/* * Copyright (c) 2007-2014, Cameron Rich * * 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 the axTLS project 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. */ /** * Load certificates/keys into memory. These can be in many different formats. * PEM support and other formats can be processed here. * * The PEM private keys may be optionally encrypted with AES128 or AES256. * The encrypted PEM keys were generated with something like: * * openssl genrsa -aes128 -passout pass:abcd -out axTLS.key_aes128.pem 512 */ #include #include #include #include "os_port.h" #include "ssl.h" static int do_obj(SSL_CTX *ssl_ctx, int obj_type, SSLObjLoader *ssl_obj, const char *password); #ifdef CONFIG_SSL_HAS_PEM static int ssl_obj_PEM_load(SSL_CTX *ssl_ctx, int obj_type, SSLObjLoader *ssl_obj, const char *password); #endif /* * Load a file into memory that is in binary DER (or ascii PEM) format. */ EXP_FUNC int STDCALL ssl_obj_load(SSL_CTX *ssl_ctx, int obj_type, const char *filename, const char *password) { #ifndef CONFIG_SSL_SKELETON_MODE static const char * const begin = "-----BEGIN"; int ret = SSL_OK; SSLObjLoader *ssl_obj = NULL; if (filename == NULL) { ret = SSL_ERROR_INVALID_KEY; goto error; } ssl_obj = (SSLObjLoader *)calloc(1, sizeof(SSLObjLoader)); ssl_obj->len = get_file(filename, &ssl_obj->buf); if (ssl_obj->len <= 0) { ret = SSL_ERROR_INVALID_KEY; goto error; } /* is the file a PEM file? */ if (strstr((char *)ssl_obj->buf, begin) != NULL) { #ifdef CONFIG_SSL_HAS_PEM ret = ssl_obj_PEM_load(ssl_ctx, obj_type, ssl_obj, password); #else #ifdef CONFIG_SSL_FULL_MODE printf("%s", unsupported_str); #endif ret = SSL_ERROR_NOT_SUPPORTED; #endif } else ret = do_obj(ssl_ctx, obj_type, ssl_obj, password); error: ssl_obj_free(ssl_obj); return ret; #else #ifdef CONFIG_SSL_FULL_MODE printf("%s", unsupported_str); #endif return SSL_ERROR_NOT_SUPPORTED; #endif /* CONFIG_SSL_SKELETON_MODE */ } /* * Transfer binary data into the object loader. */ EXP_FUNC int STDCALL ssl_obj_memory_load(SSL_CTX *ssl_ctx, int mem_type, const uint8_t *data, int len, const char *password) { int ret; SSLObjLoader *ssl_obj; ssl_obj = (SSLObjLoader *)calloc(1, sizeof(SSLObjLoader)); ssl_obj->buf = (uint8_t *)malloc(len); memcpy(ssl_obj->buf, data, len); ssl_obj->len = len; ret = do_obj(ssl_ctx, mem_type, ssl_obj, password); ssl_obj_free(ssl_obj); return ret; } /* * Actually work out what we are doing */ static int do_obj(SSL_CTX *ssl_ctx, int obj_type, SSLObjLoader *ssl_obj, const char *password) { int ret = SSL_OK; switch (obj_type) { case SSL_OBJ_RSA_KEY: ret = add_private_key(ssl_ctx, ssl_obj); break; case SSL_OBJ_X509_CERT: ret = add_cert(ssl_ctx, ssl_obj->buf, ssl_obj->len); break; #ifdef CONFIG_SSL_CERT_VERIFICATION case SSL_OBJ_X509_CACERT: add_cert_auth(ssl_ctx, ssl_obj->buf, ssl_obj->len); break; #endif #ifdef CONFIG_SSL_USE_PKCS12 case SSL_OBJ_PKCS8: ret = pkcs8_decode(ssl_ctx, ssl_obj, password); break; case SSL_OBJ_PKCS12: ret = pkcs12_decode(ssl_ctx, ssl_obj, password); break; #endif default: #ifdef CONFIG_SSL_FULL_MODE printf("%s", unsupported_str); #endif ret = SSL_ERROR_NOT_SUPPORTED; break; } return ret; } /* * Clean up our mess. */ void ssl_obj_free(SSLObjLoader *ssl_obj) { if (ssl_obj) { free(ssl_obj->buf); free(ssl_obj); } } /* * Support for PEM encoded keys/certificates. */ #ifdef CONFIG_SSL_HAS_PEM #define NUM_PEM_TYPES 4 #define IV_SIZE 16 #define IS_RSA_PRIVATE_KEY 0 #define IS_ENCRYPTED_PRIVATE_KEY 1 #define IS_PRIVATE_KEY 2 #define IS_CERTIFICATE 3 static const char * const begins[NUM_PEM_TYPES] = { "-----BEGIN RSA PRIVATE KEY-----", "-----BEGIN ENCRYPTED PRIVATE KEY-----", "-----BEGIN PRIVATE KEY-----", "-----BEGIN CERTIFICATE-----", }; static const char * const ends[NUM_PEM_TYPES] = { "-----END RSA PRIVATE KEY-----", "-----END ENCRYPTED PRIVATE KEY-----", "-----END PRIVATE KEY-----", "-----END CERTIFICATE-----", }; static const char * const aes_str[2] = { "DEK-Info: AES-128-CBC,", "DEK-Info: AES-256-CBC," }; /** * Take a base64 blob of data and decrypt it (using AES) into its * proper ASN.1 form. */ static int pem_decrypt(const char *where, const char *end, const char *password, SSLObjLoader *ssl_obj) { int ret = -1; int is_aes_256 = 0; char *start = NULL; uint8_t iv[IV_SIZE]; int i, pem_size; MD5_CTX md5_ctx; AES_CTX aes_ctx; uint8_t key[32]; /* AES256 size */ if (password == NULL || strlen(password) == 0) { #ifdef CONFIG_SSL_FULL_MODE printf("Error: Need a password for this PEM file\n"); #endif goto error; } if ((start = strstr((const char *)where, aes_str[0]))) /* AES128? */ { start += strlen(aes_str[0]); } else if ((start = strstr((const char *)where, aes_str[1]))) /* AES256? */ { is_aes_256 = 1; start += strlen(aes_str[1]); } else { #ifdef CONFIG_SSL_FULL_MODE printf("Error: Unsupported password cipher\n"); #endif goto error; } /* convert from hex to binary - assumes uppercase hex */ for (i = 0; i < IV_SIZE; i++) { char c = *start++ - '0'; iv[i] = (c > 9 ? c + '0' - 'A' + 10 : c) << 4; c = *start++ - '0'; iv[i] += (c > 9 ? c + '0' - 'A' + 10 : c); } while (*start == '\r' || *start == '\n') start++; /* turn base64 into binary */ pem_size = (int)(end-start); if (base64_decode(start, pem_size, ssl_obj->buf, &ssl_obj->len) != 0) goto error; /* work out the key */ MD5_Init(&md5_ctx); MD5_Update(&md5_ctx, (const uint8_t *)password, strlen(password)); MD5_Update(&md5_ctx, iv, SALT_SIZE); MD5_Final(key, &md5_ctx); if (is_aes_256) { MD5_Init(&md5_ctx); MD5_Update(&md5_ctx, key, MD5_SIZE); MD5_Update(&md5_ctx, (const uint8_t *)password, strlen(password)); MD5_Update(&md5_ctx, iv, SALT_SIZE); MD5_Final(&key[MD5_SIZE], &md5_ctx); } /* decrypt using the key/iv */ AES_set_key(&aes_ctx, key, iv, is_aes_256 ? AES_MODE_256 : AES_MODE_128); AES_convert_key(&aes_ctx); AES_cbc_decrypt(&aes_ctx, ssl_obj->buf, ssl_obj->buf, ssl_obj->len); ret = 0; error: return ret; } /** * Take a base64 blob of data and turn it into its proper ASN.1 form. */ static int new_pem_obj(SSL_CTX *ssl_ctx, int is_cacert, char *where, int remain, const char *password) { int ret = SSL_ERROR_BAD_CERTIFICATE; SSLObjLoader *ssl_obj = NULL; while (remain > 0) { int i, pem_size, obj_type; char *start = NULL, *end = NULL; for (i = 0; i < NUM_PEM_TYPES; i++) { if ((start = strstr(where, begins[i])) && (end = strstr(where, ends[i]))) { remain -= (int)(end-where); start += strlen(begins[i]); pem_size = (int)(end-start); ssl_obj = (SSLObjLoader *)calloc(1, sizeof(SSLObjLoader)); /* 4/3 bigger than what we need but so what */ ssl_obj->buf = (uint8_t *)calloc(1, pem_size); ssl_obj->len = pem_size; if (i == IS_RSA_PRIVATE_KEY && strstr(start, "Proc-Type:") && strstr(start, "4,ENCRYPTED")) { /* check for encrypted PEM file */ if (pem_decrypt(start, end, password, ssl_obj) < 0) { ret = SSL_ERROR_BAD_CERTIFICATE; goto error; } } else { ssl_obj->len = pem_size; if (base64_decode(start, pem_size, ssl_obj->buf, &ssl_obj->len) != 0) { ret = SSL_ERROR_BAD_CERTIFICATE; goto error; } } switch (i) { case IS_RSA_PRIVATE_KEY: obj_type = SSL_OBJ_RSA_KEY; break; case IS_ENCRYPTED_PRIVATE_KEY: case IS_PRIVATE_KEY: obj_type = SSL_OBJ_PKCS8; break; case IS_CERTIFICATE: obj_type = is_cacert ? SSL_OBJ_X509_CACERT : SSL_OBJ_X509_CERT; break; default: ret = SSL_ERROR_BAD_CERTIFICATE; goto error; } /* In a format we can now understand - so process it */ if ((ret = do_obj(ssl_ctx, obj_type, ssl_obj, password))) goto error; end += strlen(ends[i]); remain -= strlen(ends[i]); while (remain > 0 && (*end == '\r' || *end == '\n')) { end++; remain--; } where = end; break; } } ssl_obj_free(ssl_obj); ssl_obj = NULL; if (start == NULL) break; } error: ssl_obj_free(ssl_obj); return ret; } /* * Load a file into memory that is in ASCII PEM format. */ static int ssl_obj_PEM_load(SSL_CTX *ssl_ctx, int obj_type, SSLObjLoader *ssl_obj, const char *password) { char *start; /* add a null terminator */ ssl_obj->len++; ssl_obj->buf = (uint8_t *)realloc(ssl_obj->buf, ssl_obj->len); ssl_obj->buf[ssl_obj->len-1] = 0; start = (char *)ssl_obj->buf; return new_pem_obj(ssl_ctx, obj_type == SSL_OBJ_X509_CACERT, start, ssl_obj->len, password); } #endif /* CONFIG_SSL_HAS_PEM */ /** * Load the key/certificates in memory depending on compile-time and user * options. */ int load_key_certs(SSL_CTX *ssl_ctx) { int ret = SSL_OK; uint32_t options = ssl_ctx->options; #ifdef CONFIG_SSL_GENERATE_X509_CERT uint8_t *cert_data = NULL; int cert_size; static const char *dn[] = { CONFIG_SSL_X509_COMMON_NAME, CONFIG_SSL_X509_ORGANIZATION_NAME, CONFIG_SSL_X509_ORGANIZATION_UNIT_NAME }; #endif /* do the private key first */ if (strlen(CONFIG_SSL_PRIVATE_KEY_LOCATION) > 0) { if ((ret = ssl_obj_load(ssl_ctx, SSL_OBJ_RSA_KEY, CONFIG_SSL_PRIVATE_KEY_LOCATION, CONFIG_SSL_PRIVATE_KEY_PASSWORD)) < 0) goto error; } else if (!(options & SSL_NO_DEFAULT_KEY)) { #if defined(CONFIG_SSL_USE_DEFAULT_KEY) || defined(CONFIG_SSL_SKELETON_MODE) static const /* saves a few more bytes */ #include "private_key.h" ssl_obj_memory_load(ssl_ctx, SSL_OBJ_RSA_KEY, default_private_key, default_private_key_len, NULL); #endif } /* now load the certificate */ #ifdef CONFIG_SSL_GENERATE_X509_CERT if ((cert_size = ssl_x509_create(ssl_ctx, 0, dn, &cert_data)) < 0) { ret = cert_size; goto error; } ssl_obj_memory_load(ssl_ctx, SSL_OBJ_X509_CERT, cert_data, cert_size, NULL); free(cert_data); #else if (strlen(CONFIG_SSL_X509_CERT_LOCATION)) { if ((ret = ssl_obj_load(ssl_ctx, SSL_OBJ_X509_CERT, CONFIG_SSL_X509_CERT_LOCATION, NULL)) < 0) goto error; } else if (!(options & SSL_NO_DEFAULT_KEY)) { #if defined(CONFIG_SSL_USE_DEFAULT_KEY) || defined(CONFIG_SSL_SKELETON_MODE) static const /* saves a few bytes and RAM */ #include "cert.h" ssl_obj_memory_load(ssl_ctx, SSL_OBJ_X509_CERT, default_certificate, default_certificate_len, NULL); #endif } #endif error: #ifdef CONFIG_SSL_FULL_MODE if (ret) { printf("Error: Certificate or key not loaded\n"); } #endif return ret; }