/** * @file parser.c * * @brief Implementation of parser_t. * */ /* * Copyright (C) 2005-2006 Martin Willi * Copyright (C) 2005 Jan Hutter * Hochschule fuer Technik Rapperswil * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation; either version 2 of the License, or (at your * option) any later version. See . * * 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. See the GNU General Public License * for more details. */ #include #include #include #include "parser.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include typedef struct private_parser_t private_parser_t; /** * Private data stored in a context. * * Contains pointers and counters to store current state. */ struct private_parser_t { /** * Public members, see parser_t. */ parser_t public; /** * @brief Parse a 4-Bit unsigned integer from the current parsing position. * * @param this parser_t object * @param rule_number number of current rule * @param[out] output_pos pointer where to write the parsed result * @return * - SUCCESS or * - PARSE_ERROR when not successful */ status_t (*parse_uint4) (private_parser_t *this, int rule_number, u_int8_t *output_pos); /** * @brief Parse a 8-Bit unsigned integer from the current parsing position. * * @param this parser_t object * @param rule_number number of current rule * @param[out] output_pos pointer where to write the parsed result * @return * - SUCCESS or * - PARSE_ERROR when not successful */ status_t (*parse_uint8) (private_parser_t *this, int rule_number, u_int8_t *output_pos); /** * @brief Parse a 15-Bit unsigned integer from the current parsing position. * * This is a special case used for ATTRIBUTE_TYPE. * Big-/Little-endian conversion is done here. * * @param this parser_t object * @param rule_number number of current rule * @param[out] output_pos pointer where to write the parsed result * @return * - SUCCESS or * - PARSE_ERROR when not successful */ status_t (*parse_uint15) (private_parser_t *this, int rule_number, u_int16_t *output_pos); /** * @brief Parse a 16-Bit unsigned integer from the current parsing position. * * Big-/Little-endian conversion is done here. * * @param this parser_t object * @param rule_number number of current rule * @param[out] output_pos pointer where to write the parsed result * @return * - SUCCESS or * - PARSE_ERROR when not successful */ status_t (*parse_uint16) (private_parser_t *this, int rule_number, u_int16_t *output_pos); /** * @brief Parse a 32-Bit unsigned integer from the current parsing position. * * Big-/Little-endian conversion is done here. * * @param this parser_t object * @param rule_number number of current rule * @param[out] output_pos pointer where to write the parsed result * @return * - SUCCESS or * - PARSE_ERROR when not successful */ status_t (*parse_uint32) (private_parser_t *this, int rule_number, u_int32_t *output_pos); /** * @brief Parse a 64-Bit unsigned integer from the current parsing position. * * @todo add support for big-endian machines. * * @param this parser_t object * @param rule_number number of current rule * @param[out] output_pos pointer where to write the parsed result * @return * - SUCCESS or * - PARSE_ERROR when not successful */ status_t (*parse_uint64) (private_parser_t *this, int rule_number, u_int64_t *output_pos); /** * @brief Parse a given amount of bytes and writes them to a specific location * * @param this parser_t object * @param rule_number number of current rule * @param[out] output_pos pointer where to write the parsed result * @param bytes number of bytes to parse * @return * - SUCCESS or * - PARSE_ERROR when not successful */ status_t (*parse_bytes) (private_parser_t *this, int rule_number, u_int8_t *output_pos,size_t bytes); /** * @brief Parse a single Bit from the current parsing position * * @param this parser_t object * @param rule_number number of current rule * @param[out] output_pos pointer where to write the parsed result * @return * - SUCCESS or * - PARSE_ERROR when not successful */ status_t (*parse_bit) (private_parser_t *this, int rule_number, bool *output_pos); /** * @brief Parse substructures in a list * * This function calls the parser recursively to parse contained substructures * in a linked_list_t. The list must already be created. Payload defines * the type of the substructures. parsing is continued until the specified length * is completely parsed. * * @param this parser_t object * @param rule_number number of current rule * @param[out] output_pos pointer of a linked_list where substructures are added * @param payload_type type of the contained substructures to parse * @param length number of bytes to parse in this list * @return * - SUCCESS or * - PARSE_ERROR when not successful */ status_t (*parse_list) (private_parser_t *this, int rule_number, linked_list_t **output_pos, payload_type_t payload_ype, size_t length); /** * @brief Parse data from current parsing position in a chunk. * * This function clones length number of bytes to output_pos, without * modifiyng them. Space will be allocated and must be freed by caller. * * @param this parser_t object * @param rule_number number of current rule * @param[out] output_pos pointer of a chunk which will point to the allocated data * @param length number of bytes to clone * @return * - SUCCESS or * - PARSE_ERROR when not successful */ status_t (*parse_chunk) (private_parser_t *this, int rule_number, chunk_t *output_pos, size_t length); /** * Current bit for reading in input data. */ u_int8_t bit_pos; /** * Current byte for reading in input data. */ u_int8_t *byte_pos; /** * Input data to parse. */ u_int8_t *input; /** * Roof of input, used for length-checking. */ u_int8_t *input_roof; /** * Set of encoding rules for this parsing session. */ encoding_rule_t *rules; }; /** * Implementation of private_parser_t.parse_uint4. */ static status_t parse_uint4(private_parser_t *this, int rule_number, u_int8_t *output_pos) { if (this->byte_pos + sizeof(u_int8_t) > this->input_roof) { DBG1(SIG_DBG_ENC, " not enough input to parse rule %d %N", rule_number, encoding_type_names, this->rules[rule_number].type); return PARSE_ERROR; } switch (this->bit_pos) { case 0: /* caller interested in result ? */ if (output_pos != NULL) { *output_pos = *(this->byte_pos) >> 4; } this->bit_pos = 4; break; case 4: /* caller interested in result ? */ if (output_pos != NULL) { *output_pos = *(this->byte_pos) & 0x0F; } this->bit_pos = 0; this->byte_pos++; break; default: DBG2(SIG_DBG_ENC, " found rule %d %N on bitpos %d", rule_number, encoding_type_names, this->rules[rule_number].type, this->bit_pos); return PARSE_ERROR; } if (output_pos != NULL) { DBG3(SIG_DBG_ENC, " => %d", *output_pos); } return SUCCESS; } /** * Implementation of private_parser_t.parse_uint8. */ static status_t parse_uint8(private_parser_t *this, int rule_number, u_int8_t *output_pos) { if (this->byte_pos + sizeof(u_int8_t) > this->input_roof) { DBG1(SIG_DBG_ENC, " not enough input to parse rule %d %N", rule_number, encoding_type_names, this->rules[rule_number].type); return PARSE_ERROR; } if (this->bit_pos) { DBG1(SIG_DBG_ENC, " found rule %d %N on bitpos %d", rule_number, encoding_type_names, this->rules[rule_number].type, this->bit_pos); return PARSE_ERROR; } /* caller interested in result ? */ if (output_pos != NULL) { *output_pos = *(this->byte_pos); DBG3(SIG_DBG_ENC, " => %d", *output_pos); } this->byte_pos++; return SUCCESS; } /** * Implementation of private_parser_t.parse_uint15. */ static status_t parse_uint15(private_parser_t *this, int rule_number, u_int16_t *output_pos) { if (this->byte_pos + sizeof(u_int16_t) > this->input_roof) { DBG1(SIG_DBG_ENC, " not enough input to parse rule %d %N", rule_number, encoding_type_names, this->rules[rule_number].type); return PARSE_ERROR; } if (this->bit_pos != 1) { DBG2(SIG_DBG_ENC, " found rule %d %N on bitpos %d", rule_number, encoding_type_names, this->rules[rule_number].type, this->bit_pos); return PARSE_ERROR; } /* caller interested in result ? */ if (output_pos != NULL) { *output_pos = ntohs(*((u_int16_t*)this->byte_pos)) & ~0x8000; DBG3(SIG_DBG_ENC, " => %d", *output_pos); } this->byte_pos += 2; this->bit_pos = 0; return SUCCESS; } /** * Implementation of private_parser_t.parse_uint16. */ static status_t parse_uint16(private_parser_t *this, int rule_number, u_int16_t *output_pos) { if (this->byte_pos + sizeof(u_int16_t) > this->input_roof) { DBG1(SIG_DBG_ENC, " not enough input to parse rule %d %N", rule_number, encoding_type_names, this->rules[rule_number].type); return PARSE_ERROR; } if (this->bit_pos) { DBG1(SIG_DBG_ENC, " found rule %d %N on bitpos %d", rule_number, encoding_type_names, this->rules[rule_number].type, this->bit_pos); return PARSE_ERROR; } /* caller interested in result ? */ if (output_pos != NULL) { *output_pos = ntohs(*((u_int16_t*)this->byte_pos)); DBG3(SIG_DBG_ENC, " => %d", *output_pos); } this->byte_pos += 2; return SUCCESS; } /** * Implementation of private_parser_t.parse_uint32. */ static status_t parse_uint32(private_parser_t *this, int rule_number, u_int32_t *output_pos) { if (this->byte_pos + sizeof(u_int32_t) > this->input_roof) { DBG1(SIG_DBG_ENC, " not enough input to parse rule %d %N", rule_number, encoding_type_names, this->rules[rule_number].type); return PARSE_ERROR; } if (this->bit_pos) { DBG1(SIG_DBG_ENC, " found rule %d %N on bitpos %d", rule_number, encoding_type_names, this->rules[rule_number].type, this->bit_pos); return PARSE_ERROR; } /* caller interested in result ? */ if (output_pos != NULL) { *output_pos = ntohl(*((u_int32_t*)this->byte_pos)); DBG3(SIG_DBG_ENC, " => %d", *output_pos); } this->byte_pos += 4; return SUCCESS; } /** * Implementation of private_parser_t.parse_uint64. */ static status_t parse_uint64(private_parser_t *this, int rule_number, u_int64_t *output_pos) { if (this->byte_pos + sizeof(u_int64_t) > this->input_roof) { DBG1(SIG_DBG_ENC, " not enough input to parse rule %d %N", rule_number, encoding_type_names, this->rules[rule_number].type); return PARSE_ERROR; } if (this->bit_pos) { DBG1(SIG_DBG_ENC, " found rule %d %N on bitpos %d", rule_number, encoding_type_names, this->rules[rule_number].type, this->bit_pos); return PARSE_ERROR; } /* caller interested in result ? */ if (output_pos != NULL) { /* assuming little endian host order */ *(output_pos + 1) = ntohl(*((u_int32_t*)this->byte_pos)); *output_pos = ntohl(*(((u_int32_t*)this->byte_pos) + 1)); DBG3(SIG_DBG_ENC, " => %b", (void*)output_pos, sizeof(u_int64_t)); } this->byte_pos += 8; return SUCCESS; } /** * Implementation of private_parser_t.parse_bytes. */ static status_t parse_bytes (private_parser_t *this, int rule_number, u_int8_t *output_pos,size_t bytes) { if (this->byte_pos + bytes > this->input_roof) { DBG1(SIG_DBG_ENC, " not enough input to parse rule %d %N", rule_number, encoding_type_names, this->rules[rule_number].type); return PARSE_ERROR; } if (this->bit_pos) { DBG1(SIG_DBG_ENC, " found rule %d %N on bitpos %d", rule_number, encoding_type_names, this->rules[rule_number].type, this->bit_pos); return PARSE_ERROR; } /* caller interested in result ? */ if (output_pos != NULL) { memcpy(output_pos,this->byte_pos,bytes); DBG3(SIG_DBG_ENC, " => %b", (void*)output_pos, bytes); } this->byte_pos += bytes; return SUCCESS; } /** * Implementation of private_parser_t.parse_bit. */ static status_t parse_bit(private_parser_t *this, int rule_number, bool *output_pos) { if (this->byte_pos + sizeof(u_int8_t) > this->input_roof) { DBG1(SIG_DBG_ENC, " not enough input to parse rule %d %N", rule_number, encoding_type_names, this->rules[rule_number].type); return PARSE_ERROR; } /* caller interested in result ? */ if (output_pos != NULL) { u_int8_t mask; mask = 0x01 << (7 - this->bit_pos); *output_pos = *this->byte_pos & mask; if (*output_pos) { /* set to a "clean", comparable true */ *output_pos = TRUE; } DBG3(SIG_DBG_ENC, " => %d", *output_pos); } this->bit_pos = (this->bit_pos + 1) % 8; if (this->bit_pos == 0) { this->byte_pos++; } return SUCCESS; } /** * Implementation of private_parser_t.parse_list. */ static status_t parse_list(private_parser_t *this, int rule_number, linked_list_t **output_pos, payload_type_t payload_type, size_t length) { linked_list_t * list = *output_pos; if (length < 0) { DBG1(SIG_DBG_ENC, " invalid length for rule %d %N", rule_number, encoding_type_names, this->rules[rule_number].type); return PARSE_ERROR; } if (this->bit_pos) { DBG1(SIG_DBG_ENC, " found rule %d %N on bitpos %d", rule_number, encoding_type_names, this->rules[rule_number].type, this->bit_pos); return PARSE_ERROR; } while (length > 0) { u_int8_t *pos_before = this->byte_pos; payload_t *payload; status_t status; DBG2(SIG_DBG_ENC, " %d bytes left, parsing recursively %N", length, payload_type_names, payload_type); status = this->public.parse_payload((parser_t*)this, payload_type, &payload); if (status != SUCCESS) { DBG1(SIG_DBG_ENC, " parsing of a %N substructure failed", payload_type_names, payload_type); return status; } list->insert_last(list, payload); length -= this->byte_pos - pos_before; } *output_pos = list; return SUCCESS; } /** * Implementation of private_parser_t.parse_chunk. */ static status_t parse_chunk(private_parser_t *this, int rule_number, chunk_t *output_pos, size_t length) { if (this->byte_pos + length > this->input_roof) { DBG1(SIG_DBG_ENC, " not enough input (%d bytes) to parse rule %d %N", length, rule_number, encoding_type_names, this->rules[rule_number].type); return PARSE_ERROR; } if (this->bit_pos) { DBG1(SIG_DBG_ENC, " found rule %d %N on bitpos %d", rule_number, encoding_type_names, this->rules[rule_number].type, this->bit_pos); return PARSE_ERROR; } if (output_pos != NULL) { output_pos->len = length; output_pos->ptr = malloc(length); memcpy(output_pos->ptr, this->byte_pos, length); } this->byte_pos += length; DBG3(SIG_DBG_ENC, " => %b", (void*)output_pos->ptr, length); return SUCCESS; } /** * Implementation of parser_t.parse_payload. */ static status_t parse_payload(private_parser_t *this, payload_type_t payload_type, payload_t **payload) { payload_t *pld; void *output; size_t rule_count, payload_length = 0, spi_size = 0, attribute_length = 0; u_int16_t ts_type = 0; bool attribute_format = FALSE; int rule_number; encoding_rule_t *rule; /* create instance of the payload to parse */ pld = payload_create(payload_type); DBG2(SIG_DBG_ENC, "parsing %N payload, %d bytes left", payload_type_names, payload_type, this->input_roof - this->byte_pos); DBG3(SIG_DBG_ENC, "parsing payload from %b", this->byte_pos, this->input_roof-this->byte_pos); if (pld->get_type(pld) == UNKNOWN_PAYLOAD) { DBG1(SIG_DBG_ENC, " payload type %d is unknown, handling as %N", payload_type, payload_type_names, UNKNOWN_PAYLOAD); } /* base pointer for output, avoids casting in every rule */ output = pld; /* parse the payload with its own rulse */ pld->get_encoding_rules(pld, &(this->rules), &rule_count); for (rule_number = 0; rule_number < rule_count; rule_number++) { rule = &(this->rules[rule_number]); DBG2(SIG_DBG_ENC, " parsing rule %d %N", rule_number, encoding_type_names, rule->type); switch (rule->type) { case U_INT_4: { if (this->parse_uint4(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case U_INT_8: { if (this->parse_uint8(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case U_INT_16: { if (this->parse_uint16(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case U_INT_32: { if (this->parse_uint32(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case U_INT_64: { if (this->parse_uint64(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case IKE_SPI: { if (this->parse_bytes(this, rule_number, output + rule->offset,8) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case RESERVED_BIT: { if (this->parse_bit(this, rule_number, NULL) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case RESERVED_BYTE: { if (this->parse_uint8(this, rule_number, NULL) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case FLAG: { if (this->parse_bit(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case PAYLOAD_LENGTH: { if (this->parse_uint16(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } payload_length = *(u_int16_t*)(output + rule->offset); break; } case HEADER_LENGTH: { if (this->parse_uint32(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case SPI_SIZE: { if (this->parse_uint8(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } spi_size = *(u_int8_t*)(output + rule->offset); break; } case SPI: { if (this->parse_chunk(this, rule_number, output + rule->offset, spi_size) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case PROPOSALS: { size_t proposals_length = payload_length - SA_PAYLOAD_HEADER_LENGTH; if (this->parse_list(this, rule_number, output + rule->offset, PROPOSAL_SUBSTRUCTURE, proposals_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case TRANSFORMS: { size_t transforms_length = payload_length - spi_size - PROPOSAL_SUBSTRUCTURE_HEADER_LENGTH; if (this->parse_list(this, rule_number, output + rule->offset, TRANSFORM_SUBSTRUCTURE, transforms_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case TRANSFORM_ATTRIBUTES: { size_t transform_a_length = payload_length - TRANSFORM_SUBSTRUCTURE_HEADER_LENGTH; if (this->parse_list(this, rule_number, output + rule->offset, TRANSFORM_ATTRIBUTE, transform_a_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case CONFIGURATION_ATTRIBUTES: { size_t configuration_attributes_length = payload_length - CP_PAYLOAD_HEADER_LENGTH; if (this->parse_list(this, rule_number, output + rule->offset, CONFIGURATION_ATTRIBUTE, configuration_attributes_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case ATTRIBUTE_FORMAT: { if (this->parse_bit(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } attribute_format = *(bool*)(output + rule->offset); break; } case ATTRIBUTE_TYPE: { if (this->parse_uint15(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } attribute_format = *(bool*)(output + rule->offset); break; } case CONFIGURATION_ATTRIBUTE_LENGTH: { if (this->parse_uint16(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } attribute_length = *(u_int16_t*)(output + rule->offset); break; } case ATTRIBUTE_LENGTH_OR_VALUE: { if (this->parse_uint16(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } attribute_length = *(u_int16_t*)(output + rule->offset); break; } case ATTRIBUTE_VALUE: { if (attribute_format == FALSE) { if (this->parse_chunk(this, rule_number, output + rule->offset, attribute_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } } break; } case NONCE_DATA: { size_t nonce_length = payload_length - NONCE_PAYLOAD_HEADER_LENGTH; if (this->parse_chunk(this, rule_number, output + rule->offset, nonce_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case ID_DATA: { size_t data_length = payload_length - ID_PAYLOAD_HEADER_LENGTH; if (this->parse_chunk(this, rule_number, output + rule->offset, data_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case AUTH_DATA: { size_t data_length = payload_length - AUTH_PAYLOAD_HEADER_LENGTH; if (this->parse_chunk(this, rule_number, output + rule->offset, data_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case CERT_DATA: { size_t data_length = payload_length - CERT_PAYLOAD_HEADER_LENGTH; if (this->parse_chunk(this, rule_number, output + rule->offset, data_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case CERTREQ_DATA: { size_t data_length = payload_length - CERTREQ_PAYLOAD_HEADER_LENGTH; if (this->parse_chunk(this, rule_number, output + rule->offset, data_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case EAP_MESSAGE: { size_t data_length = payload_length - EAP_PAYLOAD_HEADER_LENGTH; if (this->parse_chunk(this, rule_number, output + rule->offset, data_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case SPIS: { size_t data_length = payload_length - DELETE_PAYLOAD_HEADER_LENGTH; if (this->parse_chunk(this, rule_number, output + rule->offset, data_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case VID_DATA: { size_t data_length = payload_length - VENDOR_ID_PAYLOAD_HEADER_LENGTH; if (this->parse_chunk(this, rule_number, output + rule->offset, data_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case CONFIGURATION_ATTRIBUTE_VALUE: { size_t data_length = attribute_length; if (this->parse_chunk(this, rule_number, output + rule->offset, data_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case KEY_EXCHANGE_DATA: { size_t keydata_length = payload_length - KE_PAYLOAD_HEADER_LENGTH; if (this->parse_chunk(this, rule_number, output + rule->offset, keydata_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case NOTIFICATION_DATA: { size_t notify_length = payload_length - NOTIFY_PAYLOAD_HEADER_LENGTH - spi_size; if (this->parse_chunk(this, rule_number, output + rule->offset, notify_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case ENCRYPTED_DATA: { size_t data_length = payload_length - ENCRYPTION_PAYLOAD_HEADER_LENGTH; if (this->parse_chunk(this, rule_number, output + rule->offset, data_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case TS_TYPE: { if (this->parse_uint8(this, rule_number, output + rule->offset) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } ts_type = *(u_int8_t*)(output + rule->offset); break; } case ADDRESS: { size_t address_length = (ts_type == TS_IPV4_ADDR_RANGE) ? 4 : 16; if (this->parse_chunk(this, rule_number, output + rule->offset,address_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case TRAFFIC_SELECTORS: { size_t traffic_selectors_length = payload_length - TS_PAYLOAD_HEADER_LENGTH; if (this->parse_list(this, rule_number, output + rule->offset, TRAFFIC_SELECTOR_SUBSTRUCTURE, traffic_selectors_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } case UNKNOWN_PAYLOAD: { size_t unknown_payload_data_length = payload_length - UNKNOWN_PAYLOAD_HEADER_LENGTH; if (this->parse_chunk(this, rule_number, output + rule->offset, unknown_payload_data_length) != SUCCESS) { pld->destroy(pld); return PARSE_ERROR; } break; } default: { DBG1(SIG_DBG_ENC, " no rule to parse rule %d %N", rule_number, encoding_type_names, rule->type); pld->destroy(pld); return PARSE_ERROR; } } /* process next rulue */ rule++; } *payload = pld; DBG2(SIG_DBG_ENC, "parsing %N payload finished", payload_type_names, payload_type); return SUCCESS; } /** * Implementation of parser_t.get_remaining_byte_count. */ static int get_remaining_byte_count (private_parser_t *this) { int count = (this->input_roof - this->byte_pos); return count; } /** * Implementation of parser_t.reset_context. */ static void reset_context (private_parser_t *this) { this->byte_pos = this->input; this->bit_pos = 0; } /** * Implementation of parser_t.destroy. */ static void destroy(private_parser_t *this) { free(this); } /* * Described in header. */ parser_t *parser_create(chunk_t data) { private_parser_t *this = malloc_thing(private_parser_t); this->public.parse_payload = (status_t(*)(parser_t*,payload_type_t,payload_t**)) parse_payload; this->public.reset_context = (void(*)(parser_t*)) reset_context; this->public.get_remaining_byte_count = (int (*) (parser_t *))get_remaining_byte_count; this->public.destroy = (void(*)(parser_t*)) destroy; this->parse_uint4 = parse_uint4; this->parse_uint8 = parse_uint8; this->parse_uint15 = parse_uint15; this->parse_uint16 = parse_uint16; this->parse_uint32 = parse_uint32; this->parse_uint64 = parse_uint64; this->parse_bytes = parse_bytes; this->parse_bit = parse_bit; this->parse_list = parse_list; this->parse_chunk = parse_chunk; this->input = data.ptr; this->byte_pos = data.ptr; this->bit_pos = 0; this->input_roof = data.ptr + data.len; return (parser_t*)this; }