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[/] [openrisc/] [trunk/] [rtos/] [rtems/] [c/] [src/] [libchip/] [serial/] [z85c30.c] - Rev 210
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/* * This file contains the console driver chip level routines for the * Zilog z85c30 chip. * * The Zilog Z8530 is also available as: * * + Intel 82530 * + AMD ??? * * COPYRIGHT (c) 1998 by Radstone Technology * * * THIS FILE IS PROVIDED TO YOU, THE USER, "AS IS", WITHOUT WARRANTY OF ANY * KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTY OF FITNESS FOR A PARTICULAR PURPOSE. THE ENTIRE RISK * AS TO THE QUALITY AND PERFORMANCE OF ALL CODE IN THIS FILE IS WITH YOU. * * You are hereby granted permission to use, copy, modify, and distribute * this file, provided that this notice, plus the above copyright notice * and disclaimer, appears in all copies. Radstone Technology will provide * no support for this code. * * COPYRIGHT (c) 1989-1997. * On-Line Applications Research Corporation (OAR). * Copyright assigned to U.S. Government, 1994. * * 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. * * $Id: z85c30.c,v 1.2 2001-09-27 12:01:42 chris Exp $ */ #include <rtems.h> #include <rtems/libio.h> #include <stdlib.h> #include <libchip/serial.h> #include "z85c30_p.h" #include "sersupp.h" /* * Flow control is only supported when using interrupts */ console_flow z85c30_flow_RTSCTS = { z85c30_negate_RTS, /* deviceStopRemoteTx */ z85c30_assert_RTS /* deviceStartRemoteTx */ }; console_flow z85c30_flow_DTRCTS = { z85c30_negate_DTR, /* deviceStopRemoteTx */ z85c30_assert_DTR /* deviceStartRemoteTx */ }; /* * Exported driver function table */ console_fns z85c30_fns = { libchip_serial_default_probe, /* deviceProbe */ z85c30_open, /* deviceFirstOpen */ NULL, /* deviceLastClose */ NULL, /* deviceRead */ z85c30_write_support_int, /* deviceWrite */ z85c30_initialize_interrupts, /* deviceInitialize */ z85c30_write_polled, /* deviceWritePolled */ NULL, /* deviceSetAttributes */ TRUE /* deviceOutputUsesInterrupts */ }; console_fns z85c30_fns_polled = { libchip_serial_default_probe, /* deviceProbe */ z85c30_open, /* deviceFirstOpen */ z85c30_close, /* deviceLastClose */ z85c30_inbyte_nonblocking_polled, /* deviceRead */ z85c30_write_support_polled, /* deviceWrite */ z85c30_init, /* deviceInitialize */ z85c30_write_polled, /* deviceWritePolled */ NULL, /* deviceSetAttributes */ FALSE /* deviceOutputUsesInterrupts */ }; extern void set_vector( rtems_isr_entry, rtems_vector_number, int ); /* * z85c30_initialize_port * * initialize a z85c30 Port */ Z85C30_STATIC void z85c30_initialize_port( int minor ) { unsigned32 ulCtrlPort; unsigned32 ulBaudDivisor; setRegister_f setReg; ulCtrlPort = Console_Port_Tbl[minor].ulCtrlPort1; setReg = Console_Port_Tbl[minor].setRegister; /* * Using register 4 * Set up the clock rate is 16 times the data * rate, 8 bit sync char, 1 stop bit, no parity */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR4, SCC_WR4_1_STOP | SCC_WR4_16_CLOCK ); /* * Set up for 8 bits/character on receive with * receiver disable via register 3 */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR3, SCC_WR3_RX_8_BITS ); /* * Set up for 8 bits/character on transmit * with transmitter disable via register 5 */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR5, SCC_WR5_TX_8_BITS ); /* * Clear misc control bits */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR10, 0x00 ); /* * Setup the source of the receive and xmit * clock as BRG output and the transmit clock * as the output source for TRxC pin via register 11 */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR11, SCC_WR11_OUT_BR_GEN | SCC_WR11_TRXC_OI | SCC_WR11_TX_BR_GEN | SCC_WR11_RX_BR_GEN ); ulBaudDivisor = Z85C30_Baud( (unsigned32) Console_Port_Tbl[minor].ulClock, (unsigned32) Console_Port_Tbl[minor].pDeviceParams ); /* * Setup the lower 8 bits time constants=1E. * If the time constans=1E, then the desire * baud rate will be equilvalent to 9600, via register 12. */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR12, ulBaudDivisor & 0xff ); /* * using register 13 * Setup the upper 8 bits time constant */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR13, (ulBaudDivisor>>8) & 0xff ); /* * Enable the baud rate generator enable with clock from the * SCC's PCLK input via register 14. */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR14, SCC_WR14_BR_EN | SCC_WR14_BR_SRC | SCC_WR14_NULL ); /* * We are only interested in CTS state changes */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR15, SCC_WR15_CTS_IE ); /* * Reset errors */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR0, SCC_WR0_RST_INT ); (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR0, SCC_WR0_ERR_RST ); /* * Enable the receiver via register 3 */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR3, SCC_WR3_RX_8_BITS | SCC_WR3_RX_EN ); /* * Enable the transmitter pins set via register 5. */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR5, SCC_WR5_TX_8_BITS | SCC_WR5_TX_EN ); /* * Disable interrupts */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR1, 0 ); /* * Reset TX CRC */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR0, SCC_WR0_RST_TX_CRC ); /* * Reset interrupts */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR0, SCC_WR0_RST_INT ); } /* * z85c30_open */ Z85C30_STATIC int z85c30_open( int major, int minor, void *arg ) { z85c30_initialize_port(minor); /* * Assert DTR */ if (Console_Port_Tbl[minor].pDeviceFlow !=&z85c30_flow_DTRCTS) { z85c30_assert_DTR(minor); } return(RTEMS_SUCCESSFUL); } /* * z85c30_close */ Z85C30_STATIC int z85c30_close( int major, int minor, void *arg ) { /* * Negate DTR */ if (Console_Port_Tbl[minor].pDeviceFlow !=&z85c30_flow_DTRCTS) { z85c30_negate_DTR(minor); } return(RTEMS_SUCCESSFUL); } /* * z85c30_init */ Z85C30_STATIC void z85c30_init(int minor) { unsigned32 ulCtrlPort; unsigned8 dummy; z85c30_context *pz85c30Context; setRegister_f setReg; getRegister_f getReg; setReg = Console_Port_Tbl[minor].setRegister; getReg = Console_Port_Tbl[minor].getRegister; pz85c30Context = (z85c30_context *)malloc(sizeof(z85c30_context)); Console_Port_Data[minor].pDeviceContext = (void *)pz85c30Context; pz85c30Context->ucModemCtrl = SCC_WR5_TX_8_BITS | SCC_WR5_TX_EN; ulCtrlPort = Console_Port_Tbl[minor].ulCtrlPort1; if ( ulCtrlPort == Console_Port_Tbl[minor].ulCtrlPort2 ) { /* * This is channel A */ /* * Ensure port state machine is reset */ dummy = (*getReg)(ulCtrlPort, SCC_WR0_SEL_RD0); (*setReg)(ulCtrlPort, SCC_WR0_SEL_WR9, SCC_WR9_CH_A_RST); } else { /* * This is channel B */ /* * Ensure port state machine is reset */ dummy = (*getReg)(ulCtrlPort, SCC_WR0_SEL_RD0); (*setReg)(ulCtrlPort, SCC_WR0_SEL_WR9, SCC_WR9_CH_B_RST); } } /* * These routines provide control of the RTS and DTR lines */ /* * z85c30_assert_RTS */ Z85C30_STATIC int z85c30_assert_RTS(int minor) { rtems_interrupt_level Irql; z85c30_context *pz85c30Context; setRegister_f setReg; setReg = Console_Port_Tbl[minor].setRegister; pz85c30Context = (z85c30_context *) Console_Port_Data[minor].pDeviceContext; /* * Assert RTS */ rtems_interrupt_disable(Irql); pz85c30Context->ucModemCtrl|=SCC_WR5_RTS; (*setReg)( Console_Port_Tbl[minor].ulCtrlPort1, SCC_WR0_SEL_WR5, pz85c30Context->ucModemCtrl ); rtems_interrupt_enable(Irql); return 0; } /* * z85c30_negate_RTS */ Z85C30_STATIC int z85c30_negate_RTS(int minor) { rtems_interrupt_level Irql; z85c30_context *pz85c30Context; setRegister_f setReg; setReg = Console_Port_Tbl[minor].setRegister; pz85c30Context = (z85c30_context *) Console_Port_Data[minor].pDeviceContext; /* * Negate RTS */ rtems_interrupt_disable(Irql); pz85c30Context->ucModemCtrl&=~SCC_WR5_RTS; (*setReg)( Console_Port_Tbl[minor].ulCtrlPort1, SCC_WR0_SEL_WR5, pz85c30Context->ucModemCtrl ); rtems_interrupt_enable(Irql); return 0; } /* * These flow control routines utilise a connection from the local DTR * line to the remote CTS line */ /* * z85c30_assert_DTR */ Z85C30_STATIC int z85c30_assert_DTR(int minor) { rtems_interrupt_level Irql; z85c30_context *pz85c30Context; setRegister_f setReg; setReg = Console_Port_Tbl[minor].setRegister; pz85c30Context = (z85c30_context *) Console_Port_Data[minor].pDeviceContext; /* * Assert DTR */ rtems_interrupt_disable(Irql); pz85c30Context->ucModemCtrl|=SCC_WR5_DTR; (*setReg)( Console_Port_Tbl[minor].ulCtrlPort1, SCC_WR0_SEL_WR5, pz85c30Context->ucModemCtrl ); rtems_interrupt_enable(Irql); return 0; } /* * z85c30_negate_DTR */ Z85C30_STATIC int z85c30_negate_DTR(int minor) { rtems_interrupt_level Irql; z85c30_context *pz85c30Context; setRegister_f setReg; setReg = Console_Port_Tbl[minor].setRegister; pz85c30Context = (z85c30_context *) Console_Port_Data[minor].pDeviceContext; /* * Negate DTR */ rtems_interrupt_disable(Irql); pz85c30Context->ucModemCtrl&=~SCC_WR5_DTR; (*setReg)( Console_Port_Tbl[minor].ulCtrlPort1, SCC_WR0_SEL_WR5, pz85c30Context->ucModemCtrl ); rtems_interrupt_enable(Irql); return 0; } /* * z85c30_set_attributes * * This function sets the SCC channel to reflect the requested termios * port settings. */ Z85C30_STATIC int z85c30_set_attributes( int minor, const struct termios *t ) { unsigned32 ulCtrlPort; unsigned32 ulBaudDivisor; unsigned32 wr3; unsigned32 wr4; unsigned32 wr5; int baud_requested; setRegister_f setReg; rtems_interrupt_level Irql; ulCtrlPort = Console_Port_Tbl[minor].ulCtrlPort1; setReg = Console_Port_Tbl[minor].setRegister; /* * Calculate the baud rate divisor */ baud_requested = t->c_cflag & CBAUD; if (!baud_requested) baud_requested = B9600; /* default to 9600 baud */ ulBaudDivisor = Z85C30_Baud( (unsigned32) Console_Port_Tbl[minor].ulClock, (unsigned32) termios_baud_to_number( baud_requested ) ); wr3 = SCC_WR3_RX_EN; wr4 = SCC_WR4_16_CLOCK; wr5 = SCC_WR5_TX_EN; /* * Parity */ if (t->c_cflag & PARENB) { wr4 |= SCC_WR4_PAR_EN; if (!(t->c_cflag & PARODD)) wr4 |= SCC_WR4_PAR_EVEN; } /* * Character Size */ if (t->c_cflag & CSIZE) { switch (t->c_cflag & CSIZE) { case CS5: break; case CS6: wr3 |= SCC_WR3_RX_6_BITS; wr5 |= SCC_WR5_TX_6_BITS; break; case CS7: wr3 |= SCC_WR3_RX_7_BITS; wr5 |= SCC_WR5_TX_7_BITS; break; case CS8: wr3 |= SCC_WR3_RX_8_BITS; wr5 |= SCC_WR5_TX_8_BITS; break; } } else { wr3 |= SCC_WR3_RX_8_BITS; /* default to 9600,8,N,1 */ wr5 |= SCC_WR5_TX_8_BITS; /* default to 9600,8,N,1 */ } /* * Stop Bits */ if (t->c_cflag & CSTOPB) { wr4 |= SCC_WR4_2_STOP; /* 2 stop bits */ } else { wr4 |= SCC_WR4_1_STOP; /* 1 stop bits */ } /* * Now actually set the chip */ rtems_interrupt_disable(Irql); (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR4, wr4 ); (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR3, wr3 ); (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR5, wr5 ); /* * Setup the lower 8 bits time constants=1E. * If the time constans=1E, then the desire * baud rate will be equilvalent to 9600, via register 12. */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR12, ulBaudDivisor & 0xff ); /* * using register 13 * Setup the upper 8 bits time constant */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR13, (ulBaudDivisor>>8) & 0xff ); rtems_interrupt_enable(Irql); return 0; } /* * z85c30_process * * This is the per port ISR handler. */ Z85C30_STATIC void z85c30_process( int minor, unsigned8 ucIntPend ) { unsigned32 ulCtrlPort; volatile unsigned8 z85c30_status; unsigned char cChar; setRegister_f setReg; getRegister_f getReg; ulCtrlPort = Console_Port_Tbl[minor].ulCtrlPort1; setReg = Console_Port_Tbl[minor].setRegister; getReg = Console_Port_Tbl[minor].getRegister; /* * Deal with any received characters */ while (ucIntPend&SCC_RR3_B_RX_IP) { z85c30_status = (*getReg)(ulCtrlPort, SCC_WR0_SEL_RD0); if (!Z85C30_Status_Is_RX_character_available(z85c30_status)) { break; } /* * Return the character read. */ cChar = (*getReg)(ulCtrlPort, SCC_WR0_SEL_RD8); rtems_termios_enqueue_raw_characters( Console_Port_Data[minor].termios_data, &cChar, 1 ); } /* * There could be a race condition here if there is not yet a TX * interrupt pending but the buffer is empty. This condition has * been seen before on other z8530 drivers but has not been seen * with this one. The typical solution is to use "vector includes * status" or to only look at the interrupts actually pending * in RR3. */ while (TRUE) { z85c30_status = (*getReg)(ulCtrlPort, SCC_WR0_SEL_RD0); if (!Z85C30_Status_Is_TX_buffer_empty(z85c30_status)) { /* * We'll get another interrupt when * the transmitter holding reg. becomes * free again and we are clear to send */ break; } #if 0 if (!Z85C30_Status_Is_CTS_asserted(z85c30_status)) { /* * We can't transmit yet */ (*setReg)(ulCtrlPort, SCC_WR0_SEL_WR0, SCC_WR0_RST_TX_INT); /* * The next state change of CTS will wake us up */ break; } #endif rtems_termios_dequeue_characters(Console_Port_Data[minor].termios_data, 1); if (rtems_termios_dequeue_characters( Console_Port_Data[minor].termios_data, 1)) { if (Console_Port_Tbl[minor].pDeviceFlow != &z85c30_flow_RTSCTS) { z85c30_negate_RTS(minor); } Console_Port_Data[minor].bActive = FALSE; z85c30_enable_interrupts(minor, SCC_ENABLE_ALL_INTR_EXCEPT_TX); (*setReg)(ulCtrlPort, SCC_WR0_SEL_WR0, SCC_WR0_RST_TX_INT); break; } } if (ucIntPend & SCC_RR3_B_EXT_IP) { /* * Clear the external status interrupt */ (*setReg)(ulCtrlPort, SCC_WR0_SEL_WR0, SCC_WR0_RST_INT); z85c30_status = (*getReg)(ulCtrlPort, SCC_WR0_SEL_RD0); } /* * Reset interrupts */ (*setReg)(ulCtrlPort, SCC_WR0_SEL_WR0, SCC_WR0_RST_HI_IUS); } /* * z85c30_isr * * This is the ISR handler for each Z8530. */ Z85C30_STATIC rtems_isr z85c30_isr( rtems_vector_number vector ) { int minor; unsigned32 ulCtrlPort; volatile unsigned8 ucIntPend; volatile unsigned8 ucIntPendPort; getRegister_f getReg; for (minor=0;minor<Console_Port_Count;minor++) { if(Console_Port_Tbl[minor].ulIntVector == vector && Console_Port_Tbl[minor].deviceType == SERIAL_Z85C30 ) { ulCtrlPort = Console_Port_Tbl[minor].ulCtrlPort2; getReg = Console_Port_Tbl[minor].getRegister; do { ucIntPend = (*getReg)(ulCtrlPort, SCC_WR0_SEL_RD3); /* * If this is channel A select channel A status */ if (ulCtrlPort == Console_Port_Tbl[minor].ulCtrlPort1) { ucIntPendPort = ucIntPend>>3; ucIntPendPort = ucIntPendPort&=7; } else { ucIntPendPort = ucIntPend &= 7; } if (ucIntPendPort) { z85c30_process(minor, ucIntPendPort); } } while (ucIntPendPort); } } } /* * z85c30_enable_interrupts * * This routine enables the specified interrupts for this minor. */ Z85C30_STATIC void z85c30_enable_interrupts( int minor, int interrupt_mask ) { unsigned32 ulCtrlPort; setRegister_f setReg; ulCtrlPort = Console_Port_Tbl[minor].ulCtrlPort1; setReg = Console_Port_Tbl[minor].setRegister; (*setReg)(ulCtrlPort, SCC_WR0_SEL_WR1, interrupt_mask); } /* * z85c30_initialize_interrupts * * This routine initializes the port to use interrupts. */ Z85C30_STATIC void z85c30_initialize_interrupts( int minor ) { unsigned32 ulCtrlPort1; unsigned32 ulCtrlPort2; setRegister_f setReg; ulCtrlPort1 = Console_Port_Tbl[minor].ulCtrlPort1; ulCtrlPort2 = Console_Port_Tbl[minor].ulCtrlPort2; setReg = Console_Port_Tbl[minor].setRegister; z85c30_init(minor); Console_Port_Data[minor].bActive=FALSE; z85c30_initialize_port( minor ); if (Console_Port_Tbl[minor].pDeviceFlow != &z85c30_flow_RTSCTS) { z85c30_negate_RTS(minor); } set_vector(z85c30_isr, Console_Port_Tbl[minor].ulIntVector, 1); z85c30_enable_interrupts(minor, SCC_ENABLE_ALL_INTR_EXCEPT_TX); (*setReg)(ulCtrlPort1, SCC_WR0_SEL_WR2, 0); /* XXX vector */ (*setReg)(ulCtrlPort1, SCC_WR0_SEL_WR9, SCC_WR9_MIE); /* * Reset interrupts */ (*setReg)(ulCtrlPort1, SCC_WR0_SEL_WR0, SCC_WR0_RST_INT); } /* * z85c30_write_support_int * * Console Termios output entry point. * */ Z85C30_STATIC int z85c30_write_support_int( int minor, const char *buf, int len) { unsigned32 Irql; unsigned32 ulCtrlPort; setRegister_f setReg; ulCtrlPort = Console_Port_Tbl[minor].ulCtrlPort1; setReg = Console_Port_Tbl[minor].setRegister; /* * We are using interrupt driven output and termios only sends us * one character at a time. */ if ( !len ) return 0; /* * Put the character out and enable interrupts if necessary. */ if (Console_Port_Tbl[minor].pDeviceFlow != &z85c30_flow_RTSCTS) { z85c30_assert_RTS(minor); } rtems_interrupt_disable(Irql); if ( Console_Port_Data[minor].bActive == FALSE) { Console_Port_Data[minor].bActive = TRUE; z85c30_enable_interrupts(minor, SCC_ENABLE_ALL_INTR); } (*setReg)(ulCtrlPort, SCC_WR0_SEL_WR8, *buf); rtems_interrupt_enable(Irql); return 1; } /* * z85c30_inbyte_nonblocking_polled * * This routine polls for a character. */ Z85C30_STATIC int z85c30_inbyte_nonblocking_polled( int minor ) { volatile unsigned8 z85c30_status; unsigned32 ulCtrlPort; getRegister_f getReg; ulCtrlPort = Console_Port_Tbl[minor].ulCtrlPort1; getReg = Console_Port_Tbl[minor].getRegister; /* * return -1 if a character is not available. */ z85c30_status = (*getReg)(ulCtrlPort, SCC_WR0_SEL_RD0); if (!Z85C30_Status_Is_RX_character_available(z85c30_status)) { return -1; } /* * Return the character read. */ return (*getReg)(ulCtrlPort, SCC_WR0_SEL_RD8); } /* * z85c30_write_support_polled * * Console Termios output entry point. * */ Z85C30_STATIC int z85c30_write_support_polled( int minor, const char *buf, int len) { int nwrite=0; /* * poll each byte in the string out of the port. */ while (nwrite < len) { z85c30_write_polled(minor, *buf++); nwrite++; } /* * return the number of bytes written. */ return nwrite; } /* * z85c30_write_polled * * This routine transmits a character using polling. */ Z85C30_STATIC void z85c30_write_polled( int minor, char cChar ) { volatile unsigned8 z85c30_status; unsigned32 ulCtrlPort; getRegister_f getReg; setRegister_f setReg; ulCtrlPort = Console_Port_Tbl[minor].ulCtrlPort1; getReg = Console_Port_Tbl[minor].getRegister; setReg = Console_Port_Tbl[minor].setRegister; /* * Wait for the Transmit buffer to indicate that it is empty. */ z85c30_status = (*getReg)( ulCtrlPort, SCC_WR0_SEL_RD0 ); while (!Z85C30_Status_Is_TX_buffer_empty(z85c30_status)) { /* * Yield while we wait */ #if 0 if (_System_state_Is_up(_System_state_Get())) { rtems_task_wake_after(RTEMS_YIELD_PROCESSOR); } #endif z85c30_status = (*getReg)(ulCtrlPort, SCC_WR0_SEL_RD0); } /* * Write the character. */ (*setReg)( ulCtrlPort, SCC_WR0_SEL_WR8, cChar ); }
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