/* * Author: Jon Trulson * Copyright (c) 2016 Intel Corporation * * 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, subject to * the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE * LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION * OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION * WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #pragma once /** * @file * @brief UART OW module * * This module allows one to use MRAA's UART support in order to * interact with Dallas 1-wire compliant devices on a 1-wire bus. It * makes use of the UART for timing purposes. The principle of * operation is described here: * https://www.maximintegrated.com/en/app-notes/index.mvp/id/214 * * It is important the you use a UART with CMOS/TTL level voltages * (3.3v/5v) RX and TX lines. DO NOT use standard RS232 level * voltages, or you are going to have a bad day. * * In addition, a diode should be placed across the RX and * TX lines like so: * * -| * U| * A| TX---|<--+ * R| | * T| RX-------o--------o 1-wire data bus * -| * * The diode on TX is a 1N4148 (cheap and common), with the cathode * connected to TX, and the anode connected to RX and the rest of the * 1-wire data line. * * @snippet uart_ow.c Interesting */ #ifdef __cplusplus extern "C" { #endif #include #include "common.h" #include "uart.h" /* 8 bytes (64 bits) for a device rom code */ #define MRAA_UART_OW_ROMCODE_SIZE 8 /* for now, we simply use the normal MRAA UART context */ typedef struct _mraa_uart_ow { mraa_uart_context uart; /* search state */ unsigned char ROM_NO[MRAA_UART_OW_ROMCODE_SIZE]; /* 8 byte (64b) rom code */ int LastDiscrepancy; int LastFamilyDiscrepancy; mraa_boolean_t LastDeviceFlag; } *mraa_uart_ow_context; /** * UART One Wire ROM related Command bytes */ typedef enum { MRAA_UART_OW_CMD_READ_ROM = 0x33, /**< read rom, when only one device on bus */ MRAA_UART_OW_CMD_MATCH_ROM = 0x55, /**< match a specific rom code */ MRAA_UART_OW_CMD_SKIP_ROM = 0xcc, /**< skip match/search rom */ MRAA_UART_OW_CMD_SEARCH_ROM_ALARM = 0xec, /**< search all roms in alarm state */ MRAA_UART_OW_CMD_SEARCH_ROM = 0xf0 /**< search all rom codes */ } mraa_uart_ow_rom_cmd_t; /** * Initialise uart_ow_context, uses UART board mapping * * @param uart the index of the uart set to use * @return uart_ow context or NULL */ mraa_uart_ow_context mraa_uart_ow_init(int uart); /** * Initialise a raw uart_ow_context. No board setup. * * @param path for example "/dev/ttyS0" * @return uart_ow context or NULL */ mraa_uart_ow_context mraa_uart_ow_init_raw(const char* path); /** * Get char pointer with tty device path within Linux * For example. Could point to "/dev/ttyS0" * * @param dev uart_ow context * @return char pointer of device path */ const char* mraa_uart_ow_get_dev_path(mraa_uart_ow_context dev); /** * Destroy a mraa_uart_ow_context * * @param dev uart_ow context * @return mraa_result_t */ mraa_result_t mraa_uart_ow_stop(mraa_uart_ow_context dev); /** * Read a byte from the 1-wire bus * * @param dev uart_ow context * @return the byte read or -1 for error */ int mraa_uart_ow_read_byte(mraa_uart_ow_context dev); /** * Write a byte to a 1-wire bus * * @param dev uart_ow context * @param byte the byte to write to the bus * @return the byte read back during the time slot or -1 for error */ int mraa_uart_ow_write_byte(mraa_uart_ow_context dev, uint8_t byte); /** * Write a bit to a 1-wire bus and read a bit corresponding to the * time slot back. This is possible due to the way we wired the TX * and RX together with a diode, forming a loopback. * * @param dev uart_ow context * @param bit the bit to write to the bus * @return the bit read back during the time slot or -1 for error */ int mraa_uart_ow_bit(mraa_uart_ow_context dev, uint8_t bit); /** * Send a reset pulse to the 1-wire bus and test for device presence * * @param dev uart_ow context * @return one of the mraa_result_t values */ mraa_result_t mraa_uart_ow_reset(mraa_uart_ow_context dev); /** * Begin a rom code search of the 1-wire bus. This function * implements the 1-wire search algorithm. See the uart_ow.c example * for an idea on how to use this function to identify all devices * present on the bus. * * @param dev uart_ow context * @param start true to start a new search from scratch, false to * continue an existing search * @param id the 8-byte rom code id of the current matched device when * a device is found * @return one of the mraa_result_t values */ mraa_result_t mraa_uart_ow_rom_search(mraa_uart_ow_context dev, mraa_boolean_t start, uint8_t* id); /** * Send a command byte to a device on the 1-wire bus * * @param dev uart_ow context * @param command the command byte to send * @param id the rom code id of the device to receive the command, * NULL for all devices on the bus * @return one of the mraa_result_t values */ mraa_result_t mraa_uart_ow_command(mraa_uart_ow_context dev, uint8_t command, uint8_t* id); /** * Perform a Dallas 1-wire compliant CRC8 computation on a buffer * * @param buffer the buffer containing the data * @param length the length of the buffer * @return the computed CRC */ uint8_t mraa_uart_ow_crc8(uint8_t* buffer, uint16_t length); #ifdef __cplusplus } #endif