FreeCalypso > hg > fc-magnetite
view src/cs/drivers/drv_core/uart/uart.c @ 313:5b1358df7e3c
doc/Handset-configs: L1 and the init code are now fully rebuilt from source
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Sat, 04 Nov 2017 19:40:20 +0000 |
parents | 945cf7f506b2 |
children | beff67c568cf |
line wrap: on
line source
/******************************************************************************* * * UART.C * * This module allows to use the UARTs of chipset 1.5 in interrupt mode for * the Receive side and in polling mode for the Transmit side. * The driver calls a user's function when characters are received. * * (C) Texas Instruments 1999 * ******************************************************************************/ #include "l1sw.cfg" #include "chipset.cfg" #include "board.cfg" #if (OP_L1_STANDALONE == 0) #include "main/sys_types.h" #else #include "sys_types.h" #endif #include "uart/traceswitch.h" #include "uart.h" #include <string.h> #include "memif/mem.h" #if (BOARD != 34) /* * Needed to reset and restart the sleep timer in case of incoming characters. */ #if (OP_L1_STANDALONE == 1) #include "serialswitch_core.h" #else #include "uart/serialswitch.h" #endif extern SYS_BOOL uart_sleep_timer_enabled; #endif #define BUFFER_SIZE (512) /* In bytes. */ #define FIFO_SIZE (64) /* In bytes. */ #define STX 0x02 #define DLE 0x10 /* * TLR is used to program the RX FIFO trigger levels. FCR[7:4] are not used. */ #define RX_FIFO_TRIGGER_LEVEL (12 << 4) /* * 16750 addresses. Registers accessed when LCR[7] = 0. */ #define RHR (0x00) /* Rx buffer register - Read access */ #define THR (0x00) /* Tx holding register - Write access */ #define IER (0x01) /* Interrupt enable register */ /* * 16750 addresses. Registers accessed when LCR[7] = 1. */ #define DLL (0x00) /* Divisor latch (LSB) */ #define DLM (0x01) /* Divisor latch (MSB) */ /* * EFR is accessed when LCR[7:0] = 0xBF. */ #define EFR (0x02) /* Enhanced feature register */ /* * 16750 addresses. Bit 5 of the FCR register is accessed when LCR[7] = 1. */ #define IIR (0x02) /* Interrupt ident. register - Read only */ #define FCR (0x02) /* FIFO control register - Write only */ #define LCR (0x03) /* Line control register */ #define MCR (0x04) /* Modem control register */ #define LSR (0x05) /* Line status register */ #define MSR (0x06) /* Modem status register */ #define TCR (0x06) /* Transmission control register */ #define TLR (0x07) /* Trigger level register */ #define MDR1 (0x08) /* Mode definition register 1 */ #define SCR (0x10) /* Supplementary Control register */ #define SSR (0x11) /* Supplementary Status register */ /* * Supplementary control register. */ #define TX_EMPTY_CTL_IT (0x08) #define RX_CTS_WAKE_UP_ENABLE_BIT (4) /* Use RESET_BIT and SET_BIT macros. */ /* * Enhanced feature register. */ #define ENHANCED_FEATURE_BIT (4) /* Use RESET_BIT and SET_BIT macros. */ /* * Mode definition register 1. */ #define UART_MODE (0x00) #define SIR_MODE (0x01) #define UART_MODE_AUTOBAUDING (0x02) /* Reserved in UART/IrDA. */ #define RESET_DEFAULT_STATE (0x07) #define IR_SLEEP_DISABLED (0x00) #define IR_SLEEP_ENABLED (0x08) #define SIR_TX_WITHOUT_ACREG2 (0x00) /* Reserved in UART/modem. */ #define SIR_TX_WITH_ACREG2 (0x20) /* Reserved in UART/modem. */ #define FRAME_LENGTH_METHOD (0x00) /* Reserved in UART/modem. */ #define EOT_BIT_METHOD (0x80) /* Reserved in UART/modem. */ /* * Supplementary Status Register */ #define TX_FIFO_FULL (0x01) /* * Interrupt enable register. */ #define ERBI (0x01) /* Enable received data available interrupt */ #define ETBEI (0x02) /* Enable transmitter holding register empty interrupt */ #define ELSI (0x04) /* Enable receiver line status interrupt */ #define EDSSI (0x08) /* Enable modem status interrupt */ #define IER_SLEEP (0x10) /* Enable sleep mode */ /* * Modem control register. */ #define MDTR (0x01) /* Data terminal ready. */ #define MRTS (0x02) /* Request to send. */ #define TCR_TLR_BIT (6) /* * Line status register. */ #define DR (0x01) /* Data ready */ #define OE (0x02) /* Overrun error */ #define PE (0x04) /* Parity error */ #define FE (0x08) /* Framing error */ #define BI (0x10) /* Break interrupt */ #define THRE (0x20) /* Transmitter holding register (FIFO empty) */ #define TEMT (0x40) /* Transmitter empty (FIFO and TSR both empty) */ /* * Interrupt identification register. * Bit 0 is set to 0 if an IT is pending. * Bits 1 and 2 are used to identify the IT. */ #define IIR_BITS_USED (0x07) #define IT_NOT_PENDING (0x01) #define RX_DATA (0x04) #define TX_EMPTY (0x02) #define MODEM_STATUS (0x00) /* * Line control register. */ #define WLS_5 (0x00) /* Word length: 5 bits */ #define WLS_6 (0x01) /* Word length: 6 bits */ #define WLS_7 (0x02) /* Word length: 7 bits */ #define WLS_8 (0x03) /* Word length: 8 bits */ #define STB (0x04) /* Number of stop bits: 0: 1, 1: 1,5 or 2 */ #define PEN (0x08) /* Parity enable */ #define EPS (0x10) /* Even parity select */ #define BREAK_CONTROL (0x40) /* Enable a break condition */ #define DLAB (0x80) /* Divisor latch access bit */ #define DIV_EN_BIT (7) /* * FIFO control register. */ #define FIFO_ENABLE (0x01) #define RX_FIFO_RESET (0x02) #define TX_FIFO_RESET (0x04) /* * These macros allow to read and write a UART register. */ #define READ_UART_REGISTER(UART,REG) \ *((volatile SYS_UWORD8 *) ((UART)->base_address + (REG))) #define WRITE_UART_REGISTER(UART,REG,VALUE) \ *((volatile SYS_UWORD8 *) ((UART)->base_address + (REG))) = (VALUE) #define RESET_BIT(UART,REG,BIT) \ (WRITE_UART_REGISTER ( \ UART, REG, READ_UART_REGISTER (UART, REG) & ~(1 << (BIT)))) #define SET_BIT(UART,REG,BIT) \ (WRITE_UART_REGISTER ( \ UART, REG, READ_UART_REGISTER (UART, REG) | (1 << (BIT)))) /* * These macros allow to enable or disable the wake-up interrupt. */ #define ENABLE_WAKEUP_INTERRUPT(UART) \ SET_BIT(UART, SCR, RX_CTS_WAKE_UP_ENABLE_BIT); #define DISABLE_WAKEUP_INTERRUPT(UART) \ RESET_BIT(UART, SCR, RX_CTS_WAKE_UP_ENABLE_BIT); /* * This macro allows to know if the RX buffer is full. It must be called only * from the RX interrupt handler. If it is called from the application, the * rx_in pointer may be updated if a RX interrupt occurs. */ #define RX_BUFFER_FULL(UART) \ (((UART)->rx_in == (UART)->rx_out - 1) || \ ((UART)->rx_in == (UART)->rx_out + BUFFER_SIZE - 1)) /* * This allows monitor the last 32 inbound buffers gotten from the RX FIFO. */ //#define UART_RX_BUFFER_DUMP #ifdef UART_RX_BUFFER_DUMP struct { char rx_buffer[(BUFFER_SIZE + 1) << 5]; char *rx_in; int errors_count; int wrong_interrupt_status; } uart_rx_buffer_dump = {0}; #endif typedef struct s_uart { SYS_UWORD32 base_address; /* * Buffers management. */ char rx_buffer[BUFFER_SIZE + 1]; char *rx_in; char *rx_out; void (*callback_function) (void); /* * Errors counters. */ SYS_UWORD32 framing_error; SYS_UWORD32 parity_error; SYS_UWORD32 overrun_error; /* * Framing flags. */ SYS_BOOL dle_detected; SYS_BOOL inframe; SYS_BOOL encapsulation_flag; unsigned char frame_length; } t_uart; static t_uart uart_parameter[NUMBER_OF_TR_UART]; static const SYS_UWORD32 base_address[NUMBER_OF_TR_UART] = { MEM_UART_IRDA, MEM_UART_MODEM #if (CHIPSET == 12) , MEM_UART_MODEM2 #endif }; /* * DLL (LSB) and DLH (MSB) registers values using the 13 MHz clock. */ static const SYS_UWORD8 dll[] = { 2, /* 406250 baud. */ 7, /* 115200 baud. */ 14, /* 57600 baud. */ 21, /* 38400 baud. */ 24, /* 33900 baud. */ 28, /* 28800 baud. */ 42, /* 19200 baud. */ 56, /* 14400 baud. */ 84, /* 9600 baud. */ 169, /* 4800 baud. */ 83, /* 2400 baud. */ 165, /* 1200 baud. */ 74, /* 600 baud. */ 148, /* 300 baud. */ 40, /* 150 baud. */ 81 /* 75 baud. */ }; static const SYS_UWORD8 dlh[] = { 0, /* 406250 baud. */ 0, /* 115200 baud. */ 0, /* 57600 baud. */ 0, /* 38400 baud. */ 0, /* 33900 baud. */ 0, /* 28800 baud. */ 0, /* 19200 baud. */ 0, /* 14400 baud. */ 0, /* 9600 baud. */ 0, /* 4800 baud. */ 1, /* 2400 baud. */ 2, /* 1200 baud. */ 5, /* 600 baud. */ 10, /* 300 baud. */ 21, /* 150 baud. */ 42 /* 75 baud. */ }; /******************************************************************************* * * read_rx_fifo * * Purpose : Check the bytes written into the RX FIFO. Characters are not * written in the RX buffer if it is full. The HISR is called if * enough characters are received. * * Arguments: In : uart: pointer on UART structure. * Out: none * * Returns : none * ******************************************************************************/ static void read_rx_fifo (t_uart *uart) { volatile SYS_UWORD8 status; int error_detected; SYS_UWORD8 char_received; #if (BOARD != 34) /* * Since new characters have been received, the sleep timer is reset then * restarted preventing the system to enter deep-sleep for a new period of * time. */ SER_activate_timer_hisr (); uart_sleep_timer_enabled = 1; #endif status = READ_UART_REGISTER (uart, LSR); while (status & DR) { /* While RX FIFO is not empty... */ error_detected = 0; char_received = READ_UART_REGISTER (uart, RHR); /* * Check if an error (overrun, parity, framing or break) is associated with the * received data. If there is an error the byte is not copied into the * RX buffer. */ if (status & (OE | PE | FE | BI)) { if (status & PE) uart->parity_error++; if (status & FE) uart->framing_error++; if (status & OE) uart->overrun_error++; error_detected = 1; } /* * If there is no error the byte is copied into the RX * buffer if it is not full. */ if (!error_detected && !RX_BUFFER_FULL (uart)) { *(uart->rx_in++) = char_received; if (uart->rx_in == &(uart->rx_buffer[0]) + BUFFER_SIZE + 1) uart->rx_in = &(uart->rx_buffer[0]); #ifdef UART_RX_BUFFER_DUMP *(uart_rx_buffer_dump.rx_in)++ = char_received; if (uart_rx_buffer_dump.rx_in == uart_rx_buffer_dump.rx_buffer + sizeof (uart_rx_buffer_dump.rx_buffer)) uart_rx_buffer_dump.rx_in = uart_rx_buffer_dump.rx_buffer; } else { uart_rx_buffer_dump.errors_count++; #endif } status = READ_UART_REGISTER (uart, LSR); } /* * Call the user's function. */ if (uart->callback_function != NULL) (*(uart->callback_function)) (); } /******************************************************************************* * * initialize_uart_sleep * * Purpose : Performs basic UART hardware initialization including sleep mode. * * Arguments: In : uart_id : UART id. * Out: none * * Returns: none * * Warning: Parameters are not verified. * ******************************************************************************/ void initialize_uart_sleep (T_tr_UartId uart_id) { t_uart *uart; int index; SYS_UWORD8 dummy; for (index = 0; index < NUMBER_OF_TR_UART; index++) uart_parameter[index].base_address = base_address[index]; uart = &(uart_parameter[uart_id]); /* * Mask all interrupts causes and disable sleep mode. */ WRITE_UART_REGISTER (uart, IER, 0x00); /* * Reset UART mode configuration. */ WRITE_UART_REGISTER (uart, MDR1, RESET_DEFAULT_STATE); /* * LCR[7:0] = 0xBF to allow to access EFR * EFR[4] = 1 to allow to program IER[4]. */ WRITE_UART_REGISTER (uart, LCR, 0xBF); SET_BIT (uart, EFR, ENHANCED_FEATURE_BIT); WRITE_UART_REGISTER (uart, LCR, 0x83); /* * Enable FIFO and reset them. */ WRITE_UART_REGISTER (uart, FCR, FIFO_ENABLE | RX_FIFO_RESET | TX_FIFO_RESET); /* * Program the baud generator (dummy 115200). */ WRITE_UART_REGISTER (uart, DLL, 0x07); WRITE_UART_REGISTER (uart, DLM, 0x00); /* * LCR[7] = 0 to allow to access IER and RHR - normal mode. */ RESET_BIT (uart, LCR, DIV_EN_BIT); /* * Select UART mode. */ WRITE_UART_REGISTER (uart, MDR1, UART_MODE); /* * Clear Interrupt and check that Rx FIFO is empty. */ dummy = READ_UART_REGISTER (uart, IIR); while (READ_UART_REGISTER (uart, LSR) & DR) dummy = READ_UART_REGISTER (uart, RHR); #if ((CHIPSET != 5) && (CHIPSET != 6)) /* * Enable sleep mode. */ WRITE_UART_REGISTER (uart, IER, IER_SLEEP); #endif } /******************************************************************************* * * UA_Init * * Purpose : Initializes the module and the UART. * * Arguments: In : uart_id : UART id. * baudrate: baud rate selected. * callback: user's function called characters are received. * Out: none * * Returns: none * * Warning: Parameters are not verified. * ******************************************************************************/ void UA_Init (T_tr_UartId uart_id, T_tr_Baudrate baudrate, void (callback_function (void))) { t_uart *uart; int index; #ifdef UART_RX_BUFFER_DUMP uart_rx_buffer_dump.rx_in = uart_rx_buffer_dump.rx_buffer; #endif for (index = 0; index < NUMBER_OF_TR_UART; index++) uart_parameter[index].base_address = base_address[index]; uart = &(uart_parameter[uart_id]); uart->rx_in = &(uart->rx_buffer[0]); uart->rx_out = &(uart->rx_buffer[0]); uart->callback_function = callback_function; uart->framing_error = 0; uart->parity_error = 0; uart->overrun_error = 0; uart->dle_detected = 0; uart->inframe = 0; uart->encapsulation_flag = 0; uart->frame_length = 0; /* * Mask all interrupts causes and disable sleep mode. */ WRITE_UART_REGISTER (uart, IER, 0x00); /* * Reset UART mode configuration. */ WRITE_UART_REGISTER (uart, MDR1, RESET_DEFAULT_STATE | IR_SLEEP_DISABLED | SIR_TX_WITHOUT_ACREG2 | FRAME_LENGTH_METHOD); /* * FIFO configuration. * EFR[4] = 1 to allow to program FCR[5:4] and MCR[7:5]. */ WRITE_UART_REGISTER (uart, LCR, 0xBF); SET_BIT (uart, EFR, ENHANCED_FEATURE_BIT); /* * Select the word length, the number of stop bits , the parity and set * LCR[7] (DLAB) to allow to program FCR, DLL and DLM. */ WRITE_UART_REGISTER (uart, LCR, WLS_8 | DLAB); /* * Program the trigger levels. * MCR[6] must be set to 1. */ SET_BIT (uart, MCR, TCR_TLR_BIT); WRITE_UART_REGISTER (uart, TCR, 0x0F); WRITE_UART_REGISTER ( uart, TLR, RX_FIFO_TRIGGER_LEVEL); /* * Program the FIFO control register. Bit 0 must be set when other FCR bits * are written to or they are not programmed. * FCR is a write-only register. It will not be modified. */ WRITE_UART_REGISTER (uart, FCR, FIFO_ENABLE | RX_FIFO_RESET | /* self cleared */ TX_FIFO_RESET); /* self cleared */ /* * Program the baud generator. */ WRITE_UART_REGISTER (uart, DLL, dll[baudrate]); WRITE_UART_REGISTER (uart, DLM, dlh[baudrate]); /* * Reset LCR[7] (DLAB) to have access to the RBR, THR and IER registers. */ WRITE_UART_REGISTER (uart, LCR, READ_UART_REGISTER (uart, LCR) & ~DLAB); /* * Select UART mode. */ WRITE_UART_REGISTER (uart, MDR1, UART_MODE | IR_SLEEP_DISABLED | SIR_TX_WITHOUT_ACREG2 | FRAME_LENGTH_METHOD); #if ((CHIPSET == 5) || (CHIPSET == 6)) /* * Unmask RX interrupt */ WRITE_UART_REGISTER (uart, IER, ERBI); #else /* * Unmask RX interrupt and allow sleep mode. */ WRITE_UART_REGISTER (uart, IER, ERBI | IER_SLEEP); #endif } /******************************************************************************* * * UA_ReadNChars * * Purpose : Reads N characters from the RX buffer. * * Arguments: In : uart_id : UART id. * buffer : buffer address where the characters are * copied. * chars_to_read: number of characters to read. * Out: none * * Returns : The number of characters read. * * Warning: Parameters are not verified. * ******************************************************************************/ SYS_UWORD32 UA_ReadNChars (T_tr_UartId uart_id, char *buffer, SYS_UWORD32 chars_to_read) { SYS_UWORD32 chars_in_rx_buffer; SYS_UWORD32 chars_to_copy; SYS_UWORD32 chars_written; char *rx_in; t_uart *uart; uart = &(uart_parameter[uart_id]); /* * A copy of the rx_in pointer is used because it may be updated by * the interrupt handler. * Get the number of bytes available in the RX buffer. */ rx_in = uart->rx_in; if (uart->rx_out <= rx_in) chars_in_rx_buffer = (SYS_UWORD32) (rx_in - uart->rx_out); else chars_in_rx_buffer = (SYS_UWORD32) (rx_in - uart->rx_out + BUFFER_SIZE + 1); /* * No more bytes than those received may be written in the output buffer. */ if (chars_in_rx_buffer >= chars_to_read) chars_to_copy = chars_to_read; else chars_to_copy = chars_in_rx_buffer; chars_written = chars_to_copy; /* * Write the received bytes in the output buffer. */ while (chars_to_copy) { *(buffer++) = *(uart->rx_out++); chars_to_copy--; if (uart->rx_out == &(uart->rx_buffer[0]) + BUFFER_SIZE + 1) uart->rx_out = &(uart->rx_buffer[0]); } return (chars_written); } /******************************************************************************* * * UA_ReadNBytes * * Purpose : Reads and destuff N bytes from the RX buffer. * * Arguments: In : uart_id : UART id. * buffer : buffer address where the bytes are copied. * chars_to_read: number of bytes to read. * Out: eof_detected : indicates if an EOF has been detected. Possible * values are: * - 0: EOF not detected, * - 1: EOF detected and no more bytes left, * - 2: EOF not detected and more bytes left. * Users must invoke this function one more * time in order to get those remaining * bytes, * - 3: EOF detected and more bytes left. Users * must invoke this function one more time * in order to get those remaining bytes. * * Returns : The number of bytes read. * * Warning: Parameters are not verified. * ******************************************************************************/ SYS_UWORD32 UA_ReadNBytes (T_tr_UartId uart_id, char *buffer_p, SYS_UWORD32 bytes_to_read, SYS_BOOL *eof_detected_p) { SYS_UWORD32 bytes_written; SYS_UWORD32 bytes_in_rx_buffer; SYS_UWORD32 bytes_to_process; t_uart *uart_p; char *rx_in_p; bytes_written = 0; uart_p = &(uart_parameter[uart_id]); /* * A copy of the rx_in pointer is used because it may be updated by * the interrupt handler. * Get the number of bytes available in the RX buffer. */ rx_in_p = uart_p->rx_in; if (uart_p->rx_out <= rx_in_p) bytes_in_rx_buffer = (SYS_UWORD32) (rx_in_p - uart_p->rx_out); else bytes_in_rx_buffer = (SYS_UWORD32) (rx_in_p - uart_p->rx_out + BUFFER_SIZE + 1); /* * No more bytes than those received may be processed and then written * in the output buffer. */ if (bytes_in_rx_buffer > bytes_to_read) { bytes_to_process = bytes_to_read; /* * More bytes left. Users must invoke this function one more time * in order to get those remaining bytes. */ *eof_detected_p = 2; } else { bytes_to_process = bytes_in_rx_buffer; /* * No more bytes left. */ *eof_detected_p = 0; } /* * Perform the byte destuffing and then write the "valid" received bytes in * the output buffer. */ while ((bytes_to_process) && !(*eof_detected_p & 0x01)) { switch (*(uart_p->rx_out)) { /* * Current byte is DLE. */ case DLE: if (!uart_p->dle_detected) { /* * No DLE previously detected => * Skip the current byte and set the flag. */ uart_p->dle_detected = 1; uart_p->rx_out++; } else { /* if (uart_p->dle_detected) */ if (uart_p->inframe) { /* * DLE previously detected AND currently inside of a frame => * Copy the current byte in the output buffer, reset the flag * and increase the frame length. */ uart_p->dle_detected = 0; uart_p->frame_length++; *(buffer_p++) = *(uart_p->rx_out++); bytes_written++; } else { /* if (!uart_p->inframe) */ /* * DLE previously detected AND currently outside of a frame => * Skip the current byte. */ uart_p->rx_out++; } } break; /* case DLE */ /* * Current byte is STX. */ case STX: if ((!uart_p->dle_detected) && (uart_p->inframe)) { /* * No DLE previously detected AND currently inside of a frame. */ if (uart_p->frame_length) { /* * Frame length is not zero (End of Frame) => * Skip the current byte and set the flags (EOF). */ uart_p->inframe = 0; uart_p->frame_length = 0; uart_p->rx_out++; /* * More bytes left. */ if ((*eof_detected_p == 0) && (bytes_to_process)) *eof_detected_p = 2; /* * EOF detected. */ (*eof_detected_p)++; } else { /* if (!uart_p->frame_length) */ /* * Frame length is zero (STX followed by another STX = * Synchro lost but start of a new frame) => * Skip the current byte and keep the flag set. */ uart_p->rx_out++; } } else if ((!uart_p->dle_detected) && (!uart_p->inframe)) { /* * No DLE previously detected AND currently outside of a * frame (Start of Frame) => * Skip the current byte and set the flag. */ uart_p->inframe = 1; uart_p->rx_out++; } else if ((uart_p->dle_detected) && (uart_p->inframe)) { /* * DLE previously detected AND currently inside of a frame => * Copy the current byte in the output buffer, reset the flag * and increase the frame length. */ uart_p->dle_detected = 0; uart_p->frame_length++; *(buffer_p++) = *(uart_p->rx_out++); bytes_written++; } else if ((uart_p->dle_detected) && (!uart_p->inframe)) { /* * DLE previously detected AND currently outside of a frame => * Skip the current byte and reset the flag. */ uart_p->dle_detected = 0; uart_p->rx_out++; } break; /* case STX */ /* * Current byte is neither DLE nor STX. */ default: if (uart_p->inframe) { /* * Currently inside of a frame => * Copy the current byte in the output buffer and increase * the frame length. */ uart_p->frame_length++; *(buffer_p++) = *(uart_p->rx_out++); bytes_written++; } else { /* if (!uart_p->inframe) */ /* * Currently outside of a frame => * Skip the current byte. */ uart_p->rx_out++; } break; /* default */ } if (uart_p->rx_out == &(uart_p->rx_buffer[0]) + BUFFER_SIZE + 1) uart_p->rx_out = &(uart_p->rx_buffer[0]); bytes_to_process--; } return (bytes_written); } /******************************************************************************* * * UA_WriteNChars * * Purpose : Writes N characters in the TX FIFO. * * Arguments: In : uart_id : UART id. * buffer : buffer address from which characters are * written. * bytes_to_write: number of bytes to write. * Out: none * * Returns : Number of bytes written. * * Warning: Parameters are not verified. * ******************************************************************************/ SYS_UWORD32 UA_WriteNChars (T_tr_UartId uart_id, char *buffer, SYS_UWORD32 chars_to_write) { SYS_UWORD32 chars_in_tx_fifo; SYS_UWORD32 chars_written; t_uart *uart; chars_written = 0; uart = &(uart_parameter[uart_id]); #if ((CHIPSET != 5) && (CHIPSET != 6)) /* * Disable sleep mode. */ WRITE_UART_REGISTER ( uart, IER, READ_UART_REGISTER (uart, IER) & ~IER_SLEEP); #endif /* * Copy the input buffer to the TX FIFO. * Ulyssse Bug #44: TX FIFO full status bit (SSR[1]) is corrupted during * one period of Bclock => Workaround S/W. * Write in TX FIFO only if FIFO is empty instead of writing in TX FIFO * while FIFO is not full. */ if (READ_UART_REGISTER (uart, LSR) & THRE) { chars_in_tx_fifo = 0; while ((chars_written < chars_to_write) && (chars_in_tx_fifo < FIFO_SIZE)) { WRITE_UART_REGISTER (uart, THR, *(buffer++)); chars_written++; chars_in_tx_fifo++; } } #if ((CHIPSET != 5) && (CHIPSET != 6)) /* * Re-enable sleep mode. */ WRITE_UART_REGISTER ( uart, IER, READ_UART_REGISTER (uart, IER) | IER_SLEEP); #endif return (chars_written); } /******************************************************************************* * * UA_EncapsulateNChars * * Purpose : Writes N characters in the TX FIFO in encapsulating them with 2 * STX bytes (one at the beginning and one at the end). * * Arguments: In : uart_id : UART id. * buffer : buffer address from which characters are * written. * chars_to_write: number of chars to write. * Out: none * * Returns : Number of chars written. * * Warning: Parameters are not verified. * ******************************************************************************/ SYS_UWORD32 UA_EncapsulateNChars (T_tr_UartId uart_id, char *buffer, SYS_UWORD32 chars_to_write) { SYS_UWORD32 chars_written; SYS_UWORD32 chars_in_tx_fifo; t_uart *uart; chars_written = 0; uart = &(uart_parameter[uart_id]); #if ((CHIPSET != 5) && (CHIPSET != 6)) /* * Disable sleep mode. */ WRITE_UART_REGISTER ( uart, IER, READ_UART_REGISTER (uart, IER) & ~IER_SLEEP); #endif /* * Copy the input buffer to the TX FIFO. * Ulyssse Bug #44: TX FIFO full status bit (SSR[1]) is corrupted during * one period of Bclock => Workaround S/W. * Write in TX FIFO only if FIFO is empty instead of writing in TX FIFO * while FIFO is not full. */ if (READ_UART_REGISTER (uart, LSR) & THRE) { chars_in_tx_fifo = 0; /* * Check if the message has been already encapsulated. */ if (!uart->encapsulation_flag) { /* * Write STX in the TX FIFO and set the flag. */ WRITE_UART_REGISTER (uart, THR, STX); chars_in_tx_fifo++; uart->encapsulation_flag = 1; } /* * Keep one char margin in the TX FIFO for the last STX. */ while ((chars_written < chars_to_write) && (chars_in_tx_fifo < (FIFO_SIZE-1))) { WRITE_UART_REGISTER (uart, THR, *(buffer++)); chars_written++; chars_in_tx_fifo++; } /* * Append STX byte at the end if the frame is complete. */ if (chars_written == chars_to_write) { /* * Write STX in the TX FIFO and reset the flag. */ WRITE_UART_REGISTER (uart, THR, STX); uart->encapsulation_flag = 0; } } #if ((CHIPSET != 5) && (CHIPSET != 6)) /* * Re-enable sleep mode. */ WRITE_UART_REGISTER ( uart, IER, READ_UART_REGISTER (uart, IER) | IER_SLEEP); #endif return (chars_written); } /******************************************************************************* * * UA_WriteNBytes * * Purpose : Writes N bytes in the TX FIFO in encapsulating with 2 STX bytes * at the beginning and the end of the frame, and in making byte * stuffing. * * Arguments: In : uart_id : UART id. * buffer : buffer address from which bytes are * written. * bytes_to_write: number of bytes to write. * Out: none * * Returns : Number of bytes written. * * Warning: Parameters are not verified. * ******************************************************************************/ SYS_UWORD32 UA_WriteNBytes (T_tr_UartId uart_id, SYS_UWORD8 *buffer, SYS_UWORD32 bytes_to_write) { SYS_UWORD32 bytes_written; SYS_UWORD32 bytes_in_tx_fifo; t_uart *uart; bytes_written = 0; uart = &(uart_parameter[uart_id]); #if ((CHIPSET != 5) && (CHIPSET != 6)) /* * Disable sleep mode. */ WRITE_UART_REGISTER ( uart, IER, READ_UART_REGISTER (uart, IER) & ~IER_SLEEP); #endif /* * Copy the input buffer to the TX FIFO. * Ulyssse Bug #44: TX FIFO full status bit (SSR[1]) is corrupted during * one period of Bclock => Workaround S/W. * Write in TX FIFO only if FIFO is empty instead of writing in TX FIFO * while FIFO is not full. */ if (READ_UART_REGISTER (uart, LSR) & THRE) { bytes_in_tx_fifo = 0; /* * Check if the message has been already encapsulated. */ if (!uart->encapsulation_flag) { /* * Write STX in the TX FIFO and set the flag. */ WRITE_UART_REGISTER (uart, THR, STX); bytes_in_tx_fifo++; uart->encapsulation_flag = 1; } /* * Keep 2 chars margin in the FIFO, one for the stuffing (if necessary) * and one for the last STX. */ while ((bytes_written < bytes_to_write) && (bytes_in_tx_fifo < (FIFO_SIZE-2))) { /* * Check for STX or DLE in order to perform the stuffing. */ if ((*(buffer) == STX) || (*(buffer) == DLE)) { /* * Write DLE in the TX FIFO. */ WRITE_UART_REGISTER (uart, THR, DLE); bytes_in_tx_fifo++; } WRITE_UART_REGISTER (uart, THR, *(buffer++)); bytes_written++; bytes_in_tx_fifo++; } /* * Append STX byte at the end if the frame is complete. */ if (bytes_written == bytes_to_write) { /* * Write STX in the TX FIFO and reset the flag. */ WRITE_UART_REGISTER (uart, THR, STX); uart->encapsulation_flag = 0; } } #if ((CHIPSET != 5) && (CHIPSET != 6)) /* * Re-enable sleep mode. */ WRITE_UART_REGISTER ( uart, IER, READ_UART_REGISTER (uart, IER) | IER_SLEEP); #endif return (bytes_written); } /******************************************************************************* * * UA_WriteChar * * Purpose : Writes a character in the TX FIFO. * * Arguments: In : uart: UART id. * character * Out: none * * Returns : none * * Warning: Parameters are not verified. * ******************************************************************************/ void UA_WriteChar (T_tr_UartId uart_id, char character) { (void) UA_WriteNChars (uart_id, &character, 1); } /******************************************************************************* * * UA_WriteString * * Purpose : Writes a null terminated string in the TX FIFO. * * Arguments: In : uart_id: UART id. * buffer : buffer address from which characters are written. * Out: none * * Returns : none * * Warning: Parameters are not verified. * ******************************************************************************/ void UA_WriteString (T_tr_UartId uart_id, char *buffer) { (void) UA_WriteNChars (uart_id, buffer, strlen (buffer)); } /******************************************************************************* * * UA_EnterSleep * * Purpose : Checks if UART is ready to enter Deep Sleep. If ready, enables * wake-up interrupt. * * Arguments: In : uart_id : UART id. * Out: none * * Returns: 0 : Deep Sleep is not possible. * >= 1 : Deep Sleep is possible. * * Warning: Parameters are not verified. * ******************************************************************************/ SYS_BOOL UA_EnterSleep (T_tr_UartId uart_id) { t_uart *uart; SYS_BOOL deep_sleep; volatile SYS_UWORD8 status; uart = &(uart_parameter[uart_id]); deep_sleep = 0; /* * Check if RX & TX FIFOs are both empty */ status = READ_UART_REGISTER (uart, LSR); if (!(status & DR) && (status & TEMT)) { #if ((CHIPSET != 5) && (CHIPSET != 6)) /* * Disable sleep mode. */ WRITE_UART_REGISTER ( uart, IER, READ_UART_REGISTER (uart, IER) & ~IER_SLEEP); #endif /* * Mask RX interrupt. */ WRITE_UART_REGISTER ( uart, IER, READ_UART_REGISTER (uart, IER) & ~ERBI); /* * Enable the wake-up interrupt. */ ENABLE_WAKEUP_INTERRUPT (uart); deep_sleep = 1; } return (deep_sleep); } /******************************************************************************* * * UA_WakeUp * * Purpose : Wakes up UART after Deep Sleep. * * Arguments: In : uart_id : UART id. * Out: none * * Returns: none * * Warning: Parameters are not verified. * ******************************************************************************/ void UA_WakeUp (T_tr_UartId uart_id) { t_uart *uart; uart = &(uart_parameter[uart_id]); /* * Disable the wake-up interrupt. */ DISABLE_WAKEUP_INTERRUPT (uart); /* * Unmask RX interrupts. */ WRITE_UART_REGISTER ( uart, IER, READ_UART_REGISTER (uart, IER) | ERBI); #if ((CHIPSET != 5) && (CHIPSET != 6)) /* * Allow sleep mode. */ WRITE_UART_REGISTER ( uart, IER, READ_UART_REGISTER (uart, IER) | IER_SLEEP); #endif } /******************************************************************************* * * UA_InterruptHandler * * Purpose : Interrupt handler. * * Arguments: In : uart_id : origin of interrupt * interrupt_status: source of interrupt * Out: none * * Returns : none * ******************************************************************************/ void UA_InterruptHandler (T_tr_UartId uart_id, SYS_UWORD8 interrupt_status) { t_uart *uart; uart = &(uart_parameter[uart_id]); switch (interrupt_status) { case RX_DATA: read_rx_fifo (uart); break; default: #ifdef UART_RX_BUFFER_DUMP uart_rx_buffer_dump.wrong_interrupt_status++; #endif /* No Processing */ break; } }