpgp, id); } //============================================================================ //! Saves something to filename //! \returns true on success, false on failure bool AuthXPGP::SaveCertificateToFile(std::string id, std::string filename) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::SaveCertificateToFile() " << id; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ /* get the cert first */ xpgpcert *cert = NULL; bool valid = false; std::string hash; if (id == mOwnId) { cert = mOwnCert; valid = true; } else if (locked_FindCert(id, &cert)) { valid = true; } if (valid) { valid = saveXPGPToFile(cert->certificate, filename, hash); } xpgpMtx.unlock(); /**** UNLOCK ****/ return valid; } /**** To/From DER format ***/ bool AuthXPGP::LoadCertificateFromBinary(const uint8_t *ptr, uint32_t len, std::string &id) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::LoadCertificateFromFile() " << id; std::cerr << std::endl; #endif XPGP *xpgp = loadXPGPFromDER(ptr, len); if (!xpgp) return false; return ProcessXPGP(xpgp, id); } bool AuthXPGP::SaveCertificateToBinary(std::string id, uint8_t **ptr, uint32_t *len) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::SaveCertificateToBinary() " << id; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ /* get the cert first */ xpgpcert *cert = NULL; bool valid = false; std::string hash; if (id == mOwnId) { cert = mOwnCert; valid = true; } else if (locked_FindCert(id, &cert)) { valid = true; } if (valid) { valid = saveXPGPToDER(cert->certificate, ptr, len); } xpgpMtx.unlock(); /**** UNLOCK ****/ return valid; } /* Signatures */ bool AuthXPGP::SignCertificate(std::string id) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::SignCertificate() " << id; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ /* get the cert first */ xpgpcert *cert = NULL; xpgpcert *own = mOwnCert; bool valid = false; if (locked_FindCert(id, &cert)) { if (0 < validateCertificateIsSignedByKey( cert->certificate, own->certificate)) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::SignCertificate() Signed Already: " << id; std::cerr << std::endl; #endif cert->ownsign=true; } else { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::SignCertificate() Signing Cert: " << id; std::cerr << std::endl; #endif /* sign certificate */ XPGP_sign_certificate(pgp_keyring, cert->certificate, own->certificate); /* reevaluate the auth of the xpgp */ cert->trustLvl = XPGP_auth_certificate(pgp_keyring, cert->certificate); cert->ownsign = true; mToSaveCerts = true; } valid = true; } xpgpMtx.unlock(); /**** UNLOCK ****/ return valid; } bool AuthXPGP::TrustCertificate(std::string id, bool totrust) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::TrustCertificate() " << id; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ /* get the cert first */ xpgpcert *cert = NULL; bool valid = false; if (locked_FindCert(id, &cert)) { /* if trusted -> untrust */ if (!totrust) { XPGP_signer_untrusted(pgp_keyring, cert->certificate); cert->trusted = false; } else { /* if auth then we can trust them */ if (XPGP_signer_trusted(pgp_keyring, cert->certificate)) { cert->trusted = true; } } /* reevaluate the auth of the xpgp */ cert->trustLvl = XPGP_auth_certificate(pgp_keyring, cert->certificate); valid = true; /* resave if changed trust setting */ mToSaveCerts = true; } xpgpMtx.unlock(); /**** UNLOCK ****/ return valid; } bool AuthXPGP::RevokeCertificate(std::string id) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::RevokeCertificate() " << id; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ xpgpMtx.unlock(); /**** UNLOCK ****/ return false; } bool AuthXPGP::AuthCertificate(std::string id) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::AuthCertificate() " << id; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ /* get the cert first */ xpgpcert *cert = NULL; xpgpcert *own = mOwnCert; bool valid = false; if (locked_FindCert(id, &cert)) { /* ADD IN LATER */ //if (cert->trustLvl > TRUST_SIGN_BASIC) //{ #ifdef AUTHXPGP_DEBUG // std::cerr << "AuthXPGP::AuthCertificate() Already Authed: " << id; // std::cerr << std::endl; #endif //} if (0 < validateCertificateIsSignedByKey( cert->certificate, own->certificate)) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::AuthCertificate() Signed Already: " << id; std::cerr << std::endl; #endif cert->ownsign=true; } else { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::AuthCertificate() Signing Cert: " << id; std::cerr << std::endl; #endif /* sign certificate */ XPGP_sign_certificate(pgp_keyring, cert->certificate, own->certificate); /* reevaluate the auth of the xpgp */ cert->trustLvl = XPGP_auth_certificate(pgp_keyring, cert->certificate); cert->ownsign = true; mToSaveCerts = true; } valid = true; } xpgpMtx.unlock(); /**** UNLOCK ****/ return valid; } /* Sign / Encrypt / Verify Data (TODO) */ bool AuthXPGP::SignData(std::string input, std::string &sign) { return SignData(input.c_str(), input.length(), sign); } bool AuthXPGP::SignData(const void *data, const uint32_t len, std::string &sign) { RsStackMutex stack(xpgpMtx); /***** STACK LOCK MUTEX *****/ EVP_MD_CTX *mdctx = EVP_MD_CTX_create(); unsigned int signlen = EVP_PKEY_size(pkey); unsigned char signature[signlen]; if (0 == EVP_SignInit(mdctx, EVP_sha1())) { std::cerr << "EVP_SignInit Failure!" << std::endl; EVP_MD_CTX_destroy(mdctx); return false; } if (0 == EVP_SignUpdate(mdctx, data, len)) { std::cerr << "EVP_SignUpdate Failure!" << std::endl; EVP_MD_CTX_destroy(mdctx); return false; } if (0 == EVP_SignFinal(mdctx, signature, &signlen, pkey)) { std::cerr << "EVP_SignFinal Failure!" << std::endl; EVP_MD_CTX_destroy(mdctx); return false; } EVP_MD_CTX_destroy(mdctx); sign.clear(); std::ostringstream out; out << std::hex; for(uint32_t i = 0; i < signlen; i++) { out << std::setw(2) << std::setfill('0'); out << (uint32_t) (signature[i]); } sign = out.str(); return true; } bool AuthXPGP::SignDataBin(std::string input, unsigned char *sign, unsigned int *signlen) { return SignDataBin(input.c_str(), input.length(), sign, signlen); } bool AuthXPGP::SignDataBin(const void *data, const uint32_t len, unsigned char *sign, unsigned int *signlen) { RsStackMutex stack(xpgpMtx); /***** STACK LOCK MUTEX *****/ EVP_MD_CTX *mdctx = EVP_MD_CTX_create(); unsigned int req_signlen = EVP_PKEY_size(pkey); if (req_signlen > *signlen) { /* not enough space */ std::cerr << "SignDataBin() Not Enough Sign SpacegnInit Failure!" << std::endl; return false; } if (0 == EVP_SignInit(mdctx, EVP_sha1())) { std::cerr << "EVP_SignInit Failure!" << std::endl; EVP_MD_CTX_destroy(mdctx); return false; } if (0 == EVP_SignUpdate(mdctx, data, len)) { std::cerr << "EVP_SignUpdate Failure!" << std::endl; EVP_MD_CTX_destroy(mdctx); return false; } if (0 == EVP_SignFinal(mdctx, sign, signlen, pkey)) { std::cerr << "EVP_SignFinal Failure!" << std::endl; EVP_MD_CTX_destroy(mdctx); return false; } EVP_MD_CTX_destroy(mdctx); return true; } bool AuthXPGP::VerifySignBin(std::string pid, const void *data, const uint32_t len, unsigned char *sign, unsigned int signlen) { RsStackMutex stack(xpgpMtx); /***** STACK LOCK MUTEX *****/ /* find the peer */ xpgpcert *peer; if (pid == mOwnId) { peer = mOwnCert; } else if (!locked_FindCert(pid, &peer)) { std::cerr << "VerifySignBin() no peer" << std::endl; return false; } EVP_PKEY *peerkey = peer->certificate->key->key->pkey; EVP_MD_CTX *mdctx = EVP_MD_CTX_create(); if (0 == EVP_VerifyInit(mdctx, EVP_sha1())) { std::cerr << "EVP_VerifyInit Failure!" << std::endl; EVP_MD_CTX_destroy(mdctx); return false; } if (0 == EVP_VerifyUpdate(mdctx, data, len)) { std::cerr << "EVP_VerifyUpdate Failure!" << std::endl; EVP_MD_CTX_destroy(mdctx); return false; } if (0 == EVP_VerifyFinal(mdctx, sign, signlen, peerkey)) { std::cerr << "EVP_VerifyFinal Failure!" << std::endl; EVP_MD_CTX_destroy(mdctx); return false; } EVP_MD_CTX_destroy(mdctx); return true; } /**** NEW functions we've added ****/ /**** AUX Functions ****/ bool AuthXPGP::locked_FindCert(std::string id, xpgpcert **cert) { std::map::iterator it; if (mCerts.end() != (it = mCerts.find(id))) { *cert = it->second; return true; } return false; } XPGP *AuthXPGP::loadXPGPFromFile(std::string fname, std::string hash) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::LoadXPGPFromFile()"; std::cerr << std::endl; #endif // if there is a hash - check that the file matches it before loading. XPGP *pc = NULL; FILE *pcertfp = fopen(fname.c_str(), "rb"); // load certificates from file. if (pcertfp == NULL) { #ifdef AUTHXPGP_DEBUG std::cerr << "sslroot::loadcertificate() Bad File: " << fname; std::cerr << " Cannot be Hashed!" << std::endl; #endif return NULL; } /* We only check a signature's hash if * we are loading from a configuration file. * Therefore we saved the file and it should be identical. * and a direct load + verify will work. * * If however it has been transported by email.... * Then we might have to correct the data (strip out crap) * from the configuration at the end. (XPGP load should work!) */ if (hash.length() > 1) { unsigned int signlen = EVP_PKEY_size(pkey); unsigned char signature[signlen]; int maxsize = 20480; /* should be enough for about 50 signatures */ int rbytes; char inall[maxsize]; if (0 == (rbytes = fread(inall, 1, maxsize, pcertfp))) { #ifdef AUTHXPGP_DEBUG std::cerr << "Error Reading Peer Record!" << std::endl; #endif return NULL; } //std::cerr << "Read " << rbytes << std::endl; EVP_MD_CTX *mdctx = EVP_MD_CTX_create(); if (0 == EVP_SignInit_ex(mdctx, EVP_sha1(), NULL)) { std::cerr << "EVP_SignInit Failure!" << std::endl; } if (0 == EVP_SignUpdate(mdctx, inall, rbytes)) { std::cerr << "EVP_SignUpdate Failure!" << std::endl; } if (0 == EVP_SignFinal(mdctx, signature, &signlen, pkey)) { std::cerr << "EVP_SignFinal Failure!" << std::endl; } EVP_MD_CTX_destroy(mdctx); bool same = true; if (signlen != hash.length()) { #ifdef AUTHXPGP_DEBUG std::cerr << "Different Length Signatures... "; std::cerr << "Cannot Load Certificate!" << std::endl; #endif fclose(pcertfp); return NULL; } for(int i = 0; i < (signed) signlen; i++) { if (signature[i] != (unsigned char) hash[i]) { same = false; #ifdef AUTHXPGP_DEBUG std::cerr << "Invalid Signature... "; std::cerr << "Cannot Load Certificate!" << std::endl; #endif fclose(pcertfp); return NULL; } } #ifdef AUTHXPGP_DEBUG std::cerr << "Verified Signature for: " << fname; std::cerr << std::endl; #endif } else { #ifdef AUTHXPGP_DEBUG std::cerr << "Not checking cert signature" << std::endl; #endif } fseek(pcertfp, 0, SEEK_SET); /* rewind */ pc = PEM_read_XPGP(pcertfp, NULL, NULL, NULL); fclose(pcertfp); if (pc != NULL) { // read a certificate. #ifdef AUTHXPGP_DEBUG std::cerr << "Loaded Certificate: " << pc -> name << std::endl; #endif } else // (pc == NULL) { unsigned long err = ERR_get_error(); std::cerr << "Read Failed .... CODE(" << err << ")" << std::endl; std::cerr << ERR_error_string(err, NULL) << std::endl; return NULL; } return pc; } bool AuthXPGP::saveXPGPToFile(XPGP *xpgp, std::string fname, std::string &hash) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::saveXPGPToFile()"; std::cerr << std::endl; #endif // load certificates from file. FILE *setfp = fopen(fname.c_str(), "wb"); if (setfp == NULL) { #ifdef AUTHXPGP_DEBUG std::cerr << "sslroot::savecertificate() Bad File: " << fname; std::cerr << " Cannot be Written!" << std::endl; #endif return false; } #ifdef AUTHXPGP_DEBUG std::cerr << "Writing out Cert...:" << xpgp->name << std::endl; #endif PEM_write_XPGP(setfp, xpgp); fclose(setfp); // then reopen to generate hash. setfp = fopen(fname.c_str(), "rb"); if (setfp == NULL) { #ifdef AUTHXPGP_DEBUG std::cerr << "sslroot::savecertificate() Bad File: " << fname; std::cerr << " Opened for ReHash!" << std::endl; #endif return false; } unsigned int signlen = EVP_PKEY_size(pkey); unsigned char signature[signlen]; int maxsize = 20480; int rbytes; char inall[maxsize]; if (0 == (rbytes = fread(inall, 1, maxsize, setfp))) { #ifdef AUTHXPGP_DEBUG std::cerr << "Error Writing Peer Record!" << std::endl; #endif return -1; } #ifdef AUTHXPGP_DEBUG std::cerr << "Read " << rbytes << std::endl; #endif EVP_MD_CTX *mdctx = EVP_MD_CTX_create(); if (0 == EVP_SignInit_ex(mdctx, EVP_sha1(), NULL)) { std::cerr << "EVP_SignInit Failure!" << std::endl; } if (0 == EVP_SignUpdate(mdctx, inall, rbytes)) { std::cerr << "EVP_SignUpdate Failure!" << std::endl; } if (0 == EVP_SignFinal(mdctx, signature, &signlen, pkey)) { std::cerr << "EVP_SignFinal Failure!" << std::endl; } #ifdef AUTHXPGP_DEBUG std::cerr << "Saved Cert: " << xpgp->name; std::cerr << std::endl; #endif #ifdef AUTHXPGP_DEBUG std::cerr << "Cert + Setting Signature is(" << signlen << "): "; #endif std::string signstr; for(uint32_t i = 0; i < signlen; i++) { #ifdef AUTHXPGP_DEBUG fprintf(stderr, "%02x", signature[i]); #endif signstr += signature[i]; } #ifdef AUTHXPGP_DEBUG std::cerr << std::endl; #endif hash = signstr; fclose(setfp); EVP_MD_CTX_destroy(mdctx); return true; } XPGP *AuthXPGP::loadXPGPFromPEM(std::string pem) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::LoadXPGPFromPEM()"; std::cerr << std::endl; #endif /* Put the data into a mem BIO */ char *certstr = strdup(pem.c_str()); BIO *bp = BIO_new_mem_buf(certstr, -1); XPGP *pc = PEM_read_bio_XPGP(bp, NULL, NULL, NULL); BIO_free(bp); free(certstr); return pc; } XPGP *AuthXPGP::loadXPGPFromDER(const uint8_t *ptr, uint32_t len) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::LoadXPGPFromDER()"; std::cerr << std::endl; #endif XPGP *tmp = NULL; unsigned char **certptr = (unsigned char **) &ptr; XPGP *xpgp = d2i_XPGP(&tmp, certptr, len); return xpgp; } bool AuthXPGP::saveXPGPToDER(XPGP *xpgp, uint8_t **ptr, uint32_t *len) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::saveXPGPToDER()"; std::cerr << std::endl; #endif int certlen = i2d_XPGP(xpgp, (unsigned char **) ptr); if (certlen > 0) { *len = certlen; return true; } else { *len = 0; return false; } return false; } bool AuthXPGP::ProcessXPGP(XPGP *xpgp, std::string &id) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::ProcessXPGP()"; std::cerr << std::endl; #endif /* extract id */ std::string xpgpid; if (!XPGP_check_valid_certificate(xpgp)) { /* bad certificate */ XPGP_free(xpgp); return false; } if (!getXPGPid(xpgp, xpgpid)) { /* bad certificate */ XPGP_free(xpgp); return false; } xpgpcert *cert = NULL; bool duplicate = false; xpgpMtx.lock(); /***** LOCK *****/ if (xpgpid == mOwnId) { cert = mOwnCert; duplicate = true; } else if (locked_FindCert(xpgpid, &cert)) { duplicate = true; } if (duplicate) { /* have a duplicate */ /* check that they are exact */ if (0 != XPGP_cmp(cert->certificate, xpgp)) { /* MAJOR ERROR */ XPGP_free(xpgp); xpgpMtx.unlock(); /**** UNLOCK ****/ return false; } /* transfer new signatures */ XPGP_copy_known_signatures(pgp_keyring, cert->certificate, xpgp); XPGP_free(xpgp); /* we accepted it! */ id = xpgpid; /* update signers */ cert->signers = getXPGPsigners(cert->certificate); xpgpMtx.unlock(); /**** UNLOCK ****/ return true; } xpgpMtx.unlock(); /**** UNLOCK ****/ /* if we get here -> its a new certificate */ cert = new xpgpcert(xpgp, xpgpid); xpgpMtx.lock(); /***** LOCK *****/ /* add to keyring */ XPGP_add_certificate(pgp_keyring, cert->certificate); mCerts[xpgpid] = cert; cert -> trustLvl = XPGP_auth_certificate(pgp_keyring, cert->certificate); if (cert -> trustLvl == TRUST_SIGN_TRSTED) { cert->trusted = true; cert->ownsign = true; } else if (cert->trustLvl == TRUST_SIGN_OWN) { cert->ownsign = true; } cert->signers = getXPGPsigners(xpgp); /* resave if new certificate */ mToSaveCerts = true; xpgpMtx.unlock(); /**** UNLOCK ****/ #if 0 /******************** notify of new Cert **************************/ pqiNotify *pqinotify = getPqiNotify(); if (pqinotify) { pqinotify->AddFeedItem(RS_FEED_ITEM_PEER_NEW, xpgpid, "",""); } /******************** notify of new Cert **************************/ #endif id = xpgpid; return true; } bool getXPGPid(XPGP *xpgp, std::string &xpgpid) { #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::getXPGPid()"; std::cerr << std::endl; #endif xpgpid = ""; if (xpgp == NULL) { #ifdef XPGP_DEBUG std::cerr << "AuthXPGP::getXPGPid() NULL pointer"; std::cerr << std::endl; #endif return false; } // get the first signature.... if (sk_XPGP_SIGNATURE_num(xpgp->signs) < 1) { #ifdef XPGP_DEBUG std::cerr << "AuthXPGP::getXPGPid() ERROR: No Signature"; std::cerr << std::endl; #endif return false; } XPGP_SIGNATURE *xpgpsign = sk_XPGP_SIGNATURE_value(xpgp->signs, 0); // Validate that it is a self signature. // (Already Done - but not in this function) // get the signature from the cert, and copy to the array. ASN1_BIT_STRING *signature = xpgpsign->signature; int signlen = ASN1_STRING_length(signature); if (signlen < CERTSIGNLEN) { #ifdef XPGP_DEBUG std::cerr << "AuthXPGP::getXPGPid() ERROR: Short Signature"; std::cerr << std::endl; #endif return false; } // else copy in the first CERTSIGNLEN. unsigned char *signdata = ASN1_STRING_data(signature); std::ostringstream id; for(uint32_t i = 0; i < CERTSIGNLEN; i++) { id << std::hex << std::setw(2) << std::setfill('0') << (uint16_t) (((uint8_t *) (signdata))[i]); } xpgpid = id.str(); return true; } /* validate + get id */ bool AuthXPGP::ValidateCertificateXPGP(XPGP *xpgp, std::string &peerId) { /* check self signed */ if (!XPGP_check_valid_certificate(xpgp)) { /* bad certificate */ return false; } return getXPGPid(xpgp, peerId); } /* store for discovery */ bool AuthXPGP::FailedCertificateXPGP(XPGP *xpgp, bool incoming) { std::string id; return ProcessXPGP(xpgp, id); } /* check that they are exact match */ bool AuthXPGP::CheckCertificateXPGP(std::string xpgpId, XPGP *xpgp) { xpgpMtx.lock(); /***** LOCK *****/ xpgpcert *cert = NULL; if (!locked_FindCert(xpgpId, &cert)) { /* not there -> error */ XPGP_free(xpgp); xpgpMtx.unlock(); /**** UNLOCK ****/ return false; } else { /* have a duplicate */ /* check that they are exact */ if (0 != XPGP_cmp(cert->certificate, xpgp)) { /* MAJOR ERROR */ XPGP_free(xpgp); xpgpMtx.unlock(); /**** UNLOCK ****/ return false; } /* transfer new signatures */ XPGP_copy_known_signatures(pgp_keyring, cert->certificate, xpgp); XPGP_free(xpgp); /* update signers */ cert->signers = getXPGPsigners(cert->certificate); xpgpMtx.unlock(); /**** UNLOCK ****/ return true; } } /********************************************************************************/ /********************************************************************************/ /********************************************************************************/ /********************************************************************************/ /********************************************************************************/ int pem_passwd_cb(char *buf, int size, int rwflag, void *password) { strncpy(buf, (char *)(password), size); buf[size - 1] = '\0'; return(strlen(buf)); } // Not dependent on sslroot. load, and detroys the XPGP memory. int LoadCheckXPGPandGetName(const char *cert_file, std::string &userName, std::string &userId) { /* This function loads the XPGP certificate from the file, * and checks the certificate */ FILE *tmpfp = fopen(cert_file, "r"); if (tmpfp == NULL) { #ifdef XPGP_DEBUG std::cerr << "sslroot::LoadCheckAndGetXPGPName()"; std::cerr << " Failed to open Certificate File:" << cert_file; std::cerr << std::endl; #endif return 0; } // get xPGP certificate. XPGP *xpgp = PEM_read_XPGP(tmpfp, NULL, NULL, NULL); fclose(tmpfp); // check the certificate. bool valid = false; if (xpgp) { valid = XPGP_check_valid_certificate(xpgp); } if (valid) { // extract the name. userName = getX509CNString(xpgp->subject->subject); } if (!getXPGPid(xpgp, userId)) { valid = false; } std::cout << getXPGPInfo(xpgp) << std::endl ; // clean up. XPGP_free(xpgp); if (valid) { // happy! return 1; } else { // something went wrong! return 0; } } std::string getX509NameString(X509_NAME *name) { std::string namestr; for(int i = 0; i < X509_NAME_entry_count(name); i++) { X509_NAME_ENTRY *entry = X509_NAME_get_entry(name, i); ASN1_STRING *entry_data = X509_NAME_ENTRY_get_data(entry); ASN1_OBJECT *entry_obj = X509_NAME_ENTRY_get_object(entry); namestr += "\t"; namestr += OBJ_nid2ln(OBJ_obj2nid(entry_obj)); namestr += " : "; //namestr += entry_obj -> flags; //namestr += entry_data -> length; //namestr += entry_data -> type; //namestr += entry_data -> flags; //entry -> set; if (entry_data -> data != NULL) { namestr += (char *) entry_data -> data; } else { namestr += "NULL"; } if (i + 1 < X509_NAME_entry_count(name)) { namestr += "\n"; } } return namestr; } std::string getX509CNString(X509_NAME *name) { std::string namestr; for(int i = 0; i < X509_NAME_entry_count(name); i++) { X509_NAME_ENTRY *entry = X509_NAME_get_entry(name, i); ASN1_STRING *entry_data = X509_NAME_ENTRY_get_data(entry); ASN1_OBJECT *entry_obj = X509_NAME_ENTRY_get_object(entry); if (0 == strncmp("CN", OBJ_nid2sn(OBJ_obj2nid(entry_obj)), 2)) { if (entry_data -> data != NULL) { namestr += (char *) entry_data -> data; } else { namestr += "Unknown"; } return namestr; } } return namestr; } std::string getX509TypeString(X509_NAME *name, const char *type, int len) { std::string namestr; for(int i = 0; i < X509_NAME_entry_count(name); i++) { X509_NAME_ENTRY *entry = X509_NAME_get_entry(name, i); ASN1_STRING *entry_data = X509_NAME_ENTRY_get_data(entry); ASN1_OBJECT *entry_obj = X509_NAME_ENTRY_get_object(entry); if (0 == strncmp(type, OBJ_nid2sn(OBJ_obj2nid(entry_obj)), len)) { if (entry_data -> data != NULL) { namestr += (char *) entry_data -> data; } else { namestr += "Unknown"; } return namestr; } } return namestr; } std::string getX509LocString(X509_NAME *name) { return getX509TypeString(name, "L", 2); } std::string getX509OrgString(X509_NAME *name) { return getX509TypeString(name, "O", 2); } std::string getX509CountryString(X509_NAME *name) { return getX509TypeString(name, "C", 2); } std::string getXPGPInfo(XPGP *cert) { std::stringstream out; long l; int i,j; out << "XPGP Certificate:" << std::endl; l=XPGP_get_version(cert); out << " Version: " << l+1 << "(0x" << l << ")" << std::endl; out << " Subject: " << std::endl; out << " " << getX509NameString(cert -> subject -> subject); out << std::endl; out << std::endl; out << " Signatures:" << std::endl; for(i = 0; i < sk_XPGP_SIGNATURE_num(cert->signs); i++) { out << "Sign[" << i << "] -> ["; XPGP_SIGNATURE *sig = sk_XPGP_SIGNATURE_value(cert->signs,i); ASN1_BIT_STRING *signature = sig->signature; int signlen = ASN1_STRING_length(signature); unsigned char *signdata = ASN1_STRING_data(signature); /* only show the first 8 bytes */ if (signlen > 8) signlen = 8; for(j=0;jissuer); out << std::endl; out << std::endl; } return out.str(); } std::string getXPGPAuthCode(XPGP *xpgp) { /* get the self signature -> the first signature */ std::stringstream out; if (1 > sk_XPGP_SIGNATURE_num(xpgp->signs)) { out.str(); } XPGP_SIGNATURE *sig = sk_XPGP_SIGNATURE_value(xpgp->signs,0); ASN1_BIT_STRING *signature = sig->signature; int signlen = ASN1_STRING_length(signature); unsigned char *signdata = ASN1_STRING_data(signature); /* extract the authcode from the signature */ /* convert it to a string, inverse of 2 bytes of signdata */ if (signlen > 2) signlen = 2; int j; for(j=0;j getXPGPsigners(XPGP *cert) { std::list signers; int i; for(i = 0; i < sk_XPGP_SIGNATURE_num(cert->signs); i++) { XPGP_SIGNATURE *sig = sk_XPGP_SIGNATURE_value(cert->signs,i); std::string str = getX509CNString(sig->issuer); signers.push_back(str); #ifdef XPGP_DEBUG std::cerr << "XPGPsigners(" << i << ")" << str << std::endl; #endif } return signers; } // other fns std::string getCertName(XPGP *xpgp) { std::string name = xpgp->name; // strip out bad chars. for(int i = 0; i < (signed) name.length(); i++) { if ((name[i] == '/') || (name[i] == ' ') || (name[i] == '=') || (name[i] == '\\') || (name[i] == '\t') || (name[i] == '\n')) { name[i] = '_'; } } return name; } /********** SSL ERROR STUFF ******************************************/ int printSSLError(SSL *ssl, int retval, int err, unsigned long err2, std::ostream &out) { std::string reason; std::string mainreason = std::string("UNKNOWN ERROR CODE"); if (err == SSL_ERROR_NONE) { mainreason = std::string("SSL_ERROR_NONE"); } else if (err == SSL_ERROR_ZERO_RETURN) { mainreason = std::string("SSL_ERROR_ZERO_RETURN"); } else if (err == SSL_ERROR_WANT_READ) { mainreason = std::string("SSL_ERROR_WANT_READ"); } else if (err == SSL_ERROR_WANT_WRITE) { mainreason = std::string("SSL_ERROR_WANT_WRITE"); } else if (err == SSL_ERROR_WANT_CONNECT) { mainreason = std::string("SSL_ERROR_WANT_CONNECT"); } else if (err == SSL_ERROR_WANT_ACCEPT) { mainreason = std::string("SSL_ERROR_WANT_ACCEPT"); } else if (err == SSL_ERROR_WANT_X509_LOOKUP) { mainreason = std::string("SSL_ERROR_WANT_X509_LOOKUP"); } else if (err == SSL_ERROR_SYSCALL) { mainreason = std::string("SSL_ERROR_SYSCALL"); } else if (err == SSL_ERROR_SSL) { mainreason = std::string("SSL_ERROR_SSL"); } out << "RetVal(" << retval; out << ") -> SSL Error: " << mainreason << std::endl; out << "\t + ERR Error: " << ERR_error_string(err2, NULL) << std::endl; return 1; } /***************************** OLD STORAGE of CERTS ************************* * We will retain the existing CERT storage format for the moment.... * This will enable the existing certs to be loaded in. * * BUT Save will change the format - removing the options from * the configuration file. This will mean that we can catch NEW/OLD formats. * * We only want to load old format ONCE. as we'll use it to get * the list of existing friends... * * * */ bool AuthXPGP::FinalSaveCertificates() { CheckSaveCertificates(); RsStackMutex stack(xpgpMtx); /***** LOCK *****/ mConfigSaveActive = false; return true; } bool AuthXPGP::CheckSaveCertificates() { xpgpMtx.lock(); /***** LOCK *****/ if ((mConfigSaveActive) && (mToSaveCerts)) { mToSaveCerts = false; xpgpMtx.unlock(); /**** UNLOCK ****/ saveCertificates(); return true; } xpgpMtx.unlock(); /**** UNLOCK ****/ return false; } bool AuthXPGP::saveCertificates() { // construct file name. // create the file in memory - hash + sign. // write out data to a file. xpgpMtx.lock(); /***** LOCK *****/ std::string configfile = mCertConfigFile; std::string neighdir = mNeighDir; xpgpMtx.unlock(); /**** UNLOCK ****/ /* add on the slash */ if (neighdir != "") { neighdir += "/"; } std::map::iterator mit; std::string conftxt; std::string empty(""); unsigned int i; #ifdef AUTHXPGP_DEBUG std::cerr << "AuthXPGP::saveCertificates()"; std::cerr << std::endl; #endif xpgpMtx.lock(); /***** LOCK *****/ /* iterate through both lists */ std::map::iterator it; for(it = mCerts.begin(); it != mCerts.end(); it++) { if (it->second->trustLvl > TRUST_SIGN_BASIC) { XPGP *xpgp = it->second->certificate; std::string hash; std::string neighfile = neighdir + getCertName(xpgp) + ".pqi"; if (saveXPGPToFile(xpgp, neighfile, hash)) { conftxt += "CERT "; conftxt += getCertName(xpgp); conftxt += "\n"; conftxt += hash; conftxt += "\n"; } } } // now work out signature of it all. This relies on the // EVP library of openSSL..... We are going to use signing // for the moment. unsigned int signlen = EVP_PKEY_size(pkey); unsigned char signature[signlen]; //OpenSSL_add_all_digests(); EVP_MD_CTX *mdctx = EVP_MD_CTX_create(); if (0 == EVP_SignInit_ex(mdctx, EVP_sha1(), NULL)) { #ifdef XPGP_DEBUG std::cerr << "EVP_SignInit Failure!" << std::endl; #endif } if (0 == EVP_SignUpdate(mdctx, conftxt.c_str(), conftxt.length())) { #ifdef XPGP_DEBUG std::cerr << "EVP_SignUpdate Failure!" << std::endl; #endif } if (0 == EVP_SignFinal(mdctx, signature, &signlen, pkey)) { #ifdef XPGP_DEBUG std::cerr << "EVP_SignFinal Failure!" << std::endl; #endif } #ifdef XPGP_DEBUG std::cerr << "Conf Signature is(" << signlen << "): "; #endif for(i = 0; i < signlen; i++) { #ifdef XPGP_DEBUG fprintf(stderr, "%02x", signature[i]); #endif conftxt += signature[i]; } #ifdef XPGP_DEBUG std::cerr << std::endl; #endif FILE *cfd = fopen(configfile.c_str(), "wb"); int wrec; if (1 != (wrec = fwrite(conftxt.c_str(), conftxt.length(), 1, cfd))) { #ifdef XPGP_DEBUG std::cerr << "Error writing: " << configfile << std::endl; std::cerr << "Wrote: " << wrec << "/" << 1 << " Records" << std::endl; #endif } EVP_MD_CTX_destroy(mdctx); fclose(cfd); xpgpMtx.unlock(); /**** UNLOCK ****/ return true; } /****** * Special version for backwards compatibility * * has two extra parameters. * bool oldFormat & std::map keyvaluemap * * We'll leave these in for the next couple of months... * so that old versions will automatically be converted to the * new format! * */ bool AuthXPGP::loadCertificates() { bool oldFormat; std::map keyValueMap; return loadCertificates(oldFormat, keyValueMap); } /********************* * NOTE no need to Lock here. locking handled in ProcessXPGP() */ static const uint32_t OPT_LEN = 16; static const uint32_t VAL_LEN = 1000; bool AuthXPGP::loadCertificates(bool &oldFormat, std::map &keyValueMap) { /******************************************* * open the configuration file. * read in CERT + Hash. * * construct file name. * create the file in memory - hash + sign. * write out data to a file. *****************************************/ xpgpMtx.lock(); /***** LOCK *****/ std::string configfile = mCertConfigFile; std::string neighdir = mNeighDir; xpgpMtx.unlock(); /**** UNLOCK ****/ /* add on the slash */ if (neighdir != "") { neighdir += "/"; } oldFormat = false; std::string conftxt; unsigned int maxnamesize = 1024; char name[maxnamesize]; int c; unsigned int i; FILE *cfd = fopen(configfile.c_str(), "rb"); if (cfd == NULL) { #ifdef XPGP_DEBUG std::cerr << "Unable to Load Configuration File!" << std::endl; std::cerr << "File: " << configfile << std::endl; #endif return false; } std::list fnames; std::list hashes; std::map::iterator mit; std::map tmpsettings; unsigned int signlen = EVP_PKEY_size(pkey); unsigned char conf_signature[signlen]; char *ret = NULL; for(ret = fgets(name, maxnamesize, cfd); ((ret != NULL) && (!strncmp(name, "CERT ", 5))); ret = fgets(name, maxnamesize, cfd)) { for(i = 5; (name[i] != '\n') && (i < (unsigned) maxnamesize); i++); if (name[i] == '\n') { name[i] = '\0'; } // so the name is first.... std::string fname = &(name[5]); // now read the std::string hash; std::string signature; for(i = 0; i < signlen; i++) { if (EOF == (c = fgetc(cfd))) { #ifdef XPGP_DEBUG std::cerr << "Error Reading Signature of: "; std::cerr << fname; std::cerr << std::endl; std::cerr << "ABorting Load!"; std::cerr << std::endl; #endif return -1; } unsigned char uc = (unsigned char) c; signature += (unsigned char) uc; } if ('\n' != (c = fgetc(cfd))) { #ifdef XPGP_DEBUG std::cerr << "Warning Mising seperator" << std::endl; #endif } #ifdef XPGP_DEBUG std::cerr << "Read fname:" << fname << std::endl; std::cerr << "Signature:" << std::endl; for(i = 0; i < signlen; i++) { fprintf(stderr, "%02x", (unsigned char) signature[i]); } std::cerr << std::endl; std::cerr << std::endl; #endif // push back..... fnames.push_back(fname); hashes.push_back(signature); conftxt += "CERT "; conftxt += fname; conftxt += "\n"; conftxt += signature; conftxt += "\n"; // be sure to write over a bit... name[0] = 'N'; name[1] = 'O'; } // string already waiting! for(; ((ret != NULL) && (!strncmp(name, "OPT ", 4))); ret = fgets(name, maxnamesize, cfd)) { for(i = 4; (name[i] != '\n') && (i < OPT_LEN); i++); // terminate the string. name[i] = '\0'; // so the name is first.... std::string opt = &(name[4]); // now read the std::string val; // cleaned up value. std::string valsign; // value in the file. for(i = 0; i < VAL_LEN; i++) { if (EOF == (c = fgetc(cfd))) { #ifdef XPGP_DEBUG std::cerr << "Error Reading Value of: "; std::cerr << opt; std::cerr << std::endl; std::cerr << "ABorting Load!"; std::cerr << std::endl; #endif return -1; } // remove zeros on strings... if (c != '\0') { val += (unsigned char) c; } valsign += (unsigned char) c; } if ('\n' != (c = fgetc(cfd))) { #ifdef XPGP_DEBUG std::cerr << "Warning Mising seperator" << std::endl; #endif } #ifdef XPGP_DEBUG std::cerr << "Read OPT:" << opt; std::cerr << " Val:" << val << std::endl; #endif // push back..... tmpsettings[opt] = val; conftxt += "OPT "; conftxt += opt; conftxt += "\n"; conftxt += valsign; conftxt += "\n"; // be sure to write over a bit... name[0] = 'N'; name[1] = 'O'; } // only read up to the first newline symbol.... // continue... for(i = 0; (name[i] != '\n') && (i < signlen); i++); if (i != signlen) { for(i++; i < signlen; i++) { c = fgetc(cfd); if (c == EOF) { #ifdef XPGP_DEBUG std::cerr << "Error Reading Conf Signature:"; std::cerr << std::endl; #endif return 1; } unsigned char uc = (unsigned char) c; name[i] = uc; } } #ifdef XPGP_DEBUG std::cerr << "Configuration File Signature: " << std::endl; for(i = 0; i < signlen; i++) { fprintf(stderr, "%02x", (unsigned char) name[i]); } std::cerr << std::endl; #endif // when we get here - should have the final signature in the buffer. // check. // // compare signatures. // instead of verifying with the public key.... // we'll sign it again - and compare .... FIX LATER... EVP_MD_CTX *mdctx = EVP_MD_CTX_create(); if (0 == EVP_SignInit(mdctx, EVP_sha1())) { #ifdef XPGP_DEBUG #endif std::cerr << "EVP_SignInit Failure!" << std::endl; } if (0 == EVP_SignUpdate(mdctx, conftxt.c_str(), conftxt.length())) { #ifdef XPGP_DEBUG std::cerr << "EVP_SignUpdate Failure!" << std::endl; #endif } if (0 == EVP_SignFinal(mdctx, conf_signature, &signlen, pkey)) { #ifdef XPGP_DEBUG std::cerr << "EVP_SignFinal Failure!" << std::endl; #endif } EVP_MD_CTX_destroy(mdctx); fclose(cfd); #ifdef XPGP_DEBUG std::cerr << "Recalced File Signature: " << std::endl; for(i = 0; i < signlen; i++) { fprintf(stderr, "%02x", conf_signature[i]); } std::cerr << std::endl; #endif bool same = true; for(i = 0; i < signlen; i++) { if ((unsigned char) name[i] != conf_signature[i]) { same = false; } } if (same == false) { #ifdef XPGP_DEBUG std::cerr << "ERROR VALIDATING CONFIGURATION!" << std::endl; std::cerr << "PLEASE FIX!" << std::endl; #endif return false; } std::list::iterator it; std::list::iterator it2; for(it = fnames.begin(), it2 = hashes.begin(); it != fnames.end(); it++, it2++) { std::string neighfile = neighdir + (*it) + ".pqi"; XPGP *xpgp = loadXPGPFromFile(neighfile, (*it2)); if (xpgp != NULL) { std::string id; if (ProcessXPGP(xpgp, id)) { #ifdef XPGP_DEBUG std::cerr << "Loaded Certificate: " << id; std::cerr << std::endl; #endif } } } for(mit = tmpsettings.begin(); mit != tmpsettings.end(); mit++) { keyValueMap[mit -> first] = mit -> second; } mToSaveCerts = false; if (keyValueMap.size() > 0) { oldFormat = true; mToSaveCerts = true; } return true; }