/* 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. */ #include "mod_session.h" #include "apu_version.h" #include "apr_base64.h" /* for apr_base64_decode et al */ #include "apr_lib.h" #include "apr_md5.h" #include "apr_strings.h" #include "http_log.h" #include "http_core.h" #if APU_MAJOR_VERSION == 1 && APU_MINOR_VERSION < 4 #error session_crypto_module requires APU v1.4.0 or later #elif APU_HAVE_CRYPTO == 0 #error Crypto support must be enabled in APR #else #include "apr_crypto.h" /* for apr_*_crypt et al */ #define CRYPTO_KEY "session_crypto_context" module AP_MODULE_DECLARE_DATA session_crypto_module; /** * Structure to carry the per-dir session config. */ typedef struct { apr_array_header_t *passphrases; int passphrases_set; const char *cipher; int cipher_set; } session_crypto_dir_conf; /** * Structure to carry the server wide session config. */ typedef struct { const char *library; const char *params; int library_set; } session_crypto_conf; /* Wrappers around apr_siphash24() and apr_crypto_equals(), * available in APU-1.6/APR-2.0 only. */ #if APU_MAJOR_VERSION > 1 || (APU_MAJOR_VERSION == 1 && APU_MINOR_VERSION >= 6) #include "apr_siphash.h" #define AP_SIPHASH_DSIZE APR_SIPHASH_DSIZE #define AP_SIPHASH_KSIZE APR_SIPHASH_KSIZE #define ap_siphash24_auth apr_siphash24_auth #define ap_crypto_equals apr_crypto_equals #else #define AP_SIPHASH_DSIZE 8 #define AP_SIPHASH_KSIZE 16 #define ROTL64(x, n) (((x) << (n)) | ((x) >> (64 - (n)))) #define U8TO64_LE(p) \ (((apr_uint64_t)((p)[0]) ) | \ ((apr_uint64_t)((p)[1]) << 8) | \ ((apr_uint64_t)((p)[2]) << 16) | \ ((apr_uint64_t)((p)[3]) << 24) | \ ((apr_uint64_t)((p)[4]) << 32) | \ ((apr_uint64_t)((p)[5]) << 40) | \ ((apr_uint64_t)((p)[6]) << 48) | \ ((apr_uint64_t)((p)[7]) << 56)) #define U64TO8_LE(p, v) \ do { \ (p)[0] = (unsigned char)((v) ); \ (p)[1] = (unsigned char)((v) >> 8); \ (p)[2] = (unsigned char)((v) >> 16); \ (p)[3] = (unsigned char)((v) >> 24); \ (p)[4] = (unsigned char)((v) >> 32); \ (p)[5] = (unsigned char)((v) >> 40); \ (p)[6] = (unsigned char)((v) >> 48); \ (p)[7] = (unsigned char)((v) >> 56); \ } while (0) #define SIPROUND() \ do { \ v0 += v1; v1=ROTL64(v1,13); v1 ^= v0; v0=ROTL64(v0,32); \ v2 += v3; v3=ROTL64(v3,16); v3 ^= v2; \ v0 += v3; v3=ROTL64(v3,21); v3 ^= v0; \ v2 += v1; v1=ROTL64(v1,17); v1 ^= v2; v2=ROTL64(v2,32); \ } while(0) static apr_uint64_t ap_siphash24(const void *src, apr_size_t len, const unsigned char key[AP_SIPHASH_KSIZE]) { const unsigned char *ptr, *end; apr_uint64_t v0, v1, v2, v3, m; apr_uint64_t k0, k1; unsigned int rem; k0 = U8TO64_LE(key + 0); k1 = U8TO64_LE(key + 8); v3 = k1 ^ (apr_uint64_t)0x7465646279746573ULL; v2 = k0 ^ (apr_uint64_t)0x6c7967656e657261ULL; v1 = k1 ^ (apr_uint64_t)0x646f72616e646f6dULL; v0 = k0 ^ (apr_uint64_t)0x736f6d6570736575ULL; rem = (unsigned int)(len & 0x7); for (ptr = src, end = ptr + len - rem; ptr < end; ptr += 8) { m = U8TO64_LE(ptr); v3 ^= m; SIPROUND(); SIPROUND(); v0 ^= m; } m = (apr_uint64_t)(len & 0xff) << 56; switch (rem) { case 7: m |= (apr_uint64_t)ptr[6] << 48; case 6: m |= (apr_uint64_t)ptr[5] << 40; case 5: m |= (apr_uint64_t)ptr[4] << 32; case 4: m |= (apr_uint64_t)ptr[3] << 24; case 3: m |= (apr_uint64_t)ptr[2] << 16; case 2: m |= (apr_uint64_t)ptr[1] << 8; case 1: m |= (apr_uint64_t)ptr[0]; case 0: break; } v3 ^= m; SIPROUND(); SIPROUND(); v0 ^= m; v2 ^= 0xff; SIPROUND(); SIPROUND(); SIPROUND(); SIPROUND(); return v0 ^ v1 ^ v2 ^ v3; } static void ap_siphash24_auth(unsigned char out[AP_SIPHASH_DSIZE], const void *src, apr_size_t len, const unsigned char key[AP_SIPHASH_KSIZE]) { apr_uint64_t h; h = ap_siphash24(src, len, key); U64TO8_LE(out, h); } static int ap_crypto_equals(const void *buf1, const void *buf2, apr_size_t size) { const unsigned char *p1 = buf1; const unsigned char *p2 = buf2; unsigned char diff = 0; apr_size_t i; for (i = 0; i < size; ++i) { diff |= p1[i] ^ p2[i]; } return 1 & ((diff - 1) >> 8); } #endif static void compute_auth(const void *src, apr_size_t len, const char *passphrase, apr_size_t passlen, unsigned char auth[AP_SIPHASH_DSIZE]) { unsigned char key[APR_MD5_DIGESTSIZE]; /* XXX: if we had a way to get the raw bytes from an apr_crypto_key_t * we could use them directly (not available in APR-1.5.x). * MD5 is 128bit too, so use it to get a suitable siphash key * from the passphrase. */ apr_md5(key, passphrase, passlen); ap_siphash24_auth(auth, src, len, key); } /** * Initialise the encryption as per the current config. * * Returns APR_SUCCESS if successful. */ static apr_status_t crypt_init(request_rec *r, const apr_crypto_t *f, apr_crypto_block_key_type_e **cipher, session_crypto_dir_conf * dconf) { apr_status_t res; apr_hash_t *ciphers; res = apr_crypto_get_block_key_types(&ciphers, f); if (APR_SUCCESS != res) { ap_log_rerror(APLOG_MARK, APLOG_ERR, res, r, APLOGNO(01823) "no ciphers returned by APR. " "session encryption not possible"); return res; } *cipher = apr_hash_get(ciphers, dconf->cipher, APR_HASH_KEY_STRING); if (!(*cipher)) { apr_hash_index_t *hi; const void *key; apr_ssize_t klen; int sum = 0; int offset = 0; char *options = NULL; for (hi = apr_hash_first(r->pool, ciphers); hi; hi = apr_hash_next(hi)) { apr_hash_this(hi, NULL, &klen, NULL); sum += klen + 2; } for (hi = apr_hash_first(r->pool, ciphers); hi; hi = apr_hash_next(hi)) { apr_hash_this(hi, &key, &klen, NULL); if (!options) { options = apr_palloc(r->pool, sum + 1); } else { options[offset++] = ','; options[offset++] = ' '; } strncpy(options + offset, key, klen); offset += klen; } options[offset] = 0; ap_log_rerror(APLOG_MARK, APLOG_ERR, res, r, APLOGNO(01824) "cipher '%s' not recognised by crypto driver. " "session encryption not possible, options: %s", dconf->cipher, options); return APR_EGENERAL; } return APR_SUCCESS; } /** * Encrypt the string given as per the current config. * * Returns APR_SUCCESS if successful. */ static apr_status_t encrypt_string(request_rec * r, const apr_crypto_t *f, session_crypto_dir_conf *dconf, const char *in, char **out) { apr_status_t res; apr_crypto_key_t *key = NULL; apr_size_t ivSize = 0; apr_crypto_block_t *block = NULL; unsigned char *encrypt = NULL; unsigned char *combined = NULL; apr_size_t encryptlen, tlen, combinedlen; char *base64; apr_size_t blockSize = 0; const unsigned char *iv = NULL; apr_uuid_t salt; apr_crypto_block_key_type_e *cipher; const char *passphrase; apr_size_t passlen; /* use a uuid as a salt value, and prepend it to our result */ apr_uuid_get(&salt); res = crypt_init(r, f, &cipher, dconf); if (res != APR_SUCCESS) { return res; } /* encrypt using the first passphrase in the list */ passphrase = APR_ARRAY_IDX(dconf->passphrases, 0, const char *); passlen = strlen(passphrase); res = apr_crypto_passphrase(&key, &ivSize, passphrase, passlen, (unsigned char *) (&salt), sizeof(apr_uuid_t), *cipher, APR_MODE_CBC, 1, 4096, f, r->pool); if (APR_STATUS_IS_ENOKEY(res)) { ap_log_rerror(APLOG_MARK, APLOG_ERR, res, r, APLOGNO(01825) "the passphrase '%s' was empty", passphrase); } if (APR_STATUS_IS_EPADDING(res)) { ap_log_rerror(APLOG_MARK, APLOG_ERR, res, r, APLOGNO(01826) "padding is not supported for cipher"); } if (APR_STATUS_IS_EKEYTYPE(res)) { ap_log_rerror(APLOG_MARK, APLOG_ERR, res, r, APLOGNO(01827) "the key type is not known"); } if (APR_SUCCESS != res) { ap_log_rerror(APLOG_MARK, APLOG_ERR, res, r, APLOGNO(01828) "encryption could not be configured."); return res; } res = apr_crypto_block_encrypt_init(&block, &iv, key, &blockSize, r->pool); if (APR_SUCCESS != res) { ap_log_rerror(APLOG_MARK, APLOG_ERR, res, r, APLOGNO(01829) "apr_crypto_block_encrypt_init failed"); return res; } /* encrypt the given string */ res = apr_crypto_block_encrypt(&encrypt, &encryptlen, (const unsigned char *)in, strlen(in), block); if (APR_SUCCESS != res) { ap_log_rerror(APLOG_MARK, APLOG_ERR, res, r, APLOGNO(01830) "apr_crypto_block_encrypt failed"); return res; } res = apr_crypto_block_encrypt_finish(encrypt + encryptlen, &tlen, block); if (APR_SUCCESS != res) { ap_log_rerror(APLOG_MARK, APLOG_ERR, res, r, APLOGNO(01831) "apr_crypto_block_encrypt_finish failed"); return res; } encryptlen += tlen; /* prepend the salt and the iv to the result (keep room for the MAC) */ combinedlen = AP_SIPHASH_DSIZE + sizeof(apr_uuid_t) + ivSize + encryptlen; combined = apr_palloc(r->pool, combinedlen); memcpy(combined + AP_SIPHASH_DSIZE, &salt, sizeof(apr_uuid_t)); memcpy(combined + AP_SIPHASH_DSIZE + sizeof(apr_uuid_t), iv, ivSize); memcpy(combined + AP_SIPHASH_DSIZE + sizeof(apr_uuid_t) + ivSize, encrypt, encryptlen); /* authenticate the whole salt+IV+ciphertext with a leading MAC */ compute_auth(combined + AP_SIPHASH_DSIZE, combinedlen - AP_SIPHASH_DSIZE, passphrase, passlen, combined); /* base64 encode the result (APR handles the trailing '\0') */ base64 = apr_palloc(r->pool, apr_base64_encode_len(combinedlen)); apr_base64_encode(base64, (const char *) combined, combinedlen); *out = base64; return res; } /** * Decrypt the string given as per the current config. * * Returns APR_SUCCESS if successful. */ static apr_status_t decrypt_string(request_rec * r, const apr_crypto_t *f, session_crypto_dir_conf *dconf, const char *in, char **out) { apr_status_t res; apr_crypto_key_t *key = NULL; apr_size_t ivSize = 0; apr_crypto_block_t *block = NULL; unsigned char *decrypted = NULL; apr_size_t decryptedlen, tlen; apr_size_t decodedlen; char *decoded; apr_size_t blockSize = 0; apr_crypto_block_key_type_e *cipher; unsigned char auth[AP_SIPHASH_DSIZE]; int i = 0; /* strip base64 from the string */ decoded = apr_palloc(r->pool, apr_base64_decode_len(in)); decodedlen = apr_base64_decode(decoded, in); decoded[decodedlen] = '\0'; /* sanity check - decoded too short? */ if (decodedlen < (AP_SIPHASH_DSIZE + sizeof(apr_uuid_t))) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, APR_SUCCESS, r, APLOGNO() "too short to decrypt, aborting"); return APR_ECRYPT; } res = crypt_init(r, f, &cipher, dconf); if (res != APR_SUCCESS) { return res; } /* try each passphrase in turn */ for (; i < dconf->passphrases->nelts; i++) { const char *passphrase = APR_ARRAY_IDX(dconf->passphrases, i, char *); apr_size_t passlen = strlen(passphrase); apr_size_t len = decodedlen - AP_SIPHASH_DSIZE; unsigned char *slider = (unsigned char *)decoded + AP_SIPHASH_DSIZE; /* Verify authentication of the whole salt+IV+ciphertext by computing * the MAC and comparing it (timing safe) with the one in the payload. */ compute_auth(slider, len, passphrase, passlen, auth); if (!ap_crypto_equals(auth, decoded, AP_SIPHASH_DSIZE)) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, res, r, APLOGNO() "auth does not match, skipping"); continue; } /* encrypt using the first passphrase in the list */ res = apr_crypto_passphrase(&key, &ivSize, passphrase, passlen, slider, sizeof(apr_uuid_t), *cipher, APR_MODE_CBC, 1, 4096, f, r->pool); if (APR_STATUS_IS_ENOKEY(res)) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, res, r, APLOGNO(01832) "the passphrase '%s' was empty", passphrase); continue; } else if (APR_STATUS_IS_EPADDING(res)) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, res, r, APLOGNO(01833) "padding is not supported for cipher"); continue; } else if (APR_STATUS_IS_EKEYTYPE(res)) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, res, r, APLOGNO(01834) "the key type is not known"); continue; } else if (APR_SUCCESS != res) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, res, r, APLOGNO(01835) "encryption could not be configured."); continue; } /* sanity check - decoded too short? */ if (len < (sizeof(apr_uuid_t) + ivSize)) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, APR_SUCCESS, r, APLOGNO(01836) "too short to decrypt, skipping"); res = APR_ECRYPT; continue; } /* bypass the salt at the start of the decoded block */ slider += sizeof(apr_uuid_t); len -= sizeof(apr_uuid_t); res = apr_crypto_block_decrypt_init(&block, &blockSize, slider, key, r->pool); if (APR_SUCCESS != res) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, res, r, APLOGNO(01837) "apr_crypto_block_decrypt_init failed"); continue; } /* bypass the iv at the start of the decoded block */ slider += ivSize; len -= ivSize; /* decrypt the given string */ res = apr_crypto_block_decrypt(&decrypted, &decryptedlen, slider, len, block); if (res) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, res, r, APLOGNO(01838) "apr_crypto_block_decrypt failed"); continue; } *out = (char *) decrypted; res = apr_crypto_block_decrypt_finish(decrypted + decryptedlen, &tlen, block); if (APR_SUCCESS != res) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, res, r, APLOGNO(01839) "apr_crypto_block_decrypt_finish failed"); continue; } decryptedlen += tlen; decrypted[decryptedlen] = 0; break; } if (APR_SUCCESS != res) { ap_log_rerror(APLOG_MARK, APLOG_INFO, res, r, APLOGNO(01840) "decryption failed"); } return res; } /** * Crypto encoding for the session. * * @param r The request pointer. * @param z A pointer to where the session will be written. */ static apr_status_t session_crypto_encode(request_rec * r, session_rec * z) { char *encoded = NULL; apr_status_t res; const apr_crypto_t *f = NULL; session_crypto_dir_conf *dconf = ap_get_module_config(r->per_dir_config, &session_crypto_module); if (dconf->passphrases_set && z->encoded && *z->encoded) { apr_pool_userdata_get((void **)&f, CRYPTO_KEY, r->server->process->pconf); res = encrypt_string(r, f, dconf, z->encoded, &encoded); if (res != OK) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, res, r, APLOGNO(01841) "encrypt session failed"); return res; } z->encoded = encoded; } return OK; } /** * Crypto decoding for the session. * * @param r The request pointer. * @param z A pointer to where the session will be written. */ static apr_status_t session_crypto_decode(request_rec * r, session_rec * z) { char *encoded = NULL; apr_status_t res; const apr_crypto_t *f = NULL; session_crypto_dir_conf *dconf = ap_get_module_config(r->per_dir_config, &session_crypto_module); if ((dconf->passphrases_set) && z->encoded && *z->encoded) { apr_pool_userdata_get((void **)&f, CRYPTO_KEY, r->server->process->pconf); res = decrypt_string(r, f, dconf, z->encoded, &encoded); if (res != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_ERR, res, r, APLOGNO(01842) "decrypt session failed, wrong passphrase?"); return res; } z->encoded = encoded; } return OK; } /** * Initialise the SSL in the post_config hook. */ static int session_crypto_init(apr_pool_t *p, apr_pool_t *plog, apr_pool_t *ptemp, server_rec *s) { const apr_crypto_driver_t *driver = NULL; apr_crypto_t *f = NULL; session_crypto_conf *conf = ap_get_module_config(s->module_config, &session_crypto_module); if (conf->library) { const apu_err_t *err = NULL; apr_status_t rv; rv = apr_crypto_init(p); if (APR_SUCCESS != rv) { ap_log_error(APLOG_MARK, APLOG_ERR, rv, s, APLOGNO(01843) "APR crypto could not be initialised"); return rv; } rv = apr_crypto_get_driver(&driver, conf->library, conf->params, &err, p); if (APR_EREINIT == rv) { ap_log_error(APLOG_MARK, APLOG_WARNING, rv, s, APLOGNO(01844) "warning: crypto for '%s' was already initialised, " "using existing configuration", conf->library); rv = APR_SUCCESS; } if (APR_SUCCESS != rv && err) { ap_log_error(APLOG_MARK, APLOG_ERR, rv, s, APLOGNO(01845) "The crypto library '%s' could not be loaded: %s (%s: %d)", conf->library, err->msg, err->reason, err->rc); return rv; } if (APR_ENOTIMPL == rv) { ap_log_error(APLOG_MARK, APLOG_ERR, rv, s, APLOGNO(01846) "The crypto library '%s' could not be found", conf->library); return rv; } if (APR_SUCCESS != rv || !driver) { ap_log_error(APLOG_MARK, APLOG_ERR, rv, s, APLOGNO(01847) "The crypto library '%s' could not be loaded", conf->library); return rv; } rv = apr_crypto_make(&f, driver, conf->params, p); if (APR_SUCCESS != rv) { ap_log_error(APLOG_MARK, APLOG_ERR, rv, s, APLOGNO(01848) "The crypto library '%s' could not be initialised", conf->library); return rv; } ap_log_error(APLOG_MARK, APLOG_INFO, rv, s, APLOGNO(01849) "The crypto library '%s' was loaded successfully", conf->library); apr_pool_userdata_set((const void *)f, CRYPTO_KEY, apr_pool_cleanup_null, s->process->pconf); } return OK; } static void *create_session_crypto_config(apr_pool_t * p, server_rec *s) { session_crypto_conf *new = (session_crypto_conf *) apr_pcalloc(p, sizeof(session_crypto_conf)); /* if no library has been configured, set the recommended library * as a sensible default. */ #ifdef APU_CRYPTO_RECOMMENDED_DRIVER new->library = APU_CRYPTO_RECOMMENDED_DRIVER; #endif return (void *) new; } static void *create_session_crypto_dir_config(apr_pool_t * p, char *dummy) { session_crypto_dir_conf *new = (session_crypto_dir_conf *) apr_pcalloc(p, sizeof(session_crypto_dir_conf)); new->passphrases = apr_array_make(p, 10, sizeof(char *)); /* default cipher AES256-SHA */ new->cipher = "aes256"; return (void *) new; } static void *merge_session_crypto_dir_config(apr_pool_t * p, void *basev, void *addv) { session_crypto_dir_conf *new = (session_crypto_dir_conf *) apr_pcalloc(p, sizeof(session_crypto_dir_conf)); session_crypto_dir_conf *add = (session_crypto_dir_conf *) addv; session_crypto_dir_conf *base = (session_crypto_dir_conf *) basev; new->passphrases = (add->passphrases_set == 0) ? base->passphrases : add->passphrases; new->passphrases_set = add->passphrases_set || base->passphrases_set; new->cipher = (add->cipher_set == 0) ? base->cipher : add->cipher; new->cipher_set = add->cipher_set || base->cipher_set; return new; } static const char *set_crypto_driver(cmd_parms * cmd, void *config, const char *arg) { session_crypto_conf *conf = (session_crypto_conf *)ap_get_module_config(cmd->server->module_config, &session_crypto_module); const char *err = ap_check_cmd_context(cmd, GLOBAL_ONLY); if (err != NULL) { return err; } conf->library = ap_getword_conf(cmd->pool, &arg); conf->params = arg; conf->library_set = 1; return NULL; } static const char *set_crypto_passphrase(cmd_parms * cmd, void *config, const char *arg) { int arglen = strlen(arg); char **argv; char *result; const char **passphrase; session_crypto_dir_conf *dconf = (session_crypto_dir_conf *) config; passphrase = apr_array_push(dconf->passphrases); if ((arglen > 5) && strncmp(arg, "exec:", 5) == 0) { if (apr_tokenize_to_argv(arg+5, &argv, cmd->temp_pool) != APR_SUCCESS) { return apr_pstrcat(cmd->pool, "Unable to parse exec arguments from ", arg+5, NULL); } argv[0] = ap_server_root_relative(cmd->temp_pool, argv[0]); if (!argv[0]) { return apr_pstrcat(cmd->pool, "Invalid SessionCryptoPassphrase exec location:", arg+5, NULL); } result = ap_get_exec_line(cmd->pool, (const char*)argv[0], (const char * const *)argv); if(!result) { return apr_pstrcat(cmd->pool, "Unable to get bind password from exec of ", arg+5, NULL); } *passphrase = result; } else { *passphrase = arg; } dconf->passphrases_set = 1; return NULL; } static const char *set_crypto_passphrase_file(cmd_parms *cmd, void *config, const char *filename) { char buffer[MAX_STRING_LEN]; char *arg; const char *args; ap_configfile_t *file; apr_status_t rv; filename = ap_server_root_relative(cmd->temp_pool, filename); rv = ap_pcfg_openfile(&file, cmd->temp_pool, filename); if (rv != APR_SUCCESS) { return apr_psprintf(cmd->pool, "%s: Could not open file %s: %pm", cmd->cmd->name, filename, &rv); } while (!(ap_cfg_getline(buffer, sizeof(buffer), file))) { args = buffer; while (*(arg = ap_getword_conf(cmd->pool, &args)) != '\0') { if (*arg == '#') { break; } set_crypto_passphrase(cmd, config, arg); } } ap_cfg_closefile(file); return NULL; } static const char *set_crypto_cipher(cmd_parms * cmd, void *config, const char *cipher) { session_crypto_dir_conf *dconf = (session_crypto_dir_conf *) config; dconf->cipher = cipher; dconf->cipher_set = 1; return NULL; } static const command_rec session_crypto_cmds[] = { AP_INIT_ITERATE("SessionCryptoPassphrase", set_crypto_passphrase, NULL, RSRC_CONF|OR_AUTHCFG, "The passphrase(s) used to encrypt the session. First will be used for encryption, all phrases will be accepted for decryption"), AP_INIT_TAKE1("SessionCryptoPassphraseFile", set_crypto_passphrase_file, NULL, RSRC_CONF|ACCESS_CONF, "File containing passphrase(s) used to encrypt the session, one per line. First will be used for encryption, all phrases will be accepted for decryption"), AP_INIT_TAKE1("SessionCryptoCipher", set_crypto_cipher, NULL, RSRC_CONF|OR_AUTHCFG, "The underlying crypto cipher to use"), AP_INIT_RAW_ARGS("SessionCryptoDriver", set_crypto_driver, NULL, RSRC_CONF, "The underlying crypto library driver to use"), { NULL } }; static void register_hooks(apr_pool_t * p) { ap_hook_session_encode(session_crypto_encode, NULL, NULL, APR_HOOK_LAST); ap_hook_session_decode(session_crypto_decode, NULL, NULL, APR_HOOK_FIRST); ap_hook_post_config(session_crypto_init, NULL, NULL, APR_HOOK_LAST); } AP_DECLARE_MODULE(session_crypto) = { STANDARD20_MODULE_STUFF, create_session_crypto_dir_config, /* dir config creater */ merge_session_crypto_dir_config, /* dir merger --- default is to override */ create_session_crypto_config, /* server config */ NULL, /* merge server config */ session_crypto_cmds, /* command apr_table_t */ register_hooks /* register hooks */ }; #endif