| Quellcodebibliothek Statistik Leitseite products/Sources/formale Sprachen/C/Apache/modules/ssl/ (Apache Software Stiftung Version 2.4.65©) Datei vom 4.6.2024 mit Größe 87 kB |
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Quelle ssl_engine_io.c Sprache: C |
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/* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. * The ASF licenses this file to You under the Apache License, Version 2.0 * (the "License"); you may not use this file except in compliance with * the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ /* _ _ * _ __ ___ ___ __| | ___ ___| | mod_ssl * | '_ ` _ \ / _ \ / _` | / __/ __| | Apache Interface to OpenSSL * | | | | | | (_) | (_| | \__ \__ \ | * |_| |_| |_|\___/ \__,_|___|___/___/_| * |_____| * ssl_engine_io.c * I/O Functions */ /* ``MY HACK: This universe. Just one little problem: core keeps dumping.'' -- Unknown */ #include "ssl_private.h" #include "apr_date.h" APR_IMPLEMENT_OPTIONAL_HOOK_RUN_ALL(ssl, SSL, int, proxy_post_handshake, (conn_rec *c,SSL *ssl), (c,ssl),OK,DECLINED); /* _________________________________________________________________ ** ** I/O Hooks ** _________________________________________________________________ */ /* This file is designed to be the bridge between OpenSSL and httpd. * However, we really don't expect anyone (let alone ourselves) to * remember what is in this file. So, first, a quick overview. * * In this file, you will find: * - ssl_io_filter_input (Apache input filter) * - ssl_io_filter_output (Apache output filter) * * - bio_filter_in_* (OpenSSL input filter) * - bio_filter_out_* (OpenSSL output filter) * * The input chain is roughly: * * ssl_io_filter_input->ssl_io_input_read->SSL_read->... * ...->bio_filter_in_read->ap_get_brigade/next-httpd-filter * * In mortal terminology, we do the following: * - Receive a request for data to the SSL input filter * - Call a helper function once we know we should perform a read * - Call OpenSSL's SSL_read() * - SSL_read() will then call bio_filter_in_read * - bio_filter_in_read will then try to fetch data from the next httpd filter * - bio_filter_in_read will flatten that data and return it to SSL_read * - SSL_read will then decrypt the data * - ssl_io_input_read will then receive decrypted data as a char* and * ensure that there were no read errors * - The char* is placed in a brigade and returned * * Since connection-level input filters in httpd need to be able to * handle AP_MODE_GETLINE calls (namely identifying LF-terminated strings), * ssl_io_input_getline which will handle this special case. * * Due to AP_MODE_GETLINE and AP_MODE_SPECULATIVE, we may sometimes have * 'leftover' decoded data which must be setaside for the next read. That * is currently handled by the char_buffer_{read|write} functions. So, * ssl_io_input_read may be able to fulfill reads without invoking * SSL_read(). * * Note that the filter context of ssl_io_filter_input and bio_filter_in_* * are shared as bio_filter_in_ctx_t. * * Note that the filter is by choice limited to reading at most * AP_IOBUFSIZE (8192 bytes) per call. * */ /* this custom BIO allows us to hook SSL_write directly into * an apr_bucket_brigade and use transient buckets with the SSL * malloc-ed buffer, rather than copying into a mem BIO. * also allows us to pass the brigade as data is being written * rather than buffering up the entire response in the mem BIO. * * when SSL needs to flush (e.g. SSL_accept()), it will call BIO_flush() * which will trigger a call to bio_filter_out_ctrl() -> bio_filter_out_flush(). * so we only need to flush the output ourselves if we receive an * EOS or FLUSH bucket. this was not possible with the mem BIO where we * had to flush all over the place not really knowing when it was required * to do so. */ typedef struct { SSL *pssl; BIO *pbioRead; BIO *pbioWrite; ap_filter_t *pInputFilter; ap_filter_t *pOutputFilter; SSLConnRec *config; } ssl_filter_ctx_t; typedef struct { ssl_filter_ctx_t *filter_ctx; conn_rec *c; apr_bucket_brigade *bb; /* Brigade used as a buffer. */ apr_status_t rc; } bio_filter_out_ctx_t; static bio_filter_out_ctx_t *bio_filter_out_ctx_new(ssl_filter_ctx_t *filter_ctx, conn_rec *c) { bio_filter_out_ctx_t *outctx = apr_palloc(c->pool, sizeof(*outctx)); outctx->filter_ctx = filter_ctx; outctx->c = c; outctx->bb = apr_brigade_create(c->pool, c->bucket_alloc); return outctx; } /* Pass an output brigade down the filter stack; returns 1 on success * or -1 on failure. */ static int bio_filter_out_pass(bio_filter_out_ctx_t *outctx) { AP_DEBUG_ASSERT(!APR_BRIGADE_EMPTY(outctx->bb)); outctx->rc = ap_pass_brigade(outctx->filter_ctx->pOutputFilter->next, outctx->bb); /* Fail if the connection was reset: */ if (outctx->rc == APR_SUCCESS && outctx->c->aborted) { outctx->rc = APR_ECONNRESET; } return (outctx->rc == APR_SUCCESS) ? 1 : -1; } /* Send a FLUSH bucket down the output filter stack; returns 1 on * success, -1 on failure. */ static int bio_filter_out_flush(BIO *bio) { bio_filter_out_ctx_t *outctx = (bio_filter_out_ctx_t *)BIO_get_data(bio); apr_bucket *e; ap_log_cerror(APLOG_MARK, APLOG_TRACE6, 0, outctx->c, "bio_filter_out_write: flush"); AP_DEBUG_ASSERT(APR_BRIGADE_EMPTY(outctx->bb)); e = apr_bucket_flush_create(outctx->bb->bucket_alloc); APR_BRIGADE_INSERT_TAIL(outctx->bb, e); return bio_filter_out_pass(outctx); } static int bio_filter_create(BIO *bio) { BIO_set_shutdown(bio, 1); BIO_set_init(bio, 1); #if MODSSL_USE_OPENSSL_PRE_1_1_API /* No setter method for OpenSSL 1.1.0 available, * but I can't find any functional use of the * "num" field there either. */ bio->num = -1; #endif BIO_set_data(bio, NULL); return 1; } static int bio_filter_destroy(BIO *bio) { if (bio == NULL) { return 0; } /* nothing to free here. * apache will destroy the bucket brigade for us */ return 1; } static int bio_filter_out_read(BIO *bio, char *out, int outl) { /* this is never called */ bio_filter_out_ctx_t *outctx = (bio_filter_out_ctx_t *)BIO_get_data(bio); ap_log_cerror(APLOG_MARK, APLOG_TRACE1, 0, outctx->c, "BUG: %s() should not be called", "bio_filter_out_read"); AP_DEBUG_ASSERT(0); return -1; } static int bio_filter_out_write(BIO *bio, const char *in, int inl) { bio_filter_out_ctx_t *outctx = (bio_filter_out_ctx_t *)BIO_get_data(bio); apr_bucket *e; int need_flush; BIO_clear_retry_flags(bio); #ifndef SSL_OP_NO_RENEGOTIATION /* Abort early if the client has initiated a renegotiation. */ if (outctx->filter_ctx->config->reneg_state == RENEG_ABORT) { outctx->rc = APR_ECONNABORTED; return -1; } #endif ap_log_cerror(APLOG_MARK, APLOG_TRACE6, 0, outctx->c, "bio_filter_out_write: %i bytes", inl); /* Use a transient bucket for the output data - any downstream * filter must setaside if necessary. */ e = apr_bucket_transient_create(in, inl, outctx->bb->bucket_alloc); APR_BRIGADE_INSERT_TAIL(outctx->bb, e); /* In theory, OpenSSL should flush as necessary, but it is known * not to do so correctly in some cases (< 0.9.8m; see PR 46952), * or on the proxy/client side (after ssl23_client_hello(), e.g. * ssl/proxy.t test suite). * * Historically, this flush call was performed only for an SSLv2 * connection or for a proxy connection. Calling _out_flush can * be expensive in cases where requests/responses are pipelined, * so limit the performance impact to handshake time. */ #if OPENSSL_VERSION_NUMBER < 0x0009080df need_flush = !SSL_is_init_finished(outctx->filter_ctx->pssl); #else need_flush = SSL_in_connect_init(outctx->filter_ctx->pssl); #endif if (need_flush) { e = apr_bucket_flush_create(outctx->bb->bucket_alloc); APR_BRIGADE_INSERT_TAIL(outctx->bb, e); } if (bio_filter_out_pass(outctx) < 0) { return -1; } return inl; } static long bio_filter_out_ctrl(BIO *bio, int cmd, long num, void *ptr) { long ret = 1; bio_filter_out_ctx_t *outctx = (bio_filter_out_ctx_t *)BIO_get_data(bio); switch (cmd) { case BIO_CTRL_RESET: case BIO_CTRL_EOF: case BIO_C_SET_BUF_MEM_EOF_RETURN: ap_log_cerror(APLOG_MARK, APLOG_TRACE4, 0, outctx->c, "output bio: unhandled control %d", cmd); ret = 0; break; case BIO_CTRL_WPENDING: case BIO_CTRL_PENDING: case BIO_CTRL_INFO: ret = 0; break; case BIO_CTRL_GET_CLOSE: ret = (long)BIO_get_shutdown(bio); break; case BIO_CTRL_SET_CLOSE: BIO_set_shutdown(bio, (int)num); break; case BIO_CTRL_FLUSH: ret = bio_filter_out_flush(bio); break; case BIO_CTRL_DUP: ret = 1; break; /* N/A */ case BIO_C_SET_BUF_MEM: case BIO_C_GET_BUF_MEM_PTR: /* we don't care */ case BIO_CTRL_PUSH: case BIO_CTRL_POP: default: ret = 0; break; } return ret; } static int bio_filter_out_gets(BIO *bio, char *buf, int size) { /* this is never called */ bio_filter_out_ctx_t *outctx = (bio_filter_out_ctx_t *)BIO_get_data(bio); ap_log_cerror(APLOG_MARK, APLOG_TRACE1, 0, outctx->c, "BUG: %s() should not be called", "bio_filter_out_gets"); AP_DEBUG_ASSERT(0); return -1; } static int bio_filter_out_puts(BIO *bio, const char *str) { /* this is never called */ bio_filter_out_ctx_t *outctx = (bio_filter_out_ctx_t *)BIO_get_data(bio); ap_log_cerror(APLOG_MARK, APLOG_TRACE1, 0, outctx->c, "BUG: %s() should not be called", "bio_filter_out_puts"); AP_DEBUG_ASSERT(0); return -1; } typedef struct { int length; char *value; } char_buffer_t; typedef struct { SSL *ssl; BIO *bio_out; ap_filter_t *f; apr_status_t rc; ap_input_mode_t mode; apr_read_type_e block; apr_bucket_brigade *bb; char_buffer_t cbuf; apr_pool_t *pool; char buffer[AP_IOBUFSIZE]; ssl_filter_ctx_t *filter_ctx; } bio_filter_in_ctx_t; /* * this char_buffer api might seem silly, but we don't need to copy * any of this data and we need to remember the length. */ /* Copy up to INL bytes from the char_buffer BUFFER into IN. Note * that due to the strange way this API is designed/used, the * char_buffer object is used to cache a segment of inctx->buffer, and * then this function called to copy (part of) that segment to the * beginning of inctx->buffer. So the segments to copy cannot be * presumed to be non-overlapping, and memmove must be used. */ static int char_buffer_read(char_buffer_t *buffer, char *in, int inl) { if (!buffer->length) { return 0; } if (buffer->length > inl) { /* we have enough to fill the caller's buffer */ memmove(in, buffer->value, inl); buffer->value += inl; buffer->length -= inl; } else { /* swallow remainder of the buffer */ memmove(in, buffer->value, buffer->length); inl = buffer->length; buffer->value = NULL; buffer->length = 0; } return inl; } static int char_buffer_write(char_buffer_t *buffer, char *in, int inl) { buffer->value = in; buffer->length = inl; return inl; } /* This function will read from a brigade and discard the read buckets as it * proceeds. It will read at most *len bytes. */ static apr_status_t brigade_consume(apr_bucket_brigade *bb, apr_read_type_e block, char *c, apr_size_t *len) { apr_size_t actual = 0; apr_status_t status = APR_SUCCESS; while (!APR_BRIGADE_EMPTY(bb)) { apr_bucket *b = APR_BRIGADE_FIRST(bb); const char *str; apr_size_t str_len; apr_size_t consume; /* Justin points out this is an http-ism that might * not fit if brigade_consume is added to APR. Perhaps * apr_bucket_read(eos_bucket) should return APR_EOF? * Then this becomes mainline instead of a one-off. */ if (APR_BUCKET_IS_EOS(b)) { status = APR_EOF; break; } /* The reason I'm not offering brigade_consume yet * across to apr-util is that the following call * illustrates how borked that API really is. For * this sort of case (caller provided buffer) it * would be much more trivial for apr_bucket_consume * to do all the work that follows, based on the * particular characteristics of the bucket we are * consuming here. */ status = apr_bucket_read(b, &str, &str_len, block); if (status != APR_SUCCESS) { if (APR_STATUS_IS_EOF(status)) { /* This stream bucket was consumed */ apr_bucket_delete(b); continue; } break; } if (str_len > 0) { /* Do not block once some data has been consumed */ block = APR_NONBLOCK_READ; /* Assure we don't overflow. */ consume = (str_len + actual > *len) ? *len - actual : str_len; memcpy(c, str, consume); c += consume; actual += consume; if (consume >= b->length) { /* This physical bucket was consumed */ apr_bucket_delete(b); } else { /* Only part of this physical bucket was consumed */ b->start += consume; b->length -= consume; } } else if (b->length == 0) { apr_bucket_delete(b); } /* This could probably be actual == *len, but be safe from stray * photons. */ if (actual >= *len) { break; } } *len = actual; return status; } /* * this is the function called by SSL_read() */ static int bio_filter_in_read(BIO *bio, char *in, int inlen) { apr_size_t inl = inlen; bio_filter_in_ctx_t *inctx = (bio_filter_in_ctx_t *)BIO_get_data(bio); apr_read_type_e block = inctx->block; inctx->rc = APR_SUCCESS; /* OpenSSL catches this case, so should we. */ if (!in) return 0; BIO_clear_retry_flags(bio); #ifndef SSL_OP_NO_RENEGOTIATION /* Abort early if the client has initiated a renegotiation. */ if (inctx->filter_ctx->config->reneg_state == RENEG_ABORT) { inctx->rc = APR_ECONNABORTED; return -1; } #endif if (!inctx->bb) { inctx->rc = APR_EOF; return -1; } if (APR_BRIGADE_EMPTY(inctx->bb)) { inctx->rc = ap_get_brigade(inctx->f->next, inctx->bb, AP_MODE_READBYTES, block, inl); /* If the read returns EAGAIN or success with an empty * brigade, return an error after setting the retry flag; * SSL_read() will then return -1, and SSL_get_error() will * indicate SSL_ERROR_WANT_READ. */ if (APR_STATUS_IS_EAGAIN(inctx->rc) || APR_STATUS_IS_EINTR(inctx->rc) || (inctx->rc == APR_SUCCESS && APR_BRIGADE_EMPTY(inctx->bb))) { BIO_set_retry_read(bio); return -1; } if (block == APR_BLOCK_READ && APR_STATUS_IS_TIMEUP(inctx->rc) && APR_BRIGADE_EMPTY(inctx->bb)) { /* don't give up, just return the timeout */ return -1; } if (inctx->rc != APR_SUCCESS) { /* Unexpected errors discard the brigade */ apr_brigade_cleanup(inctx->bb); inctx->bb = NULL; return -1; } } inctx->rc = brigade_consume(inctx->bb, block, in, &inl); if (inctx->rc == APR_SUCCESS) { return (int)inl; } if (APR_STATUS_IS_EAGAIN(inctx->rc) || APR_STATUS_IS_EINTR(inctx->rc)) { BIO_set_retry_read(bio); return (int)inl; } /* Unexpected errors and APR_EOF clean out the brigade. * Subsequent calls will return APR_EOF. */ apr_brigade_cleanup(inctx->bb); inctx->bb = NULL; if (APR_STATUS_IS_EOF(inctx->rc) && inl) { /* Provide the results of this read pass, * without resetting the BIO retry_read flag */ return (int)inl; } return -1; } static int bio_filter_in_write(BIO *bio, const char *in, int inl) { bio_filter_in_ctx_t *inctx = (bio_filter_in_ctx_t *)BIO_get_data(bio); ap_log_cerror(APLOG_MARK, APLOG_TRACE1, 0, inctx->f->c, "BUG: %s() should not be called", "bio_filter_in_write"); AP_DEBUG_ASSERT(0); return -1; } static int bio_filter_in_puts(BIO *bio, const char *str) { bio_filter_in_ctx_t *inctx = (bio_filter_in_ctx_t *)BIO_get_data(bio); ap_log_cerror(APLOG_MARK, APLOG_TRACE1, 0, inctx->f->c, "BUG: %s() should not be called", "bio_filter_in_puts"); AP_DEBUG_ASSERT(0); return -1; } static int bio_filter_in_gets(BIO *bio, char *buf, int size) { bio_filter_in_ctx_t *inctx = (bio_filter_in_ctx_t *)BIO_get_data(bio); ap_log_cerror(APLOG_MARK, APLOG_TRACE1, 0, inctx->f->c, "BUG: %s() should not be called", "bio_filter_in_gets"); AP_DEBUG_ASSERT(0); return -1; } static long bio_filter_in_ctrl(BIO *bio, int cmd, long num, void *ptr) { bio_filter_in_ctx_t *inctx = (bio_filter_in_ctx_t *)BIO_get_data(bio); switch (cmd) { #ifdef BIO_CTRL_EOF case BIO_CTRL_EOF: return inctx->rc == APR_EOF; #endif default: break; } ap_log_cerror(APLOG_MARK, APLOG_TRACE1, 0, inctx->f->c, "BUG: bio_filter_in_ctrl() should not be called with cmd=%i", cmd); return 0; } #if MODSSL_USE_OPENSSL_PRE_1_1_API static BIO_METHOD bio_filter_out_method = { BIO_TYPE_MEM, "APR output filter", bio_filter_out_write, bio_filter_out_read, /* read is never called */ bio_filter_out_puts, /* puts is never called */ bio_filter_out_gets, /* gets is never called */ bio_filter_out_ctrl, bio_filter_create, bio_filter_destroy, NULL }; static BIO_METHOD bio_filter_in_method = { BIO_TYPE_MEM, "APR input filter", bio_filter_in_write, /* write is never called */ bio_filter_in_read, bio_filter_in_puts, /* puts is never called */ bio_filter_in_gets, /* gets is never called */ bio_filter_in_ctrl, /* ctrl is called for EOF check */ bio_filter_create, bio_filter_destroy, NULL }; #else static BIO_METHOD *bio_filter_out_method = NULL; static BIO_METHOD *bio_filter_in_method = NULL; void init_bio_methods(void) { bio_filter_out_method = BIO_meth_new(BIO_TYPE_MEM, "APR output filter"); BIO_meth_set_write(bio_filter_out_method, &bio_filter_out_write); BIO_meth_set_read(bio_filter_out_method, &bio_filter_out_read); /* read is never called */ BIO_meth_set_puts(bio_filter_out_method, &bio_filter_out_puts); /* puts is never called */ BIO_meth_set_gets(bio_filter_out_method, &bio_filter_out_gets); /* gets is never called */ BIO_meth_set_ctrl(bio_filter_out_method, &bio_filter_out_ctrl); BIO_meth_set_create(bio_filter_out_method, &bio_filter_create); BIO_meth_set_destroy(bio_filter_out_method, &bio_filter_destroy); bio_filter_in_method = BIO_meth_new(BIO_TYPE_MEM, "APR input filter"); BIO_meth_set_write(bio_filter_in_method, &bio_filter_in_write); /* write is never called */ BIO_meth_set_read(bio_filter_in_method, &bio_filter_in_read); BIO_meth_set_puts(bio_filter_in_method, &bio_filter_in_puts); /* puts is never called */ BIO_meth_set_gets(bio_filter_in_method, &bio_filter_in_gets); /* gets is never called */ BIO_meth_set_ctrl(bio_filter_in_method, &bio_filter_in_ctrl); /* ctrl is never called */ BIO_meth_set_create(bio_filter_in_method, &bio_filter_create); BIO_meth_set_destroy(bio_filter_in_method, &bio_filter_destroy); } void free_bio_methods(void) { BIO_meth_free(bio_filter_out_method); BIO_meth_free(bio_filter_in_method); } #endif static apr_status_t ssl_io_input_read(bio_filter_in_ctx_t *inctx, char *buf, apr_size_t *len) { apr_size_t wanted = *len; apr_size_t bytes = 0; int rc; *len = 0; /* If we have something leftover from last time, try that first. */ if ((bytes = char_buffer_read(&inctx->cbuf, buf, wanted))) { *len = bytes; if (inctx->mode == AP_MODE_SPECULATIVE) { /* We want to rollback this read. */ if (inctx->cbuf.length > 0) { inctx->cbuf.value -= bytes; inctx->cbuf.length += bytes; } else { char_buffer_write(&inctx->cbuf, buf, (int)bytes); } return APR_SUCCESS; } /* This could probably be *len == wanted, but be safe from stray * photons. */ if (*len >= wanted) { return APR_SUCCESS; } if (inctx->mode == AP_MODE_GETLINE) { if (memchr(buf, APR_ASCII_LF, *len)) { return APR_SUCCESS; } } else { /* Down to a nonblock pattern as we have some data already */ inctx->block = APR_NONBLOCK_READ; } } while (1) { if (!inctx->filter_ctx->pssl) { /* Ensure a non-zero error code is returned */ if (inctx->rc == APR_SUCCESS) { inctx->rc = APR_EGENERAL; } break; } /* We rely on SSL_get_error() after the read, which requires an empty * error queue before the read in order to work properly. */ ERR_clear_error(); /* SSL_read may not read because we haven't taken enough data * from the stack. This is where we want to consider all of * the blocking and SPECULATIVE semantics */ rc = SSL_read(inctx->filter_ctx->pssl, buf + bytes, wanted - bytes); if (rc > 0) { *len += rc; if (inctx->mode == AP_MODE_SPECULATIVE) { /* We want to rollback this read. */ char_buffer_write(&inctx->cbuf, buf, rc); } return inctx->rc; } else /* (rc <= 0) */ { int ssl_err; conn_rec *c; if (rc == 0) { /* If EAGAIN, we will loop given a blocking read, * otherwise consider ourselves at EOF. */ if (APR_STATUS_IS_EAGAIN(inctx->rc) || APR_STATUS_IS_EINTR(inctx->rc)) { /* Already read something, return APR_SUCCESS instead. * On win32 in particular, but perhaps on other kernels, * a blocking call isn't 'always' blocking. */ if (*len > 0) { inctx->rc = APR_SUCCESS; break; } if (inctx->block == APR_NONBLOCK_READ) { break; } } else { if (*len > 0) { inctx->rc = APR_SUCCESS; break; } } } ssl_err = SSL_get_error(inctx->filter_ctx->pssl, rc); c = (conn_rec*)SSL_get_app_data(inctx->filter_ctx->pssl); if (ssl_err == SSL_ERROR_WANT_READ) { /* * If OpenSSL wants to read more, and we were nonblocking, * report as an EAGAIN. Otherwise loop, pulling more * data from network filter. * * (This is usually the case when the client forces an SSL * renegotiation which is handled implicitly by OpenSSL.) */ inctx->rc = APR_EAGAIN; if (*len > 0) { inctx->rc = APR_SUCCESS; break; } if (inctx->block == APR_NONBLOCK_READ) { break; } continue; /* Blocking and nothing yet? Try again. */ } else if (ssl_err == SSL_ERROR_SYSCALL) { if (APR_STATUS_IS_EAGAIN(inctx->rc) || APR_STATUS_IS_EINTR(inctx->rc)) { /* Already read something, return APR_SUCCESS instead. */ if (*len > 0) { inctx->rc = APR_SUCCESS; break; } if (inctx->block == APR_NONBLOCK_READ) { break; } continue; /* Blocking and nothing yet? Try again. */ } else if (APR_STATUS_IS_TIMEUP(inctx->rc)) { /* just return it, the calling layer might be fine with it, and we do not want to bloat the log. */ } else { ap_log_cerror(APLOG_MARK, APLOG_INFO, inctx->rc, c, APLOGNO(01991) "SSL input filter read failed."); } } else if (rc == 0 && ssl_err == SSL_ERROR_ZERO_RETURN) { inctx->rc = APR_EOF; break; } else /* if (ssl_err == SSL_ERROR_SSL) */ { /* * Log SSL errors and any unexpected conditions. */ ap_log_cerror(APLOG_MARK, APLOG_INFO, inctx->rc, c, APLOGNO(01992) "SSL library error %d reading data", ssl_err); ssl_log_ssl_error(SSLLOG_MARK, APLOG_INFO, mySrvFromConn(c)); } if (rc == 0) { inctx->rc = APR_EOF; break; } if (inctx->rc == APR_SUCCESS) { inctx->rc = APR_EGENERAL; } break; } } return inctx->rc; } /* Read a line of input from the SSL input layer into buffer BUF of * length *LEN; updating *len to reflect the length of the line * including the LF character. */ static apr_status_t ssl_io_input_getline(bio_filter_in_ctx_t *inctx, char *buf, apr_size_t *len) { const char *pos = NULL; apr_status_t status; apr_size_t tmplen = *len, buflen = *len, offset = 0; *len = 0; /* * in most cases we get all the headers on the first SSL_read. * however, in certain cases SSL_read will only get a partial * chunk of the headers, so we try to read until LF is seen. */ while (tmplen > 0) { status = ssl_io_input_read(inctx, buf + offset, &tmplen); if (status != APR_SUCCESS) { if (APR_STATUS_IS_EAGAIN(status) && (*len > 0)) { /* Save the part of the line we already got */ char_buffer_write(&inctx->cbuf, buf, *len); } return status; } *len += tmplen; if ((pos = memchr(buf, APR_ASCII_LF, *len))) { break; } offset += tmplen; tmplen = buflen - offset; } if (pos) { char *value; int length; apr_size_t bytes = pos - buf; bytes += 1; value = buf + bytes; length = *len - bytes; char_buffer_write(&inctx->cbuf, value, length); *len = bytes; } return APR_SUCCESS; } static apr_status_t ssl_filter_write(ap_filter_t *f, const char *data, apr_size_t len) { ssl_filter_ctx_t *filter_ctx = f->ctx; bio_filter_out_ctx_t *outctx; int res; /* write SSL */ if (filter_ctx->pssl == NULL) { return APR_EGENERAL; } ap_log_cerror(APLOG_MARK, APLOG_TRACE6, 0, f->c, "ssl_filter_write: %"APR_SIZE_T_FMT" bytes", len); /* We rely on SSL_get_error() after the write, which requires an empty error * queue before the write in order to work properly. */ ERR_clear_error(); outctx = (bio_filter_out_ctx_t *)BIO_get_data(filter_ctx->pbioWrite); res = SSL_write(filter_ctx->pssl, (unsigned char *)data, len); if (res < 0) { int ssl_err = SSL_get_error(filter_ctx->pssl, res); conn_rec *c = (conn_rec*)SSL_get_app_data(outctx->filter_ctx->pssl); if (ssl_err == SSL_ERROR_WANT_WRITE) { /* * If OpenSSL wants to write more, and we were nonblocking, * report as an EAGAIN. Otherwise loop, pushing more * data at the network filter. * * (This is usually the case when the client forces an SSL * renegotiation which is handled implicitly by OpenSSL.) */ outctx->rc = APR_EAGAIN; } else if (ssl_err == SSL_ERROR_WANT_READ) { /* * If OpenSSL wants to read during write, and we were * nonblocking, set the sense explicitly to read and * report as an EAGAIN. * * (This is usually the case when the client forces an SSL * renegotiation which is handled implicitly by OpenSSL.) */ outctx->c->cs->sense = CONN_SENSE_WANT_READ; outctx->rc = APR_EAGAIN; ap_log_cerror(APLOG_MARK, APLOG_TRACE6, 0, outctx->c, "Want read during nonblocking write"); } else if (ssl_err == SSL_ERROR_SYSCALL) { ap_log_cerror(APLOG_MARK, APLOG_INFO, outctx->rc, c, APLOGNO(01993) "SSL output filter write failed."); } else /* if (ssl_err == SSL_ERROR_SSL) */ { /* * Log SSL errors */ ap_log_cerror(APLOG_MARK, APLOG_INFO, outctx->rc, c, APLOGNO(01994) "SSL library error %d writing data", ssl_err); ssl_log_ssl_error(SSLLOG_MARK, APLOG_INFO, mySrvFromConn(c)); } if (outctx->rc == APR_SUCCESS) { outctx->rc = APR_EGENERAL; } } else if ((apr_size_t)res != len) { conn_rec *c = f->c; char *reason = "reason unknown"; /* XXX: probably a better way to determine this */ if (SSL_total_renegotiations(filter_ctx->pssl)) { reason = "likely due to failed renegotiation"; } ap_log_cerror(APLOG_MARK, APLOG_INFO, outctx->rc, c, APLOGNO(01995) "failed to write %" APR_SSIZE_T_FMT " of %" APR_SIZE_T_FMT " bytes (%s)", len - (apr_size_t)res, len, reason); outctx->rc = APR_EGENERAL; } return outctx->rc; } /* Just use a simple request. Any request will work for this, because * we use a flag in the conn_rec->conn_vector now. The fake request just * gets the request back to the Apache core so that a response can be sent. * Since we use an HTTP/1.x request, we also have to inject the empty line * that terminates the headers, or the core will read more data from the * socket. */ #define HTTP_ON_HTTPS_PORT \ "GET / HTTP/1.0" CRLF #define HTTP_ON_HTTPS_PORT_BUCKET(alloc) \ apr_bucket_immortal_create(HTTP_ON_HTTPS_PORT, \ sizeof(HTTP_ON_HTTPS_PORT) - 1, \ alloc) /* Custom apr_status_t error code, used when a plain HTTP request is * received on an SSL port. */ #define MODSSL_ERROR_HTTP_ON_HTTPS (APR_OS_START_USERERR + 0) /* Custom apr_status_t error code, used when the proxy cannot * establish an outgoing SSL connection. */ #define MODSSL_ERROR_BAD_GATEWAY (APR_OS_START_USERERR + 1) static void ssl_io_filter_disable(SSLConnRec *sslconn, bio_filter_in_ctx_t *inctx) { SSL_free(inctx->ssl); sslconn->ssl = NULL; inctx->ssl = NULL; inctx->filter_ctx->pssl = NULL; } static apr_status_t ssl_io_filter_error(bio_filter_in_ctx_t *inctx, apr_bucket_brigade *bb, apr_status_t status, int is_init) { ap_filter_t *f = inctx->f; SSLConnRec *sslconn = myConnConfig(f->c); apr_bucket *bucket; int send_eos = 1; switch (status) { case MODSSL_ERROR_HTTP_ON_HTTPS: /* log the situation */ ap_log_cerror(APLOG_MARK, APLOG_INFO, 0, f->c, APLOGNO(01996) "SSL handshake failed: HTTP spoken on HTTPS port; " "trying to send HTML error page"); ssl_log_ssl_error(SSLLOG_MARK, APLOG_INFO, sslconn->server); ssl_io_filter_disable(sslconn, inctx); f->c->keepalive = AP_CONN_CLOSE; if (is_init) { sslconn->non_ssl_request = NON_SSL_SEND_REQLINE; return APR_EGENERAL; } sslconn->non_ssl_request = NON_SSL_SEND_HDR_SEP; /* fake the request line */ bucket = HTTP_ON_HTTPS_PORT_BUCKET(f->c->bucket_alloc); send_eos = 0; break; case MODSSL_ERROR_BAD_GATEWAY: ap_log_cerror(APLOG_MARK, APLOG_INFO, 0, f->c, APLOGNO(01997) "SSL handshake failed: sending 502"); f->c->aborted = 1; return APR_EGENERAL; default: return status; } APR_BRIGADE_INSERT_TAIL(bb, bucket); if (send_eos) { bucket = apr_bucket_eos_create(f->c->bucket_alloc); APR_BRIGADE_INSERT_TAIL(bb, bucket); } return APR_SUCCESS; } static const char ssl_io_filter[] = "SSL/TLS Filter"; static const char ssl_io_buffer[] = "SSL/TLS Buffer"; static const char ssl_io_coalesce[] = "SSL/TLS Coalescing Filter"; /* * Close the SSL part of the socket connection * (called immediately _before_ the socket is closed) * or called with */ static void ssl_filter_io_shutdown(ssl_filter_ctx_t *filter_ctx, conn_rec *c, int abortive) { SSL *ssl = filter_ctx->pssl; const char *type = ""; SSLConnRec *sslconn = myConnConfig(c); int shutdown_type; int loglevel = APLOG_DEBUG; const char *logno; if (!ssl) { return; } /* * Now close the SSL layer of the connection. We've to take * the TLSv1 standard into account here: * * | 7.2.1. Closure alerts * | * | The client and the server must share knowledge that the connection is * | ending in order to avoid a truncation attack. Either party may * | initiate the exchange of closing messages. * | * | close_notify * | This message notifies the recipient that the sender will not send * | any more messages on this connection. The session becomes * | unresumable if any connection is terminated without proper * | close_notify messages with level equal to warning. * | * | Either party may initiate a close by sending a close_notify alert. * | Any data received after a closure alert is ignored. * | * | Each party is required to send a close_notify alert before closing * | the write side of the connection. It is required that the other party * | respond with a close_notify alert of its own and close down the * | connection immediately, discarding any pending writes. It is not * | required for the initiator of the close to wait for the responding * | close_notify alert before closing the read side of the connection. * * This means we've to send a close notify message, but haven't to wait * for the close notify of the client. Actually we cannot wait for the * close notify of the client because some clients (including Netscape * 4.x) don't send one, so we would hang. */ /* * exchange close notify messages, but allow the user * to force the type of handshake via SetEnvIf directive */ if (abortive) { shutdown_type = SSL_SENT_SHUTDOWN|SSL_RECEIVED_SHUTDOWN; type = "abortive"; logno = APLOGNO(01998); loglevel = APLOG_INFO; } else switch (sslconn->shutdown_type) { case SSL_SHUTDOWN_TYPE_UNCLEAN: /* perform no close notify handshake at all (violates the SSL/TLS standard!) */ shutdown_type = SSL_SENT_SHUTDOWN|SSL_RECEIVED_SHUTDOWN; type = "unclean"; logno = APLOGNO(01999); break; case SSL_SHUTDOWN_TYPE_ACCURATE: /* send close notify and wait for clients close notify (standard compliant, but usually causes connection hangs) */ shutdown_type = 0; type = "accurate"; logno = APLOGNO(02000); break; default: /* * case SSL_SHUTDOWN_TYPE_UNSET: * case SSL_SHUTDOWN_TYPE_STANDARD: */ /* send close notify, but don't wait for clients close notify (standard compliant and safe, so it's the DEFAULT!) */ shutdown_type = SSL_RECEIVED_SHUTDOWN; type = "standard"; logno = APLOGNO(02001); break; } SSL_set_shutdown(ssl, shutdown_type); modssl_smart_shutdown(ssl); /* and finally log the fact that we've closed the connection */ if (APLOG_CS_IS_LEVEL(c, mySrvFromConn(c), loglevel)) { /* Intentional no APLOGNO */ /* logno provides APLOGNO */ ap_log_cserror(APLOG_MARK, loglevel, 0, c, mySrvFromConn(c), "%sConnection closed to child %ld with %s shutdown " "(server %s)", logno, c->id, type, ssl_util_vhostid(c->pool, mySrvFromConn(c))); } /* deallocate the SSL connection */ if (sslconn->client_cert) { X509_free(sslconn->client_cert); sslconn->client_cert = NULL; } SSL_free(ssl); sslconn->ssl = NULL; filter_ctx->pssl = NULL; /* so filters know we've been shutdown */ if (abortive) { /* prevent any further I/O */ c->aborted = 1; } } static apr_status_t ssl_io_filter_cleanup(void *data) { ssl_filter_ctx_t *filter_ctx = data; if (filter_ctx->pssl) { conn_rec *c = (conn_rec *)SSL_get_app_data(filter_ctx->pssl); SSLConnRec *sslconn = myConnConfig(c); SSL_free(filter_ctx->pssl); sslconn->ssl = filter_ctx->pssl = NULL; } return APR_SUCCESS; } /* * The hook is NOT registered with ap_hook_process_connection. Instead, it is * called manually from the churn () before it tries to read any data. * There is some problem if I accept conn_rec *. Still investigating.. * Adv. if conn_rec * can be accepted is we can hook this function using the * ap_hook_process_connection hook. */ /* Perform the SSL handshake (whether in client or server mode), if * necessary, for the given connection. */ static apr_status_t ssl_io_filter_handshake(ssl_filter_ctx_t *filter_ctx) { conn_rec *c = (conn_rec *)SSL_get_app_data(filter_ctx->pssl); SSLConnRec *sslconn = myConnConfig(c); SSLSrvConfigRec *sc; X509 *cert; int n; int ssl_err; long verify_result; server_rec *server; if (SSL_is_init_finished(filter_ctx->pssl)) { return APR_SUCCESS; } server = sslconn->server; if (c->outgoing) { #ifdef HAVE_TLSEXT apr_ipsubnet_t *ip; #ifdef HAVE_TLS_ALPN const char *alpn_note; apr_array_header_t *alpn_proposed = NULL; int alpn_empty_ok = 1; #endif #endif const char *hostname_note = apr_table_get(c->notes, "proxy-request-hostname"); BOOL proxy_ssl_check_peer_ok = TRUE; int post_handshake_rc = OK; SSLDirConfigRec *dc; dc = sslconn->dc; sc = mySrvConfig(server); #ifdef HAVE_TLSEXT #ifdef HAVE_TLS_ALPN alpn_note = apr_table_get(c->notes, "proxy-request-alpn-protos"); if (alpn_note) { char *protos, *s, *p, *last, *proto; apr_size_t len; /* Transform the note into a protocol formatted byte array: * (len-byte proto-char+)* * We need the remote server to agree on one of these, unless 'http/1.1' * is also among our proposals. Because pre-ALPN remotes will speak this. */ alpn_proposed = apr_array_make(c->pool, 3, sizeof(const char*)); alpn_empty_ok = 0; s = protos = apr_pcalloc(c->pool, strlen(alpn_note)+1); p = apr_pstrdup(c->pool, alpn_note); while ((p = apr_strtok(p, ", ", &last))) { len = last - p - (*last? 1 : 0); if (len > 255) { ap_log_cerror(APLOG_MARK, APLOG_ERR, 0, c, APLOGNO(03309) "ALPN proxy protocol identifier too long: %s", p); ssl_log_ssl_error(SSLLOG_MARK, APLOG_ERR, server); return APR_EGENERAL; } proto = apr_pstrndup(c->pool, p, len); APR_ARRAY_PUSH(alpn_proposed, const char*) = proto; if (!strcmp("http/1.1", proto)) { alpn_empty_ok = 1; } *s++ = (unsigned char)len; while (len--) { *s++ = *p++; } p = NULL; } ap_log_cerror(APLOG_MARK, APLOG_TRACE1, 0, c, "setting alpn protos from '%s', protolen=%d", alpn_note, (int)(s - protos)); if (protos != s && SSL_set_alpn_protos(filter_ctx->pssl, (unsigned char *)protos, s - protos)) { ap_log_cerror(APLOG_MARK, APLOG_WARNING, 0, c, APLOGNO(03310) "error setting alpn protos from '%s'", alpn_note); ssl_log_ssl_error(SSLLOG_MARK, APLOG_WARNING, server); /* If ALPN was requested and we cannot do it, we must fail */ return MODSSL_ERROR_BAD_GATEWAY; } } #endif /* defined HAVE_TLS_ALPN */ /* * Enable SNI for backend requests. Make sure we don't do it for * pure SSLv3 connections, and also prevent IP addresses * from being included in the SNI extension. (OpenSSL would simply * pass them on, but RFC 6066 is quite clear on this: "Literal * IPv4 and IPv6 addresses are not permitted".) */ if (hostname_note && #ifndef OPENSSL_NO_SSL3 dc->proxy->protocol != SSL_PROTOCOL_SSLV3 && #endif apr_ipsubnet_create(&ip, hostname_note, NULL, c->pool) != APR_SUCCESS) { if (SSL_set_tlsext_host_name(filter_ctx->pssl, hostname_note)) { ap_log_cerror(APLOG_MARK, APLOG_TRACE3, 0, c, "SNI extension for SSL Proxy request set to '%s'", hostname_note); } else { ap_log_cerror(APLOG_MARK, APLOG_WARNING, 0, c, APLOGNO(02002) "Failed to set SNI extension for SSL Proxy " "request to '%s'", hostname_note); ssl_log_ssl_error(SSLLOG_MARK, APLOG_WARNING, server); } } #endif /* defined HAVE_TLSEXT */ if ((n = SSL_connect(filter_ctx->pssl)) <= 0) { ap_log_cerror(APLOG_MARK, APLOG_INFO, 0, c, APLOGNO(02003) "SSL Proxy connect failed"); ssl_log_ssl_error(SSLLOG_MARK, APLOG_INFO, server); /* ensure that the SSL structures etc are freed, etc: */ ssl_filter_io_shutdown(filter_ctx, c, 1); apr_table_setn(c->notes, "SSL_connect_rv", "err"); return MODSSL_ERROR_BAD_GATEWAY; } cert = SSL_get_peer_certificate(filter_ctx->pssl); if (dc->proxy->ssl_check_peer_expire != FALSE) { if (!cert || (X509_cmp_current_time( X509_get_notBefore(cert)) >= 0) || (X509_cmp_current_time( X509_get_notAfter(cert)) <= 0)) { proxy_ssl_check_peer_ok = FALSE; ap_log_cerror(APLOG_MARK, APLOG_INFO, 0, c, APLOGNO(02004) "SSL Proxy: Peer certificate is expired"); } } if ((dc->proxy->ssl_check_peer_name != FALSE) && ((dc->proxy->ssl_check_peer_cn != FALSE) || (dc->proxy->ssl_check_peer_name == TRUE)) && hostname_note) { if (!cert || modssl_X509_match_name(c->pool, cert, hostname_note, TRUE, server) == FALSE) { proxy_ssl_check_peer_ok = FALSE; ap_log_cerror(APLOG_MARK, APLOG_INFO, 0, c, APLOGNO(02411) "SSL Proxy: Peer certificate does not match " "for hostname %s", hostname_note); } } else if ((dc->proxy->ssl_check_peer_cn == TRUE) && hostname_note) { const char *hostname; int match = 0; hostname = ssl_var_lookup(NULL, server, c, NULL, "SSL_CLIENT_S_DN_CN"); /* Do string match or simplest wildcard match if that * fails. */ match = strcasecmp(hostname, hostname_note) == 0; if (!match && strncmp(hostname, "*.", 2) == 0) { const char *p = ap_strchr_c(hostname_note, '.'); match = p && strcasecmp(p, hostname + 1) == 0; } if (!match) { proxy_ssl_check_peer_ok = FALSE; ap_log_cerror(APLOG_MARK, APLOG_INFO, 0, c, APLOGNO(02005) "SSL Proxy: Peer certificate CN mismatch:" " Certificate CN: %s Requested hostname: %s", hostname, hostname_note); } } #ifdef HAVE_TLS_ALPN /* If we proposed ALPN protocol(s), we need to check if the server * agreed to one of them. While <https://www.rfc-editor.org/rfc/rfc7301.txt> * chapter 3.2 says the server SHALL error the handshake in such a case, * the reality is that some servers fall back to their default, e.g. http/1.1. * (we also do this right now) * We need to treat this as an error for security reasons. */ if (alpn_proposed && alpn_proposed->nelts > 0) { const char *selected; unsigned int slen; SSL_get0_alpn_selected(filter_ctx->pssl, (const unsigned char**)&selected, &slen); if (!selected || !slen) { /* No ALPN selection reported by the remote server. This could mean * it does not support ALPN (old server) or that it does not support * any of our proposals (Apache itself up to 2.4.48 at least did that). */ if (!alpn_empty_ok) { ap_log_cerror(APLOG_MARK, APLOG_INFO, 0, c, APLOGNO(10273) "SSL Proxy: Peer did not select any of our ALPN protocols [%s].", alpn_note); proxy_ssl_check_peer_ok = FALSE; } } else { const char *proto; int i, found = 0; for (i = 0; !found && i < alpn_proposed->nelts; ++i) { proto = APR_ARRAY_IDX(alpn_proposed, i, const char *); found = !strncmp(selected, proto, slen); } if (!found) { /* From a conforming peer, this should never happen, * but life always finds a way... */ proto = apr_pstrndup(c->pool, selected, slen); ap_log_cerror(APLOG_MARK, APLOG_INFO, 0, c, APLOGNO(10274) "SSL Proxy: Peer proposed ALPN protocol %s which is none " "of our proposals [%s].", proto, alpn_note); proxy_ssl_check_peer_ok = FALSE; } } } #endif if (proxy_ssl_check_peer_ok == TRUE) { /* another chance to fail */ post_handshake_rc = ssl_run_proxy_post_handshake(c, filter_ctx->pssl); } if (cert) { X509_free(cert); } if (proxy_ssl_check_peer_ok != TRUE || (post_handshake_rc != OK && post_handshake_rc != DECLINED)) { /* ensure that the SSL structures etc are freed, etc: */ ssl_filter_io_shutdown(filter_ctx, c, 1); apr_table_setn(c->notes, "SSL_connect_rv", "err"); return MODSSL_ERROR_BAD_GATEWAY; } apr_table_setn(c->notes, "SSL_connect_rv", "ok"); return APR_SUCCESS; } /* We rely on SSL_get_error() after the accept, which requires an empty * error queue before the accept in order to work properly. */ ERR_clear_error(); if ((n = SSL_accept(filter_ctx->pssl)) <= 0) { bio_filter_in_ctx_t *inctx = (bio_filter_in_ctx_t *) BIO_get_data(filter_ctx->pbioRead); bio_filter_out_ctx_t *outctx = (bio_filter_out_ctx_t *) BIO_get_data(filter_ctx->pbioWrite); apr_status_t rc = inctx->rc ? inctx->rc : outctx->rc ; ssl_err = SSL_get_error(filter_ctx->pssl, n); if (ssl_err == SSL_ERROR_ZERO_RETURN) { /* * The case where the connection was closed before any data * was transferred. That's not a real error and can occur * sporadically with some clients. */ ap_log_cerror(APLOG_MARK, APLOG_INFO, rc, c, APLOGNO(02006) "SSL handshake stopped: connection was closed"); } else if (ssl_err == SSL_ERROR_WANT_READ) { /* * This is in addition to what was present earlier. It is * borrowed from openssl_state_machine.c [mod_tls]. * TBD. */ outctx->rc = APR_EAGAIN; return APR_EAGAIN; } else if (ERR_GET_LIB(ERR_peek_error()) == ERR_LIB_SSL && ERR_GET_REASON(ERR_peek_error()) == SSL_R_HTTP_REQUEST) { /* * The case where OpenSSL has recognized a HTTP request: * This means the client speaks plain HTTP on our HTTPS port. * ssl_io_filter_error will disable the ssl filters when it * sees this status code. */ return MODSSL_ERROR_HTTP_ON_HTTPS; } else if (ssl_err == SSL_ERROR_SYSCALL) { ap_log_cerror(APLOG_MARK, APLOG_DEBUG, rc, c, APLOGNO(02007) "SSL handshake interrupted by system " "[Hint: Stop button pressed in browser?!]"); } else /* if (ssl_err == SSL_ERROR_SSL) */ { /* * Log SSL errors and any unexpected conditions. */ ap_log_cerror(APLOG_MARK, APLOG_INFO, rc, c, APLOGNO(02008) "SSL library error %d in handshake " "(server %s)", ssl_err, ssl_util_vhostid(c->pool, server)); ssl_log_ssl_error(SSLLOG_MARK, APLOG_INFO, server); } if (inctx->rc == APR_SUCCESS) { inctx->rc = APR_EGENERAL; } ssl_filter_io_shutdown(filter_ctx, c, 1); return inctx->rc; } sc = mySrvConfig(sslconn->server); /* * Check for failed client authentication */ verify_result = SSL_get_verify_result(filter_ctx->pssl); if ((verify_result != X509_V_OK) || sslconn->verify_error) { if (ssl_verify_error_is_optional(verify_result) && (sc->server->auth.verify_mode == SSL_CVERIFY_OPTIONAL_NO_CA)) { /* leaving this log message as an error for the moment, * according to the mod_ssl docs: * "level optional_no_ca is actually against the idea * of authentication (but can be used to establish * SSL test pages, etc.)" * optional_no_ca doesn't appear to work as advertised * in 1.x */ ap_log_cerror(APLOG_MARK, APLOG_INFO, 0, c, APLOGNO(02009) "SSL client authentication failed, " "accepting certificate based on " "\"SSLVerifyClient optional_no_ca\" " "configuration"); ssl_log_ssl_error(SSLLOG_MARK, APLOG_INFO, server); } else { const char *error = sslconn->verify_error ? sslconn->verify_error : X509_verify_cert_error_string(verify_result); ap_log_cerror(APLOG_MARK, APLOG_INFO, 0, c, APLOGNO(02010) "SSL client authentication failed: %s", error ? error : "unknown"); ssl_log_ssl_error(SSLLOG_MARK, APLOG_INFO, server); ssl_filter_io_shutdown(filter_ctx, c, 1); return APR_ECONNABORTED; } } /* * Remember the peer certificate's DN */ if ((cert = SSL_get_peer_certificate(filter_ctx->pssl))) { if (sslconn->client_cert) { X509_free(sslconn->client_cert); } sslconn->client_cert = cert; sslconn->client_dn = NULL; } /* * Make really sure that when a peer certificate * is required we really got one... (be paranoid) */ if ((sc->server->auth.verify_mode == SSL_CVERIFY_REQUIRE) && !sslconn->client_cert) { ap_log_cerror(APLOG_MARK, APLOG_INFO, 0, c, APLOGNO(02011) "No acceptable peer certificate available"); ssl_filter_io_shutdown(filter_ctx, c, 1); return APR_ECONNABORTED; } return APR_SUCCESS; } static apr_status_t ssl_io_filter_input(ap_filter_t *f, apr_bucket_brigade *bb, ap_input_mode_t mode, apr_read_type_e block, apr_off_t readbytes) { apr_status_t status; bio_filter_in_ctx_t *inctx = f->ctx; const char *start = inctx->buffer; /* start of block to return */ apr_size_t len = sizeof(inctx->buffer); /* length of block to return */ int is_init = (mode == AP_MODE_INIT); apr_bucket *bucket; if (f->c->aborted) { /* XXX: Ok, if we aborted, we ARE at the EOS. We also have * aborted. This 'double protection' is probably redundant, * but also effective against just about anything. */ bucket = apr_bucket_eos_create(f->c->bucket_alloc); APR_BRIGADE_INSERT_TAIL(bb, bucket); return APR_ECONNABORTED; } if (!inctx->ssl) { SSLConnRec *sslconn = myConnConfig(f->c); if (sslconn->non_ssl_request == NON_SSL_SEND_REQLINE) { bucket = HTTP_ON_HTTPS_PORT_BUCKET(f->c->bucket_alloc); APR_BRIGADE_INSERT_TAIL(bb, bucket); if (mode != AP_MODE_SPECULATIVE) { sslconn->non_ssl_request = NON_SSL_SEND_HDR_SEP; } return APR_SUCCESS; } if (sslconn->non_ssl_request == NON_SSL_SEND_HDR_SEP) { bucket = apr_bucket_immortal_create(CRLF, 2, f->c->bucket_alloc); APR_BRIGADE_INSERT_TAIL(bb, bucket); if (mode != AP_MODE_SPECULATIVE) { sslconn->non_ssl_request = NON_SSL_SET_ERROR_MSG; } return APR_SUCCESS; } return ap_get_brigade(f->next, bb, mode, block, readbytes); } /* XXX: we don't currently support anything other than these modes. */ if (mode != AP_MODE_READBYTES && mode != AP_MODE_GETLINE && mode != AP_MODE_SPECULATIVE && mode != AP_MODE_INIT) { return APR_ENOTIMPL; } inctx->mode = mode; inctx->block = block; /* XXX: we could actually move ssl_io_filter_handshake to an * ap_hook_process_connection but would still need to call it for * AP_MODE_INIT for protocols that may upgrade the connection * rather than have SSLEngine On configured. */ if ((status = ssl_io_filter_handshake(inctx->filter_ctx)) != APR_SUCCESS) { return ssl_io_filter_error(inctx, bb, status, is_init); } if (is_init) { /* protocol module needs to handshake before sending * data to client (e.g. NNTP or FTP) */ return APR_SUCCESS; } if (inctx->mode == AP_MODE_READBYTES || inctx->mode == AP_MODE_SPECULATIVE) { /* Protected from truncation, readbytes < MAX_SIZE_T * FIXME: No, it's *not* protected. -- jre */ if (readbytes < len) { len = (apr_size_t)readbytes; } status = ssl_io_input_read(inctx, inctx->buffer, &len); } else if (inctx->mode == AP_MODE_GETLINE) { const char *pos; /* Satisfy the read directly out of the buffer if possible; * invoking ssl_io_input_getline will mean the entire buffer * is copied once (unnecessarily) for each GETLINE call. */ if (inctx->cbuf.length && (pos = memchr(inctx->cbuf.value, APR_ASCII_LF, inctx->cbuf.length)) != NULL) { start = inctx->cbuf.value; len = 1 + pos - start; /* +1 to include LF */ /* Buffer contents now consumed. */ inctx->cbuf.value += len; inctx->cbuf.length -= len; status = APR_SUCCESS; } else { /* Otherwise fall back to the hard way. */ status = ssl_io_input_getline(inctx, inctx->buffer, &len); } } else { /* We have no idea what you are talking about, so return an error. */ status = APR_ENOTIMPL; } /* It is possible for mod_ssl's BIO to be used outside of the * direct control of mod_ssl's input or output filter -- notably, * when mod_ssl initiates a renegotiation. Switching the BIO mode * back to "blocking" here ensures such operations don't fail with * SSL_ERROR_WANT_READ. */ inctx->block = APR_BLOCK_READ; /* Handle custom errors. */ if (status != APR_SUCCESS) { return ssl_io_filter_error(inctx, bb, status, 0); } /* Create a transient bucket out of the decrypted data. */ if (len > 0) { bucket = apr_bucket_transient_create(start, len, f->c->bucket_alloc); APR_BRIGADE_INSERT_TAIL(bb, bucket); } return APR_SUCCESS; } /* ssl_io_filter_output() produces one SSL/TLS record per bucket * passed down the output filter stack. This results in a high * overhead (more network packets & TLS processing) for any output * comprising many small buckets. SSI output passed through the HTTP * chunk filter, for example, may produce many brigades containing * small buckets - [chunk-size CRLF] [chunk-data] [CRLF]. * * Sending HTTP response headers as a separate TLS record to the * response body also reveals information to a network observer (the * size of headers) which can be significant. * * The coalescing filter merges data buckets with the aim of producing * fewer, larger TLS records - without copying/buffering all content * and introducing unnecessary overhead. * * ### This buffering could be probably be done more comprehensively * ### in ssl_io_filter_output itself. * * ### Another possible performance optimisation in particular for the * ### [HEAP] [FILE] HTTP response case is using a brigade rather than * ### a char array to buffer; using apr_brigade_write() to append * ### will use already-allocated memory from the HEAP, reducing # of * ### copies. */ #define COALESCE_BYTES (AP_IOBUFSIZE) struct coalesce_ctx { char buffer[COALESCE_BYTES]; apr_size_t bytes; /* number of bytes of buffer used. */ }; static apr_status_t ssl_io_filter_coalesce(ap_filter_t *f, apr_bucket_brigade *bb) { apr_bucket *e, *upto; apr_size_t bytes = 0; struct coalesce_ctx *ctx = f->ctx; apr_size_t buffered = ctx ? ctx->bytes : 0; /* space used on entry */ unsigned count = 0; /* The brigade consists of zero-or-more small data buckets which * can be coalesced (referred to as the "prefix"), followed by the * remainder of the brigade. * * Find the last bucket - if any - of that prefix. count gives * the number of buckets in the prefix. The "prefix" must contain * only data buckets with known length, and must be of a total * size which fits into the buffer. * * N.B.: The process here could be repeated throughout the brigade * (coalesce any run of consecutive data buckets) but this would * add significant complexity, particularly to memory * management. */ for (e = APR_BRIGADE_FIRST(bb); e != APR_BRIGADE_SENTINEL(bb) && !APR_BUCKET_IS_METADATA(e) && e->length != (apr_size_t)-1 && e->length <= COALESCE_BYTES && (buffered + bytes + e->length) <= COALESCE_BYTES; e = APR_BUCKET_NEXT(e)) { /* don't count zero-length buckets */ if (e->length) { bytes += e->length; count++; } } /* If there is room remaining and the next bucket is a data * bucket, try to include it in the prefix to coalesce. For a * typical [HEAP] [FILE] HTTP response brigade, this handles * merging the headers and the start of the body into a single TLS * record. */ if (bytes + buffered > 0 && bytes + buffered < COALESCE_BYTES && e != APR_BRIGADE_SENTINEL(bb) && !APR_BUCKET_IS_METADATA(e)) { apr_status_t rv = APR_SUCCESS; /* For an indeterminate length bucket (PIPE/CGI/...), try a * non-blocking read to have it morph into a HEAP. If the * read fails with EAGAIN, it is harmless to try a split * anyway, split is ENOTIMPL for most PIPE-like buckets. */ if (e->length == (apr_size_t)-1) { const char *discard; apr_size_t ignore; rv = apr_bucket_read(e, &discard, &ignore, APR_NONBLOCK_READ); if (rv != APR_SUCCESS && !APR_STATUS_IS_EAGAIN(rv)) { ap_log_cerror(APLOG_MARK, APLOG_ERR, rv, f->c, APLOGNO(10232) "coalesce failed to read from %s bucket", e->type->name); return AP_FILTER_ERROR; } } if (rv == APR_SUCCESS) { /* If the read above made the bucket morph, it may now fit * entirely within the buffer. Otherwise, split it so it does * fit. */ if (e->length > COALESCE_BYTES || e->length + buffered + bytes > COALESCE_BYTES) { rv = apr_bucket_split(e, COALESCE_BYTES - (buffered + bytes)); } if (rv == APR_SUCCESS && e->length == 0) { /* As above, don't count in the prefix if the bucket is * now zero-length. */ } else if (rv == APR_SUCCESS) { ap_log_cerror(APLOG_MARK, APLOG_TRACE4, 0, f->c, "coalesce: adding %" APR_SIZE_T_FMT " bytes " "from split %s bucket, total %" APR_SIZE_T_FMT, e->length, e->type->name, bytes + buffered); count++; bytes += e->length; e = APR_BUCKET_NEXT(e); } --> -------------------- --> maximum size reached --> -------------------- ¤ Dauer der Verarbeitung: 0.40 Sekunden (vorverarbeitet) ¤*© Formatika GbR, Deutschland |
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2026-03-28