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/* * console.c * * This file contains the MVME167 termios console package. Only asynchronous * I/O is supported. * * /dev/tty0 is channel 0, Serial Port 1/Console on the MVME712M. * /dev/tty1 is channel 1, Serial Port 2/TTY01 on the MVME712M. * /dev/tty2 is channel 2, Serial Port 3 on the MVME712M. * /dev/tty3 is channel 3, Serial Port 4 on the MVME712M. * * Normal I/O uses DMA for output, interrupts for input. /dev/console is * fixed to be /dev/tty01, Serial Port 2. Very limited support is provided * for polled I/O. Polled I/O is intended only for running the RTEMS test * suites. In all cases, Serial Port 1/Console is allocated to 167Bug and * is the dedicated debugger port. We configure GDB to use 167Bug for * debugging. When debugging with GDB or 167Bug, do not open /dev/tty00. * * Modern I/O chips often contain a number of I/O devices that can operate * almost independently of each other. Typically, in RTEMS, all devices in * an I/O chip are handled by a single device driver, but that need not be * always the case. Each device driver must supply six entry points in the * Device Driver Table: a device initialization function, as well as an open, * close, read, write and a control function. RTEMS assigns a device major * number to each device driver. This major device number is the index of the * device driver entries in the Device Driver Table, and it used to identify * a particular device driver. To distinguish multiple I/O sub-devices within * an I/O chip, RTEMS supports device minor numbers. When a I/O device is * initialized, the major number is supplied to the initialization function. * That function must register each sub-device with a separate name and minor * number (as well as the supplied major number). When an application opens a * device by name, the corresponding major and minor numbers are returned to * the caller to be used in subsequent I/O operations (although these details * are typically hidden within the library functions). * * Such a scheme recognizes that the initialization of the individual * sub-devices is generally not completely independent. For example, the * four serial ports of the CD2401 can be configured almost independently * from each other. One port could be configured to operate in asynchronous * mode with interrupt-driven I/O, while another port could be configured to * operate in HDLC mode with DMA I/O. However, a device reset command will * reset all four channels, and the width of DMA transfers and the number of * retries following bus errors selected applies to all four channels. * Consequently, when initializing one channel, one must be careful not to * destroy the configuration of other channels that are already configured. * * One problem with the RTEMS I/O initialization model is that no information * other than a device major number is passed to the initialization function. * Consequently, the sub-devices must be initialized with some pre-determined * configuration. To change the configuration of a sub-device, it is * necessary to either rewrite the initialization function, or to make a * series of rtems_io_control() calls after initialization. The first * approach is not very elegant. The second approach is acceptable if an * application is simply changing baud rates, parity or other such * asynchronous parameters (as supplied by the termios package). But what if * an application requires one channel to run in HDLC or Bisync mode and * another in async mode? With a single driver per I/O chip approach, the * device driver must support multiple protocols. This is feasible, but it * often means that an application that only does asynchronous I/O now links * in code for other unused protocols, thus wasting precious ROM space. * Worse, it requires that the sub-devices be initialized in some * configuration, and that configuration then changed through a series of * device driver control calls. There is no standard API in RTEMS to switch * a serial line to some synchronous protocol. * * A better approach is to treat each channel as a separate device, each with * its own device device driver. The application then supplies its own device * driver table with only the required protocols (drivers) on each line. The * problem with this approach is that the device drivers are not really * independent, given that the I/O sub-devices within a common chip are not * independent themselves. Consequently, the related device drivers must * share some information. In RTEMS, there is no standard location in which * to share information. * * This driver handles all four channels, i.e. it distinguishes the * sub-devices using minor device numbers. Only asynchronous I/O is * supported. The console is currently fixed to be channel 1 on the CD2401, * which corresponds to the TTY01 port (Serial Port 2) on the MVME712M * Transition Module. * * The CD2401 does either interrupt-driven or DMA I/O; it does not support * polling. In interrupt-driven or DMA I/O modes, interrupts from the CD2401 * are routed to the MC68040, and the processor generates an interrupt * acknowledge cycle directly to the CD2401 to obtain an interrupt vector. * The PCCchip2 supports a pseudo-polling mode in which interrupts from the * CD2401 are not routed to the MC68040, but can be detected by the processor * by reading the appropriate CD2401 registers. In this mode, interrupt * acknowledge cycles must be generated to the CD2401 by reading the * appropriate PCCchip2 registers. * * Interrupts from the four channels cannot be routed independently; either * all channels are used in the pseudo-polling mode, or all channels are used * in interrupt-driven/DMA mode. There is no advantage in using the speudo- * polling mode. Consenquently, this driver performs DMA input and output. * Output is performed directly from the termios raw output buffer, while * input is accumulated into a separate buffer. * * THIS MODULE IS NOT RE-ENTRANT! Simultaneous access to a device from * multiple tasks is likely to cause significant problems! Concurrency * control is implemented in the termios package. * * THE INTERRUPT LEVEL IS SET TO 1 FOR ALL CHANNELS. * If the CD2401 is to be used for high speed synchronous serial I/O, the * interrupt priority might need to be increased. * * ALL INTERRUPT HANDLERS ARE SHARED. * When adding extra device drivers, either rewrite the interrupt handlers * to demultiplex the interrupts, or install separate vectors. Common vectors * are currently used to catch spurious interrupts. We could already have * installed separate vectors for each channel and used the spurious * interrupt handler defined in some other BSPs, but handling spurious * interrupts from the CD2401 in this device driver allows us to record more * information on the source of the interrupts. Furthermore, we have observed * the occasional spurious interrupt from channel 0. We definitely do not * to call a debugger for those. * * All page references are to the MVME166/MVME167/MVME187 Single Board * Computer Programmer's Reference Guide (MVME187PG/D2) with the April * 1993 supplements/addenda (MVME187PG/D2A1). * * Copyright (c) 1998, National Research Council of Canada * * The license and distribution terms for this file may be * found in the file LICENSE in this distribution or at * http://www.OARcorp.com/rtems/license.html. */ #define M167_INIT #include <stdarg.h> #include <stdio.h> #include <termios.h> #include <bsp.h> /* Must be before libio.h */ #include <rtems/libio.h> /* Channel info */ /* static */ volatile struct { void *tty; /* Really a struct rtems_termios_tty * */ int len; /* Record nb of chars being TX'ed */ const char *buf; /* Record where DMA is coming from */ rtems_unsigned32 spur_cnt; /* Nb of spurious ints so far */ rtems_unsigned32 spur_dev; /* Indo on last spurious int */ rtems_unsigned32 buserr_addr; /* Faulting address */ rtems_unsigned32 buserr_type; /* Reason of bus error during DMA */ rtems_unsigned8 own_buf_A; /* If true, buffer A belongs to the driver */ rtems_unsigned8 own_buf_B; /* If true, buffer B belongs to the driver */ rtems_unsigned8 txEmpty; /* If true, the output FIFO is supposed to be empty */ } CD2401_Channel_Info[4]; /* * The number of channels already opened. If zero, enable the interrupts. The * initial value must be 0. If initialized explicitly, the variable ends up * in the .data section. Its value is not re-initialized on system restart. * Furthermore, because the variable is changed, the .data section would not * be ROMable. We thus leave the variable uninitialized, which causes it to * be allocated in the .bss section, and rely on RTEMS to zero the .bss * section on every startup. */ rtems_unsigned8 Init_count; /* Record previous handlers */ rtems_isr_entry Prev_re_isr; /* Previous rx exception isr */ rtems_isr_entry Prev_rx_isr; /* Previous rx isr */ rtems_isr_entry Prev_tx_isr; /* Previous tx isr */ rtems_isr_entry Prev_modem_isr; /* Previous modem/timer isr */ /* Define the following symbol to trace the calls to this driver */ /* #define CD2401_RECORD_DEBUG_INFO */ #include "console-recording.c" /* Utility functions */ void cd2401_udelay( unsigned long delay ); void cd2401_chan_cmd( rtems_unsigned8 channel, rtems_unsigned8 cmd, rtems_unsigned8 wait ); rtems_unsigned16 cd2401_bitrate_divisor( rtems_unsigned32 clkrate, rtems_unsigned32* bitrate ); void cd2401_initialize( void ); void cd2401_interrupts_initialize( rtems_boolean enable ); /* ISRs */ rtems_isr cd2401_modem_isr( rtems_vector_number vector ); rtems_isr cd2401_re_isr( rtems_vector_number vector ); rtems_isr cd2401_rx_isr( rtems_vector_number vector ); rtems_isr cd2401_tx_isr( rtems_vector_number vector ); /* Termios callbacks */ int cd2401_firstOpen( int major, int minor, void *arg ); int cd2401_lastClose( int major, int minor, void *arg ); int cd2401_setAttributes( int minor, const struct termios *t ); int cd2401_startRemoteTx( int minor ); int cd2401_stopRemoteTx( int minor ); int cd2401_write( int minor, const char *buf, int len ); int cd2401_drainOutput( int minor ); int _167Bug_pollRead( int minor ); int _167Bug_pollWrite( int minor, const char *buf, int len ); /* * Utility functions. */ /* * Assumes that clock ticks 1 million times per second. * * MAXIMUM DELAY IS ABOUT 20 ms * * Input parameters: * delay: Number of microseconds to delay. * * Output parameters: NONE * * Return values: NONE */ void cd2401_udelay ( unsigned long delay ) { unsigned long i = 20000; /* In case clock is off */ rtems_interval ticks_per_second, start_ticks, end_ticks, current_ticks; rtems_clock_get( RTEMS_CLOCK_GET_TICKS_PER_SECOND, &ticks_per_second ); rtems_clock_get( RTEMS_CLOCK_GET_TICKS_SINCE_BOOT, &start_ticks ); end_ticks = start_ticks + delay; do { rtems_clock_get(RTEMS_CLOCK_GET_TICKS_SINCE_BOOT, ¤t_ticks); } while ( --i && (current_ticks <= end_ticks) ); CD2401_RECORD_DELAY_INFO(( start_ticks, end_ticks, current_ticks, i )); } /* * cd2401_chan_cmd * * Sends a CCR command to the specified channel. Waits for any unfinished * previous command to complete, then sends the specified command. Optionally * wait for the current command to finish before returning. * * Input parameters: * channel - CD2401 channel number * cmd - command byte * wait - if non-zero, wait for specified command to complete before * returning. * * Output parameters: NONE * * Return values: NONE */ void cd2401_chan_cmd( rtems_unsigned8 channel, rtems_unsigned8 cmd, rtems_unsigned8 wait ) { if ( channel < 4 ) { cd2401->car = channel; /* Select channel */ while ( cd2401->ccr != 0 ); /* Wait for completion of any previous command */ cd2401->ccr = cmd; /* Send command */ if ( wait ) while( cd2401->ccr != 0 );/* Wait for completion */ } else { /* This may not be the best error message */ rtems_fatal_error_occurred( RTEMS_INVALID_NUMBER ); } } /* * cd2401_bitrate_divisor * * Compute the divisor and clock source to use to obtain the desired bitrate. * * Input parameters: * clkrate - system clock rate (CLK input frequency) * bitrate - the desired bitrate * * Output parameters: * bitrate - The actual bitrate achievable, to the nearest bps. * * Return values: * Returns divisor in lower byte and clock source in upper byte for the * specified bitrate. */ rtems_unsigned16 cd2401_bitrate_divisor( rtems_unsigned32 clkrate, rtems_unsigned32* bitrate ) { rtems_unsigned32 divisor; rtems_unsigned16 clksource; divisor = *bitrate << 3; /* temporary; multiply by 8 for CLK/8 */ divisor = (clkrate + (divisor>>1)) / divisor; /* divisor for clk0 (CLK/8) */ /* Use highest speed clock source for best precision - try from clk0 to clk4: */ for( clksource = 0; clksource < 0x0400 && divisor > 0x100; clksource += 0x0100 ) divisor >>= 2; divisor--; /* adjustment, see specs */ if( divisor < 1 ) divisor = 1; else if( divisor > 0xFF ) divisor = 0xFF; *bitrate = clkrate / (1 << ((clksource >> 7)+3)) / (divisor+1); return( clksource | divisor ); } /* * cd2401_initialize * * Initializes the CD2401 device. Individual channels on the chip are left in * their default reset state, and should be subsequently configured. * * Input parameters: NONE * * Output parameters: NONE * * Return values: NONE */ void cd2401_initialize( void ) { int i; for ( i = 3; i >= 0; i-- ) { CD2401_Channel_Info[i].tty = NULL; CD2401_Channel_Info[i].len = 0; CD2401_Channel_Info[i].buf = NULL; CD2401_Channel_Info[i].spur_cnt = 0; CD2401_Channel_Info[i].spur_dev = 0; CD2401_Channel_Info[i].buserr_type = 0; CD2401_Channel_Info[i].buserr_addr = 0; CD2401_Channel_Info[i].own_buf_A = TRUE; CD2401_Channel_Info[i].own_buf_B = TRUE; CD2401_Channel_Info[i].txEmpty = TRUE; } /* * Normally, do a device reset here. If we do it, we will most likely clober * the port settings for 167Bug on channel 0. So we just shut up all the * ports by disabling their interrupts. */ #if 0 cd2401->gfrcr = 0; /* So we can detect that device init is done */ cd2401_chan_cmd( 0x10, 0); /* Reset all */ while(cd2401->gfrcr == 0); /* Wait for reset all */ #endif /* * The CL-CD2400/2401 manual (part no 542400-003) states on page 87 that * the LICR "contains the number of the interrupting channel being served. * The channel number is always that of the current acknowledged interrupt." * THE USER MUST PROGRAM CHANNEL NUMBER IN LICR! It is not set automatically * by the hardware, as suggested by the manual. * * The updated manual (part no 542400-007) has the story strait. The CD2401 * automatically initializes the LICR to contain the channel number in bits * 2 and 3. However, these bits are not preserved when the user defined bits * are written. * * The same vector number is used for all four channels. Different vector * numbers could be programmed for each channel, thus avoiding the need to * demultiplex the interrupts in the ISR. */ for ( i = 0; i < 4; i++ ) { cd2401->car = i; /* Select channel */ cd2401->livr = 0x5C; /* Motorola suggested value p. 3-15 */ cd2401->licr = i << 2; /* Don't rely on reset value */ cd2401->ier = 0; /* Disable all interrupts */ } /* * The content of the CD2401 xpilr registers must match the A7-A0 addresses * generated by the PCCchip2 during interrupt acknowledge cycles in order * for the CD2401 to recognize the IACK cycle and clear its interrupt * request. */ cd2401->mpilr = 0x01; /* Match pccchip2->modem_piack p. 3-27 */ cd2401->tpilr = 0x02; /* Match pccchip2->tx_piack p. 3-28 */ cd2401->rpilr = 0x03; /* Match pccchip2->rx_piack p. 3-29 */ /* Global CD2401 registers */ cd2401->dmr = 0; /* 16-bit DMA transfers when possible */ cd2401->bercnt = 0; /* Do not retry DMA upon bus errors */ /* * Setup timer prescaler period, which clocks timers 1 and 2 (or rx timeout * and tx delay). The prescaler is clocked by the system clock) / 2048. The * register must be in the range 0x0A..0xFF, ie. a rescaler period range of * about 1ms..26ms for a nominal system clock rate of 20MHz. */ cd2401->tpr = 0x0A; /* Same value as 167Bug */ } /* * cd2401_interrupts_initialize * * This routine enables or disables the CD2401 interrupts to the MC68040. * Interrupts cannot be enabled/disabled on a per-channel basis. * * Input parameters: * enable - if true, enable the interrupts, else disable them. * * Output parameters: NONE * * Return values: NONE * * THE FIRST CD2401 CHANNEL OPENED SHOULD ENABLE INTERRUPTS. * THE LAST CD2401 CHANNEL CLOSED SHOULD DISABLE INTERRUPTS. */ void cd2401_interrupts_initialize( rtems_boolean enable ) { if ( enable ) { /* * Enable interrupts from the CD2401 in the PCCchip2. * During DMA transfers, the MC68040 supplies dirty data during read cycles * from the CD2401 and leaves the data dirty in its data cache if there is * a cache hit. The MC68040 updates the data cache during write cycles from * the CD2401 if there is a cache hit. */ pccchip2->SCC_error = 0x01; pccchip2->SCC_modem_int_ctl = 0x10 | CD2401_INT_LEVEL; pccchip2->SCC_tx_int_ctl = 0x10 | CD2401_INT_LEVEL; pccchip2->SCC_rx_int_ctl = 0x50 | CD2401_INT_LEVEL; pccchip2->gen_control |= 0x02; /* Enable pccchip2 interrupts */ } else { /* Disable interrupts */ pccchip2->SCC_modem_int_ctl &= 0xEF; pccchip2->SCC_tx_int_ctl &= 0xEF; pccchip2->SCC_rx_int_ctl &= 0xEF; } } /* ISRs */ /* * cd2401_modem_isr * * Modem/timer interrupt (group 1) from CD2401. These are not used, and not * expected. Record as spurious and clear. * * Input parameters: * vector - vector number * * Output parameters: NONE * * Return values: NONE */ rtems_isr cd2401_modem_isr( rtems_vector_number vector ) { rtems_unsigned8 ch; /* Get interrupting channel ID */ ch = cd2401->licr >> 2; /* Record interrupt info for debugging */ CD2401_Channel_Info[ch].spur_dev = (vector << 24) | (cd2401->stk << 16) | (cd2401->mir << 8) | cd2401->misr; CD2401_Channel_Info[ch].spur_cnt++; cd2401->meoir = 0; /* EOI */ CD2401_RECORD_MODEM_ISR_SPURIOUS_INFO(( ch, CD2401_Channel_Info[ch].spur_dev, CD2401_Channel_Info[ch].spur_cnt )); } /* * cd2401_re_isr * * RX exception interrupt (group 3, receiver exception) from CD2401. These are * not used, and not expected. Record as spurious and clear. * * FIX THIS ISR TO DETECT BREAK CONDITIONS AND RAISE SIGINT * * Input parameters: * vector - vector number * * Output parameters: NONE * * Return values: NONE */ rtems_isr cd2401_re_isr( rtems_vector_number vector ) { rtems_unsigned8 ch; /* Get interrupting channel ID */ ch = cd2401->licr >> 2; /* Record interrupt info for debugging */ CD2401_Channel_Info[ch].spur_dev = (vector << 24) | (cd2401->stk << 16) | (cd2401->rir << 8) | cd2401->u5.b.risrl; CD2401_Channel_Info[ch].spur_cnt++; if ( cd2401->u5.b.risrl & 0x80 ) /* Timeout interrupt? */ cd2401->ier &= 0xDF; /* Disable rx timeout interrupt */ cd2401->reoir = 0x08; /* EOI; exception char not read */ CD2401_RECORD_RE_ISR_SPURIOUS_INFO(( ch, CD2401_Channel_Info[ch].spur_dev, CD2401_Channel_Info[ch].spur_cnt )); } /* * cd2401_rx_isr * * RX interrupt (group 3, receiver data) from CD2401. * * Input parameters: * vector - vector number * * Output parameters: NONE * * Return values: NONE */ rtems_isr cd2401_rx_isr( rtems_vector_number vector ) { char c; rtems_unsigned8 ch, status, nchars, i, total; char buffer[256]; status = cd2401->u5.b.risrl; ch = cd2401->licr >> 2; /* Has this channel been initialized or is it a condition we ignore? */ if ( CD2401_Channel_Info[ch].tty && !status ) { /* Normal Rx Int, read chars, enqueue them, and issue EOI */ total = nchars = cd2401->rfoc; /* Nb of chars to retrieve from rx FIFO */ i = 0; while ( nchars-- > 0 ) { c = (char)cd2401->dr; /* Next char in rx FIFO */ rtems_termios_enqueue_raw_characters( CD2401_Channel_Info[ch].tty ,&c, 1 ); buffer[i++] = c; } cd2401->reoir = 0; /* EOI */ CD2401_RECORD_RX_ISR_INFO(( ch, total, buffer )); } else { /* No, record as spurious interrupt */ CD2401_Channel_Info[ch].spur_dev = (vector << 24) | (cd2401->stk << 16) | (cd2401->rir << 8) | cd2401->u5.b.risrl; CD2401_Channel_Info[ch].spur_cnt++; cd2401->reoir = 0x04; /* EOI - character not read */ CD2401_RECORD_RX_ISR_SPURIOUS_INFO(( ch, status, CD2401_Channel_Info[ch].spur_dev, CD2401_Channel_Info[ch].spur_cnt )); } } /* * cd2401_tx_isr * * TX interrupt (group 2) from CD2401. * * Input parameters: * vector - vector number * * Output parameters: NONE * * Return values: NONE */ rtems_isr cd2401_tx_isr( rtems_vector_number vector ) { rtems_unsigned8 ch, status, buserr, initial_ier, final_ier; status = cd2401->tisr; ch = cd2401->licr >> 2; initial_ier = cd2401->ier; /* Has this channel been initialized? */ if ( !CD2401_Channel_Info[ch].tty ) { /* No, record as spurious interrupt */ CD2401_Channel_Info[ch].spur_dev = (vector << 24) | (cd2401->stk << 16) | (cd2401->tir << 8) | cd2401->tisr; CD2401_Channel_Info[ch].spur_cnt++; final_ier = cd2401->ier &= 0xFC;/* Shut up, whoever you are */ cd2401->teoir = 0x88; /* EOI - Terminate buffer and no transfer */ CD2401_RECORD_TX_ISR_SPURIOUS_INFO(( ch, status, initial_ier, final_ier, CD2401_Channel_Info[ch].spur_dev, CD2401_Channel_Info[ch].spur_cnt )); return; } if ( status & 0x80 ) { /* * Bus error occurred during DMA transfer. For now, just record. * Get reason for DMA bus error and clear the report for the next occurrence */ buserr = pccchip2->SCC_error; pccchip2->SCC_error = 0x01; CD2401_Channel_Info[ch].buserr_type = (vector << 24) | (buserr << 16) | (cd2401->tir << 8) | cd2401->tisr; CD2401_Channel_Info[ch].buserr_addr = (((rtems_unsigned32)cd2401->tcbadru) << 16) | cd2401->tcbadrl; cd2401->teoir = 0x80; /* EOI - terminate bad buffer */ CD2401_RECORD_TX_ISR_BUSERR_INFO(( ch, status, initial_ier, buserr, CD2401_Channel_Info[ch].buserr_type, CD2401_Channel_Info[ch].buserr_addr )); return; } if ( status & 0x20 ) { /* DMA done -- Turn off TxD int, turn on TxMpty */ final_ier = cd2401->ier = (cd2401->ier & 0xFE) | 0x02; if( status & 0x08 ) { /* Transmit buffer B was released */ CD2401_Channel_Info[ch].own_buf_B = TRUE; } else { /* Transmit buffer A was released */ CD2401_Channel_Info[ch].own_buf_A = TRUE; } CD2401_RECORD_TX_ISR_INFO(( ch, status, initial_ier, final_ier, CD2401_Channel_Info[ch].txEmpty )); /* This call can result in a call to cd2401_write() */ rtems_termios_dequeue_characters ( CD2401_Channel_Info[ch].tty, CD2401_Channel_Info[ch].len ); cd2401->teoir = 0x08; /* EOI - no data transfered */ } else if ( status & 0x02 ) { /* TxEmpty */ CD2401_Channel_Info[ch].txEmpty = TRUE; final_ier = cd2401->ier &= 0xFD;/* Shut up the interrupts */ cd2401->teoir = 0x08; /* EOI - no data transfered */ CD2401_RECORD_TX_ISR_INFO(( ch, status, initial_ier, final_ier, CD2401_Channel_Info[ch].txEmpty )); } else { /* Why did we get a Tx interrupt? */ CD2401_Channel_Info[ch].spur_dev = (vector << 24) | (cd2401->stk << 16) | (cd2401->tir << 8) | cd2401->tisr; CD2401_Channel_Info[ch].spur_cnt++; cd2401->teoir = 0x08; /* EOI - no data transfered */ CD2401_RECORD_TX_ISR_SPURIOUS_INFO(( ch, status, initial_ier, 0xFF, CD2401_Channel_Info[ch].spur_dev, CD2401_Channel_Info[ch].spur_cnt )); } } /* * termios callbacks */ /* * cd2401_firstOpen * * This is the first time that this minor device (channel) is opened. * Complete the asynchronous initialization. * * Input parameters: * major - device major number * minor - channel number * arg - pointer to a struct rtems_libio_open_close_args_t * * Output parameters: NONE * * Return value: IGNORED */ int cd2401_firstOpen( int major, int minor, void *arg ) { rtems_libio_open_close_args_t *args = arg; rtems_libio_ioctl_args_t newarg; struct termios termios; rtems_status_code sc; rtems_interrupt_level level; rtems_interrupt_disable (level); /* * Set up the line with the specified parameters. The difficulty is that * the line parameters are stored in the struct termios field of a * struct rtems_termios_tty that is not defined in a public header file. * Therefore, we do not have direct access to the termios passed in with * arg. So we make a rtems_termios_ioctl() call to get a pointer to the * termios structure. * * THIS KLUDGE MAY BREAK IN THE FUTURE! * * We could have made a tcgetattr() call if we had our fd. */ newarg.iop = args->iop; newarg.command = RTEMS_IO_GET_ATTRIBUTES; newarg.buffer = &termios; sc = rtems_termios_ioctl (&newarg); if (sc != RTEMS_SUCCESSFUL) rtems_fatal_error_occurred (sc); /* * Turn off hardware flow control. It is a pain with 3-wire cables. * The rtems_termios_ioctl() call below results in a call to * cd2401_setAttributes to initialize the line. The caller will "wait" * on the ttyMutex that it already owns; this is safe in RTEMS. */ termios.c_cflag |= CLOCAL; /* Ignore modem status lines */ newarg.command = RTEMS_IO_SET_ATTRIBUTES; sc = rtems_termios_ioctl (&newarg); if (sc != RTEMS_SUCCESSFUL) rtems_fatal_error_occurred (sc); /* Mark that the channel as initialized */ CD2401_Channel_Info[minor].tty = args->iop->data1; /* If the first of the four channels to open, set up the interrupts */ if ( !Init_count++ ) { /* Install the interrupt handlers */ Prev_re_isr = (rtems_isr_entry) set_vector( cd2401_re_isr, 0x5C, 1 ); Prev_modem_isr = (rtems_isr_entry) set_vector( cd2401_modem_isr, 0x5D, 1 ); Prev_tx_isr = (rtems_isr_entry) set_vector( cd2401_tx_isr, 0x5E, 1 ); Prev_rx_isr = (rtems_isr_entry) set_vector( cd2401_rx_isr, 0x5F, 1 ); cd2401_interrupts_initialize( TRUE ); } CD2401_RECORD_FIRST_OPEN_INFO(( minor, Init_count )); rtems_interrupt_enable (level); /* Return something */ return RTEMS_SUCCESSFUL; } /* * cd2401_lastClose * * There are no more opened file descriptors to this device. Close it down. * * Input parameters: * major - device major number * minor - channel number * arg - pointer to a struct rtems_libio_open_close_args_t */ int cd2401_lastClose( int major, int minor, void *arg ) { rtems_interrupt_level level; rtems_interrupt_disable (level); /* Mark that the channel is no longer is use */ CD2401_Channel_Info[minor].tty = NULL; /* If the last of the four channels to close, disable the interrupts */ if ( !--Init_count ) { cd2401_interrupts_initialize( FALSE ); /* De-install the interrupt handlers */ set_vector( Prev_re_isr, 0x5C, 1 ); set_vector( Prev_modem_isr, 0x5D, 1 ); set_vector( Prev_tx_isr, 0x5E, 1 ); set_vector( Prev_rx_isr, 0x5F, 1 ); } CD2401_RECORD_LAST_CLOSE_INFO(( minor, Init_count )); rtems_interrupt_enable (level); /* return something */ return RTEMS_SUCCESSFUL; } /* * cd2401_setAttributes * * Set up the selected channel of the CD2401 chip for doing asynchronous * I/O with DMA. * * The chip must already have been initialized by cd2401_initialize(). * * This code was written for clarity. The code space it occupies could be * reduced. The code could also be compiled with aggressive optimization * turned on. * * Input parameters: * minor - the selected channel * t - the termios parameters * * Output parameters: NONE * * Return value: IGNORED */ int cd2401_setAttributes( int minor, const struct termios *t ) { rtems_unsigned8 csize, cstopb, parodd, parenb, ignpar, inpck; rtems_unsigned8 hw_flow_ctl, sw_flow_ctl, extra_flow_ctl; rtems_unsigned8 icrnl, igncr, inlcr, brkint, ignbrk, parmrk, istrip; rtems_unsigned8 need_reinitialization = FALSE; rtems_unsigned8 read_enabled; rtems_unsigned16 tx_period, rx_period; rtems_unsigned32 out_baud, in_baud; rtems_interrupt_level level; /* Determine what the line parameters should be */ /* Output baud rate */ switch ( cfgetospeed (t) ) { default: out_baud = 9600; break; case B50: out_baud = 50; break; case B75: out_baud = 75; break; case B110: out_baud = 110; break; case B134: out_baud = 134; break; case B150: out_baud = 150; break; case B200: out_baud = 200; break; case B300: out_baud = 300; break; case B600: out_baud = 600; break; case B1200: out_baud = 1200; break; case B1800: out_baud = 1800; break; case B2400: out_baud = 2400; break; case B4800: out_baud = 4800; break; case B9600: out_baud = 9600; break; case B19200: out_baud = 19200; break; case B38400: out_baud = 38400; break; case B57600: out_baud = 57600; break; case B115200: out_baud = 115200; break; case B230400: out_baud = 230400; break; case B460800: out_baud = 460800; break; } /* Input baud rate */ switch ( cfgetispeed (t) ) { default: in_baud = out_baud; break; case B50: in_baud = 50; break; case B75: in_baud = 75; break; case B110: in_baud = 110; break; case B134: in_baud = 134; break; case B150: in_baud = 150; break; case B200: in_baud = 200; break; case B300: in_baud = 300; break; case B600: in_baud = 600; break; case B1200: in_baud = 1200; break; case B1800: in_baud = 1800; break; case B2400: in_baud = 2400; break; case B4800: in_baud = 4800; break; case B9600: in_baud = 9600; break; case B19200: in_baud = 19200; break; case B38400: in_baud = 38400; break; case B57600: in_baud = 57600; break; case B115200: in_baud = 115200; break; case B230400: in_baud = 230400; break; case B460800: in_baud = 460800; break; } /* Number of bits per char */ switch ( t->c_cflag & CSIZE ) { case CS5: csize = 0x04; break; case CS6: csize = 0x05; break; case CS7: csize = 0x06; break; case CS8: csize = 0x07; break; } /* Parity */ if ( t->c_cflag & PARODD ) parodd = 0x80; /* Odd parity */ else parodd = 0; if ( t->c_cflag & PARENB ) parenb = 0x40; /* Parity enabled on Tx and Rx */ else parenb = 0x00; /* No parity on Tx and Rx */ /* CD2401 IGNPAR and INPCK bits are inverted wrt POSIX standard? */ if ( t->c_iflag & INPCK ) ignpar = 0; /* Check parity on input */ else ignpar = 0x10; /* Do not check parity on input */ if ( t->c_iflag & IGNPAR ) { inpck = 0x03; /* Discard error character */ parmrk = 0; } else { if ( t->c_iflag & PARMRK ) { inpck = 0x01; /* Translate to 0xFF 0x00 <char> */ parmrk = 0x04; } else { inpck = 0x01; /* Translate to 0x00 */ parmrk = 0; } } /* Stop bits */ if ( t->c_cflag & CSTOPB ) cstopb = 0x04; /* Two stop bits */ else cstopb = 0x02; /* One stop bit */ /* Modem flow control */ if ( t->c_cflag & CLOCAL ) hw_flow_ctl = 0x04; /* Always assert RTS before Tx */ else hw_flow_ctl = 0x07; /* Always assert RTS before Tx, wait for CTS and DSR */ /* XON/XOFF Tx flow control */ if ( t->c_iflag & IXON ) { sw_flow_ctl = 0x40; /* Tx in-band flow ctl enabled, wait for XON */ extra_flow_ctl = 0x30; /* Eat XON/XOFF, XON/XOFF in SCHR1, SCHR2 */ } else { sw_flow_ctl = 0; /* Tx in-band flow ctl disabled */ extra_flow_ctl = 0; /* Pass on XON/XOFF */ } /* CL/LF translation */ if ( t->c_iflag & ICRNL ) icrnl = 0x40; /* Map CR to NL on input */ else icrnl = 0; /* Pass on CR */ if ( t->c_iflag & INLCR ) inlcr = 0x20; /* Map NL to CR on input */ else inlcr = 0; /* Pass on NL */ if ( t->c_iflag & IGNCR ) igncr = 0x80; /* CR discarded on input */ else igncr = 0; /* Break handling */ if ( t->c_iflag & IGNBRK ) { ignbrk = 0x10; /* Ignore break on input */ brkint = 0x08; } else { if ( t->c_iflag & BRKINT ) { ignbrk = 0; /* Generate SIGINT (interrupt ) */ brkint = 0; } else { ignbrk = 0; /* Convert to 0x00 */ brkint = 0x08; } } /* Stripping */ if ( t->c_iflag & ISTRIP ) istrip = 0x80; /* Strip to 7 bits */ else istrip = 0; /* Leave as 8 bits */ rx_period = cd2401_bitrate_divisor( 20000000Ul, &in_baud ); tx_period = cd2401_bitrate_divisor( 20000000Ul, &out_baud ); /* * If this is the first time that the line characteristics are set up, then * the device must be re-initialized. * Also check if we need to change anything. It is preferable to not touch * the device if nothing changes. As soon as we touch it, it tends to * glitch. If anything changes, we reprogram all registers. This is * harmless. */ if ( ( CD2401_Channel_Info[minor].tty == 0 ) || ( cd2401->cor1 != (parodd | parenb | ignpar | csize) ) || ( cd2401->cor2 != (sw_flow_ctl | hw_flow_ctl) ) || ( cd2401->cor3 != (extra_flow_ctl | cstopb) ) || ( cd2401->cor6 != (igncr | icrnl | inlcr | ignbrk | brkint | parmrk | inpck) ) || ( cd2401->cor7 != istrip ) || ( cd2401->u1.async.schr1 != t->c_cc[VSTART] ) || ( cd2401->u1.async.schr2 != t->c_cc[VSTOP] ) || ( cd2401->rbpr != (unsigned char)rx_period ) || ( cd2401->rcor != (unsigned char)(rx_period >> 8) ) || ( cd2401->tbpr != (unsigned char)tx_period ) || ( cd2401->tcor != ( (tx_period >> 3) & 0xE0 ) ) ) need_reinitialization = TRUE; /* Write to the ports */ rtems_interrupt_disable (level); cd2401->car = minor; /* Select channel */ read_enabled = cd2401->csr & 0x80 ? TRUE : FALSE; if ( (t->c_cflag & CREAD ? TRUE : FALSE ) != read_enabled ) { /* Read enable status is changing */ need_reinitialization = TRUE; } if ( need_reinitialization ) { /* * Could not find a way to test whether the CD2401 was done transmitting. * The TxEmpty interrupt does not seem to indicate that the FIFO is empty * in DMA mode. So, just wait a while for output to drain. May not be * enough, but it will have to do (should be long enough for 1 char at * 9600 bsp)... */ cd2401_udelay( 2000L ); /* Clear channel */ cd2401_chan_cmd (minor, 0x40, 1); cd2401->car = minor; /* Select channel */ cd2401->cmr = 0x42; /* Interrupt Rx, DMA Tx, async mode */ cd2401->cor1 = parodd | parenb | ignpar | csize; cd2401->cor2 = sw_flow_ctl | hw_flow_ctl; cd2401->cor3 = extra_flow_ctl | cstopb; cd2401->cor4 = 0x0A; /* No DSR/DCD/CTS detect; FIFO threshold of 10 */ cd2401->cor5 = 0x0A; /* No DSR/DCD/CTS detect; DTR threshold of 10 */ cd2401->cor6 = igncr | icrnl | inlcr | ignbrk | brkint | parmrk | inpck; cd2401->cor7 = istrip; /* No LNext; ignore XON/XOFF if frame error; no tx translations */ /* Special char 1: XON character */ cd2401->u1.async.schr1 = t->c_cc[VSTART]; /* special char 2: XOFF character */ cd2401->u1.async.schr2 = t->c_cc[VSTOP]; /* * Special chars 3 and 4, char range, LNext, RFAR[1..4] and CRC * are unused, left as is. */ /* Set baudrates for receiver and transmitter */ cd2401->rbpr = (unsigned char)rx_period; cd2401->rcor = (unsigned char)(rx_period >> 8); /* no DPLL */ cd2401->tbpr = (unsigned char)tx_period; cd2401->tcor = (tx_period >> 3) & 0xE0; /* no x1 ext clk, no loopback */ /* Timeout for 4 chars at 9600, 8 bits per char, 1 stop bit */ cd2401->u2.w.rtpr = 0x04; /* NEED TO LOOK AT THIS LINE! */ if ( t->c_cflag & CREAD ) { /* Re-initialize channel, enable rx and tx */ cd2401_chan_cmd (minor, 0x2A, 1); /* Enable rx data ints */ cd2401->ier = 0x08; } else { /* Re-initialize channel, enable tx, disable rx */ cd2401_chan_cmd (minor, 0x29, 1); } } CD2401_RECORD_SET_ATTRIBUTES_INFO(( minor, need_reinitialization, csize, cstopb, parodd, parenb, ignpar, inpck, hw_flow_ctl, sw_flow_ctl, extra_flow_ctl, icrnl, igncr, inlcr, brkint, ignbrk, parmrk, istrip, tx_period, rx_period, out_baud, in_baud )); rtems_interrupt_enable (level); /* * Looks like the CD2401 needs time to settle after initialization. Give it * 10 ms. I don't really believe it, but if output resumes to quickly after * this call, the first few characters are not right. */ if ( need_reinitialization ) cd2401_udelay( 10000L ); /* Return something */ return RTEMS_SUCCESSFUL; } /* * cd2401_startRemoreTx * * Defined as a callback, but it would appear that it is never called. The * POSIX standard states that when the tcflow() function is called with the * TCION action, the system wall transmit a START character. Presumably, * tcflow() is called internally when IXOFF is set in the termios c_iflag * field when the input buffer can accomodate enough characters. It should * probably be called from fillBufferQueue(). Clearly, the function is also * explicitly callable by user code. The action is clearly to send the START * character, regardless of whether START/STOP flow control is in effect. * * Input parameters: * minor - selected channel * * Output parameters: NONE * * Return value: IGNORED * * PROPER START CHARACTER MUST BE PROGRAMMED IN SCHR1. */ int cd2401_startRemoteTx( int minor ) { rtems_interrupt_level level; rtems_interrupt_disable (level); cd2401->car = minor; /* Select channel */ cd2401->stcr = 0x01; /* Send SCHR1 ahead of chars in FIFO */ CD2401_RECORD_START_REMOTE_TX_INFO(( minor )); rtems_interrupt_enable (level); /* Return something */ return RTEMS_SUCCESSFUL; } /* * cd2401_stopRemoteTx * * Defined as a callback, but it would appear that it is never called. The * POSIX standard states that when the tcflow() function is called with the * TCIOFF function, the system wall transmit a STOP character. Presumably, * tcflow() is called internally when IXOFF is set in the termios c_iflag * field as the input buffer is about to overflow. It should probably be * called from rtems_termios_enqueue_raw_characters(). Clearly, the function * is also explicitly callable by user code. The action is clearly to send * the STOP character, regardless of whether START/STOP flow control is in * effect. * * Input parameters: * minor - selected channel * * Output parameters: NONE * * Return value: IGNORED * * PROPER STOP CHARACTER MUST BE PROGRAMMED IN SCHR2. */ int cd2401_stopRemoteTx( int minor ) { rtems_interrupt_level level; rtems_interrupt_disable (level); cd2401->car = minor; /* Select channel */ cd2401->stcr = 0x02; /* Send SCHR2 ahead of chars in FIFO */ CD2401_RECORD_STOP_REMOTE_TX_INFO(( minor )); rtems_interrupt_enable (level); /* Return something */ return RTEMS_SUCCESSFUL; } /* * cd2401_write * * Initiate DMA output. Termios guarantees that the buffer does not wrap * around, so we can do DMA strait from the supplied buffer. * * Input parameters: * minor - selected channel * buf - output buffer * len - number of chars to output * * Output parameters: NONE * * Return value: IGNORED * * MUST BE EXECUTED WITH THE CD2401 INTERRUPTS DISABLED! * The processor is placed at interrupt level CD2401_INT_LEVEL explicitly in * console_write(). The processor is necessarily at interrupt level 1 in * cd2401_tx_isr(). */ int cd2401_write( int minor, const char *buf, int len ) { cd2401->car = minor; /* Select channel */ if ( (cd2401->dmabsts & 0x08) == 0 ) { /* Next buffer is A. Wait for it to be ours. */ while ( cd2401->atbsts & 0x01 ); CD2401_Channel_Info[minor].own_buf_A = FALSE; CD2401_Channel_Info[minor].len = len; CD2401_Channel_Info[minor].buf = buf; cd2401->atbadru = (rtems_unsigned16)( ( (rtems_unsigned32) buf ) >> 16 ); cd2401->atbadrl = (rtems_unsigned16)( (rtems_unsigned32) buf ); cd2401->atbcnt = len; CD2401_RECORD_WRITE_INFO(( len, buf, 'A' )); cd2401->atbsts = 0x03; /* CD2401 owns buffer, int when empty */ } else { /* Next buffer is B. Wait for it to be ours. */ while ( cd2401->btbsts & 0x01 ); CD2401_Channel_Info[minor].own_buf_B = FALSE; CD2401_Channel_Info[minor].len = len; CD2401_Channel_Info[minor].buf = buf; cd2401->btbadru = (rtems_unsigned16)( ( (rtems_unsigned32) buf ) >> 16 ); cd2401->btbadrl = (rtems_unsigned16)( (rtems_unsigned32) buf ); cd2401->btbcnt = len; CD2401_RECORD_WRITE_INFO(( len, buf, 'B' )); cd2401->btbsts = 0x03; /* CD2401 owns buffer, int when empty */ } /* Nuts -- Need TxD ints */ CD2401_Channel_Info[minor].txEmpty = FALSE; cd2401->ier |= 0x01; /* Return something */ return RTEMS_SUCCESSFUL; } #if 0 /* * cd2401_drainOutput * * Wait for the txEmpty indication on the specified channel. * * Input parameters: * minor - selected channel * * Output parameters: NONE * * Return value: IGNORED * * MUST NOT BE EXECUTED WITH THE CD2401 INTERRUPTS DISABLED! * The txEmpty flag is set by the tx ISR. */ int cd2401_drainOutput( int minor ) { CD2401_RECORD_DRAIN_OUTPUT_INFO(( CD2401_Channel_Info[minor].txEmpty, CD2401_Channel_Info[minor].own_buf_A, CD2401_Channel_Info[minor].own_buf_B )); while( ! (CD2401_Channel_Info[minor].txEmpty && CD2401_Channel_Info[minor].own_buf_A && CD2401_Channel_Info[minor].own_buf_B) ); /* Return something */ return RTEMS_SUCCESSFUL; } #endif /* * _167Bug_pollRead * * Read a character from the 167Bug console, and return it. Return -1 * if there is no character in the input FIFO. * * Input parameters: * minor - selected channel * * Output parameters: NONE * * Return value: char returned as positive signed int * -1 if no character is present in the input FIFO. * * CANNOT BE COMBINED WITH INTERRUPT DRIVEN I/O! * This function is invoked when the device driver is compiled with * CD2401_POLLED_IO set to 1 above. All I/O is then done through 167Bug. */ int _167Bug_pollRead( int minor ) { int char_not_available; unsigned char c; /* Check for a char in the input FIFO */ asm volatile( "movew #0x1, -(%%sp) /* Code for .INSTAT */ movew %1, -(%%sp) /* Channel */ trap #15 /* Trap to 167Bug */ .short 0x60 /* Code for .REDIR */ move %%cc, %0 /* Get condition codes */ andil #4, %0" /* Keep the Zero bit */ : "=d" (char_not_available) : "d" (minor): "%%cc" ); if (char_not_available) return -1; /* Read the char and return it */ asm volatile( "subq.l #2,%%a7 /* Space for result */ movew #0x0, -(%%sp) /* Code for .INCHR */ movew %1, -(%%sp) /* Channel */ trap #15 /* Trap to 167 Bug */ .short 0x60 /* Code for .REDIR */ moveb (%%a7)+, %0" /* Pop char into c */ : "=d" (c) : "d" (minor) ); return (int)c; } /* * _167Bug_pollWrite * * Output buffer through 167Bug. Returns only once every character has been * sent (polled output). * * Input parameters: * minor - selected channel * buf - output buffer * len - number of chars to output * * Output parameters: NONE * * Return value: IGNORED * * CANNOT BE COMBINED WITH INTERRUPT DRIVEN I/O! * This function is invoked when the device driver is compiled with * CD2401_POLLED_IO set to 1 above. All I/O is then done through 167Bug. */ int _167Bug_pollWrite( int minor, const char *buf, int len ) { const char *endbuf = buf + len; asm volatile( "pea (%0) /* endbuf */ pea (%1) /* buf */ movew #0x21, -(%%sp) /* Code for .OUTSTR */ movew %2, -(%%sp) /* Channel */ trap #15 /* Trap to 167Bug */ .short 0x60" /* Code for .REDIR */ :: "a" (endbuf), "a" (buf), "d" (minor) ); /* Return something */ return RTEMS_SUCCESSFUL; } /* * Print functions: prototyped in bsp.h * Debug printing on Channel 1 */ void printk( char *fmt, ... ) { va_list ap; /* points to each unnamed argument in turn */ static char buf[256]; unsigned int level; _CPU_ISR_Disable(level); va_start(ap, fmt); /* make ap point to 1st unnamed arg */ vsprintf(buf, fmt, ap); /* send output to buffer */ BSP_output_string(buf); /* print buffer -- Channel 1 */ va_end(ap); /* clean up and re-enable interrupts */ _CPU_ISR_Enable(level); } void BSP_output_string( char * buf ) { int len = strlen(buf); rtems_status_code sc; /* The first argument forces a print to Port2 (ttyS1) */ sc = _167Bug_pollWrite(1, buf, len); if (sc != RTEMS_SUCCESSFUL) rtems_fatal_error_occurred (sc); } /* *************** * BOILERPLATE * *************** * * All these functions are prototyped in rtems/c/src/lib/include/console.h. */ /* * Initialize and register the device */ rtems_device_driver console_initialize( rtems_device_major_number major, rtems_device_minor_number minor, void *arg ) { rtems_status_code status; /* * Set up TERMIOS */ rtems_termios_initialize (); /* * Do device-specific initialization */ cd2401_initialize (); /* * Register the devices */ status = rtems_io_register_name ("/dev/tty0", major, 0); if (status != RTEMS_SUCCESSFUL) rtems_fatal_error_occurred (status); status = rtems_io_register_name ("/dev/tty1", major, 1); if (status != RTEMS_SUCCESSFUL) rtems_fatal_error_occurred (status); status = rtems_io_register_name ("/dev/console", major, 1); if (status != RTEMS_SUCCESSFUL) rtems_fatal_error_occurred (status); status = rtems_io_register_name ("/dev/tty2", major, 2); if (status != RTEMS_SUCCESSFUL) rtems_fatal_error_occurred (status); status = rtems_io_register_name ("/dev/tty3", major, 3); if (status != RTEMS_SUCCESSFUL) rtems_fatal_error_occurred (status); return RTEMS_SUCCESSFUL; } /* * Open the device */ rtems_device_driver console_open( rtems_device_major_number major, rtems_device_minor_number minor, void * arg ) { #if CD2401_POLLED_IO /* I/O is limited to 167Bug console. minor is ignored! */ static const rtems_termios_callbacks callbacks = { NULL, /* firstOpen */ NULL, /* lastClose */ _167Bug_pollRead, /* pollRead */ _167Bug_pollWrite, /* write */ NULL, /* setAttributes */ NULL, /* stopRemoteTx */ NULL, /* startRemoteTx */ 0 /* outputUsesInterrupts */ }; #else static const rtems_termios_callbacks callbacks = { cd2401_firstOpen, /* firstOpen */ cd2401_lastClose, /* lastClose */ NULL, /* pollRead */ cd2401_write, /* write */ cd2401_setAttributes, /* setAttributes */ cd2401_stopRemoteTx, /* stopRemoteTx */ cd2401_startRemoteTx, /* startRemoteTx */ 1 /* outputUsesInterrupts */ }; #endif return rtems_termios_open (major, minor, arg, &callbacks); } /* * Close the device */ rtems_device_driver console_close( rtems_device_major_number major, rtems_device_minor_number minor, void * arg ) { return rtems_termios_close (arg); } /* * Read from the device */ rtems_device_driver console_read( rtems_device_major_number major, rtems_device_minor_number minor, void * arg ) { return rtems_termios_read (arg); } /* * Write to the device */ rtems_device_driver console_write( rtems_device_major_number major, rtems_device_minor_number minor, void * arg ) { return rtems_termios_write (arg); } /* * Handle ioctl request. */ rtems_device_driver console_control( rtems_device_major_number major, rtems_device_minor_number minor, void * arg ) { return rtems_termios_ioctl (arg); }
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