ref: 7be7d0681f567e97fd37f937c2e5e486d6d74eab
dir: /sys/src/ape/lib/openssl/demos/easy_tls/easy-tls.c/
/* -*- Mode: C; c-file-style: "bsd" -*- */ /* * easy-tls.c -- generic TLS proxy. * $Id: easy-tls.c,v 1.4 2002/03/05 09:07:16 bodo Exp $ */ /* (c) Copyright 1999 Bodo Moeller. All rights reserved. This is free software; you can redistributed and/or modify it unter the terms of either - the GNU General Public License as published by the Free Software Foundation, version 1, or (at your option) any later version, or - the following license: */ /* * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that each of the following * conditions is met: * * 1. Redistributions qualify as "freeware" or "Open Source Software" under * one of the following terms: * * (a) Redistributions are made at no charge beyond the reasonable cost of * materials and delivery. * * (b) Redistributions are accompanied by a copy of the Source Code * or by an irrevocable offer to provide a copy of the Source Code * for up to three years at the cost of materials and delivery. * Such redistributions must allow further use, modification, and * redistribution of the Source Code under substantially the same * terms as this license. * * 2. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 3. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * 4. All advertising materials mentioning features or use of this * software must display the following acknowledgment: * "This product includes software developed by Bodo Moeller." * (If available, substitute umlauted o for oe.) * * 5. Redistributions of any form whatsoever must retain the following * acknowledgment: * "This product includes software developed by Bodo Moeller." * * THIS SOFTWARE IS PROVIDED BY BODO MOELLER ``AS IS'' AND ANY * EXPRESSED OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL BODO MOELLER OR * HIS CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED * OF THE POSSIBILITY OF SUCH DAMAGE. */ /* * Attribution for OpenSSL library: * * This product includes cryptographic software written by Eric Young * ([email protected]). This product includes software written by Tim * Hudson ([email protected]). * This product includes software developed by the OpenSSL Project * for use in the OpenSSL Toolkit. (http://www.openssl.org/) */ static char const rcsid[] = "$Id: easy-tls.c,v 1.4 2002/03/05 09:07:16 bodo Exp $"; #include <assert.h> #include <errno.h> #include <fcntl.h> #include <limits.h> #include <stdarg.h> #include <stdio.h> #include <string.h> #include <sys/select.h> #include <sys/socket.h> #include <sys/stat.h> #include <sys/time.h> #include <sys/types.h> #include <sys/utsname.h> #include <unistd.h> #include <openssl/crypto.h> #include <openssl/dh.h> #include <openssl/dsa.h> #include <openssl/err.h> #include <openssl/evp.h> #include <openssl/opensslv.h> #include <openssl/pem.h> #include <openssl/rand.h> #ifndef NO_RSA #include <openssl/rsa.h> #endif #include <openssl/ssl.h> #include <openssl/x509.h> #include <openssl/x509_vfy.h> #if OPENSSL_VERSION_NUMBER < 0x00904000L /* 0.9.4-dev */ # error "This program needs OpenSSL 0.9.4 or later." #endif #include "easy-tls.h" /* include after <openssl/ssl.h> if both are needed */ #if TLS_INFO_SIZE > PIPE_BUF # if PIPE_BUF < 512 # error "PIPE_BUF < 512" /* non-POSIX */ # endif # error "TLS_INFO_SIZE > PIPE_BUF" #endif /*****************************************************************************/ #ifdef TLS_APP # include TLS_APP #endif /* Applications can define: * TLS_APP_PROCESS_INIT -- void ...(int fd, int client_p, void *apparg) * TLS_CUMULATE_ERRORS * TLS_ERROR_BUFSIZ * TLS_APP_ERRFLUSH -- void ...(int child_p, char *, size_t, void *apparg) */ #ifndef TLS_APP_PROCESS_INIT # define TLS_APP_PROCESS_INIT(fd, client_p, apparg) ((void) 0) #endif #ifndef TLS_ERROR_BUFSIZ # define TLS_ERROR_BUFSIZ (10*160) #endif #if TLS_ERROR_BUFSIZ < 2 /* {'\n',0} */ # error "TLS_ERROR_BUFSIZE is too small." #endif #ifndef TLS_APP_ERRFLUSH # define TLS_APP_ERRFLUSH tls_app_errflush static void tls_app_errflush(int child_p, char *errbuf, size_t num, void *apparg) { fputs(errbuf, stderr); } #endif /*****************************************************************************/ #ifdef DEBUG_TLS # define DEBUG_MSG(x) fprintf(stderr," %s\n",x) # define DEBUG_MSG2(x,y) fprintf(stderr, " %s: %d\n",x,y) static int tls_loop_count = 0; static int tls_select_count = 0; #else # define DEBUG_MSG(x) (void)0 # define DEBUG_MSG2(x,y) (void)0 #endif static void tls_rand_seed_uniquely(void); static void tls_proxy(int clear_fd, int tls_fd, int info_fd, SSL_CTX *ctx, int client_p); static int tls_socket_nonblocking(int fd); static int tls_child_p = 0; static void *tls_child_apparg; struct tls_start_proxy_args tls_start_proxy_defaultargs(void) { struct tls_start_proxy_args ret; ret.fd = -1; ret.client_p = -1; ret.ctx = NULL; ret.pid = NULL; ret.infofd = NULL; return ret; } /* Slice in TLS proxy process at fd. * Return value: * 0 ok (*pid is set to child's PID if pid != NULL), * < 0 look at errno * > 0 other error * (return value encodes place of error) * */ int tls_start_proxy(struct tls_start_proxy_args a, void *apparg) { int fds[2] = {-1, -1}; int infofds[2] = {-1, -1}; int r, getfd, getfl; int ret; DEBUG_MSG2("tls_start_proxy fd", a.fd); DEBUG_MSG2("tls_start_proxy client_p", a.client_p); if (a.fd == -1 || a.client_p == -1 || a.ctx == NULL) return 1; if (a.pid != NULL) { *a.pid = 0; } if (a.infofd != NULL) { *a.infofd = -1; } r = socketpair(AF_UNIX, SOCK_STREAM, 0, fds); if (r == -1) return -1; if (a.fd >= FD_SETSIZE || fds[0] >= FD_SETSIZE) { ret = 2; goto err; } if (a.infofd != NULL) { r = pipe(infofds); if (r == -1) { ret = -3; goto err; } } r = fork(); if (r == -1) { ret = -4; goto err; } if (r == 0) { DEBUG_MSG("fork"); tls_child_p = 1; tls_child_apparg = apparg; close(fds[1]); if (infofds[0] != -1) close(infofds[0]); TLS_APP_PROCESS_INIT(a.fd, a.client_p, apparg); DEBUG_MSG("TLS_APP_PROCESS_INIT"); tls_proxy(fds[0], a.fd, infofds[1], a.ctx, a.client_p); exit(0); } if (a.pid != NULL) *a.pid = r; if (infofds[1] != -1) { close(infofds[1]); infofds[1] = -1; } /* install fds[1] in place of fd: */ close(fds[0]); fds[0] = -1; getfd = fcntl(a.fd, F_GETFD); getfl = fcntl(a.fd, F_GETFL); r = dup2(fds[1], a.fd); close(fds[1]); fds[1] = -1; if (r == -1) { ret = -5; goto err; } if (getfd != 1) fcntl(a.fd, F_SETFD, getfd); if (getfl & O_NONBLOCK) (void)tls_socket_nonblocking(a.fd); if (a.infofd != NULL) *a.infofd = infofds[0]; return 0; err: if (fds[0] != -1) close(fds[0]); if (fds[1] != -1) close(fds[1]); if (infofds[0] != -1) close(infofds[0]); if (infofds[1] != -1) close(infofds[1]); return ret; } /*****************************************************************************/ static char errbuf[TLS_ERROR_BUFSIZ]; static size_t errbuf_i = 0; static void tls_errflush(void *apparg) { if (errbuf_i == 0) return; assert(errbuf_i < sizeof errbuf); assert(errbuf[errbuf_i] == 0); if (errbuf_i == sizeof errbuf - 1) { /* make sure we have a newline, even if string has been truncated */ errbuf[errbuf_i - 1] = '\n'; } /* TLS_APP_ERRFLUSH may modify the string as needed, * e.g. substitute other characters for \n for convenience */ TLS_APP_ERRFLUSH(tls_child_p, errbuf, errbuf_i, apparg); errbuf_i = 0; } static void tls_errprintf(int flush, void *apparg, const char *fmt, ...) { va_list args; int r; if (errbuf_i < sizeof errbuf - 1) { size_t n; va_start(args, fmt); n = (sizeof errbuf) - errbuf_i; r = vsnprintf(errbuf + errbuf_i, n, fmt, args); if (r >= n) r = n - 1; if (r >= 0) { errbuf_i += r; } else { errbuf_i = sizeof errbuf - 1; errbuf[errbuf_i] = '\0'; } assert(errbuf_i < sizeof errbuf); assert(errbuf[errbuf_i] == 0); } #ifndef TLS_CUMULATE_ERRORS tls_errflush(apparg); #else if (flush) tls_errflush(apparg); #endif } /* app_prefix.. are for additional information provided by caller. * If OpenSSL error queue is empty, print default_text ("???" if NULL). */ static char * tls_openssl_errors(const char *app_prefix_1, const char *app_prefix_2, const char *default_text, void *apparg) { static char reasons[255]; size_t reasons_i; unsigned long err; const char *file; int line; const char *data; int flags; char *errstring; int printed_something = 0; reasons_i = 0; assert(app_prefix_1 != NULL); assert(app_prefix_2 != NULL); if (default_text == NULL) default_text = "?""?""?"; while ((err = ERR_get_error_line_data(&file,&line,&data,&flags)) != 0) { if (reasons_i < sizeof reasons) { size_t n; int r; n = (sizeof reasons) - reasons_i; r = snprintf(reasons + reasons_i, n, "%s%s", (reasons_i > 0 ? ", " : ""), ERR_reason_error_string(err)); if (r >= n) r = n - 1; if (r >= 0) { reasons_i += r; } else { reasons_i = sizeof reasons; } assert(reasons_i <= sizeof reasons); } errstring = ERR_error_string(err, NULL); assert(errstring != NULL); tls_errprintf(0, apparg, "OpenSSL error%s%s: %s:%s:%d:%s\n", app_prefix_1, app_prefix_2, errstring, file, line, (flags & ERR_TXT_STRING) ? data : ""); printed_something = 1; } if (!printed_something) { assert(reasons_i == 0); snprintf(reasons, sizeof reasons, "%s", default_text); tls_errprintf(0, apparg, "OpenSSL error%s%s: %s\n", app_prefix_1, app_prefix_2, default_text); } #ifdef TLS_CUMULATE_ERRORS tls_errflush(apparg); #endif assert(errbuf_i == 0); return reasons; } /*****************************************************************************/ static int tls_init_done = 0; static int tls_init(void *apparg) { if (tls_init_done) return 0; SSL_load_error_strings(); if (!SSL_library_init() /* aka SSLeay_add_ssl_algorithms() */ ) { tls_errprintf(1, apparg, "SSL_library_init failed.\n"); return -1; } tls_init_done = 1; tls_rand_seed(); return 0; } /*****************************************************************************/ static void tls_rand_seed_uniquely(void) { struct { pid_t pid; time_t time; void *stack; } data; data.pid = getpid(); data.time = time(NULL); data.stack = (void *)&data; RAND_seed((const void *)&data, sizeof data); } void tls_rand_seed(void) { struct { struct utsname uname; int uname_1; int uname_2; uid_t uid; uid_t euid; gid_t gid; gid_t egid; } data; data.uname_1 = uname(&data.uname); data.uname_2 = errno; /* Let's hope that uname fails randomly :-) */ data.uid = getuid(); data.euid = geteuid(); data.gid = getgid(); data.egid = getegid(); RAND_seed((const void *)&data, sizeof data); tls_rand_seed_uniquely(); } static int tls_rand_seeded_p = 0; #define my_MIN_SEED_BYTES 256 /* struct stat can be larger than 128 */ int tls_rand_seed_from_file(const char *filename, size_t n, void *apparg) { /* Seed OpenSSL's random number generator from file. Try to read n bytes if n > 0, whole file if n == 0. */ int r; if (tls_init(apparg) == -1) return -1; tls_rand_seed(); r = RAND_load_file(filename, (n > 0 && n < LONG_MAX) ? (long)n : LONG_MAX); /* r is the number of bytes filled into the random number generator, * which are taken from "stat(filename, ...)" in addition to the * file contents. */ assert(1 < my_MIN_SEED_BYTES); /* We need to detect at least those cases when the file does not exist * at all. With current versions of OpenSSL, this should do it: */ if (n == 0) n = my_MIN_SEED_BYTES; if (r < n) { tls_errprintf(1, apparg, "rand_seed_from_file: could not read %d bytes from %s.\n", n, filename); return -1; } else { tls_rand_seeded_p = 1; return 0; } } void tls_rand_seed_from_memory(const void *buf, size_t n) { size_t i = 0; while (i < n) { size_t rest = n - i; int chunk = rest < INT_MAX ? (int)rest : INT_MAX; RAND_seed((const char *)buf + i, chunk); i += chunk; } tls_rand_seeded_p = 1; } /*****************************************************************************/ struct tls_x509_name_string { char str[100]; }; static void tls_get_x509_subject_name_oneline(X509 *cert, struct tls_x509_name_string *namestring) { X509_NAME *name; if (cert == NULL) { namestring->str[0] = '\0'; return; } name = X509_get_subject_name(cert); /* does not increment any reference counter */ assert(sizeof namestring->str >= 4); /* "?" or "...", plus 0 */ if (name == NULL) { namestring->str[0] = '?'; namestring->str[1] = 0; } else { size_t len; X509_NAME_oneline(name, namestring->str, sizeof namestring->str); len = strlen(namestring->str); assert(namestring->str[len] == 0); assert(len < sizeof namestring->str); if (len+1 == sizeof namestring->str) { /* (Probably something was cut off.) * Does not really work -- X509_NAME_oneline truncates after * name components, we cannot tell from the result whether * anything is missing. */ assert(namestring->str[len] == 0); namestring->str[--len] = '.'; namestring->str[--len] = '.'; namestring->str[--len] = '.'; } } } /*****************************************************************************/ /* to hinder OpenSSL from asking for passphrases */ static int no_passphrase_callback(char *buf, int num, int w, void *arg) { return -1; } #if OPENSSL_VERSION_NUMBER >= 0x00907000L static int verify_dont_fail_cb(X509_STORE_CTX *c, void *unused_arg) #else static int verify_dont_fail_cb(X509_STORE_CTX *c) #endif { int i; i = X509_verify_cert(c); /* sets c->error */ #if OPENSSL_VERSION_NUMBER >= 0x00905000L /* don't allow unverified * certificates -- they could * survive session reuse, but * OpenSSL < 0.9.5-dev does not * preserve their verify_result */ if (i == 0) return 1; else #endif return i; } static DH *tls_dhe1024 = NULL; /* generating these takes a while, so do it just once */ void tls_set_dhe1024(int i, void *apparg) { DSA *dsaparams; DH *dhparams; const char *seed[] = { ";-) :-( :-) :-( ", ";-) :-( :-) :-( ", "Random String no. 12", ";-) :-( :-) :-( ", "hackers have even mo", /* from jargon file */ }; unsigned char seedbuf[20]; tls_init(apparg); if (i >= 0) { i %= sizeof seed / sizeof seed[0]; assert(strlen(seed[i]) == 20); memcpy(seedbuf, seed[i], 20); dsaparams = DSA_generate_parameters(1024, seedbuf, 20, NULL, NULL, 0, NULL); } else { /* random parameters (may take a while) */ dsaparams = DSA_generate_parameters(1024, NULL, 0, NULL, NULL, 0, NULL); } if (dsaparams == NULL) { tls_openssl_errors("", "", NULL, apparg); return; } dhparams = DSA_dup_DH(dsaparams); DSA_free(dsaparams); if (dhparams == NULL) { tls_openssl_errors("", "", NULL, apparg); return; } if (tls_dhe1024 != NULL) DH_free(tls_dhe1024); tls_dhe1024 = dhparams; } struct tls_create_ctx_args tls_create_ctx_defaultargs(void) { struct tls_create_ctx_args ret; ret.client_p = 0; ret.certificate_file = NULL; ret.key_file = NULL; ret.ca_file = NULL; ret.verify_depth = -1; ret.fail_unless_verified = 0; ret.export_p = 0; return ret; } SSL_CTX * tls_create_ctx(struct tls_create_ctx_args a, void *apparg) { int r; static long context_num = 0; SSL_CTX *ret; const char *err_pref_1 = "", *err_pref_2 = ""; if (tls_init(apparg) == -1) return NULL; ret = SSL_CTX_new((a.client_p? SSLv23_client_method:SSLv23_server_method)()); if (ret == NULL) goto err; SSL_CTX_set_default_passwd_cb(ret, no_passphrase_callback); SSL_CTX_set_mode(ret, SSL_MODE_ENABLE_PARTIAL_WRITE); if ((a.certificate_file != NULL) || (a.key_file != NULL)) { if (a.key_file == NULL) { tls_errprintf(1, apparg, "Need a key file.\n"); goto err_return; } if (a.certificate_file == NULL) { tls_errprintf(1, apparg, "Need a certificate chain file.\n"); goto err_return; } if (!SSL_CTX_use_PrivateKey_file(ret, a.key_file, SSL_FILETYPE_PEM)) goto err; if (!tls_rand_seeded_p) { /* particularly paranoid people may not like this -- * so provide your own random seeding before calling this */ if (tls_rand_seed_from_file(a.key_file, 0, apparg) == -1) goto err_return; } if (!SSL_CTX_use_certificate_chain_file(ret, a.certificate_file)) goto err; if (!SSL_CTX_check_private_key(ret)) { tls_errprintf(1, apparg, "Private key \"%s\" does not match certificate \"%s\".\n", a.key_file, a.certificate_file); goto err_peek; } } if ((a.ca_file != NULL) || (a.verify_depth > 0)) { context_num++; r = SSL_CTX_set_session_id_context(ret, (const void *)&context_num, (unsigned int)sizeof context_num); if (!r) goto err; SSL_CTX_set_verify(ret, SSL_VERIFY_PEER | (a.fail_unless_verified ? SSL_VERIFY_FAIL_IF_NO_PEER_CERT : 0), 0); if (!a.fail_unless_verified) SSL_CTX_set_cert_verify_callback(ret, verify_dont_fail_cb, NULL); if (a.verify_depth > 0) SSL_CTX_set_verify_depth(ret, a.verify_depth); if (a.ca_file != NULL) { r = SSL_CTX_load_verify_locations(ret, a.ca_file, NULL /* no CA-directory */); /* does not report failure if file does not exist ... */ if (!r) { err_pref_1 = " while processing certificate file "; err_pref_2 = a.ca_file; goto err; } if (!a.client_p) { /* SSL_load_client_CA_file is a misnomer, it just creates a list of CNs. */ SSL_CTX_set_client_CA_list(ret, SSL_load_client_CA_file(a.ca_file)); /* SSL_CTX_set_client_CA_list does not have a return value; * it does not really need one, but make sure * (we really test if SSL_load_client_CA_file worked) */ if (SSL_CTX_get_client_CA_list(ret) == NULL) { tls_errprintf(1, apparg, "Could not set client CA list from \"%s\".\n", a.ca_file); goto err_peek; } } } } if (!a.client_p) { if (tls_dhe1024 == NULL) { int i; RAND_bytes((unsigned char *) &i, sizeof i); /* make sure that i is non-negative -- pick one of the provided * seeds */ if (i < 0) i = -i; if (i < 0) i = 0; tls_set_dhe1024(i, apparg); if (tls_dhe1024 == NULL) goto err_return; } if (!SSL_CTX_set_tmp_dh(ret, tls_dhe1024)) goto err; /* avoid small subgroup attacks: */ SSL_CTX_set_options(ret, SSL_OP_SINGLE_DH_USE); } #ifndef NO_RSA if (!a.client_p && a.export_p) { RSA *tmpkey; tmpkey = RSA_generate_key(512, RSA_F4, 0, NULL); if (tmpkey == NULL) goto err; if (!SSL_CTX_set_tmp_rsa(ret, tmpkey)) { RSA_free(tmpkey); goto err; } RSA_free(tmpkey); /* SSL_CTX_set_tmp_rsa uses a duplicate. */ } #endif return ret; err_peek: if (!ERR_peek_error()) goto err_return; err: tls_openssl_errors(err_pref_1, err_pref_2, NULL, apparg); err_return: if (ret != NULL) SSL_CTX_free(ret); return NULL; } /*****************************************************************************/ static int tls_socket_nonblocking(int fd) { int v, r; v = fcntl(fd, F_GETFL, 0); if (v == -1) { if (errno == EINVAL) return 0; /* already shut down -- ignore */ return -1; } r = fcntl(fd, F_SETFL, v | O_NONBLOCK); if (r == -1) { if (errno == EINVAL) return 0; /* already shut down -- ignore */ return -1; } return 0; } static int max(int a, int b) { return a > b ? a : b; } static void tls_sockets_select(int read_select_1, int read_select_2, int write_select_1, int write_select_2, int seconds /* timeout, -1 means no timeout */) { int maxfd, n; fd_set reads, writes; struct timeval timeout; struct timeval *timeout_p; assert(read_select_1 >= -1 && read_select_2 >= -1 && write_select_1 >= -1 && write_select_2 >= -1); assert(read_select_1 < FD_SETSIZE && read_select_2 < FD_SETSIZE -1 && write_select_1 < FD_SETSIZE -1 && write_select_2 < FD_SETSIZE -1); maxfd = max(max(read_select_1, read_select_2), max(write_select_1, write_select_2)); assert(maxfd >= 0); FD_ZERO(&reads); FD_ZERO(&writes); for(n = 0; n < 4; ++n) { int i = n % 2; int w = n >= 2; /* loop over all (i, w) in {0,1}x{0,1} */ int fd; if (i == 0 && w == 0) fd = read_select_1; else if (i == 1 && w == 0) fd = read_select_2; else if (i == 0 && w == 1) fd = write_select_1; else { assert(i == 1 && w == 1); fd = write_select_2; } if (fd >= 0) { if (w == 0) FD_SET(fd, &reads); else /* w == 1 */ FD_SET(fd, &writes); } } if (seconds >= 0) { timeout.tv_sec = seconds; timeout.tv_usec = 0; timeout_p = &timeout; } else timeout_p = NULL; DEBUG_MSG2("select no.", ++tls_select_count); select(maxfd + 1, &reads, &writes, (fd_set *) NULL, timeout_p); DEBUG_MSG("cont."); } /*****************************************************************************/ #define TUNNELBUFSIZE (16*1024) struct tunnelbuf { char buf[TUNNELBUFSIZE]; size_t len; size_t offset; }; static int tls_connect_attempt(SSL *, int *write_select, int *read_select, int *closed, int *progress, const char **err_pref); static int tls_accept_attempt(SSL *, int *write_select, int *read_select, int *closed, int *progress, const char **err_pref); static int tls_write_attempt(SSL *, struct tunnelbuf *, int *write_select, int *read_select, int *closed, int *progress, const char **err_pref); static int tls_read_attempt(SSL *, struct tunnelbuf *, int *write_select, int *read_select, int *closed, int *progress, const char **err_pref); static int write_attempt(int fd, struct tunnelbuf *, int *select, int *closed, int *progress); static int read_attempt(int fd, struct tunnelbuf *, int *select, int *closed, int *progress); static void write_info(SSL *ssl, int *info_fd) { if (*info_fd != -1) { long v; int v_ok; struct tls_x509_name_string peer; char infobuf[TLS_INFO_SIZE]; int r; DEBUG_MSG("write_info"); v = SSL_get_verify_result(ssl); v_ok = (v == X509_V_OK) ? 'A' : 'E'; /* Auth./Error */ { X509 *peercert; peercert = SSL_get_peer_certificate(ssl); tls_get_x509_subject_name_oneline(peercert, &peer); if (peercert != NULL) X509_free(peercert); } if (peer.str[0] == '\0') v_ok = '0'; /* no cert at all */ else if (strchr(peer.str, '\n')) { /* should not happen, but make sure */ *strchr(peer.str, '\n') = '\0'; } r = snprintf(infobuf, sizeof infobuf, "%c:%s\n%s\n", v_ok, X509_verify_cert_error_string(v), peer.str); DEBUG_MSG2("snprintf", r); if (r == -1 || r >= sizeof infobuf) r = sizeof infobuf - 1; write(*info_fd, infobuf, r); close (*info_fd); *info_fd = -1; } } /* tls_proxy expects that all fds are closed after return */ static void tls_proxy(int clear_fd, int tls_fd, int info_fd, SSL_CTX *ctx, int client_p) { struct tunnelbuf clear_to_tls, tls_to_clear; SSL *ssl; BIO *rbio, *wbio; int closed, in_handshake; const char *err_pref_1 = "", *err_pref_2 = ""; const char *err_def = NULL; assert(clear_fd != -1); assert(tls_fd != -1); assert(clear_fd < FD_SETSIZE); assert(tls_fd < FD_SETSIZE); /* info_fd may be -1 */ assert(ctx != NULL); tls_rand_seed_uniquely(); tls_socket_nonblocking(clear_fd); DEBUG_MSG2("clear_fd", clear_fd); tls_socket_nonblocking(tls_fd); DEBUG_MSG2("tls_fd", tls_fd); ssl = SSL_new(ctx); if (ssl == NULL) goto err; DEBUG_MSG("SSL_new"); if (!SSL_set_fd(ssl, tls_fd)) goto err; rbio = SSL_get_rbio(ssl); wbio = SSL_get_wbio(ssl); /* should be the same, but who cares */ assert(rbio != NULL); assert(wbio != NULL); if (client_p) SSL_set_connect_state(ssl); else SSL_set_accept_state(ssl); closed = 0; in_handshake = 1; tls_to_clear.len = 0; tls_to_clear.offset = 0; clear_to_tls.len = 0; clear_to_tls.offset = 0; err_def = "I/O error"; /* loop finishes as soon as we detect that one side closed; * when all (program and OS) buffers have enough space, * the data from the last succesful read in each direction is transferred * before close */ do { int clear_read_select = 0, clear_write_select = 0, tls_read_select = 0, tls_write_select = 0, progress = 0; int r; unsigned long num_read = BIO_number_read(rbio), num_written = BIO_number_written(wbio); DEBUG_MSG2("loop iteration", ++tls_loop_count); if (in_handshake) { DEBUG_MSG("in_handshake"); if (client_p) r = tls_connect_attempt(ssl, &tls_write_select, &tls_read_select, &closed, &progress, &err_pref_1); else r = tls_accept_attempt(ssl, &tls_write_select, &tls_read_select, &closed, &progress, &err_pref_1); if (r != 0) { write_info(ssl, &info_fd); goto err; } if (closed) goto err_return; if (!SSL_in_init(ssl)) { in_handshake = 0; write_info(ssl, &info_fd); } } if (clear_to_tls.len != 0 && !in_handshake) { assert(!closed); r = tls_write_attempt(ssl, &clear_to_tls, &tls_write_select, &tls_read_select, &closed, &progress, &err_pref_1); if (r != 0) goto err; if (closed) { assert(progress); tls_to_clear.offset = 0; tls_to_clear.len = 0; } } if (tls_to_clear.len != 0) { assert(!closed); r = write_attempt(clear_fd, &tls_to_clear, &clear_write_select, &closed, &progress); if (r != 0) goto err_return; if (closed) { assert(progress); clear_to_tls.offset = 0; clear_to_tls.len = 0; } } if (!closed) { if (clear_to_tls.offset + clear_to_tls.len < sizeof clear_to_tls.buf) { r = read_attempt(clear_fd, &clear_to_tls, &clear_read_select, &closed, &progress); if (r != 0) goto err_return; if (closed) { r = SSL_shutdown(ssl); DEBUG_MSG2("SSL_shutdown", r); } } } if (!closed && !in_handshake) { if (tls_to_clear.offset + tls_to_clear.len < sizeof tls_to_clear.buf) { r = tls_read_attempt(ssl, &tls_to_clear, &tls_write_select, &tls_read_select, &closed, &progress, &err_pref_1); if (r != 0) goto err; if (closed) { r = SSL_shutdown(ssl); DEBUG_MSG2("SSL_shutdown", r); } } } if (!progress) { DEBUG_MSG("!progress?"); if (num_read != BIO_number_read(rbio) || num_written != BIO_number_written(wbio)) progress = 1; if (!progress) { DEBUG_MSG("!progress"); assert(clear_read_select || tls_read_select || clear_write_select || tls_write_select); tls_sockets_select(clear_read_select ? clear_fd : -1, tls_read_select ? tls_fd : -1, clear_write_select ? clear_fd : -1, tls_write_select ? tls_fd : -1, -1); } } } while (!closed); return; err: tls_openssl_errors(err_pref_1, err_pref_2, err_def, tls_child_apparg); err_return: return; } static int tls_get_error(SSL *ssl, int r, int *write_select, int *read_select, int *closed, int *progress) { int err = SSL_get_error(ssl, r); if (err == SSL_ERROR_NONE) { assert(r > 0); *progress = 1; return 0; } assert(r <= 0); switch (err) { case SSL_ERROR_ZERO_RETURN: assert(r == 0); *closed = 1; *progress = 1; return 0; case SSL_ERROR_WANT_WRITE: *write_select = 1; return 0; case SSL_ERROR_WANT_READ: *read_select = 1; return 0; } return -1; } static int tls_connect_attempt(SSL *ssl, int *write_select, int *read_select, int *closed, int *progress, const char **err_pref) { int n, r; DEBUG_MSG("tls_connect_attempt"); n = SSL_connect(ssl); DEBUG_MSG2("SSL_connect",n); r = tls_get_error(ssl, n, write_select, read_select, closed, progress); if (r == -1) *err_pref = " during SSL_connect"; return r; } static int tls_accept_attempt(SSL *ssl, int *write_select, int *read_select, int *closed, int *progress, const char **err_pref) { int n, r; DEBUG_MSG("tls_accept_attempt"); n = SSL_accept(ssl); DEBUG_MSG2("SSL_accept",n); r = tls_get_error(ssl, n, write_select, read_select, closed, progress); if (r == -1) *err_pref = " during SSL_accept"; return r; } static int tls_write_attempt(SSL *ssl, struct tunnelbuf *buf, int *write_select, int *read_select, int *closed, int *progress, const char **err_pref) { int n, r; DEBUG_MSG("tls_write_attempt"); n = SSL_write(ssl, buf->buf + buf->offset, buf->len); DEBUG_MSG2("SSL_write",n); r = tls_get_error(ssl, n, write_select, read_select, closed, progress); if (n > 0) { buf->len -= n; assert(buf->len >= 0); if (buf->len == 0) buf->offset = 0; else buf->offset += n; } if (r == -1) *err_pref = " during SSL_write"; return r; } static int tls_read_attempt(SSL *ssl, struct tunnelbuf *buf, int *write_select, int *read_select, int *closed, int *progress, const char **err_pref) { int n, r; size_t total; DEBUG_MSG("tls_read_attempt"); total = buf->offset + buf->len; assert(total < sizeof buf->buf); n = SSL_read(ssl, buf->buf + total, (sizeof buf->buf) - total); DEBUG_MSG2("SSL_read",n); r = tls_get_error(ssl, n, write_select, read_select, closed, progress); if (n > 0) { buf->len += n; assert(buf->offset + buf->len <= sizeof buf->buf); } if (r == -1) *err_pref = " during SSL_read"; return r; } static int get_error(int r, int *select, int *closed, int *progress) { if (r >= 0) { *progress = 1; if (r == 0) *closed = 1; return 0; } else { assert(r == -1); if (errno == EAGAIN || errno == EWOULDBLOCK) { *select = 1; return 0; } else if (errno == EPIPE) { *progress = 1; *closed = 1; return 0; } else return -1; } } static int write_attempt(int fd, struct tunnelbuf *buf, int *select, int *closed, int *progress) { int n, r; DEBUG_MSG("write_attempt"); n = write(fd, buf->buf + buf->offset, buf->len); DEBUG_MSG2("write",n); r = get_error(n, select, closed, progress); if (n > 0) { buf->len -= n; assert(buf->len >= 0); if (buf->len == 0) buf->offset = 0; else buf->offset += n; } if (r == -1) tls_errprintf(1, tls_child_apparg, "write error: %s\n", strerror(errno)); return r; } static int read_attempt(int fd, struct tunnelbuf *buf, int *select, int *closed, int *progress) { int n, r; size_t total; DEBUG_MSG("read_attempt"); total = buf->offset + buf->len; assert(total < sizeof buf->buf); n = read(fd, buf->buf + total, (sizeof buf->buf) - total); DEBUG_MSG2("read",n); r = get_error(n, select, closed, progress); if (n > 0) { buf->len += n; assert(buf->offset + buf->len <= sizeof buf->buf); } if (r == -1) tls_errprintf(1, tls_child_apparg, "read error: %s\n", strerror(errno)); return r; }