/** * Copyright (c) 2015 - 2019, Nordic Semiconductor ASA * * All rights reserved. * * Redistribution and use in source and binary forms, with or without modification, * are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * 2. Redistributions in binary form, except as embedded into a Nordic * Semiconductor ASA integrated circuit in a product or a software update for * such product, 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. * * 3. Neither the name of Nordic Semiconductor ASA nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. * * 4. This software, with or without modification, must only be used with a * Nordic Semiconductor ASA integrated circuit. * * 5. Any software provided in binary form under this license must not be reverse * engineered, decompiled, modified and/or disassembled. * * THIS SOFTWARE IS PROVIDED BY NORDIC SEMICONDUCTOR ASA "AS IS" AND ANY EXPRESS * OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY, NONINFRINGEMENT, AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL NORDIC SEMICONDUCTOR ASA 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. * */ #include "sdk_common.h" #if NRF_MODULE_ENABLED(NFC_T2T_PARSER) #include #include #include "nrf_delay.h" #include "nfc_t2t_parser.h" #define NRF_LOG_MODULE_NAME nfc_t2t_parser #if NFC_T2T_PARSER_LOG_ENABLED #define NRF_LOG_LEVEL NFC_T2T_PARSER_LOG_LEVEL #define NRF_LOG_INFO_COLOR NFC_T2T_PARSER_INFO_COLOR #include "nrf_log.h" NRF_LOG_MODULE_REGISTER(); #else // NFC_T2T_PARSER_LOG_ENABLED #define NRF_LOG_LEVEL 0 #include "nrf_log.h" #endif // NFC_T2T_PARSER_LOG_ENABLED /// Gets least significant nibble (a 4-bit value) from a byte. #define LSN_GET(val) (val & 0x0F) /// Gets most significant nibble (a 4-bit value) from a byte. #define MSN_GET(val) ((val >> 4) & 0x0F) /** * @brief Function for inserting the TLV block into a @ref type_2_tag_t structure. * * The content of a TLV block structure pointed by the p_tlv_block is copied into a TLV block * array within the structure pointed by the p_type_2_tag. * * @param[in,out] p_type_2_tag Pointer to the structure that contains the TLV blocks array. * @param[in] p_tlv_block Pointer to the TLV block to insert. * * @retval NRF_SUCCESS If the block was inserted successfully. * @retval NRF_ERROR_NO_MEM If there is already maximum number of blocks stored in the array. * */ static ret_code_t type_2_tag_tlv_block_insert(type_2_tag_t * p_type_2_tag, tlv_block_t * p_tlv_block) { if (p_type_2_tag->tlv_count == p_type_2_tag->max_tlv_blocks) { return NRF_ERROR_NO_MEM; } // Copy contents of the source block. p_type_2_tag->p_tlv_block_array[p_type_2_tag->tlv_count] = *p_tlv_block; p_type_2_tag->tlv_count++; return NRF_SUCCESS; } /** * @brief Function for checking if the TLV block length is correct. * * Some TLV block has predefined length: * TLV_NULL and TLV_TERMINATOR always have a length of 1 byte. * TLV_LOCK_CONTROL and TLV_MEMORY_CONTROL always have a length of 3 bytes. * * @param[in] p_block_to_check Pointer to the structure that contains the TLV block length. * * @retval TRUE If the length is correct. * @retval FALSE Otherwise. * */ static bool tlv_block_is_data_length_correct(tlv_block_t * p_block_to_check) { switch (p_block_to_check->tag) { case TLV_NULL: case TLV_TERMINATOR: if (p_block_to_check->length != TLV_NULL_TERMINATOR_LEN) { return false; } break; case TLV_LOCK_CONTROL: case TLV_MEMORY_CONTROL: if (p_block_to_check->length != TLV_LOCK_MEMORY_CTRL_LEN) { return false; } break; case TLV_NDEF_MESSAGE: case TLV_PROPRIETARY: default: // Any length will do. break; } return true; } /** * @brief Function for checking if the end of the tag data area was reached. * * @param[in] p_type_2_tag Pointer to the structure that contains the data area size. * @param[in] offset Current byte offset. * * @retval TRUE If the offset indicates the end of the data area. * @retval FALSE Otherwise. * */ static bool type_2_tag_is_end_reached(type_2_tag_t * p_type_2_tag, uint16_t offset) { return offset == (p_type_2_tag->cc.data_area_size + T2T_FIRST_DATA_BLOCK_OFFSET); } /** * @brief Function for checking if version of Type 2 Tag specification read from a tag is supported. * * @param[in] p_type_2_tag Pointer to the structure that contains the tag version. * * @retval TRUE If the version is supported and tag data can be parsed. * @retval FALSE Otherwise. * */ static bool type_2_tag_is_version_supported(type_2_tag_t * p_type_2_tag) { // Simple check atm, as only 1 major version has been issued so far, so no backward compatibility // is needed, tags with newer version implemented shall be rejected according to the doc. return p_type_2_tag->cc.major_version == T2T_SUPPORTED_MAJOR_VERSION; } /** * @brief Function for checking if the field fits into the data area specified in * the Capability Container. * * @param[in] p_type_2_tag Pointer to the structure that contains the data area size. * @param[in] offset As Offset of the field to check. * @param[in] field_length Length of the field to check. * * @retval TRUE If the field fits into the data area. * @retval FALSE If the field exceeds the data area. * */ static bool type_2_tag_is_field_within_data_range(type_2_tag_t * p_type_2_tag, uint16_t offset, uint16_t field_length) { // Invalid argument, return false. if (field_length == 0) { return false; } return ( (offset + field_length - 1) < (p_type_2_tag->cc.data_area_size + T2T_FIRST_DATA_BLOCK_OFFSET) ) && ( offset >= T2T_FIRST_DATA_BLOCK_OFFSET ); } /** * @brief Function for reading the tag field of a TLV block from the p_raw_data buffer. * * This function reads the tag field containing a TLV block type and inserts its value into * a structure pointed by the p_tlv_buf pointer. * * @param[in] p_type_2_tag Pointer to the structure that contains Type 2 Tag data parsed so far. * @param[in] p_raw_data Pointer to the buffer with a raw data from the tag. * @param[in,out] p_t_offset As input: offset of the tag field to read. As output: offset of * the first byte after the tag field. * @param[out] p_tlv_buf Pointer to a @ref tlv_block_t structure where the tag type will be * inserted. * * @retval NRF_SUCCESS If the tag field at specified offset is correct. * @retval NRF_ERROR_INVALID_DATA If the tag field at specified offset exceeds the data * area specified in the Capability Container. * */ static ret_code_t type_2_tag_type_extract(type_2_tag_t * p_type_2_tag, uint8_t * p_raw_data, uint16_t * p_t_offset, tlv_block_t * p_tlv_buf) { if (!type_2_tag_is_field_within_data_range(p_type_2_tag, *p_t_offset, TLV_T_LENGTH)) { return NRF_ERROR_INVALID_DATA; } p_tlv_buf->tag = p_raw_data[*p_t_offset]; *p_t_offset += TLV_T_LENGTH; return NRF_SUCCESS; } /** * @brief Function for reading the length field of a TLV block from the p_raw_data buffer. * * This function reads the length field of a TLV block and inserts its value into a structure * pointed by the p_tlv_buf pointer. * * @param[in] p_type_2_tag Pointer to the structure that contains Type 2 Tag data parsed so far. * @param[in] p_raw_data Pointer to the buffer with a raw data from the tag. * @param[in,out] p_l_offset As input: offset of the length field to read. As output: offset of * the first byte after the length field. * @param[out] p_tlv_buf Pointer to a @ref tlv_block_t structure where the length will be * inserted. * * @retval NRF_SUCCESS If the length field at specified offset is correct. * @retval NRF_ERROR_INVALID_DATA If the length field at specified offset exceeds the data * area specified in the Capability Container or has * incorrect format. * */ static ret_code_t type_2_tag_length_extract(type_2_tag_t * p_type_2_tag, uint8_t * p_raw_data, uint16_t * p_l_offset, tlv_block_t * p_tlv_buf) { uint16_t length; if (!type_2_tag_is_field_within_data_range(p_type_2_tag, *p_l_offset, TLV_L_SHORT_LENGTH)) { return NRF_ERROR_INVALID_DATA; } length = p_raw_data[*p_l_offset]; if (length == TLV_L_FORMAT_FLAG) { // Check another two bytes. if (!type_2_tag_is_field_within_data_range(p_type_2_tag, *p_l_offset, TLV_L_LONG_LENGTH)) { return NRF_ERROR_INVALID_DATA; } length = uint16_big_decode(&p_raw_data[*p_l_offset + 1]); // Long length value cannot be lower than 0xFF. if (length < 0xFF) { return NRF_ERROR_INVALID_DATA; } p_tlv_buf->length = length; *p_l_offset += TLV_L_LONG_LENGTH; } else { p_tlv_buf->length = length; *p_l_offset += TLV_L_SHORT_LENGTH; } return NRF_SUCCESS; } /** * @brief Function for reading a pointer to the value field of a TLV block from the p_raw_data buffer. * * This function reads a pointer to the value field of a TLV block and inserts it into * a structure pointed by the p_tlv_buf pointer. If there is no value field present in the * TLV block, NULL is inserted. * * @param[in] p_type_2_tag Pointer to the structure that contains Type 2 Tag data parsed so far. * @param[in] p_raw_data Pointer to the buffer with a raw data from the tag. * @param[in,out] p_v_offset As input: offset of the value field to read. As output: offset of * the first byte after the value field. * @param[in,out] p_tlv_buf Pointer to a @ref tlv_block_t structure where the value field * pointer will be inserted. * * @retval NRF_SUCCESS If the value field at specified offset is correct. * @retval NRF_ERROR_INVALID_DATA If the value field at specified offset exceeds the data * area specified in the Capability Container. * */ static ret_code_t type_2_tag_value_ptr_extract(type_2_tag_t * p_type_2_tag, uint8_t * p_raw_data, uint16_t * p_v_offset, tlv_block_t * p_tlv_buf) { if (p_tlv_buf->length == 0) { // Clear the value pointer, don't touch the offset. p_tlv_buf->p_value = NULL; } else { if (!type_2_tag_is_field_within_data_range(p_type_2_tag, *p_v_offset, p_tlv_buf->length)) { return NRF_ERROR_INVALID_DATA; } p_tlv_buf->p_value = p_raw_data + *p_v_offset; *p_v_offset += p_tlv_buf->length; } return NRF_SUCCESS; } /** * @brief Function for reading a single TLV block from the p_raw_data buffer. * * This function reads a single TLV block from the p_raw_data buffer and stores its contents in a * structure pointed by the p_tlv_buf. * * @param[in] p_type_2_tag Pointer to the structure that contains Type 2 Tag data parsed so far. * @param[in] p_raw_data Pointer to the buffer with a raw data from the tag. * @param[in,out] p_tlv_offset As input: offset of the TLV block to read. As output: offset of the * next TLV block, 0 if it was the last block. * @param[out] p_tlv_buf Pointer to a @ref tlv_block_t structure that will be filled with * the data read. * * @retval NRF_SUCCESS If the parsing operation of the block succeeded. Otherwise, an error * code is returned. * */ static ret_code_t type_2_tag_tlv_block_extract(type_2_tag_t * p_type_2_tag, uint8_t * p_raw_data, uint16_t * p_offset, tlv_block_t * p_tlv_buf) { ret_code_t err_code; memset(p_tlv_buf, 0, sizeof(tlv_block_t)); // TLV Tag field. err_code = type_2_tag_type_extract(p_type_2_tag, p_raw_data, p_offset, p_tlv_buf); if (err_code != NRF_SUCCESS) { return err_code; } // Further processing depends on tag field value. switch (p_tlv_buf->tag) { case TLV_NULL: // Simply ignore NULL blocks, leave the incremented offset. break; case TLV_TERMINATOR: // Write 0 to the offset variable, indicating that last TLV block was found. *p_offset = 0; break; case TLV_LOCK_CONTROL: case TLV_MEMORY_CONTROL: case TLV_NDEF_MESSAGE: case TLV_PROPRIETARY: default: // Unknown blocks should also be extracted. err_code = type_2_tag_length_extract(p_type_2_tag, p_raw_data, p_offset, p_tlv_buf); if (err_code != NRF_SUCCESS) { return err_code; } if (p_tlv_buf->length > 0) { err_code = type_2_tag_value_ptr_extract(p_type_2_tag, p_raw_data, p_offset, p_tlv_buf); if (err_code != NRF_SUCCESS) { return err_code; } } break; } return NRF_SUCCESS; } /** * @brief Function for checking the checksum bytes of the UID stored in internal area. * * This function calculates the block check character (BCC) bytes based on the parsed serial number * and compares them with bytes read from the Type 2 Tag. * * @param[in] p_sn Pointer to the @ref type_2_tag_serial_number_t structure to check. * * @retval TRUE If the calculated BCC matched the BCC from the tag. * @retval FALSE Otherwise. * */ static bool type_2_tag_is_bcc_correct(type_2_tag_serial_number_t * p_sn) { uint8_t bcc1 = (uint8_t)T2T_UID_BCC_CASCADE_BYTE ^ (uint8_t)p_sn->manufacturer_id ^ (uint8_t)((p_sn->serial_number_part_1 >> 8) & 0xFF) ^ (uint8_t)(p_sn->serial_number_part_1 & 0xFF); uint8_t bcc2 = (uint8_t)((p_sn->serial_number_part_2 >> 24) & 0xFF) ^ (uint8_t)((p_sn->serial_number_part_2 >> 16) & 0xFF) ^ (uint8_t)((p_sn->serial_number_part_2 >> 8) & 0xFF) ^ (uint8_t)( p_sn->serial_number_part_2 & 0xFF); return (bcc1 == p_sn->check_byte_0) && (bcc2 == p_sn->check_byte_1); } /** * @brief Function for parsing an internal area of a Type 2 Tag. * * This function reads data from an internal area in the raw data buffer and fills the * @ref type_2_tag_serial_number_t structure within @ref type_2_tag_t. * * @param[in,out] p_type_2_tag Pointer to the structure that will be filled with parsed data. * @param[in] p_raw_data Pointer to the buffer with raw data from the tag. * * @retval NRF_SUCCESS If the parsing operation of the internal area succeeded. * Otherwise, an error code is returned. * */ static ret_code_t type_2_tag_internal_parse(type_2_tag_t * p_type_2_tag, uint8_t * p_raw_data) { p_type_2_tag->sn.manufacturer_id = p_raw_data[0]; p_type_2_tag->sn.serial_number_part_1 = uint16_big_decode(&p_raw_data[1]); p_type_2_tag->sn.check_byte_0 = p_raw_data[3]; p_type_2_tag->sn.serial_number_part_2 = uint32_big_decode(&p_raw_data[4]); p_type_2_tag->sn.check_byte_1 = p_raw_data[8]; p_type_2_tag->sn.internal = p_raw_data[9]; p_type_2_tag->lock_bytes = uint16_big_decode(&p_raw_data[10]); if (!type_2_tag_is_bcc_correct(&p_type_2_tag->sn)) { NRF_LOG_WARNING("Warning! BCC of the serial number is not correct!"); } return NRF_SUCCESS; } /** * @brief Function for parsing a Capabiliy Container area of a Type 2 Tag. * * This function reads data from a Capability Container area in the raw data buffer and fills the * @ref type_2_tag_capability_container_t structure within @ref type_2_tag_t. * * @param[in,out] p_type_2_tag Pointer to the structure that will be filled with parsed data. * @param[in] p_raw_data Pointer to the buffer with raw data from the tag. * * @retval NRF_SUCCESS If the parsing operation of the Capability Container succeeded. * Otherwise, an error code is returned. * */ static ret_code_t type_2_tag_cc_parse(type_2_tag_t * p_type_2_tag, uint8_t * p_raw_data) { uint8_t * p_cc_block = p_raw_data + T2T_CC_BLOCK_OFFSET; if (p_cc_block[0] != T2T_NFC_FORUM_DEFINED_DATA) { return NRF_ERROR_INVALID_DATA; } p_type_2_tag->cc.major_version = MSN_GET(p_cc_block[1]); p_type_2_tag->cc.minor_version = LSN_GET(p_cc_block[1]); p_type_2_tag->cc.data_area_size = p_cc_block[2] * 8; p_type_2_tag->cc.read_access = MSN_GET(p_cc_block[3]); p_type_2_tag->cc.write_access = LSN_GET(p_cc_block[3]); return NRF_SUCCESS; } /** * @brief Function for parsing a single TLV block. * * This function reads a single TLV block from the raw data buffer, from the position indicated by * the p_tlv_offset, and adds it to the @ref type_2_tag_t structure. * * @param[in,out] p_type_2_tag Pointer to the structure that will be filled with parsed data. * @param[in] p_raw_data Pointer to the buffer with raw data from the tag. * @param[in,out] p_tlv_offset As input: offset of the TLV block to parse. As output: offset of the * next TLV block, 0 if it was the last block. * * @retval NRF_SUCCESS If the parsing operation of the block succeeded. Otherwise, an error * code is returned. * */ static ret_code_t type_2_tag_tlv_parse(type_2_tag_t * p_type_2_tag, uint8_t * p_raw_data, uint16_t * p_tlv_offset) { ret_code_t err_code; tlv_block_t new_block; // Get tag field. err_code = type_2_tag_tlv_block_extract(p_type_2_tag, p_raw_data, p_tlv_offset, &new_block); if (err_code != NRF_SUCCESS) { return err_code; } if (!tlv_block_is_data_length_correct(&new_block)) { return NRF_ERROR_INVALID_DATA; } // Further action depends on tag type. switch (new_block.tag) { case TLV_NULL: case TLV_TERMINATOR: // Ignore them. break; case TLV_LOCK_CONTROL: case TLV_MEMORY_CONTROL: case TLV_NDEF_MESSAGE: case TLV_PROPRIETARY: default: // Unknown tag types are also added. err_code = type_2_tag_tlv_block_insert(p_type_2_tag, &new_block); if (err_code != NRF_SUCCESS) { NRF_LOG_WARNING("Warning! Not enough memory to insert all of the blocks!"); return err_code; } break; } return NRF_SUCCESS; } void type_2_tag_clear(type_2_tag_t * p_type_2_tag) { p_type_2_tag->tlv_count = 0; memset(&p_type_2_tag->cc, 0, sizeof(p_type_2_tag->cc)); memset(&p_type_2_tag->sn, 0, sizeof(p_type_2_tag->sn)); } ret_code_t type_2_tag_parse(type_2_tag_t * p_type_2_tag, uint8_t * p_raw_data) { ret_code_t err_code; type_2_tag_clear(p_type_2_tag); err_code = type_2_tag_internal_parse(p_type_2_tag, p_raw_data); if (err_code != NRF_SUCCESS) { return err_code; } err_code = type_2_tag_cc_parse(p_type_2_tag, p_raw_data); if (err_code != NRF_SUCCESS) { return err_code; } if (!type_2_tag_is_version_supported(p_type_2_tag)) { return NRF_ERROR_NOT_SUPPORTED; } uint16_t offset = T2T_FIRST_DATA_BLOCK_OFFSET; while (offset > 0) { // Check if end of tag is reached (no terminator block was present). if (type_2_tag_is_end_reached(p_type_2_tag, offset)) { NRF_LOG_DEBUG("No terminator block was found in the tag!"); break; } err_code = type_2_tag_tlv_parse(p_type_2_tag, p_raw_data, &offset); if (err_code != NRF_SUCCESS) { return err_code; } } return NRF_SUCCESS; } void type_2_tag_printout(type_2_tag_t * p_type_2_tag) { uint32_t i; NRF_LOG_INFO("Type 2 Tag contents:"); NRF_LOG_INFO("Number of TLV blocks: %d", p_type_2_tag->tlv_count); NRF_LOG_DEBUG("Internal data:"); NRF_LOG_DEBUG(" Manufacturer ID: 0x%02x", p_type_2_tag->sn.manufacturer_id); NRF_LOG_DEBUG(" Serial number part 1: 0x%04x", p_type_2_tag->sn.serial_number_part_1); NRF_LOG_DEBUG(" Check byte 0: 0x%02x", p_type_2_tag->sn.check_byte_0); NRF_LOG_DEBUG(" Serial number part 2: 0x%08lx", p_type_2_tag->sn.serial_number_part_2); NRF_LOG_DEBUG(" Check byte 1: 0x%02x", p_type_2_tag->sn.check_byte_1); NRF_LOG_DEBUG(" Internal byte: 0x%02x", p_type_2_tag->sn.internal); NRF_LOG_DEBUG(" Lock bytes: 0x%04x", p_type_2_tag->lock_bytes); NRF_LOG_DEBUG("Capability Container data:"); NRF_LOG_DEBUG(" Major version number: %d", p_type_2_tag->cc.major_version); NRF_LOG_DEBUG(" Minor version number: %d", p_type_2_tag->cc.minor_version); NRF_LOG_DEBUG(" Data area size: %d", p_type_2_tag->cc.data_area_size); NRF_LOG_DEBUG(" Read access: 0x%02X", p_type_2_tag->cc.read_access); NRF_LOG_DEBUG(" Write access: 0x%02X", p_type_2_tag->cc.write_access); for (i = 0; i < p_type_2_tag->tlv_count; i++) { NRF_LOG_INFO("TLV block 0x%02X: ", p_type_2_tag->p_tlv_block_array[i].tag); switch (p_type_2_tag->p_tlv_block_array[i].tag) { case TLV_LOCK_CONTROL: NRF_LOG_INFO("Lock Control"); break; case TLV_MEMORY_CONTROL: NRF_LOG_INFO("Memory Control"); break; case TLV_NDEF_MESSAGE: NRF_LOG_INFO("NDEF Message"); break; case TLV_PROPRIETARY: NRF_LOG_INFO("Proprietary"); break; case TLV_NULL: NRF_LOG_INFO("Null\r\n"); break; case TLV_TERMINATOR: NRF_LOG_INFO("Terminator"); break; default: NRF_LOG_INFO("Unknown"); break; } NRF_LOG_INFO(" Data length: %d", p_type_2_tag->p_tlv_block_array[i].length); if (p_type_2_tag->p_tlv_block_array[i].length > 0) { NRF_LOG_DEBUG(" Data:"); NRF_LOG_HEXDUMP_DEBUG(p_type_2_tag->p_tlv_block_array[i].p_value, p_type_2_tag->p_tlv_block_array[i].length); } } } #endif // NRF_MODULE_ENABLED(NFC_T2T_PARSER)