/* rhash.c - implementation of LibRHash library calls * * Copyright: 2008-2012 Aleksey Kravchenko * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY * or FITNESS FOR A PARTICULAR PURPOSE. Use this program at your own risk! */ /* macros for large file support, must be defined before any include file */ #define _LARGEFILE64_SOURCE #define _FILE_OFFSET_BITS 64 #include /* memset() */ #include /* free() */ #include /* ptrdiff_t */ #include #include #include /* modifier for Windows DLL */ #if defined(_WIN32) && defined(RHASH_EXPORTS) # define RHASH_API __declspec(dllexport) #endif #include "byte_order.h" #include "algorithms.h" #include "util.h" #include "hex.h" #include "rhash.h" /* RHash library interface */ #define STATE_ACTIVE 0xb01dbabe #define STATE_STOPED 0xdeadbeef #define STATE_DELETED 0xdecea5ed #define RCTX_AUTO_FINAL 0x1 #define RCTX_FINALIZED 0x2 #define RCTX_FINALIZED_MASK (RCTX_AUTO_FINAL | RCTX_FINALIZED) #define RHPR_FORMAT (RHPR_RAW | RHPR_HEX | RHPR_BASE32 | RHPR_BASE64) #define RHPR_MODIFIER (RHPR_UPPERCASE | RHPR_REVERSE) /** * Initialize static data of rhash algorithms */ void rhash_library_init(void) { rhash_init_algorithms(RHASH_ALL_HASHES); #ifdef USE_OPENSSL rhash_plug_openssl(); #endif } /** * Returns the number of supported hash algorithms. * * @return the number of supported hash functions */ int RHASH_API rhash_count(void) { return rhash_info_size; } /* Lo-level rhash library functions */ /** * Allocate and initialize RHash context for calculating hash(es). * After initializing rhash_update()/rhash_final() functions should be used. * Then the context must be freed by calling rhash_free(). * * @param hash_id union of bit flags, containing ids of hashes to calculate. * @return initialized rhash context, NULL on error and errno is set */ RHASH_API rhash rhash_init(unsigned hash_id) { unsigned tail_bit_index; /* index of hash_id trailing bit */ unsigned num = 0; /* number of hashes to compute */ rhash_context_ext *rctx = NULL; /* allocated rhash context */ size_t hash_size_sum = 0; /* size of hash contexts to store in rctx */ unsigned i, bit_index, id; struct rhash_hash_info* info; size_t aligned_size; char* phash_ctx; hash_id &= RHASH_ALL_HASHES; if (hash_id == 0) { errno = EINVAL; return NULL; } tail_bit_index = rhash_ctz(hash_id); /* get trailing bit index */ assert(tail_bit_index < RHASH_HASH_COUNT); id = 1 << tail_bit_index; if (hash_id == id) { /* handle the most common case of only one hash */ num = 1; info = &rhash_info_table[tail_bit_index]; hash_size_sum = info->context_size; } else { /* another case: hash_id contains several hashes */ for (bit_index = tail_bit_index; id <= hash_id; bit_index++, id = id << 1) { assert(id != 0); assert(bit_index < RHASH_HASH_COUNT); info = &rhash_info_table[bit_index]; if (hash_id & id) { /* align sizes by 8 bytes */ aligned_size = (info->context_size + 7) & ~7; hash_size_sum += aligned_size; num++; } } assert(num > 1); } /* align the size of the rhash context common part */ aligned_size = (offsetof(rhash_context_ext, vector[num]) + 7) & ~7; assert(aligned_size >= sizeof(rhash_context_ext)); /* allocate rhash context with enough memory to store contexts of all used hashes */ rctx = (rhash_context_ext*)malloc(aligned_size + hash_size_sum); if (rctx == NULL) return NULL; /* initialize common fields of the rhash context */ memset(rctx, 0, sizeof(rhash_context_ext)); rctx->rc.hash_id = hash_id; rctx->flags = RCTX_AUTO_FINAL; /* turn on auto-final by default */ rctx->state = STATE_ACTIVE; rctx->hash_vector_size = num; /* aligned hash contexts follows rctx->vector[num] in the same memory block */ phash_ctx = (char*)rctx + aligned_size; assert(phash_ctx >= (char*)&rctx->vector[num]); /* initialize context for every hash in a loop */ for (bit_index = tail_bit_index, id = 1 << tail_bit_index, i = 0; id <= hash_id; bit_index++, id = id << 1) { /* check if a hash function with given id shall be included into rctx */ if ((hash_id & id) != 0) { info = &rhash_info_table[bit_index]; assert(info->context_size > 0); assert(((phash_ctx - (char*)0) & 7) == 0); /* hash context is aligned */ assert(info->init != NULL); rctx->vector[i].hash_info = info; rctx->vector[i].context = phash_ctx; #if 0 /* BTIH initialization is complex, save pointer for later */ if ((id & RHASH_BTIH) != 0) rctx->bt_ctx = phash_ctx; #endif phash_ctx += (info->context_size + 7) & ~7; /* initialize the i-th hash context */ info->init(rctx->vector[i].context); i++; } } return &rctx->rc; /* return allocated and initialized rhash context */ } /** * Free RHash context memory. * * @param ctx the context to free. */ void rhash_free(rhash ctx) { rhash_context_ext* const ectx = (rhash_context_ext*)ctx; unsigned i; if (ctx == 0) return; assert(ectx->hash_vector_size <= RHASH_HASH_COUNT); ectx->state = STATE_DELETED; /* mark memory block as being removed */ /* clean the hash functions, which require additional clean up */ for (i = 0; i < ectx->hash_vector_size; i++) { struct rhash_hash_info* info = ectx->vector[i].hash_info; if (info->cleanup != 0) { info->cleanup(ectx->vector[i].context); } } free(ectx); } /** * Re-initialize RHash context to reuse it. * Useful to speed up processing of many small messages. * * @param ctx context to reinitialize */ RHASH_API void rhash_reset(rhash ctx) { rhash_context_ext* const ectx = (rhash_context_ext*)ctx; unsigned i; assert(ectx->hash_vector_size > 0); assert(ectx->hash_vector_size <= RHASH_HASH_COUNT); ectx->state = STATE_ACTIVE; /* re-activate the structure */ /* re-initialize every hash in a loop */ for (i = 0; i < ectx->hash_vector_size; i++) { struct rhash_hash_info* info = ectx->vector[i].hash_info; if (info->cleanup != 0) { info->cleanup(ectx->vector[i].context); } assert(info->init != NULL); info->init(ectx->vector[i].context); } ectx->flags &= ~RCTX_FINALIZED; /* clear finalized state */ } /** * Calculate hashes of message. * Can be called repeatedly with chunks of the message to be hashed. * * @param ctx the rhash context * @param message message chunk * @param length length of the message chunk * @return 0 on success; On fail return -1 and set errno */ RHASH_API int rhash_update(rhash ctx, const void* message, size_t length) { rhash_context_ext* const ectx = (rhash_context_ext*)ctx; unsigned i; assert(ectx->hash_vector_size <= RHASH_HASH_COUNT); if (ectx->state != STATE_ACTIVE) return 0; /* do nothing if canceled */ ctx->msg_size += length; /* call update method for every algorithm */ for (i = 0; i < ectx->hash_vector_size; i++) { struct rhash_hash_info* info = ectx->vector[i].hash_info; assert(info->update != 0); info->update(ectx->vector[i].context, message, length); } return 0; /* no error processing at the moment */ } /** * Finalize hash calculation and optionally store the first hash. * * @param ctx the rhash context * @param first_result optional buffer to store a calculated hash with the lowest available id * @return 0 on success; On fail return -1 and set errno */ RHASH_API int rhash_final(rhash ctx, unsigned char* first_result) { unsigned i = 0; unsigned char buffer[130]; unsigned char* out = (first_result ? first_result : buffer); rhash_context_ext* const ectx = (rhash_context_ext*)ctx; assert(ectx->hash_vector_size <= RHASH_HASH_COUNT); /* skip final call if already finalized and auto-final is on */ if ((ectx->flags & RCTX_FINALIZED_MASK) == (RCTX_AUTO_FINAL | RCTX_FINALIZED)) return 0; /* call final method for every algorithm */ for (i = 0; i < ectx->hash_vector_size; i++) { struct rhash_hash_info* info = ectx->vector[i].hash_info; assert(info->final != 0); assert(info->info->digest_size < sizeof(buffer)); info->final(ectx->vector[i].context, out); out = buffer; } ectx->flags |= RCTX_FINALIZED; return 0; /* no error processing at the moment */ } /** * Store digest for given hash_id. * If hash_id is zero, function stores digest for a hash with the lowest id found in the context. * For nonzero hash_id the context must contain it, otherwise function silently does nothing. * * @param ctx rhash context * @param hash_id id of hash to retrieve or zero for hash with the lowest available id * @param result buffer to put the hash into */ static void rhash_put_digest(rhash ctx, unsigned hash_id, unsigned char* result) { rhash_context_ext* const ectx = (rhash_context_ext*)ctx; unsigned i; rhash_vector_item *item; struct rhash_hash_info* info; unsigned char* digest; assert(ectx); assert(ectx->hash_vector_size > 0 && ectx->hash_vector_size <= RHASH_HASH_COUNT); /* finalize context if not yet finalized and auto-final is on */ if ((ectx->flags & RCTX_FINALIZED_MASK) == RCTX_AUTO_FINAL) { rhash_final(ctx, NULL); } if (hash_id == 0) { item = &ectx->vector[0]; /* get the first hash */ info = item->hash_info; } else { for (i = 0;; i++) { if (i >= ectx->hash_vector_size) { return; /* hash_id not found, do nothing */ } item = &ectx->vector[i]; info = item->hash_info; if (info->info->hash_id == hash_id) break; } } digest = ((unsigned char*)item->context + info->digest_diff); if (info->info->flags & F_SWAP32) { assert((info->info->digest_size & 3) == 0); /* NB: the next call is correct only for multiple of 4 byte size */ rhash_swap_copy_str_to_u32(result, 0, digest, info->info->digest_size); } else if (info->info->flags & F_SWAP64) { rhash_swap_copy_u64_to_str(result, digest, info->info->digest_size); } else { memcpy(result, digest, info->info->digest_size); } } /** * Set the callback function to be called from the * rhash_file() and rhash_file_update() functions * on processing every file block. The file block * size is set internally by rhash and now is 8 KiB. * * @param ctx rhash context * @param callback pointer to the callback function * @param callback_data pointer to data passed to the callback */ RHASH_API void rhash_set_callback(rhash ctx, rhash_callback_t callback, void* callback_data) { ((rhash_context_ext*)ctx)->callback = callback; ((rhash_context_ext*)ctx)->callback_data = callback_data; } /* hi-level message hashing interface */ /** * Compute a hash of the given message. * * @param hash_id id of hash sum to compute * @param message the message to process * @param length message length * @param result buffer to receive binary hash string * @return 0 on success, -1 on error */ RHASH_API int rhash_msg(unsigned hash_id, const void* message, size_t length, unsigned char* result) { rhash ctx; hash_id &= RHASH_ALL_HASHES; ctx = rhash_init(hash_id); if (ctx == NULL) return -1; rhash_update(ctx, message, length); rhash_final(ctx, result); rhash_free(ctx); return 0; } /** * Hash a file or stream. Multiple hashes can be computed. * First, inintialize ctx parameter with rhash_init() before calling * rhash_file_update(). Then use rhash_final() and rhash_print() * to retrive hash values. Finaly call rhash_free() on ctx * to free allocated memory or call rhash_reset() to reuse ctx. * * @param ctx rhash context * @param fd descriptor of the file to hash * @return 0 on success, -1 on error and errno is set */ RHASH_API int rhash_file_update(rhash ctx, FILE* fd) { rhash_context_ext* const ectx = (rhash_context_ext*)ctx; const size_t block_size = 8192; unsigned char *buffer, *pmem; size_t length = 0, align8; int res = 0; if (ectx->state != STATE_ACTIVE) return 0; /* do nothing if canceled */ if (ctx == NULL) { errno = EINVAL; return -1; } pmem = (unsigned char*)malloc(block_size + 8); if (!pmem) return -1; /* errno is set to ENOMEM according to UNIX 98 */ align8 = ((unsigned char*)0 - pmem) & 7; buffer = pmem + align8; while (!feof(fd)) { /* stop if canceled */ if (ectx->state != STATE_ACTIVE) break; length = fread(buffer, 1, block_size, fd); if (ferror(fd)) { res = -1; /* note: errno contains error code */ break; } else if (length) { rhash_update(ctx, buffer, length); if (ectx->callback) { ((rhash_callback_t)ectx->callback)(ectx->callback_data, ectx->rc.msg_size); } } } free(buffer); return res; } /** * Compute a single hash for given file. * * @param hash_id id of hash sum to compute * @param filepath path to the file to hash * @param result buffer to receive hash value with the lowest requested id * @return 0 on success, -1 on error and errno is set */ RHASH_API int rhash_file(unsigned hash_id, const char* filepath, unsigned char* result) { FILE* fd; rhash ctx; int res; hash_id &= RHASH_ALL_HASHES; if (hash_id == 0) { errno = EINVAL; return -1; } if ((fd = fopen(filepath, "rb")) == NULL) return -1; if ((ctx = rhash_init(hash_id)) == NULL) return -1; res = rhash_file_update(ctx, fd); /* hash the file */ fclose(fd); rhash_final(ctx, result); rhash_free(ctx); return res; } #ifdef _WIN32 /* windows only function */ #include /** * Compute a single hash for given file. * * @param hash_id id of hash sum to compute * @param filepath path to the file to hash * @param result buffer to receive hash value with the lowest requested id * @return 0 on success, -1 on error, -1 on error and errno is set */ RHASH_API int rhash_wfile(unsigned hash_id, const wchar_t* filepath, unsigned char* result) { FILE* fd; rhash ctx; int res; hash_id &= RHASH_ALL_HASHES; if (hash_id == 0) { errno = EINVAL; return -1; } if ((fd = _wfsopen(filepath, L"rb", _SH_DENYWR)) == NULL) return -1; if ((ctx = rhash_init(hash_id)) == NULL) return -1; res = rhash_file_update(ctx, fd); /* hash the file */ fclose(fd); rhash_final(ctx, result); rhash_free(ctx); return res; } #endif /* RHash information functions */ /** * Returns information about a hash function by its hash_id. * * @param hash_id the id of hash algorithm * @return pointer to the rhash_info structure containing the information */ const rhash_info* rhash_info_by_id(unsigned hash_id) { hash_id &= RHASH_ALL_HASHES; /* check that only one bit is set */ if (hash_id != (hash_id & -(int)hash_id)) return NULL; /* note: alternative condition is (hash_id == 0 || (hash_id & (hash_id - 1)) != 0) */ return rhash_info_table[rhash_ctz(hash_id)].info; } #if 0 /** * Detect default digest output format for given hash algorithm. * * @param hash_id the id of hash algorithm * @return 1 for base32 format, 0 for hexadecimal */ RHASH_API int rhash_is_base32(unsigned hash_id) { /* fast method is just to test a bit-mask */ return ((hash_id & (RHASH_TTH | RHASH_AICH)) != 0); } #endif /** * Returns size of binary digest for given hash algorithm. * * @param hash_id the id of hash algorithm * @return digest size in bytes */ RHASH_API int rhash_get_digest_size(unsigned hash_id) { hash_id &= RHASH_ALL_HASHES; if (hash_id == 0 || (hash_id & (hash_id - 1)) != 0) return -1; return (int)rhash_info_table[rhash_ctz(hash_id)].info->digest_size; } /** * Returns length of digest hash string in default output format. * * @param hash_id the id of hash algorithm * @return the length of hash string */ RHASH_API int rhash_get_hash_length(unsigned hash_id) { const rhash_info* info = rhash_info_by_id(hash_id); return (int)(info ? (info->flags & F_BS32 ? BASE32_LENGTH(info->digest_size) : info->digest_size * 2) : 0); } /** * Returns a name of given hash algorithm. * * @param hash_id the id of hash algorithm * @return algorithm name */ RHASH_API const char* rhash_get_name(unsigned hash_id) { const rhash_info* info = rhash_info_by_id(hash_id); return (info ? info->name : 0); } /** * Returns a name part of magnet urn of the given hash algorithm. * Such magnet_name is used to generate a magnet link of the form * urn:<magnet_name>=<hash_value>. * * @param hash_id the id of hash algorithm * @return name */ RHASH_API const char* rhash_get_magnet_name(unsigned hash_id) { const rhash_info* info = rhash_info_by_id(hash_id); return (info ? info->magnet_name : 0); } #if 0 static size_t rhash_get_magnet_url_size(const char* filepath, rhash context, unsigned hash_mask, int flags) { size_t size = 0; /* count terminating '\0' */ unsigned bit, hash = context->hash_id & hash_mask; /* RHPR_NO_MAGNET, RHPR_FILESIZE */ if ((flags & RHPR_NO_MAGNET) == 0) { size += 8; } if ((flags & RHPR_FILESIZE) != 0) { uint64_t num = context->msg_size; size += 4; if (num == 0) size++; else { for (; num; num /= 10, size++); } } if (filepath) { size += 4 + rhash_urlencode(NULL, filepath); } /* loop through hash values */ for (bit = hash & -(int)hash; bit <= hash; bit <<= 1) { const char* name; if ((bit & hash) == 0) continue; if ((name = rhash_get_magnet_name(bit)) == 0) continue; size += (7 + 2) + strlen(name); size += rhash_print(NULL, context, bit, (bit & (RHASH_SHA1 | RHASH_BTIH) ? RHPR_BASE32 : 0)); } return size; } /** * Print magnet link with given filepath and calculated hash sums into the * output buffer. The hash_mask can limit which hash values will be printed. * The function returns the size of the required buffer. * If output is NULL the . * * @param output a string buffer to receive the magnet link or NULL * @param filepath the file path to be printed or NULL * @param context algorithms state * @param hash_mask bit mask of the hash sums to add to the link * @param flags can be combination of bits RHPR_UPPERCASE, RHPR_NO_MAGNET, * RHPR_FILESIZE * @return number of written characters, including terminating '\0' on success, 0 on fail */ RHASH_API size_t rhash_print_magnet(char* output, const char* filepath, rhash context, unsigned hash_mask, int flags) { int i; const char* begin = output; if (output == NULL) return rhash_get_magnet_url_size( filepath, context, hash_mask, flags); /* RHPR_NO_MAGNET, RHPR_FILESIZE */ if ((flags & RHPR_NO_MAGNET) == 0) { strcpy(output, "magnet:?"); output += 8; } if ((flags & RHPR_FILESIZE) != 0) { strcpy(output, "xl="); output += 3; output += rhash_sprintI64(output, context->msg_size); *(output++) = '&'; } if (filepath) { strcpy(output, "dn="); output += 3; output += rhash_urlencode(output, filepath); *(output++) = '&'; } flags &= RHPR_UPPERCASE; for (i = 0; i < 2; i++) { unsigned bit; unsigned hash = context->hash_id & hash_mask; hash = (i == 0 ? hash & (RHASH_ED2K | RHASH_AICH) : hash & ~(RHASH_ED2K | RHASH_AICH)); if (!hash) continue; /* loop through hash values */ for (bit = hash & -(int)hash; bit <= hash; bit <<= 1) { const char* name; if ((bit & hash) == 0) continue; if (!(name = rhash_get_magnet_name(bit))) continue; strcpy(output, "xt=urn:"); output += 7; strcpy(output, name); output += strlen(name); *(output++) = ':'; output += rhash_print(output, context, bit, (bit & (RHASH_SHA1 | RHASH_BTIH) ? flags | RHPR_BASE32 : flags)); *(output++) = '&'; } } output[-1] = '\0'; /* terminate the line */ return (output - begin); } /* hash sum output */ /** * Print a text presentation of a given hash sum to the specified buffer, * * @param output a buffer to print the hash to * @param bytes a hash sum to print * @param size a size of hash sum in bytes * @param flags a bit-mask controlling how to format the hash sum, * can be a mix of the flags: RHPR_RAW, RHPR_HEX, RHPR_BASE32, * RHPR_BASE64, RHPR_UPPERCASE, RHPR_REVERSE * @return the number of written characters */ size_t rhash_print_bytes(char* output, const unsigned char* bytes, size_t size, int flags) { size_t str_len; int upper_case = (flags & RHPR_UPPERCASE); int format = (flags & ~RHPR_MODIFIER); switch (format) { case RHPR_HEX: str_len = size * 2; rhash_byte_to_hex(output, bytes, (unsigned)size, upper_case); break; case RHPR_BASE32: str_len = BASE32_LENGTH(size); rhash_byte_to_base32(output, bytes, (unsigned)size, upper_case); break; case RHPR_BASE64: str_len = BASE64_LENGTH(size); rhash_byte_to_base64(output, bytes, (unsigned)size); break; default: str_len = size; memcpy(output, bytes, size); break; } return str_len; } /** * Print text presentation of a hash sum with given hash_id to the specified * output buffer. If the hash_id is zero, then print the hash sum with * the lowest id stored in the hash context. * The function call fails if the context doesn't include a hash with the * given hash_id. * * @param output a buffer to print the hash to * @param context algorithms state * @param hash_id id of the hash sum to print or 0 to print the first hash * saved in the context. * @param flags a bitmask controlling how to print the hash. Can contain flags * RHPR_UPPERCASE, RHPR_HEX, RHPR_BASE32, RHPR_BASE64, etc. * @return the number of written characters on success or 0 on fail */ size_t RHASH_API rhash_print(char* output, rhash context, unsigned hash_id, int flags) { const rhash_info* info; unsigned char digest[80]; size_t digest_size; info = (hash_id != 0 ? rhash_info_by_id(hash_id) : ((rhash_context_ext*)context)->vector[0].hash_info->info); if (info == NULL) return 0; digest_size = info->digest_size; assert(digest_size <= 64); flags &= (RHPR_FORMAT | RHPR_MODIFIER); if ((flags & RHPR_FORMAT) == 0) { /* use default format if not specified by flags */ flags |= (info->flags & RHASH_INFO_BASE32 ? RHPR_BASE32 : RHPR_HEX); } if (output == NULL) { switch (flags & RHPR_FORMAT) { case RHPR_HEX: return (digest_size * 2); case RHPR_BASE32: return BASE32_LENGTH(digest_size); case RHPR_BASE64: return BASE64_LENGTH(digest_size); default: return digest_size; } } /* note: use info->hash_id, cause hash_id can be 0 */ rhash_put_digest(context, info->hash_id, digest); if ((flags & ~RHPR_UPPERCASE) == (RHPR_REVERSE | RHPR_HEX)) { /* reverse the digest */ unsigned char *p = digest, *r = digest + digest_size - 1; char tmp; for (; p < r; p++, r--) { tmp = *p; *p = *r; *r = tmp; } } return rhash_print_bytes(output, digest, digest_size, flags); } #if defined(_WIN32) && defined(RHASH_EXPORTS) #include BOOL APIENTRY DllMain(HMODULE hModule, DWORD reason, LPVOID reserved); BOOL APIENTRY DllMain(HMODULE hModule, DWORD reason, LPVOID reserved) { (void)hModule; (void)reserved; switch (reason) { case DLL_PROCESS_ATTACH: rhash_library_init(); break; case DLL_PROCESS_DETACH: /*rhash_library_free();*/ case DLL_THREAD_ATTACH: case DLL_THREAD_DETACH: break; } return TRUE; } #endif #define PVOID2UPTR(p) ((rhash_uptr_t)((char*)p - 0)) /** * Process a rhash message. * * @param msg_id message identifier * @param dst message destination (can be NULL for generic messages) * @param ldata data depending on message * @param rdata data depending on message * @return message-specific data */ RHASH_API rhash_uptr_t rhash_transmit(unsigned msg_id, void* dst, rhash_uptr_t ldata, rhash_uptr_t rdata) { /* for messages working with rhash context */ rhash_context_ext* const ctx = (rhash_context_ext*)dst; switch (msg_id) { case RMSG_GET_CONTEXT: { unsigned i; for (i = 0; i < ctx->hash_vector_size; i++) { struct rhash_hash_info* info = ctx->vector[i].hash_info; if (info->info->hash_id == (unsigned)ldata) return PVOID2UPTR(ctx->vector[i].context); } return (rhash_uptr_t)0; } case RMSG_CANCEL: /* mark rhash context as canceled, in a multithreaded program */ atomic_compare_and_swap(&ctx->state, STATE_ACTIVE, STATE_STOPED); return 0; case RMSG_IS_CANCELED: return (ctx->state == STATE_STOPED); case RMSG_GET_FINALIZED: return ((ctx->flags & RCTX_FINALIZED) != 0); case RMSG_SET_AUTOFINAL: ctx->flags &= ~RCTX_AUTO_FINAL; if (ldata) ctx->flags |= RCTX_AUTO_FINAL; break; /* OpenSSL related messages */ #ifdef USE_OPENSSL case RMSG_SET_OPENSSL_MASK: rhash_openssl_hash_mask = (unsigned)ldata; break; case RMSG_GET_OPENSSL_MASK: return rhash_openssl_hash_mask; #endif default: return RHASH_ERROR; /* unknown message */ } return 0; } #endif