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[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [packages/] [hal/] [mn10300/] [stdeval1/] [v2_0/] [src/] [hal_diag.c] - Rev 279

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/*=============================================================================
//
//      hal_diag.c
//
//      HAL diagnostic output code
//
//=============================================================================
//####ECOSGPLCOPYRIGHTBEGIN####
// -------------------------------------------
// This file is part of eCos, the Embedded Configurable Operating System.
// Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc.
//
// eCos is free software; you can redistribute it and/or modify it under
// the terms of the GNU General Public License as published by the Free
// Software Foundation; either version 2 or (at your option) any later version.
//
// eCos is distributed in the hope that it will be useful, but WITHOUT ANY
// WARRANTY; without even the implied warranty of MERCHANTABILITY or
// FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
// for more details.
//
// You should have received a copy of the GNU General Public License along
// with eCos; if not, write to the Free Software Foundation, Inc.,
// 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA.
//
// As a special exception, if other files instantiate templates or use macros
// or inline functions from this file, or you compile this file and link it
// with other works to produce a work based on this file, this file does not
// by itself cause the resulting work to be covered by the GNU General Public
// License. However the source code for this file must still be made available
// in accordance with section (3) of the GNU General Public License.
//
// This exception does not invalidate any other reasons why a work based on
// this file might be covered by the GNU General Public License.
//
// Alternative licenses for eCos may be arranged by contacting Red Hat, Inc.
// at http://sources.redhat.com/ecos/ecos-license/
// -------------------------------------------
//####ECOSGPLCOPYRIGHTEND####
//=============================================================================
//#####DESCRIPTIONBEGIN####
//
// Author(s):   nickg
// Contributors:        nickg
// Date:        1998-03-02
// Purpose:     HAL diagnostic output
// Description: Implementations of HAL diagnostic output support.
//
//####DESCRIPTIONEND####
//
//===========================================================================*/
 
#include <pkgconf/hal.h>
 
#include <cyg/infra/cyg_type.h>          // base types
#include <cyg/infra/cyg_trac.h>         // tracing macros
#include <cyg/infra/cyg_ass.h>          // assertion macros
 
#include <cyg/hal/hal_diag.h>
#include <cyg/hal/hal_intr.h>
 
/*---------------------------------------------------------------------------*/
/* Select default diag channel to use                                        */
 
//#define CYG_KERNEL_DIAG_ROMART
//#define CYG_KERNEL_DIAG_SERIAL1
//#define CYG_KERNEL_DIAG_SERIAL2
//#define CYG_KERNEL_DIAG_GDB
 
#if !defined(CYG_KERNEL_DIAG_SERIAL1) && \
    !defined(CYG_KERNEL_DIAG_SERIAL2) && \
    !defined(CYG_KERNEL_DIAG_ROMART)
 
# if defined(CYG_HAL_MN10300_AM31_STDEVAL1)
 
#  if defined(CYG_HAL_STARTUP_RAM)
 
#   if defined(CYGSEM_HAL_USE_ROM_MONITOR_CygMon)
 
     // If loaded into RAM via CYGMON we diag via
     // serial 2 using GDB protocol
 
#    define CYG_KERNEL_DIAG_SERIAL2
#    define CYG_KERNEL_DIAG_GDB
 
#   elif defined(CYGSEM_HAL_USE_ROM_MONITOR_Sload)
 
     // If loaded into RAM via SLOAD we diag via
     // serial 1
 
#    define CYG_KERNEL_DIAG_SERIAL1
 
#   elif defined(CYGSEM_HAL_USE_ROM_MONITOR_GDB_stubs)
 
     // If loaded into RAM via GDB STUB ROM we diag via
     // serial 1 using GDB protocol
 
#    define CYG_KERNEL_DIAG_SERIAL1
#    define CYG_KERNEL_DIAG_GDB
 
#   endif // defined(CYGSEM_HAL_USE_ROM_MONITOR_CygMon)
 
#  elif defined(CYG_HAL_STARTUP_ROM)
 
    // If we are ROM resident, we diag via serial 1
 
#  define CYG_KERNEL_DIAG_SERIAL1
 
#  endif // defined(CYG_HAL_STARTUP_RAM)
 
# endif // defined(CYG_HAL_MN10300_AM31_STDEVAL1)
 
#endif // if ...
 
/*---------------------------------------------------------------------------*/
// PromICE AI interface
 
#if defined(CYG_HAL_MN10300_STDEVAL1_ROMART) || defined(CYG_KERNEL_DIAG_ROMART)
 
#ifdef CYG_HAL_MN10300_AM31_STDEVAL1
#define PROMICE_AILOC           0x40008000
#endif
 
#define PROMICE_BUS_SIZE        16
#define PROMICE_BURST_SIZE      1
 
#if PROMICE_BUS_SIZE == 16
 
typedef volatile struct
{
    volatile cyg_uint16 zero;
//    cyg_uint16          pad1[PROMICE_BURST_SIZE];
    volatile cyg_uint16 one;
//    cyg_uint16          pad2[PROMICE_BURST_SIZE];
    volatile cyg_uint16 data;
//    cyg_uint16          pad3[PROMICE_BURST_SIZE];
    volatile cyg_uint16 status;
 
} AISTRUCT;
 
#endif
 
AISTRUCT *AI = (AISTRUCT *)PROMICE_AILOC;
 
#define PROMICE_STATUS_TDA      0x01
#define PROMICE_STATUS_HDA      0x02
#define PROMICE_STATUS_OVR      0x04
 
 
void ai_diag_init()
{
    volatile cyg_uint8 junk;
 
    while( AI->status == 0xCC )
        continue;
 
    junk = AI->data;
}
 
static void ai_write_char(cyg_uint8 data)
{
    volatile cyg_uint8 junk;
    int i;
 
    // Wait for tda == 0
    while( (AI->status & PROMICE_STATUS_TDA) == PROMICE_STATUS_TDA )
        continue;
 
    // Send start bit
    junk = AI->one;
 
    for( i = 0; i < 8; i++ )
    {
        // send ls bit of data
        if( (data & 1) == 1 )
            junk = AI->one;
        else
            junk = AI->zero;
 
        // shift down for next bit
        data >>= 1;
    }
 
    // Send stop bit
    junk = AI->one;
 
    // all done
}
 
void ai_diag_write_char(char c)
{
    ai_write_char((cyg_uint8)c);
}
 
void ai_diag_drain() {}
 
void ai_diag_read_char(char *c) { *c = '\n'; }
 
void ai_writes(char *s)
{
    while( *s ) ai_write_char( *s++ );
}
 
void ai_write_hex( cyg_uint32 x)
{
    int i;
    ai_writes("0x");
    for( i = 28; i >=0 ; i-=4 )
    {
        char *d = "0123456789ABCDEF";
        ai_write_char( d[(x>>i)&0xf] );
    }
    ai_write_char(' ');
}
 
#if defined(CYG_KERNEL_DIAG_ROMART)
 
#define hal_diag_init_serial ai_diag_init
#define hal_diag_write_char_serial ai_diag_write_char
#define hal_diag_drain_serial ai_diag_drain
#define hal_diag_read_char_serial ai_diag_read_char
 
#endif
 
#endif
 
/*---------------------------------------------------------------------------*/
// MN10300 Serial line
 
#if defined(CYG_HAL_MN10300_STDEVAL1_SERIAL1) || defined(CYG_KERNEL_DIAG_SERIAL1)
 
// We use serial1 on MN103002
#define SERIAL1_CR       ((volatile cyg_uint16 *)0x34000810)
#define SERIAL1_ICR      ((volatile cyg_uint8 *) 0x34000814)
#define SERIAL1_TXR      ((volatile cyg_uint8 *) 0x34000818)
#define SERIAL1_RXR      ((volatile cyg_uint8 *) 0x34000819)
#define SERIAL1_SR       ((volatile cyg_uint16 *)0x3400081c)
 
// Timer 1 provided baud rate divisor
#define TIMER1_MD       ((volatile cyg_uint8 *)0x34001001)
#define TIMER1_BR       ((volatile cyg_uint8 *)0x34001011)
#define TIMER1_CR       ((volatile cyg_uint8 *)0x34001021)
 
#define PORT3_MD        ((volatile cyg_uint8 *)0x36008025)
 
// Mystery register
#define TMPSCNT         ((volatile cyg_uint8 *)0x34001071)
 
#define SIO1_LSTAT_TRDY  0x20
#define SIO1_LSTAT_RRDY  0x10
 
void hal_diag_init_serial1(void)
{
    // 48 translates to 38400 baud.
    *TIMER1_BR = 48;
 
    // Timer1 sourced from IOCLK
    *TIMER1_MD = 0x80;    
 
    // Mode on PORT3, used for serial line controls.
    *PORT3_MD = 0x01;
 
    // No interrupts for now.
    *SERIAL1_ICR = 0x00;
 
    // Source from timer 1, 8bit chars, enable tx and rx
    *SERIAL1_CR = 0xc084;    
}
 
void hal_diag_write_char_serial1(char c)
{
    register volatile cyg_uint16 *volatile tty_status = SERIAL1_SR;
    register volatile cyg_uint8 *volatile tty_tx = SERIAL1_TXR;
 
    while( (*tty_status & SIO1_LSTAT_TRDY) != 0 ) continue;
 
    *tty_tx = c;
}
 
void hal_diag_drain_serial1(void)
{
    register volatile cyg_uint16 *volatile tty_status = SERIAL1_SR;
 
    while( (*tty_status & SIO1_LSTAT_TRDY) != 0 ) continue;
}
 
void hal_diag_read_char_serial1(char *c)
{
    register volatile cyg_uint16 *volatile tty_status = SERIAL1_SR;
    register volatile cyg_uint8 *volatile tty_rx = SERIAL1_RXR;
 
    while( (*tty_status & SIO1_LSTAT_RRDY) == 0 ) continue;
 
    *c = *tty_rx;
 
    // We must ack the interrupt caused by that read to avoid
    // confusing cygmon.
    HAL_INTERRUPT_ACKNOWLEDGE( CYGNUM_HAL_INTERRUPT_SERIAL_1_RX );
}
 
#if defined(CYG_KERNEL_DIAG_SERIAL1)
 
#define hal_diag_init_serial hal_diag_init_serial1
#define hal_diag_write_char_serial hal_diag_write_char_serial1
#define hal_diag_drain_serial hal_diag_drain_serial1
#define hal_diag_read_char_serial hal_diag_read_char_serial1
 
#endif
 
#endif
 
#if defined(CYG_HAL_MN10300_AM31_STDEVAL1)
 
void led(int x)
{
    *((cyg_uint8 *)0x36008004) = x<<4;
}
 
#endif
 
 
/*---------------------------------------------------------------------------*/
 
#if defined(CYG_HAL_MN10300_STDEVAL1_SERIAL2) || defined(CYG_KERNEL_DIAG_SERIAL2)
 
// We use serial2 on MN103002
#define SERIAL2_CR       ((volatile cyg_uint16 *)0x34000820)
#define SERIAL2_ICR      ((volatile cyg_uint8 *) 0x34000824)
#define SERIAL2_TXR      ((volatile cyg_uint8 *) 0x34000828)
#define SERIAL2_RXR      ((volatile cyg_uint8 *) 0x34000829)
#define SERIAL2_SR       ((volatile cyg_uint8 *)0x3400082c)
#define SERIAL2_TR       ((volatile cyg_uint8 *)0x3400082d)
 
// Timer 2 provided baud rate divisor
#define TIMER2_MD       ((volatile cyg_uint8 *)0x34001002)
#define TIMER2_BR       ((volatile cyg_uint8 *)0x34001012)
#define TIMER2_CR       ((volatile cyg_uint8 *)0x34001022)
 
#define PORT3_MD        ((volatile cyg_uint8 *)0x36008025)
 
// Mystery register
#define TMPSCNT         ((volatile cyg_uint8 *)0x34001071)
 
#define SIO2_LSTAT_TRDY  0x20
#define SIO2_LSTAT_RRDY  0x10
 
void hal_diag_init_serial2(void)
{
#if !defined(CYGSEM_HAL_USE_ROM_MONITOR_CygMon)
 
    // 16 and 22 translate to 38400 baud.
    *TIMER2_BR = 16;
    *SERIAL2_TR = 22;
 
    // Timer2 sourced from IOCLK
    *TIMER2_MD = 0x80;    
 
    // Mode on PORT3, used for serial line controls.
    *PORT3_MD = 0x01;
 
    // No interrupts for now.
    *SERIAL2_ICR = 0x00;
 
    // Source from timer 2, 8bit chars, enable tx and rx
    *SERIAL2_CR = 0xc081;
 
#endif    
}
 
void hal_diag_write_char_serial2(char c)
{
    register volatile cyg_uint8 *volatile tty_status = SERIAL2_SR;
    register volatile cyg_uint8 *volatile tty_tx = SERIAL2_TXR;
 
    while( (*tty_status & SIO2_LSTAT_TRDY) != 0 ) continue;
 
    *tty_tx = c;
}
 
void hal_diag_drain_serial2(void)
{
    register volatile cyg_uint8 *volatile tty_status = SERIAL2_SR;
 
    while( (*tty_status & SIO2_LSTAT_TRDY) != 0 ) continue;
}
 
void hal_diag_read_char_serial2(char *c)
{
    register volatile cyg_uint8 *volatile tty_status = SERIAL2_SR;
    register volatile cyg_uint8 *volatile tty_rx = SERIAL2_RXR;
 
    while( (*tty_status & SIO2_LSTAT_RRDY) == 0 ) continue;
 
    *c = *tty_rx;
 
#if !defined(CYGSEM_HAL_USE_ROM_MONITOR_CygMon)    
    // We must ack the interrupt caused by that read to avoid
    // confusing the stubs.
    HAL_INTERRUPT_ACKNOWLEDGE( CYGNUM_HAL_INTERRUPT_SERIAL_2_RX );
#endif
}
 
#if defined(CYG_KERNEL_DIAG_SERIAL2)
 
#define hal_diag_init_serial hal_diag_init_serial2
#define hal_diag_write_char_serial hal_diag_write_char_serial2
#define hal_diag_drain_serial hal_diag_drain_serial2
#define hal_diag_read_char_serial hal_diag_read_char_serial2
 
#endif
 
#endif
 
/*---------------------------------------------------------------------------*/
 
void hal_diag_init(void)
{
    hal_diag_init_serial();
}
 
void hal_diag_write_char(char c)
{
#ifdef CYG_KERNEL_DIAG_GDB
 
    static char line[100];
    static int pos = 0;
 
    // No need to send CRs
    if( c == '\r' ) return;
 
    line[pos++] = c;
 
    if( c == '\n' || pos == sizeof(line) )
    {
        // Disable interrupts. This prevents GDB trying to interrupt us
        // while we are in the middle of sending a packet. The serial
        // receive interrupt will be seen when we re-enable interrupts
        // later.
 
        CYG_INTERRUPT_STATE oldstate;
        CYG_BYTE wdcr;
        HAL_DISABLE_INTERRUPTS(oldstate);
 
        // Beacuse of problems with NT on the testfarm, we also have
        // to disable the watchdog here. This only matters in the
        // watchdog tests. And yes, this sends my irony meter off the
        // scale too.
 
        HAL_READ_UINT8( 0x34004002, wdcr );
        HAL_WRITE_UINT8( 0x34004002, wdcr&0x3F );
 
        while(1)
        {
            static char hex[] = "0123456789ABCDEF";
            cyg_uint8 csum = 0;
            int i;
 
            hal_diag_write_char_serial('$');
            hal_diag_write_char_serial('O');
            csum += 'O';
            for( i = 0; i < pos; i++ )
            {
                char ch = line[i];
                char h = hex[(ch>>4)&0xF];
                char l = hex[ch&0xF];
                hal_diag_write_char_serial(h);
                hal_diag_write_char_serial(l);
                csum += h;
                csum += l;
            }
            hal_diag_write_char_serial('#');
            hal_diag_write_char_serial(hex[(csum>>4)&0xF]);
            hal_diag_write_char_serial(hex[csum&0xF]);
 
#if !defined(CYGSEM_HAL_USE_ROM_MONITOR_CygMon)
            {
                char c1;
 
                hal_diag_read_char_serial( &c1 );
 
                if( c1 == '+' ) break;
 
                if( cyg_hal_is_break( &c1, 1 ) )
                    cyg_hal_user_break( NULL );
 
            }
#else
            // When using Cygmon, the ack character is absorbed by cygmon's
            // serial interrupt handler that is looking for Ctrl-Cs.
            break;
#endif
        }
 
        pos = 0;
 
        // Wait for tx buffer to drain
        hal_diag_drain_serial();
 
        // And re-enable interrupts
        HAL_RESTORE_INTERRUPTS(oldstate);        
        HAL_WRITE_UINT8( 0x34004002, wdcr );
 
    }
 
#else
    hal_diag_write_char_serial(c);
#endif    
}
 
 
 
 
void hal_diag_read_char(char *c)
{
    hal_diag_read_char_serial(c);
}
 
 
/*---------------------------------------------------------------------------*/
/* End of hal_diag.c */
 

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