/************************************************************************************//** * \file Source\ARMCM0_XMC1\uart.c * \brief Bootloader UART communication interface source file. * \ingroup Target_ARMCM0_XMC1 * \internal *---------------------------------------------------------------------------------------- * C O P Y R I G H T *---------------------------------------------------------------------------------------- * Copyright (c) 2016 by Feaser http://www.feaser.com All rights reserved * *---------------------------------------------------------------------------------------- * L I C E N S E *---------------------------------------------------------------------------------------- * This file is part of OpenBLT. OpenBLT 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 3 of the License, or (at your option) any later * version. * * OpenBLT 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. * * You have received a copy of the GNU General Public License along with OpenBLT. It * should be located in ".\Doc\license.html". If not, contact Feaser to obtain a copy. * * \endinternal ****************************************************************************************/ /**************************************************************************************** * Include files ****************************************************************************************/ #include "boot.h" /* bootloader generic header */ #include "xmc_uart.h" /* UART driver header */ #if (BOOT_COM_UART_ENABLE > 0) /**************************************************************************************** * Macro definitions ****************************************************************************************/ /** \brief Timeout time for the reception of a CTO packet. The timer is started upon * reception of the first packet byte. */ #define UART_CTO_RX_PACKET_TIMEOUT_MS (100u) /** \brief Timeout for transmitting a byte in milliseconds. */ #define UART_BYTE_TX_TIMEOUT_MS (10u) /** \brief Macro for accessing the UART channel handle in the format that is expected * by the XMClib UART driver. */ #define UART_CHANNEL ((XMC_USIC_CH_t *)(uartChannelMap[BOOT_COM_UART_CHANNEL_INDEX])) /**************************************************************************************** * Local constant declarations ****************************************************************************************/ /** \brief Helper array to quickly convert the channel index, as specific in the boot- * loader's configuration header, to the associated channel handle that the * XMClib's UART driver requires. */ static const XMC_USIC_CH_t *uartChannelMap[] = { XMC_UART0_CH0, /* BOOT_COM_UART_CHANNEL_INDEX = 0 */ XMC_UART0_CH1, /* BOOT_COM_UART_CHANNEL_INDEX = 1 */ XMC_UART1_CH0, /* BOOT_COM_UART_CHANNEL_INDEX = 2 */ XMC_UART1_CH1 /* BOOT_COM_UART_CHANNEL_INDEX = 3 */ }; /**************************************************************************************** * Function prototypes ****************************************************************************************/ static blt_bool UartReceiveByte(blt_int8u *data); static blt_bool UartTransmitByte(blt_int8u data); /************************************************************************************//** ** \brief Initializes the UART communication interface. ** \return none. ** ****************************************************************************************/ void UartInit(void) { XMC_UART_CH_CONFIG_t uart_config; /* the current implementation supports XMC_UART0_CH0 to XMC_UART2_CH1. throw an * assertion error in case a different CAN channel is configured. */ ASSERT_CT((BOOT_COM_UART_CHANNEL_INDEX >= 0) && (BOOT_COM_UART_CHANNEL_INDEX <= 3)); /* set configuration and initialize UART channel */ uart_config.baudrate = BOOT_COM_UART_BAUDRATE; uart_config.data_bits = 8; uart_config.frame_length = 8; uart_config.stop_bits = 1; uart_config.oversampling = 16; uart_config.parity_mode = XMC_USIC_CH_PARITY_MODE_NONE; XMC_UART_CH_Init(UART_CHANNEL, &uart_config); /* configure small transmit and receive FIFO */ XMC_USIC_CH_TXFIFO_Configure(UART_CHANNEL, 16U, XMC_USIC_CH_FIFO_SIZE_16WORDS, 1U); XMC_USIC_CH_RXFIFO_Configure(UART_CHANNEL, 0U, XMC_USIC_CH_FIFO_SIZE_16WORDS, 1U); /* start UART */ XMC_UART_CH_Start(UART_CHANNEL); } /*** end of UartInit ***/ /************************************************************************************//** ** \brief Transmits a packet formatted for the communication interface. ** \param data Pointer to byte array with data that it to be transmitted. ** \param len Number of bytes that are to be transmitted. ** \return none. ** ****************************************************************************************/ void UartTransmitPacket(blt_int8u *data, blt_int8u len) { blt_int16u data_index; blt_bool result; /* verify validity of the len-parameter */ ASSERT_RT(len <= BOOT_COM_UART_TX_MAX_DATA); /* first transmit the length of the packet */ result = UartTransmitByte(len); ASSERT_RT(result == BLT_TRUE); /* transmit all the packet bytes one-by-one */ for (data_index = 0; data_index < len; data_index++) { /* keep the watchdog happy */ CopService(); /* write byte */ result = UartTransmitByte(data[data_index]); ASSERT_RT(result == BLT_TRUE); } } /*** end of UartTransmitPacket ***/ /************************************************************************************//** ** \brief Receives a communication interface packet if one is present. ** \param data Pointer to byte array where the data is to be stored. ** \param len Pointer where the length of the packet is to be stored. ** \return BLT_TRUE if a packet was received, BLT_FALSE otherwise. ** ****************************************************************************************/ blt_bool UartReceivePacket(blt_int8u *data, blt_int8u *len) { static blt_int8u xcpCtoReqPacket[BOOT_COM_UART_RX_MAX_DATA+1]; /* one extra for length */ static blt_int8u xcpCtoRxLength; static blt_bool xcpCtoRxInProgress = BLT_FALSE; static blt_int32u xcpCtoRxStartTime = 0; /* start of cto packet received? */ if (xcpCtoRxInProgress == BLT_FALSE) { /* store the message length when received */ if (UartReceiveByte(&xcpCtoReqPacket[0]) == BLT_TRUE) { if ( (xcpCtoReqPacket[0] > 0) && (xcpCtoReqPacket[0] <= BOOT_COM_UART_RX_MAX_DATA) ) { /* store the start time */ xcpCtoRxStartTime = TimerGet(); /* reset packet data count */ xcpCtoRxLength = 0; /* indicate that a cto packet is being received */ xcpCtoRxInProgress = BLT_TRUE; } } } else { /* store the next packet byte */ if (UartReceiveByte(&xcpCtoReqPacket[xcpCtoRxLength+1]) == BLT_TRUE) { /* increment the packet data count */ xcpCtoRxLength++; /* check to see if the entire packet was received */ if (xcpCtoRxLength == xcpCtoReqPacket[0]) { /* copy the packet data */ CpuMemCopy((blt_int32u)data, (blt_int32u)&xcpCtoReqPacket[1], xcpCtoRxLength); /* done with cto packet reception */ xcpCtoRxInProgress = BLT_FALSE; /* set the packet length */ *len = xcpCtoRxLength; /* packet reception complete */ return BLT_TRUE; } } else { /* check packet reception timeout */ if (TimerGet() > (xcpCtoRxStartTime + UART_CTO_RX_PACKET_TIMEOUT_MS)) { /* cancel cto packet reception due to timeout. note that that automaticaly * discards the already received packet bytes, allowing the host to retry. */ xcpCtoRxInProgress = BLT_FALSE; } } } /* packet reception not yet complete */ return BLT_FALSE; } /*** end of UartReceivePacket ***/ /************************************************************************************//** ** \brief Receives a communication interface byte if one is present. ** \param data Pointer to byte where the data is to be stored. ** \return BLT_TRUE if a byte was received, BLT_FALSE otherwise. ** ****************************************************************************************/ static blt_bool UartReceiveByte(blt_int8u *data) { if (XMC_USIC_CH_RXFIFO_IsEmpty(UART_CHANNEL) == 0) { /* retrieve and store the newly received byte */ *data = (blt_int8u)XMC_UART_CH_GetReceivedData(UART_CHANNEL); /* all done */ return BLT_TRUE; } /* still here to no new byte received */ return BLT_FALSE; } /*** end of UartReceiveByte ***/ /************************************************************************************//** ** \brief Transmits a communication interface byte. ** \param data Value of byte that is to be transmitted. ** \return BLT_TRUE if the byte was transmitted, BLT_FALSE otherwise. ** ****************************************************************************************/ static blt_bool UartTransmitByte(blt_int8u data) { blt_int32u timeout; blt_bool result = BLT_TRUE; /* check if tx fifo can accept new data */ if (XMC_USIC_CH_TXFIFO_IsFull(UART_CHANNEL) != 0) { /* tx fifo full. should not happen */ return BLT_FALSE; } /* submit data for transmission */ XMC_UART_CH_Transmit(UART_CHANNEL, data); /* set timeout time to wait for transmit completion. */ timeout = TimerGet() + UART_BYTE_TX_TIMEOUT_MS; /* wait for transmission to be done */ while( (XMC_USIC_CH_TXFIFO_GetEvent(UART_CHANNEL) & XMC_USIC_CH_TXFIFO_EVENT_STANDARD) == 0) { /* keep the watchdog happy */ CopService(); /* break loop upon timeout. this would indicate a hardware failure. */ if (TimerGet() > timeout) { result = BLT_FALSE; break; } } /* reset event */ XMC_USIC_CH_TXFIFO_ClearEvent(UART_CHANNEL, XMC_USIC_CH_TXFIFO_EVENT_STANDARD); /* give the result back to the caller */ return result; } /*** end of UartTransmitByte ***/ #endif /* BOOT_COM_UART_ENABLE > 0 */ /*********************************** end of uart.c *************************************/