/* * Copyright (c) 2019, Redis Labs * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * 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. * * Neither the name of Redis nor the names of its contributors may be used * to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS 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 THE COPYRIGHT OWNER OR 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. */ #include "server.h" #include "connhelpers.h" #include "adlist.h" #ifdef USE_OPENSSL #include #include #include #define REDIS_TLS_PROTO_TLSv1 (1<<0) #define REDIS_TLS_PROTO_TLSv1_1 (1<<1) #define REDIS_TLS_PROTO_TLSv1_2 (1<<2) #define REDIS_TLS_PROTO_TLSv1_3 (1<<3) /* Use safe defaults */ #ifdef TLS1_3_VERSION #define REDIS_TLS_PROTO_DEFAULT (REDIS_TLS_PROTO_TLSv1_2|REDIS_TLS_PROTO_TLSv1_3) #else #define REDIS_TLS_PROTO_DEFAULT (REDIS_TLS_PROTO_TLSv1_2) #endif extern ConnectionType CT_Socket; SSL_CTX *redis_tls_ctx; static int parseProtocolsConfig(const char *str) { int i, count = 0; int protocols = 0; if (!str) return REDIS_TLS_PROTO_DEFAULT; sds *tokens = sdssplitlen(str, strlen(str), " ", 1, &count); if (!tokens) { serverLog(LL_WARNING, "Invalid tls-protocols configuration string"); return -1; } for (i = 0; i < count; i++) { if (!strcasecmp(tokens[i], "tlsv1")) protocols |= REDIS_TLS_PROTO_TLSv1; else if (!strcasecmp(tokens[i], "tlsv1.1")) protocols |= REDIS_TLS_PROTO_TLSv1_1; else if (!strcasecmp(tokens[i], "tlsv1.2")) protocols |= REDIS_TLS_PROTO_TLSv1_2; else if (!strcasecmp(tokens[i], "tlsv1.3")) { #ifdef TLS1_3_VERSION protocols |= REDIS_TLS_PROTO_TLSv1_3; #else serverLog(LL_WARNING, "TLSv1.3 is specified in tls-protocols but not supported by OpenSSL."); protocols = -1; break; #endif } else { serverLog(LL_WARNING, "Invalid tls-protocols specified. " "Use a combination of 'TLSv1', 'TLSv1.1', 'TLSv1.2' and 'TLSv1.3'."); protocols = -1; break; } } sdsfreesplitres(tokens, count); return protocols; } /* list of connections with pending data already read from the socket, but not * served to the reader yet. */ static list *pending_list = NULL; void tlsInit(void) { ERR_load_crypto_strings(); SSL_load_error_strings(); SSL_library_init(); if (!RAND_poll()) { serverLog(LL_WARNING, "OpenSSL: Failed to seed random number generator."); } pending_list = listCreate(); /* Server configuration */ server.tls_auth_clients = 1; /* Secure by default */ } /* Attempt to configure/reconfigure TLS. This operation is atomic and will * leave the SSL_CTX unchanged if fails. */ int tlsConfigure(redisTLSContextConfig *ctx_config) { char errbuf[256]; SSL_CTX *ctx = NULL; if (!ctx_config->cert_file) { serverLog(LL_WARNING, "No tls-cert-file configured!"); goto error; } if (!ctx_config->key_file) { serverLog(LL_WARNING, "No tls-key-file configured!"); goto error; } if (!ctx_config->ca_cert_file && !ctx_config->ca_cert_dir) { serverLog(LL_WARNING, "Either tls-ca-cert-file or tls-ca-cert-dir must be configured!"); goto error; } ctx = SSL_CTX_new(SSLv23_method()); SSL_CTX_set_options(ctx, SSL_OP_NO_SSLv2|SSL_OP_NO_SSLv3); SSL_CTX_set_options(ctx, SSL_OP_SINGLE_DH_USE); #ifdef SSL_OP_DONT_INSERT_EMPTY_FRAGMENTS SSL_CTX_set_options(ctx, SSL_OP_DONT_INSERT_EMPTY_FRAGMENTS); #endif int protocols = parseProtocolsConfig(ctx_config->protocols); if (protocols == -1) goto error; if (!(protocols & REDIS_TLS_PROTO_TLSv1)) SSL_CTX_set_options(ctx, SSL_OP_NO_TLSv1); if (!(protocols & REDIS_TLS_PROTO_TLSv1_1)) SSL_CTX_set_options(ctx, SSL_OP_NO_TLSv1_1); #ifdef SSL_OP_NO_TLSv1_2 if (!(protocols & REDIS_TLS_PROTO_TLSv1_2)) SSL_CTX_set_options(ctx, SSL_OP_NO_TLSv1_2); #endif #ifdef SSL_OP_NO_TLSv1_3 if (!(protocols & REDIS_TLS_PROTO_TLSv1_3)) SSL_CTX_set_options(ctx, SSL_OP_NO_TLSv1_3); #endif #ifdef SSL_OP_NO_COMPRESSION SSL_CTX_set_options(ctx, SSL_OP_NO_COMPRESSION); #endif #ifdef SSL_OP_NO_CLIENT_RENEGOTIATION SSL_CTX_set_options(ctx, SSL_OP_NO_CLIENT_RENEGOTIATION); #endif if (ctx_config->prefer_server_ciphers) SSL_CTX_set_options(ctx, SSL_OP_CIPHER_SERVER_PREFERENCE); SSL_CTX_set_mode(ctx, SSL_MODE_ENABLE_PARTIAL_WRITE|SSL_MODE_ACCEPT_MOVING_WRITE_BUFFER); SSL_CTX_set_verify(ctx, SSL_VERIFY_PEER|SSL_VERIFY_FAIL_IF_NO_PEER_CERT, NULL); #if defined(SSL_CTX_set_ecdh_auto) SSL_CTX_set_ecdh_auto(ctx, 1); #endif if (SSL_CTX_use_certificate_file(ctx, ctx_config->cert_file, SSL_FILETYPE_PEM) <= 0) { ERR_error_string_n(ERR_get_error(), errbuf, sizeof(errbuf)); serverLog(LL_WARNING, "Failed to load certificate: %s: %s", ctx_config->cert_file, errbuf); goto error; } if (SSL_CTX_use_PrivateKey_file(ctx, ctx_config->key_file, SSL_FILETYPE_PEM) <= 0) { ERR_error_string_n(ERR_get_error(), errbuf, sizeof(errbuf)); serverLog(LL_WARNING, "Failed to load private key: %s: %s", ctx_config->key_file, errbuf); goto error; } if (SSL_CTX_load_verify_locations(ctx, ctx_config->ca_cert_file, ctx_config->ca_cert_dir) <= 0) { ERR_error_string_n(ERR_get_error(), errbuf, sizeof(errbuf)); serverLog(LL_WARNING, "Failed to configure CA certificate(s) file/directory: %s", errbuf); goto error; } if (ctx_config->dh_params_file) { FILE *dhfile = fopen(ctx_config->dh_params_file, "r"); DH *dh = NULL; if (!dhfile) { serverLog(LL_WARNING, "Failed to load %s: %s", ctx_config->dh_params_file, strerror(errno)); goto error; } dh = PEM_read_DHparams(dhfile, NULL, NULL, NULL); fclose(dhfile); if (!dh) { serverLog(LL_WARNING, "%s: failed to read DH params.", ctx_config->dh_params_file); goto error; } if (SSL_CTX_set_tmp_dh(ctx, dh) <= 0) { ERR_error_string_n(ERR_get_error(), errbuf, sizeof(errbuf)); serverLog(LL_WARNING, "Failed to load DH params file: %s: %s", ctx_config->dh_params_file, errbuf); DH_free(dh); goto error; } DH_free(dh); } if (ctx_config->ciphers && !SSL_CTX_set_cipher_list(ctx, ctx_config->ciphers)) { serverLog(LL_WARNING, "Failed to configure ciphers: %s", ctx_config->ciphers); goto error; } #ifdef TLS1_3_VERSION if (ctx_config->ciphersuites && !SSL_CTX_set_ciphersuites(ctx, ctx_config->ciphersuites)) { serverLog(LL_WARNING, "Failed to configure ciphersuites: %s", ctx_config->ciphersuites); goto error; } #endif SSL_CTX_free(redis_tls_ctx); redis_tls_ctx = ctx; return C_OK; error: if (ctx) SSL_CTX_free(ctx); return C_ERR; } #ifdef TLS_DEBUGGING #define TLSCONN_DEBUG(fmt, ...) \ serverLog(LL_DEBUG, "TLSCONN: " fmt, __VA_ARGS__) #else #define TLSCONN_DEBUG(fmt, ...) #endif ConnectionType CT_TLS; /* Normal socket connections have a simple events/handler correlation. * * With TLS connections we need to handle cases where during a logical read * or write operation, the SSL library asks to block for the opposite * socket operation. * * When this happens, we need to do two things: * 1. Make sure we register for the even. * 2. Make sure we know which handler needs to execute when the * event fires. That is, if we notify the caller of a write operation * that it blocks, and SSL asks for a read, we need to trigger the * write handler again on the next read event. * */ typedef enum { WANT_READ = 1, WANT_WRITE } WantIOType; #define TLS_CONN_FLAG_READ_WANT_WRITE (1<<0) #define TLS_CONN_FLAG_WRITE_WANT_READ (1<<1) #define TLS_CONN_FLAG_FD_SET (1<<2) typedef struct tls_connection { connection c; int flags; SSL *ssl; char *ssl_error; listNode *pending_list_node; } tls_connection; connection *connCreateTLS(void) { tls_connection *conn = zcalloc(sizeof(tls_connection)); conn->c.type = &CT_TLS; conn->c.fd = -1; conn->ssl = SSL_new(redis_tls_ctx); return (connection *) conn; } connection *connCreateAcceptedTLS(int fd, int require_auth) { tls_connection *conn = (tls_connection *) connCreateTLS(); conn->c.fd = fd; conn->c.state = CONN_STATE_ACCEPTING; if (!require_auth) { /* We still verify certificates if provided, but don't require them. */ SSL_set_verify(conn->ssl, SSL_VERIFY_PEER, NULL); } SSL_set_fd(conn->ssl, conn->c.fd); SSL_set_accept_state(conn->ssl); return (connection *) conn; } static void tlsEventHandler(struct aeEventLoop *el, int fd, void *clientData, int mask); /* Process the return code received from OpenSSL> * Update the want parameter with expected I/O. * Update the connection's error state if a real error has occured. * Returns an SSL error code, or 0 if no further handling is required. */ static int handleSSLReturnCode(tls_connection *conn, int ret_value, WantIOType *want) { if (ret_value <= 0) { int ssl_err = SSL_get_error(conn->ssl, ret_value); switch (ssl_err) { case SSL_ERROR_WANT_WRITE: *want = WANT_WRITE; return 0; case SSL_ERROR_WANT_READ: *want = WANT_READ; return 0; case SSL_ERROR_SYSCALL: conn->c.last_errno = errno; if (conn->ssl_error) zfree(conn->ssl_error); conn->ssl_error = errno ? zstrdup(strerror(errno)) : NULL; break; default: /* Error! */ conn->c.last_errno = 0; if (conn->ssl_error) zfree(conn->ssl_error); conn->ssl_error = zmalloc(512); ERR_error_string_n(ERR_get_error(), conn->ssl_error, 512); break; } return ssl_err; } return 0; } void registerSSLEvent(tls_connection *conn, WantIOType want) { int mask = aeGetFileEvents(server.el, conn->c.fd); switch (want) { case WANT_READ: if (mask & AE_WRITABLE) aeDeleteFileEvent(server.el, conn->c.fd, AE_WRITABLE); if (!(mask & AE_READABLE)) aeCreateFileEvent(server.el, conn->c.fd, AE_READABLE, tlsEventHandler, conn); break; case WANT_WRITE: if (mask & AE_READABLE) aeDeleteFileEvent(server.el, conn->c.fd, AE_READABLE); if (!(mask & AE_WRITABLE)) aeCreateFileEvent(server.el, conn->c.fd, AE_WRITABLE, tlsEventHandler, conn); break; default: serverAssert(0); break; } } void updateSSLEvent(tls_connection *conn) { int mask = aeGetFileEvents(server.el, conn->c.fd); int need_read = conn->c.read_handler || (conn->flags & TLS_CONN_FLAG_WRITE_WANT_READ); int need_write = conn->c.write_handler || (conn->flags & TLS_CONN_FLAG_READ_WANT_WRITE); if (need_read && !(mask & AE_READABLE)) aeCreateFileEvent(server.el, conn->c.fd, AE_READABLE, tlsEventHandler, conn); if (!need_read && (mask & AE_READABLE)) aeDeleteFileEvent(server.el, conn->c.fd, AE_READABLE); if (need_write && !(mask & AE_WRITABLE)) aeCreateFileEvent(server.el, conn->c.fd, AE_WRITABLE, tlsEventHandler, conn); if (!need_write && (mask & AE_WRITABLE)) aeDeleteFileEvent(server.el, conn->c.fd, AE_WRITABLE); } static void tlsHandleEvent(tls_connection *conn, int mask) { int ret; TLSCONN_DEBUG("tlsEventHandler(): fd=%d, state=%d, mask=%d, r=%d, w=%d, flags=%d", fd, conn->c.state, mask, conn->c.read_handler != NULL, conn->c.write_handler != NULL, conn->flags); ERR_clear_error(); switch (conn->c.state) { case CONN_STATE_CONNECTING: if (connGetSocketError((connection *) conn)) { conn->c.last_errno = errno; conn->c.state = CONN_STATE_ERROR; } else { if (!(conn->flags & TLS_CONN_FLAG_FD_SET)) { SSL_set_fd(conn->ssl, conn->c.fd); conn->flags |= TLS_CONN_FLAG_FD_SET; } ret = SSL_connect(conn->ssl); if (ret <= 0) { WantIOType want = 0; if (!handleSSLReturnCode(conn, ret, &want)) { registerSSLEvent(conn, want); /* Avoid hitting UpdateSSLEvent, which knows nothing * of what SSL_connect() wants and instead looks at our * R/W handlers. */ return; } /* If not handled, it's an error */ conn->c.state = CONN_STATE_ERROR; } else { conn->c.state = CONN_STATE_CONNECTED; } } if (!callHandler((connection *) conn, conn->c.conn_handler)) return; conn->c.conn_handler = NULL; break; case CONN_STATE_ACCEPTING: ret = SSL_accept(conn->ssl); if (ret <= 0) { WantIOType want = 0; if (!handleSSLReturnCode(conn, ret, &want)) { /* Avoid hitting UpdateSSLEvent, which knows nothing * of what SSL_connect() wants and instead looks at our * R/W handlers. */ registerSSLEvent(conn, want); return; } /* If not handled, it's an error */ conn->c.state = CONN_STATE_ERROR; } else { conn->c.state = CONN_STATE_CONNECTED; } if (!callHandler((connection *) conn, conn->c.conn_handler)) return; conn->c.conn_handler = NULL; break; case CONN_STATE_CONNECTED: { int call_read = ((mask & AE_READABLE) && conn->c.read_handler) || ((mask & AE_WRITABLE) && (conn->flags & TLS_CONN_FLAG_READ_WANT_WRITE)); int call_write = ((mask & AE_WRITABLE) && conn->c.write_handler) || ((mask & AE_READABLE) && (conn->flags & TLS_CONN_FLAG_WRITE_WANT_READ)); /* Normally we execute the readable event first, and the writable * event laster. This is useful as sometimes we may be able * to serve the reply of a query immediately after processing the * query. * * However if WRITE_BARRIER is set in the mask, our application is * asking us to do the reverse: never fire the writable event * after the readable. In such a case, we invert the calls. * This is useful when, for instance, we want to do things * in the beforeSleep() hook, like fsynching a file to disk, * before replying to a client. */ int invert = conn->c.flags & CONN_FLAG_WRITE_BARRIER; if (!invert && call_read) { conn->flags &= ~TLS_CONN_FLAG_READ_WANT_WRITE; if (!callHandler((connection *) conn, conn->c.read_handler)) return; } /* Fire the writable event. */ if (call_write) { conn->flags &= ~TLS_CONN_FLAG_WRITE_WANT_READ; if (!callHandler((connection *) conn, conn->c.write_handler)) return; } /* If we have to invert the call, fire the readable event now * after the writable one. */ if (invert && call_read) { conn->flags &= ~TLS_CONN_FLAG_READ_WANT_WRITE; if (!callHandler((connection *) conn, conn->c.read_handler)) return; } /* If SSL has pending that, already read from the socket, we're at * risk of not calling the read handler again, make sure to add it * to a list of pending connection that should be handled anyway. */ if ((mask & AE_READABLE)) { if (SSL_pending(conn->ssl) > 0) { if (!conn->pending_list_node) { listAddNodeTail(pending_list, conn); conn->pending_list_node = listLast(pending_list); } } else if (conn->pending_list_node) { listDelNode(pending_list, conn->pending_list_node); conn->pending_list_node = NULL; } } break; } default: break; } updateSSLEvent(conn); } static void tlsEventHandler(struct aeEventLoop *el, int fd, void *clientData, int mask) { UNUSED(el); UNUSED(fd); tls_connection *conn = clientData; tlsHandleEvent(conn, mask); } static void connTLSClose(connection *conn_) { tls_connection *conn = (tls_connection *) conn_; if (conn->ssl) { SSL_free(conn->ssl); conn->ssl = NULL; } if (conn->ssl_error) { zfree(conn->ssl_error); conn->ssl_error = NULL; } if (conn->pending_list_node) { listDelNode(pending_list, conn->pending_list_node); conn->pending_list_node = NULL; } CT_Socket.close(conn_); } static int connTLSAccept(connection *_conn, ConnectionCallbackFunc accept_handler) { tls_connection *conn = (tls_connection *) _conn; int ret; if (conn->c.state != CONN_STATE_ACCEPTING) return C_ERR; ERR_clear_error(); /* Try to accept */ conn->c.conn_handler = accept_handler; ret = SSL_accept(conn->ssl); if (ret <= 0) { WantIOType want = 0; if (!handleSSLReturnCode(conn, ret, &want)) { registerSSLEvent(conn, want); /* We'll fire back */ return C_OK; } else { conn->c.state = CONN_STATE_ERROR; return C_ERR; } } conn->c.state = CONN_STATE_CONNECTED; if (!callHandler((connection *) conn, conn->c.conn_handler)) return C_OK; conn->c.conn_handler = NULL; return C_OK; } static int connTLSConnect(connection *conn_, const char *addr, int port, const char *src_addr, ConnectionCallbackFunc connect_handler) { tls_connection *conn = (tls_connection *) conn_; if (conn->c.state != CONN_STATE_NONE) return C_ERR; ERR_clear_error(); /* Initiate Socket connection first */ if (CT_Socket.connect(conn_, addr, port, src_addr, connect_handler) == C_ERR) return C_ERR; /* Return now, once the socket is connected we'll initiate * TLS connection from the event handler. */ return C_OK; } static int connTLSWrite(connection *conn_, const void *data, size_t data_len) { tls_connection *conn = (tls_connection *) conn_; int ret, ssl_err; if (conn->c.state != CONN_STATE_CONNECTED) return -1; ERR_clear_error(); ret = SSL_write(conn->ssl, data, data_len); if (ret <= 0) { WantIOType want = 0; if (!(ssl_err = handleSSLReturnCode(conn, ret, &want))) { if (want == WANT_READ) conn->flags |= TLS_CONN_FLAG_WRITE_WANT_READ; updateSSLEvent(conn); errno = EAGAIN; return -1; } else { if (ssl_err == SSL_ERROR_ZERO_RETURN || ((ssl_err == SSL_ERROR_SYSCALL && !errno))) { conn->c.state = CONN_STATE_CLOSED; return 0; } else { conn->c.state = CONN_STATE_ERROR; return -1; } } } return ret; } static int connTLSRead(connection *conn_, void *buf, size_t buf_len) { tls_connection *conn = (tls_connection *) conn_; int ret; int ssl_err; if (conn->c.state != CONN_STATE_CONNECTED) return -1; ERR_clear_error(); ret = SSL_read(conn->ssl, buf, buf_len); if (ret <= 0) { WantIOType want = 0; if (!(ssl_err = handleSSLReturnCode(conn, ret, &want))) { if (want == WANT_WRITE) conn->flags |= TLS_CONN_FLAG_READ_WANT_WRITE; updateSSLEvent(conn); errno = EAGAIN; return -1; } else { if (ssl_err == SSL_ERROR_ZERO_RETURN || ((ssl_err == SSL_ERROR_SYSCALL) && !errno)) { conn->c.state = CONN_STATE_CLOSED; return 0; } else { conn->c.state = CONN_STATE_ERROR; return -1; } } } return ret; } static const char *connTLSGetLastError(connection *conn_) { tls_connection *conn = (tls_connection *) conn_; if (conn->ssl_error) return conn->ssl_error; return NULL; } int connTLSSetWriteHandler(connection *conn, ConnectionCallbackFunc func, int barrier) { conn->write_handler = func; if (barrier) conn->flags |= CONN_FLAG_WRITE_BARRIER; else conn->flags &= ~CONN_FLAG_WRITE_BARRIER; updateSSLEvent((tls_connection *) conn); return C_OK; } int connTLSSetReadHandler(connection *conn, ConnectionCallbackFunc func) { conn->read_handler = func; updateSSLEvent((tls_connection *) conn); return C_OK; } static void setBlockingTimeout(tls_connection *conn, long long timeout) { anetBlock(NULL, conn->c.fd); anetSendTimeout(NULL, conn->c.fd, timeout); anetRecvTimeout(NULL, conn->c.fd, timeout); } static void unsetBlockingTimeout(tls_connection *conn) { anetNonBlock(NULL, conn->c.fd); anetSendTimeout(NULL, conn->c.fd, 0); anetRecvTimeout(NULL, conn->c.fd, 0); } static int connTLSBlockingConnect(connection *conn_, const char *addr, int port, long long timeout) { tls_connection *conn = (tls_connection *) conn_; int ret; if (conn->c.state != CONN_STATE_NONE) return C_ERR; /* Initiate socket blocking connect first */ if (CT_Socket.blocking_connect(conn_, addr, port, timeout) == C_ERR) return C_ERR; /* Initiate TLS connection now. We set up a send/recv timeout on the socket, * which means the specified timeout will not be enforced accurately. */ SSL_set_fd(conn->ssl, conn->c.fd); setBlockingTimeout(conn, timeout); if ((ret = SSL_connect(conn->ssl)) <= 0) { conn->c.state = CONN_STATE_ERROR; return C_ERR; } unsetBlockingTimeout(conn); conn->c.state = CONN_STATE_CONNECTED; return C_OK; } static ssize_t connTLSSyncWrite(connection *conn_, char *ptr, ssize_t size, long long timeout) { tls_connection *conn = (tls_connection *) conn_; setBlockingTimeout(conn, timeout); SSL_clear_mode(conn->ssl, SSL_MODE_ENABLE_PARTIAL_WRITE); int ret = SSL_write(conn->ssl, ptr, size); SSL_set_mode(conn->ssl, SSL_MODE_ENABLE_PARTIAL_WRITE); unsetBlockingTimeout(conn); return ret; } static ssize_t connTLSSyncRead(connection *conn_, char *ptr, ssize_t size, long long timeout) { tls_connection *conn = (tls_connection *) conn_; setBlockingTimeout(conn, timeout); int ret = SSL_read(conn->ssl, ptr, size); unsetBlockingTimeout(conn); return ret; } static ssize_t connTLSSyncReadLine(connection *conn_, char *ptr, ssize_t size, long long timeout) { tls_connection *conn = (tls_connection *) conn_; ssize_t nread = 0; setBlockingTimeout(conn, timeout); size--; while(size) { char c; if (SSL_read(conn->ssl,&c,1) <= 0) { nread = -1; goto exit; } if (c == '\n') { *ptr = '\0'; if (nread && *(ptr-1) == '\r') *(ptr-1) = '\0'; goto exit; } else { *ptr++ = c; *ptr = '\0'; nread++; } size--; } exit: unsetBlockingTimeout(conn); return nread; } ConnectionType CT_TLS = { .ae_handler = tlsEventHandler, .accept = connTLSAccept, .connect = connTLSConnect, .blocking_connect = connTLSBlockingConnect, .read = connTLSRead, .write = connTLSWrite, .close = connTLSClose, .set_write_handler = connTLSSetWriteHandler, .set_read_handler = connTLSSetReadHandler, .get_last_error = connTLSGetLastError, .sync_write = connTLSSyncWrite, .sync_read = connTLSSyncRead, .sync_readline = connTLSSyncReadLine, }; int tlsHasPendingData() { if (!pending_list) return 0; return listLength(pending_list) > 0; } void tlsProcessPendingData() { listIter li; listNode *ln; listRewind(pending_list,&li); while((ln = listNext(&li))) { tls_connection *conn = listNodeValue(ln); tlsHandleEvent(conn, AE_READABLE); } } #else /* USE_OPENSSL */ void tlsInit(void) { } int tlsConfigure(redisTLSContextConfig *ctx_config) { UNUSED(ctx_config); return C_OK; } connection *connCreateTLS(void) { return NULL; } connection *connCreateAcceptedTLS(int fd, int require_auth) { UNUSED(fd); UNUSED(require_auth); return NULL; } int tlsHasPendingData() { return 0; } void tlsProcessPendingData() { } #endif