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[/] [openrisc/] [trunk/] [gnu-old/] [gdb-6.8/] [sim/] [m68hc11/] [dv-m68hc11tim.c] - Diff between revs 827 and 840

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/*  dv-m68hc11tim.c -- Simulation of the 68HC11 timer devices.
/*  dv-m68hc11tim.c -- Simulation of the 68HC11 timer devices.
    Copyright (C) 1999, 2000, 2002, 2003, 2007, 2008
    Copyright (C) 1999, 2000, 2002, 2003, 2007, 2008
    Free Software Foundation, Inc.
    Free Software Foundation, Inc.
    Written by Stephane Carrez (stcarrez@nerim.fr)
    Written by Stephane Carrez (stcarrez@nerim.fr)
    (From a driver model Contributed by Cygnus Solutions.)
    (From a driver model Contributed by Cygnus Solutions.)
 
 
    This file is part of the program GDB, the GNU debugger.
    This file is part of the program GDB, the GNU debugger.
 
 
    This program is free software; you can redistribute it and/or modify
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 3 of the License, or
    the Free Software Foundation; either version 3 of the License, or
    (at your option) any later version.
    (at your option) any later version.
 
 
    This program is distributed in the hope that it will be useful,
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    GNU General Public License for more details.
 
 
    You should have received a copy of the GNU General Public License
    You should have received a copy of the GNU General Public License
    along with this program.  If not, see <http://www.gnu.org/licenses/>.
    along with this program.  If not, see <http://www.gnu.org/licenses/>.
 
 
    */
    */
 
 
 
 
#include "sim-main.h"
#include "sim-main.h"
#include "hw-main.h"
#include "hw-main.h"
#include "sim-assert.h"
#include "sim-assert.h"
#include <limits.h>
#include <limits.h>
 
 
/* DEVICE
/* DEVICE
 
 
        m68hc11tim - m68hc11 timer devices
        m68hc11tim - m68hc11 timer devices
 
 
 
 
   DESCRIPTION
   DESCRIPTION
 
 
        Implements the m68hc11 timer as described in Chapter 10
        Implements the m68hc11 timer as described in Chapter 10
        of the pink book.
        of the pink book.
 
 
 
 
   PROPERTIES
   PROPERTIES
 
 
        none
        none
 
 
 
 
   PORTS
   PORTS
 
 
   reset (input)
   reset (input)
 
 
        Reset the timer device.  This port must be connected to
        Reset the timer device.  This port must be connected to
        the cpu-reset output port.
        the cpu-reset output port.
 
 
   capture (input)
   capture (input)
 
 
        Input capture.  This port must be connected to the input
        Input capture.  This port must be connected to the input
        captures.  It latches the current TCNT free running counter
        captures.  It latches the current TCNT free running counter
        into one of the three input capture registers.
        into one of the three input capture registers.
 
 
   */
   */
 
 
 
 
 
 
/* port ID's */
/* port ID's */
 
 
enum
enum
{
{
  RESET_PORT,
  RESET_PORT,
  CAPTURE
  CAPTURE
};
};
 
 
 
 
static const struct hw_port_descriptor m68hc11tim_ports[] =
static const struct hw_port_descriptor m68hc11tim_ports[] =
{
{
  { "reset",   RESET_PORT, 0, input_port, },
  { "reset",   RESET_PORT, 0, input_port, },
  { "capture", CAPTURE,    0, input_port, },
  { "capture", CAPTURE,    0, input_port, },
  { NULL, },
  { NULL, },
};
};
 
 
 
 
/* Timer Controller information.  */
/* Timer Controller information.  */
struct m68hc11tim
struct m68hc11tim
{
{
  unsigned long cop_delay;
  unsigned long cop_delay;
  unsigned long rti_delay;
  unsigned long rti_delay;
  unsigned long ovf_delay;
  unsigned long ovf_delay;
  signed64      clock_prescaler;
  signed64      clock_prescaler;
  signed64      tcnt_adjust;
  signed64      tcnt_adjust;
  signed64      cop_prev_interrupt;
  signed64      cop_prev_interrupt;
  signed64      rti_prev_interrupt;
  signed64      rti_prev_interrupt;
 
 
  /* Periodic timers.  */
  /* Periodic timers.  */
  struct hw_event *rti_timer_event;
  struct hw_event *rti_timer_event;
  struct hw_event *cop_timer_event;
  struct hw_event *cop_timer_event;
  struct hw_event *tof_timer_event;
  struct hw_event *tof_timer_event;
  struct hw_event *cmp_timer_event;
  struct hw_event *cmp_timer_event;
};
};
 
 
 
 
 
 
/* Finish off the partially created hw device.  Attach our local
/* Finish off the partially created hw device.  Attach our local
   callbacks.  Wire up our port names etc.  */
   callbacks.  Wire up our port names etc.  */
 
 
static hw_io_read_buffer_method m68hc11tim_io_read_buffer;
static hw_io_read_buffer_method m68hc11tim_io_read_buffer;
static hw_io_write_buffer_method m68hc11tim_io_write_buffer;
static hw_io_write_buffer_method m68hc11tim_io_write_buffer;
static hw_port_event_method m68hc11tim_port_event;
static hw_port_event_method m68hc11tim_port_event;
static hw_ioctl_method m68hc11tim_ioctl;
static hw_ioctl_method m68hc11tim_ioctl;
 
 
#define M6811_TIMER_FIRST_REG (M6811_TCTN)
#define M6811_TIMER_FIRST_REG (M6811_TCTN)
#define M6811_TIMER_LAST_REG  (M6811_PACNT)
#define M6811_TIMER_LAST_REG  (M6811_PACNT)
 
 
 
 
static void
static void
attach_m68hc11tim_regs (struct hw *me,
attach_m68hc11tim_regs (struct hw *me,
                        struct m68hc11tim *controller)
                        struct m68hc11tim *controller)
{
{
  hw_attach_address (hw_parent (me), M6811_IO_LEVEL, io_map,
  hw_attach_address (hw_parent (me), M6811_IO_LEVEL, io_map,
                     M6811_TIMER_FIRST_REG,
                     M6811_TIMER_FIRST_REG,
                     M6811_TIMER_LAST_REG - M6811_TIMER_FIRST_REG + 1,
                     M6811_TIMER_LAST_REG - M6811_TIMER_FIRST_REG + 1,
                     me);
                     me);
}
}
 
 
static void
static void
m68hc11tim_finish (struct hw *me)
m68hc11tim_finish (struct hw *me)
{
{
  struct m68hc11tim *controller;
  struct m68hc11tim *controller;
 
 
  controller = HW_ZALLOC (me, struct m68hc11tim);
  controller = HW_ZALLOC (me, struct m68hc11tim);
  set_hw_data (me, controller);
  set_hw_data (me, controller);
  set_hw_io_read_buffer (me, m68hc11tim_io_read_buffer);
  set_hw_io_read_buffer (me, m68hc11tim_io_read_buffer);
  set_hw_io_write_buffer (me, m68hc11tim_io_write_buffer);
  set_hw_io_write_buffer (me, m68hc11tim_io_write_buffer);
  set_hw_ports (me, m68hc11tim_ports);
  set_hw_ports (me, m68hc11tim_ports);
  set_hw_port_event (me, m68hc11tim_port_event);
  set_hw_port_event (me, m68hc11tim_port_event);
#ifdef set_hw_ioctl
#ifdef set_hw_ioctl
  set_hw_ioctl (me, m68hc11tim_ioctl);
  set_hw_ioctl (me, m68hc11tim_ioctl);
#else
#else
  me->to_ioctl = m68hc11tim_ioctl;
  me->to_ioctl = m68hc11tim_ioctl;
#endif
#endif
 
 
  /* Preset defaults.  */
  /* Preset defaults.  */
  controller->clock_prescaler = 1;
  controller->clock_prescaler = 1;
  controller->tcnt_adjust = 0;
  controller->tcnt_adjust = 0;
 
 
  /* Attach ourself to our parent bus.  */
  /* Attach ourself to our parent bus.  */
  attach_m68hc11tim_regs (me, controller);
  attach_m68hc11tim_regs (me, controller);
}
}
 
 
 
 
/* An event arrives on an interrupt port.  */
/* An event arrives on an interrupt port.  */
 
 
static void
static void
m68hc11tim_port_event (struct hw *me,
m68hc11tim_port_event (struct hw *me,
                       int my_port,
                       int my_port,
                       struct hw *source,
                       struct hw *source,
                       int source_port,
                       int source_port,
                       int level)
                       int level)
{
{
  SIM_DESC sd;
  SIM_DESC sd;
  struct m68hc11tim *controller;
  struct m68hc11tim *controller;
  sim_cpu *cpu;
  sim_cpu *cpu;
  unsigned8 val;
  unsigned8 val;
  unsigned16 tcnt;
  unsigned16 tcnt;
 
 
  controller = hw_data (me);
  controller = hw_data (me);
  sd         = hw_system (me);
  sd         = hw_system (me);
  cpu        = STATE_CPU (sd, 0);
  cpu        = STATE_CPU (sd, 0);
  switch (my_port)
  switch (my_port)
    {
    {
    case RESET_PORT:
    case RESET_PORT:
      {
      {
        HW_TRACE ((me, "Timer reset"));
        HW_TRACE ((me, "Timer reset"));
 
 
        /* Cancel all timer events.  */
        /* Cancel all timer events.  */
        if (controller->rti_timer_event)
        if (controller->rti_timer_event)
          {
          {
            hw_event_queue_deschedule (me, controller->rti_timer_event);
            hw_event_queue_deschedule (me, controller->rti_timer_event);
            controller->rti_timer_event = 0;
            controller->rti_timer_event = 0;
            controller->rti_prev_interrupt = 0;
            controller->rti_prev_interrupt = 0;
          }
          }
        if (controller->cop_timer_event)
        if (controller->cop_timer_event)
          {
          {
            hw_event_queue_deschedule (me, controller->cop_timer_event);
            hw_event_queue_deschedule (me, controller->cop_timer_event);
            controller->cop_timer_event = 0;
            controller->cop_timer_event = 0;
            controller->cop_prev_interrupt = 0;
            controller->cop_prev_interrupt = 0;
          }
          }
        if (controller->tof_timer_event)
        if (controller->tof_timer_event)
          {
          {
            hw_event_queue_deschedule (me, controller->tof_timer_event);
            hw_event_queue_deschedule (me, controller->tof_timer_event);
            controller->tof_timer_event = 0;
            controller->tof_timer_event = 0;
          }
          }
        if (controller->cmp_timer_event)
        if (controller->cmp_timer_event)
          {
          {
            hw_event_queue_deschedule (me, controller->cmp_timer_event);
            hw_event_queue_deschedule (me, controller->cmp_timer_event);
            controller->cmp_timer_event = 0;
            controller->cmp_timer_event = 0;
          }
          }
 
 
        /* Reset the state of Timer registers.  This also restarts
        /* Reset the state of Timer registers.  This also restarts
           the timer events (overflow and RTI clock).  The pending
           the timer events (overflow and RTI clock).  The pending
           flags (TFLG2) must be cleared explicitly here.  */
           flags (TFLG2) must be cleared explicitly here.  */
        val = 0;
        val = 0;
        cpu->ios[M6811_TFLG2] = 0;
        cpu->ios[M6811_TFLG2] = 0;
        m68hc11tim_io_write_buffer (me, &val, io_map,
        m68hc11tim_io_write_buffer (me, &val, io_map,
                                    (unsigned_word) M6811_TMSK2, 1);
                                    (unsigned_word) M6811_TMSK2, 1);
        m68hc11tim_io_write_buffer (me, &val, io_map,
        m68hc11tim_io_write_buffer (me, &val, io_map,
                                    (unsigned_word) M6811_PACTL, 1);
                                    (unsigned_word) M6811_PACTL, 1);
        break;
        break;
      }
      }
 
 
    case CAPTURE:
    case CAPTURE:
      tcnt = (uint16) ((cpu->cpu_absolute_cycle - controller->tcnt_adjust)
      tcnt = (uint16) ((cpu->cpu_absolute_cycle - controller->tcnt_adjust)
                       / controller->clock_prescaler);
                       / controller->clock_prescaler);
      switch (level)
      switch (level)
        {
        {
        case M6811_TIC1:
        case M6811_TIC1:
        case M6811_TIC2:
        case M6811_TIC2:
        case M6811_TIC3:
        case M6811_TIC3:
          cpu->ios[level] = tcnt >> 8;
          cpu->ios[level] = tcnt >> 8;
          cpu->ios[level + 1] = tcnt;
          cpu->ios[level + 1] = tcnt;
          break;
          break;
 
 
        default:
        default:
          hw_abort (me, "Invalid event parameter %d", level);
          hw_abort (me, "Invalid event parameter %d", level);
          break;
          break;
        }
        }
      break;
      break;
 
 
    default:
    default:
      hw_abort (me, "Event on unknown port %d", my_port);
      hw_abort (me, "Event on unknown port %d", my_port);
      break;
      break;
    }
    }
}
}
 
 
enum event_type
enum event_type
{
{
  COP_EVENT,
  COP_EVENT,
  RTI_EVENT,
  RTI_EVENT,
  OVERFLOW_EVENT,
  OVERFLOW_EVENT,
  COMPARE_EVENT
  COMPARE_EVENT
};
};
 
 
void
void
m68hc11tim_timer_event (struct hw *me, void *data)
m68hc11tim_timer_event (struct hw *me, void *data)
{
{
  SIM_DESC sd;
  SIM_DESC sd;
  struct m68hc11tim *controller;
  struct m68hc11tim *controller;
  sim_cpu *cpu;
  sim_cpu *cpu;
  enum event_type type;
  enum event_type type;
  unsigned long delay;
  unsigned long delay;
  struct hw_event **eventp;
  struct hw_event **eventp;
  int check_interrupt = 0;
  int check_interrupt = 0;
  unsigned mask;
  unsigned mask;
  unsigned flags;
  unsigned flags;
  unsigned long tcnt_internal;
  unsigned long tcnt_internal;
  unsigned long tcnt, tcnt_prev;
  unsigned long tcnt, tcnt_prev;
  signed64 tcnt_insn_end;
  signed64 tcnt_insn_end;
  signed64 tcnt_insn_start;
  signed64 tcnt_insn_start;
  int i;
  int i;
  sim_events *events;
  sim_events *events;
 
 
  controller = hw_data (me);
  controller = hw_data (me);
  sd         = hw_system (me);
  sd         = hw_system (me);
  cpu        = STATE_CPU (sd, 0);
  cpu        = STATE_CPU (sd, 0);
  type       = (enum event_type) ((long) data) & 0x0FF;
  type       = (enum event_type) ((long) data) & 0x0FF;
  events     = STATE_EVENTS (sd);
  events     = STATE_EVENTS (sd);
 
 
  delay = 0;
  delay = 0;
  switch (type)
  switch (type)
    {
    {
    case COP_EVENT:
    case COP_EVENT:
      eventp = &controller->cop_timer_event;
      eventp = &controller->cop_timer_event;
      delay  = controller->cop_delay;
      delay  = controller->cop_delay;
      delay  = controller->cop_prev_interrupt + controller->cop_delay;
      delay  = controller->cop_prev_interrupt + controller->cop_delay;
      controller->cop_prev_interrupt = delay;
      controller->cop_prev_interrupt = delay;
      delay  = delay - cpu->cpu_absolute_cycle;
      delay  = delay - cpu->cpu_absolute_cycle;
      check_interrupt = 1;
      check_interrupt = 1;
      delay += events->nr_ticks_to_process;
      delay += events->nr_ticks_to_process;
      break;
      break;
 
 
    case RTI_EVENT:
    case RTI_EVENT:
      eventp = &controller->rti_timer_event;
      eventp = &controller->rti_timer_event;
      delay  = controller->rti_prev_interrupt + controller->rti_delay;
      delay  = controller->rti_prev_interrupt + controller->rti_delay;
 
 
      if (((long) (data) & 0x0100) == 0)
      if (((long) (data) & 0x0100) == 0)
        {
        {
          cpu->ios[M6811_TFLG2] |= M6811_RTIF;
          cpu->ios[M6811_TFLG2] |= M6811_RTIF;
          check_interrupt = 1;
          check_interrupt = 1;
          controller->rti_prev_interrupt = delay;
          controller->rti_prev_interrupt = delay;
          delay += controller->rti_delay;
          delay += controller->rti_delay;
        }
        }
      delay = delay - cpu->cpu_absolute_cycle;
      delay = delay - cpu->cpu_absolute_cycle;
      delay += events->nr_ticks_to_process;
      delay += events->nr_ticks_to_process;
      break;
      break;
 
 
    case OVERFLOW_EVENT:
    case OVERFLOW_EVENT:
      /* Compute the 68HC11 internal free running counter.  */
      /* Compute the 68HC11 internal free running counter.  */
      tcnt_internal = (cpu->cpu_absolute_cycle - controller->tcnt_adjust);
      tcnt_internal = (cpu->cpu_absolute_cycle - controller->tcnt_adjust);
 
 
      /* We must take into account the prescaler that comes
      /* We must take into account the prescaler that comes
         before the counter (it's a power of 2).  */
         before the counter (it's a power of 2).  */
      tcnt_internal &= 0x0ffff * controller->clock_prescaler;
      tcnt_internal &= 0x0ffff * controller->clock_prescaler;
 
 
      /* Compute the time when the overflow will occur.  It occurs when
      /* Compute the time when the overflow will occur.  It occurs when
         the counter increments from 0x0ffff to 0x10000 (and thus resets).  */
         the counter increments from 0x0ffff to 0x10000 (and thus resets).  */
      delay = (0x10000 * controller->clock_prescaler) - tcnt_internal;
      delay = (0x10000 * controller->clock_prescaler) - tcnt_internal;
 
 
      /* The 'nr_ticks_to_process' will be subtracted when the event
      /* The 'nr_ticks_to_process' will be subtracted when the event
         is scheduled.  */
         is scheduled.  */
      delay += events->nr_ticks_to_process;
      delay += events->nr_ticks_to_process;
 
 
      eventp = &controller->tof_timer_event;
      eventp = &controller->tof_timer_event;
      if (((long) (data) & 0x100) == 0)
      if (((long) (data) & 0x100) == 0)
        {
        {
          cpu->ios[M6811_TFLG2] |= M6811_TOF;
          cpu->ios[M6811_TFLG2] |= M6811_TOF;
          check_interrupt = 1;
          check_interrupt = 1;
        }
        }
      break;
      break;
 
 
    case COMPARE_EVENT:
    case COMPARE_EVENT:
      /* Compute value of TCNT register (64-bit precision) at beginning
      /* Compute value of TCNT register (64-bit precision) at beginning
         and end of instruction.  */
         and end of instruction.  */
      tcnt_insn_end = (cpu->cpu_absolute_cycle - controller->tcnt_adjust);
      tcnt_insn_end = (cpu->cpu_absolute_cycle - controller->tcnt_adjust);
      tcnt_insn_start = (tcnt_insn_end - cpu->cpu_current_cycle);
      tcnt_insn_start = (tcnt_insn_end - cpu->cpu_current_cycle);
 
 
      /* TCNT value at beginning of current instruction.  */
      /* TCNT value at beginning of current instruction.  */
      tcnt_prev = (tcnt_insn_start / controller->clock_prescaler) & 0x0ffff;
      tcnt_prev = (tcnt_insn_start / controller->clock_prescaler) & 0x0ffff;
 
 
      /* TCNT value at end of current instruction.  */
      /* TCNT value at end of current instruction.  */
      tcnt = (tcnt_insn_end / controller->clock_prescaler) & 0x0ffff;
      tcnt = (tcnt_insn_end / controller->clock_prescaler) & 0x0ffff;
 
 
      /* We must take into account the prescaler that comes
      /* We must take into account the prescaler that comes
         before the counter (it's a power of 2).  */
         before the counter (it's a power of 2).  */
      tcnt_internal = tcnt_insn_end;
      tcnt_internal = tcnt_insn_end;
      tcnt_internal &= 0x0ffff * controller->clock_prescaler;
      tcnt_internal &= 0x0ffff * controller->clock_prescaler;
 
 
      flags = cpu->ios[M6811_TMSK1];
      flags = cpu->ios[M6811_TMSK1];
      mask  = 0x80;
      mask  = 0x80;
      delay = 65536 * controller->clock_prescaler;
      delay = 65536 * controller->clock_prescaler;
 
 
      /* Scan each output compare register to see if one matches
      /* Scan each output compare register to see if one matches
         the free running counter.  Set the corresponding OCi flag
         the free running counter.  Set the corresponding OCi flag
         if the output compare is enabled.  */
         if the output compare is enabled.  */
      for (i = M6811_TOC1; i <= M6811_TOC5; i += 2, mask >>= 1)
      for (i = M6811_TOC1; i <= M6811_TOC5; i += 2, mask >>= 1)
        {
        {
          unsigned long compare;
          unsigned long compare;
 
 
          compare = (cpu->ios[i] << 8) + cpu->ios[i + 1];
          compare = (cpu->ios[i] << 8) + cpu->ios[i + 1];
 
 
          /* See if compare is reached; handle wrap arround.  */
          /* See if compare is reached; handle wrap arround.  */
          if ((compare >= tcnt_prev && compare <= tcnt && tcnt_prev < tcnt)
          if ((compare >= tcnt_prev && compare <= tcnt && tcnt_prev < tcnt)
              || (compare >= tcnt_prev && tcnt_prev > tcnt)
              || (compare >= tcnt_prev && tcnt_prev > tcnt)
              || (compare < tcnt && tcnt_prev > tcnt))
              || (compare < tcnt && tcnt_prev > tcnt))
            {
            {
              unsigned dt;
              unsigned dt;
 
 
              if (compare > tcnt)
              if (compare > tcnt)
                dt = 0x10000 - compare - tcnt;
                dt = 0x10000 - compare - tcnt;
              else
              else
                dt = tcnt - compare;
                dt = tcnt - compare;
 
 
              cpu->ios[M6811_TFLG1] |= mask;
              cpu->ios[M6811_TFLG1] |= mask;
 
 
              /* Raise interrupt now at the correct CPU cycle so that
              /* Raise interrupt now at the correct CPU cycle so that
                 we can find the interrupt latency.  */
                 we can find the interrupt latency.  */
              cpu->cpu_absolute_cycle -= dt;
              cpu->cpu_absolute_cycle -= dt;
              interrupts_update_pending (&cpu->cpu_interrupts);
              interrupts_update_pending (&cpu->cpu_interrupts);
              cpu->cpu_absolute_cycle += dt;
              cpu->cpu_absolute_cycle += dt;
            }
            }
 
 
          /* Compute how many times for the next match.
          /* Compute how many times for the next match.
             Use the internal counter value to take into account the
             Use the internal counter value to take into account the
             prescaler accurately.  */
             prescaler accurately.  */
          compare = compare * controller->clock_prescaler;
          compare = compare * controller->clock_prescaler;
          if (compare > tcnt_internal)
          if (compare > tcnt_internal)
            compare = compare - tcnt_internal;
            compare = compare - tcnt_internal;
          else
          else
            compare = compare - tcnt_internal
            compare = compare - tcnt_internal
              + 65536 * controller->clock_prescaler;
              + 65536 * controller->clock_prescaler;
 
 
          if (compare < delay)
          if (compare < delay)
            delay = compare;
            delay = compare;
        }
        }
 
 
      /* Deactivate the compare timer if no output compare is enabled.  */
      /* Deactivate the compare timer if no output compare is enabled.  */
      if ((flags & 0xF8) == 0)
      if ((flags & 0xF8) == 0)
        delay = 0;
        delay = 0;
      else
      else
        delay += events->nr_ticks_to_process;
        delay += events->nr_ticks_to_process;
 
 
      eventp = &controller->cmp_timer_event;
      eventp = &controller->cmp_timer_event;
      break;
      break;
 
 
    default:
    default:
      eventp = 0;
      eventp = 0;
      break;
      break;
    }
    }
 
 
  if (*eventp)
  if (*eventp)
    {
    {
      hw_event_queue_deschedule (me, *eventp);
      hw_event_queue_deschedule (me, *eventp);
      *eventp = 0;
      *eventp = 0;
    }
    }
 
 
  if (delay != 0)
  if (delay != 0)
    {
    {
      *eventp = hw_event_queue_schedule (me, delay,
      *eventp = hw_event_queue_schedule (me, delay,
                                         m68hc11tim_timer_event,
                                         m68hc11tim_timer_event,
                                         (void*) type);
                                         (void*) type);
    }
    }
 
 
  if (check_interrupt)
  if (check_interrupt)
    interrupts_update_pending (&cpu->cpu_interrupts);
    interrupts_update_pending (&cpu->cpu_interrupts);
}
}
 
 
 
 
/* Descriptions of the Timer I/O ports.  These descriptions are only used to
/* Descriptions of the Timer I/O ports.  These descriptions are only used to
   give information of the Timer device under GDB.  */
   give information of the Timer device under GDB.  */
io_reg_desc tmsk1_desc[] = {
io_reg_desc tmsk1_desc[] = {
  { M6811_OC1I,  "OC1I ", "Timer Output Compare 1 Interrupt Enable" },
  { M6811_OC1I,  "OC1I ", "Timer Output Compare 1 Interrupt Enable" },
  { M6811_OC2I,  "OC2I ", "Timer Output Compare 2 Interrupt Enable" },
  { M6811_OC2I,  "OC2I ", "Timer Output Compare 2 Interrupt Enable" },
  { M6811_OC3I,  "OC3I ", "Timer Output Compare 3 Interrupt Enable" },
  { M6811_OC3I,  "OC3I ", "Timer Output Compare 3 Interrupt Enable" },
  { M6811_OC4I,  "OC4I ", "Timer Output Compare 4 Interrupt Enable" },
  { M6811_OC4I,  "OC4I ", "Timer Output Compare 4 Interrupt Enable" },
  { M6811_OC5I,  "OC5I ", "Timer Input Capture 4 / Output Compare 5 Enable" },
  { M6811_OC5I,  "OC5I ", "Timer Input Capture 4 / Output Compare 5 Enable" },
  { M6811_IC1I,  "IC1I ", "Timer Input Capture 1 Interrupt Enable" },
  { M6811_IC1I,  "IC1I ", "Timer Input Capture 1 Interrupt Enable" },
  { M6811_IC2I,  "IC2I ", "Timer Input Capture 2 Interrupt Enable" },
  { M6811_IC2I,  "IC2I ", "Timer Input Capture 2 Interrupt Enable" },
  { M6811_IC3I,  "IC3I ", "Timer Input Capture 3 Interrupt Enable" },
  { M6811_IC3I,  "IC3I ", "Timer Input Capture 3 Interrupt Enable" },
  { 0, 0, 0 }
  { 0, 0, 0 }
};
};
 
 
io_reg_desc tflg1_desc[] = {
io_reg_desc tflg1_desc[] = {
  { M6811_OC1F,  "OC1F ", "Timer Output Compare 1 Interrupt Flag" },
  { M6811_OC1F,  "OC1F ", "Timer Output Compare 1 Interrupt Flag" },
  { M6811_OC2F,  "OC2F ", "Timer Output Compare 2 Interrupt Flag" },
  { M6811_OC2F,  "OC2F ", "Timer Output Compare 2 Interrupt Flag" },
  { M6811_OC3F,  "OC3F ", "Timer Output Compare 3 Interrupt Flag" },
  { M6811_OC3F,  "OC3F ", "Timer Output Compare 3 Interrupt Flag" },
  { M6811_OC4F,  "OC4F ", "Timer Output Compare 4 Interrupt Flag" },
  { M6811_OC4F,  "OC4F ", "Timer Output Compare 4 Interrupt Flag" },
  { M6811_OC5F,  "OC5F ", "Timer Input Capture 4 / Output Compare 5 Flag" },
  { M6811_OC5F,  "OC5F ", "Timer Input Capture 4 / Output Compare 5 Flag" },
  { M6811_IC1F,  "IC1F ", "Timer Input Capture 1 Interrupt Flag" },
  { M6811_IC1F,  "IC1F ", "Timer Input Capture 1 Interrupt Flag" },
  { M6811_IC2F,  "IC2F ", "Timer Input Capture 2 Interrupt Flag" },
  { M6811_IC2F,  "IC2F ", "Timer Input Capture 2 Interrupt Flag" },
  { M6811_IC3F,  "IC3F ", "Timer Input Capture 3 Interrupt Flag" },
  { M6811_IC3F,  "IC3F ", "Timer Input Capture 3 Interrupt Flag" },
  { 0, 0, 0 }
  { 0, 0, 0 }
};
};
 
 
io_reg_desc tmsk2_desc[] = {
io_reg_desc tmsk2_desc[] = {
  { M6811_TOI,    "TOI   ", "Timer Overflow Interrupt Enable" },
  { M6811_TOI,    "TOI   ", "Timer Overflow Interrupt Enable" },
  { M6811_RTII,   "RTII  ", "RTI Interrupt Enable" },
  { M6811_RTII,   "RTII  ", "RTI Interrupt Enable" },
  { M6811_PAOVI,  "PAOVI ", "Pulse Accumulator Overflow Interrupt Enable" },
  { M6811_PAOVI,  "PAOVI ", "Pulse Accumulator Overflow Interrupt Enable" },
  { M6811_PAII,   "PAII  ", "Pulse Accumulator Interrupt Enable" },
  { M6811_PAII,   "PAII  ", "Pulse Accumulator Interrupt Enable" },
  { M6811_PR1,    "PR1   ", "Timer prescaler (PR1)" },
  { M6811_PR1,    "PR1   ", "Timer prescaler (PR1)" },
  { M6811_PR0,    "PR0   ", "Timer prescaler (PR0)" },
  { M6811_PR0,    "PR0   ", "Timer prescaler (PR0)" },
  { M6811_TPR_1,  "TPR_1 ", "Timer prescaler div 1" },
  { M6811_TPR_1,  "TPR_1 ", "Timer prescaler div 1" },
  { M6811_TPR_4,  "TPR_4 ", "Timer prescaler div 4" },
  { M6811_TPR_4,  "TPR_4 ", "Timer prescaler div 4" },
  { M6811_TPR_8,  "TPR_8 ", "Timer prescaler div 8" },
  { M6811_TPR_8,  "TPR_8 ", "Timer prescaler div 8" },
  { M6811_TPR_16, "TPR_16", "Timer prescaler div 16" },
  { M6811_TPR_16, "TPR_16", "Timer prescaler div 16" },
  { 0,  0, 0 }
  { 0,  0, 0 }
};
};
 
 
io_reg_desc tflg2_desc[] = {
io_reg_desc tflg2_desc[] = {
  { M6811_TOF,   "TOF   ", "Timer Overflow Bit" },
  { M6811_TOF,   "TOF   ", "Timer Overflow Bit" },
  { M6811_RTIF,  "RTIF  ", "Read Time Interrupt Flag" },
  { M6811_RTIF,  "RTIF  ", "Read Time Interrupt Flag" },
  { M6811_PAOVF, "PAOVF ", "Pulse Accumulator Overflow Interrupt Flag" },
  { M6811_PAOVF, "PAOVF ", "Pulse Accumulator Overflow Interrupt Flag" },
  { M6811_PAIF,  "PAIF  ", "Pulse Accumulator Input Edge" },
  { M6811_PAIF,  "PAIF  ", "Pulse Accumulator Input Edge" },
  { 0,  0, 0 }
  { 0,  0, 0 }
};
};
 
 
io_reg_desc pactl_desc[] = {
io_reg_desc pactl_desc[] = {
  { M6811_DDRA7,  "DDRA7 ", "Data Direction for Port A bit-7" },
  { M6811_DDRA7,  "DDRA7 ", "Data Direction for Port A bit-7" },
  { M6811_PAEN,   "PAEN  ", "Pulse Accumulator System Enable" },
  { M6811_PAEN,   "PAEN  ", "Pulse Accumulator System Enable" },
  { M6811_PAMOD,  "PAMOD ", "Pulse Accumulator Mode" },
  { M6811_PAMOD,  "PAMOD ", "Pulse Accumulator Mode" },
  { M6811_PEDGE,  "PEDGE ", "Pulse Accumulator Edge Control" },
  { M6811_PEDGE,  "PEDGE ", "Pulse Accumulator Edge Control" },
  { M6811_RTR1,   "RTR1  ", "RTI Interrupt rate select (RTR1)" },
  { M6811_RTR1,   "RTR1  ", "RTI Interrupt rate select (RTR1)" },
  { M6811_RTR0,   "RTR0  ", "RTI Interrupt rate select (RTR0)" },
  { M6811_RTR0,   "RTR0  ", "RTI Interrupt rate select (RTR0)" },
  { 0,  0, 0 }
  { 0,  0, 0 }
};
};
 
 
static double
static double
to_realtime (sim_cpu *cpu, signed64 t)
to_realtime (sim_cpu *cpu, signed64 t)
{
{
  return (double) (t) / (double) (cpu->cpu_frequency / 4);
  return (double) (t) / (double) (cpu->cpu_frequency / 4);
}
}
 
 
const char*
const char*
cycle_to_string (sim_cpu *cpu, signed64 t, int flags)
cycle_to_string (sim_cpu *cpu, signed64 t, int flags)
{
{
  char time_buf[32];
  char time_buf[32];
  char cycle_buf[32];
  char cycle_buf[32];
  static char buf[64];
  static char buf[64];
 
 
  time_buf[0] = 0;
  time_buf[0] = 0;
  cycle_buf[0] = 0;
  cycle_buf[0] = 0;
  if (flags & PRINT_TIME)
  if (flags & PRINT_TIME)
    {
    {
      double dt;
      double dt;
 
 
      dt = to_realtime (cpu, t);
      dt = to_realtime (cpu, t);
      if (dt < 0.001)
      if (dt < 0.001)
        sprintf (time_buf, " (%3.1f us)", dt * 1000000.0);
        sprintf (time_buf, " (%3.1f us)", dt * 1000000.0);
      else if (dt < 1.0)
      else if (dt < 1.0)
        sprintf (time_buf, " (%3.1f ms)", dt * 1000.0);
        sprintf (time_buf, " (%3.1f ms)", dt * 1000.0);
      else
      else
        sprintf (time_buf, " (%3.1f s)", dt);
        sprintf (time_buf, " (%3.1f s)", dt);
    }
    }
 
 
  if (flags & PRINT_CYCLE)
  if (flags & PRINT_CYCLE)
    sprintf (cycle_buf, " cycle%s",
    sprintf (cycle_buf, " cycle%s",
             (t > 1 ? "s" : ""));
             (t > 1 ? "s" : ""));
 
 
  if (t < LONG_MAX)
  if (t < LONG_MAX)
    sprintf (buf, "%9lu%s%s", (unsigned long) t, cycle_buf, time_buf);
    sprintf (buf, "%9lu%s%s", (unsigned long) t, cycle_buf, time_buf);
  else
  else
    sprintf (buf, "%llu%s%s", t, cycle_buf, time_buf);
    sprintf (buf, "%llu%s%s", t, cycle_buf, time_buf);
  return buf;
  return buf;
}
}
 
 
static void
static void
m68hc11tim_print_timer (struct hw *me, const char *name,
m68hc11tim_print_timer (struct hw *me, const char *name,
                        struct hw_event *event)
                        struct hw_event *event)
{
{
  SIM_DESC sd;
  SIM_DESC sd;
 
 
  sd = hw_system (me);
  sd = hw_system (me);
  if (event == 0)
  if (event == 0)
    {
    {
      sim_io_printf (sd, "  No %s interrupt will be raised.\n", name);
      sim_io_printf (sd, "  No %s interrupt will be raised.\n", name);
    }
    }
  else
  else
    {
    {
      signed64 t;
      signed64 t;
      sim_cpu* cpu;
      sim_cpu* cpu;
 
 
      cpu = STATE_CPU (sd, 0);
      cpu = STATE_CPU (sd, 0);
 
 
      t  = hw_event_remain_time (me, event);
      t  = hw_event_remain_time (me, event);
      sim_io_printf (sd, "  Next %s interrupt in %s\n",
      sim_io_printf (sd, "  Next %s interrupt in %s\n",
                     name, cycle_to_string (cpu, t, PRINT_TIME | PRINT_CYCLE));
                     name, cycle_to_string (cpu, t, PRINT_TIME | PRINT_CYCLE));
    }
    }
}
}
 
 
static void
static void
m68hc11tim_info (struct hw *me)
m68hc11tim_info (struct hw *me)
{
{
  SIM_DESC sd;
  SIM_DESC sd;
  uint16 base = 0;
  uint16 base = 0;
  sim_cpu *cpu;
  sim_cpu *cpu;
  struct m68hc11tim *controller;
  struct m68hc11tim *controller;
  uint8 val;
  uint8 val;
  uint16 val16;
  uint16 val16;
 
 
  sd = hw_system (me);
  sd = hw_system (me);
  cpu = STATE_CPU (sd, 0);
  cpu = STATE_CPU (sd, 0);
  controller = hw_data (me);
  controller = hw_data (me);
 
 
  sim_io_printf (sd, "M68HC11 Timer:\n");
  sim_io_printf (sd, "M68HC11 Timer:\n");
 
 
  base = cpu_get_io_base (cpu);
  base = cpu_get_io_base (cpu);
 
 
  /* Info for TIC1 */
  /* Info for TIC1 */
  val16  = (cpu->ios[M6811_TIC1_H] << 8) + cpu->ios[M6811_TIC1_L];
  val16  = (cpu->ios[M6811_TIC1_H] << 8) + cpu->ios[M6811_TIC1_L];
  print_io_word (sd, "TIC1 ", 0, val16, base + M6811_TIC1);
  print_io_word (sd, "TIC1 ", 0, val16, base + M6811_TIC1);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  /* Info for TIC2 */
  /* Info for TIC2 */
  val16  = (cpu->ios[M6811_TIC2_H] << 8) + cpu->ios[M6811_TIC2_L];
  val16  = (cpu->ios[M6811_TIC2_H] << 8) + cpu->ios[M6811_TIC2_L];
  print_io_word (sd, "TIC2 ", 0, val16, base + M6811_TIC2);
  print_io_word (sd, "TIC2 ", 0, val16, base + M6811_TIC2);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  /* Info for TIC3 */
  /* Info for TIC3 */
  val16  = (cpu->ios[M6811_TIC3_H] << 8) + cpu->ios[M6811_TIC3_L];
  val16  = (cpu->ios[M6811_TIC3_H] << 8) + cpu->ios[M6811_TIC3_L];
  print_io_word (sd, "TIC3 ", 0, val16, base + M6811_TIC3);
  print_io_word (sd, "TIC3 ", 0, val16, base + M6811_TIC3);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  /* Info for TOC1 */
  /* Info for TOC1 */
  val16  = (cpu->ios[M6811_TOC1_H] << 8) + cpu->ios[M6811_TOC1_L];
  val16  = (cpu->ios[M6811_TOC1_H] << 8) + cpu->ios[M6811_TOC1_L];
  print_io_word (sd, "TOC1 ", 0, val16, base + M6811_TOC1);
  print_io_word (sd, "TOC1 ", 0, val16, base + M6811_TOC1);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  /* Info for TOC2 */
  /* Info for TOC2 */
  val16  = (cpu->ios[M6811_TOC2_H] << 8) + cpu->ios[M6811_TOC2_L];
  val16  = (cpu->ios[M6811_TOC2_H] << 8) + cpu->ios[M6811_TOC2_L];
  print_io_word (sd, "TOC2 ", 0, val16, base + M6811_TOC2);
  print_io_word (sd, "TOC2 ", 0, val16, base + M6811_TOC2);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  /* Info for TOC3 */
  /* Info for TOC3 */
  val16  = (cpu->ios[M6811_TOC3_H] << 8) + cpu->ios[M6811_TOC3_L];
  val16  = (cpu->ios[M6811_TOC3_H] << 8) + cpu->ios[M6811_TOC3_L];
  print_io_word (sd, "TOC3 ", 0, val16, base + M6811_TOC3);
  print_io_word (sd, "TOC3 ", 0, val16, base + M6811_TOC3);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  /* Info for TOC4 */
  /* Info for TOC4 */
  val16  = (cpu->ios[M6811_TOC4_H] << 8) + cpu->ios[M6811_TOC4_L];
  val16  = (cpu->ios[M6811_TOC4_H] << 8) + cpu->ios[M6811_TOC4_L];
  print_io_word (sd, "TOC4 ", 0, val16, base + M6811_TOC4);
  print_io_word (sd, "TOC4 ", 0, val16, base + M6811_TOC4);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  /* Info for TOC5 */
  /* Info for TOC5 */
  val16  = (cpu->ios[M6811_TOC5_H] << 8) + cpu->ios[M6811_TOC5_L];
  val16  = (cpu->ios[M6811_TOC5_H] << 8) + cpu->ios[M6811_TOC5_L];
  print_io_word (sd, "TOC5 ", 0, val16, base + M6811_TOC5);
  print_io_word (sd, "TOC5 ", 0, val16, base + M6811_TOC5);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  /* Info for TMSK1 */
  /* Info for TMSK1 */
  val  = cpu->ios[M6811_TMSK1];
  val  = cpu->ios[M6811_TMSK1];
  print_io_byte (sd, "TMSK1 ", tmsk1_desc, val, base + M6811_TMSK1);
  print_io_byte (sd, "TMSK1 ", tmsk1_desc, val, base + M6811_TMSK1);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  /* Info for TFLG1 */
  /* Info for TFLG1 */
  val = cpu->ios[M6811_TFLG1];
  val = cpu->ios[M6811_TFLG1];
  print_io_byte (sd, "TFLG1", tflg1_desc, val, base + M6811_TFLG1);
  print_io_byte (sd, "TFLG1", tflg1_desc, val, base + M6811_TFLG1);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  val  = cpu->ios[M6811_TMSK2];
  val  = cpu->ios[M6811_TMSK2];
  print_io_byte (sd, "TMSK2 ", tmsk2_desc, val, base + M6811_TMSK2);
  print_io_byte (sd, "TMSK2 ", tmsk2_desc, val, base + M6811_TMSK2);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  val = cpu->ios[M6811_TFLG2];
  val = cpu->ios[M6811_TFLG2];
  print_io_byte (sd, "TFLG2", tflg2_desc, val, base + M6811_TFLG2);
  print_io_byte (sd, "TFLG2", tflg2_desc, val, base + M6811_TFLG2);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  val = cpu->ios[M6811_PACTL];
  val = cpu->ios[M6811_PACTL];
  print_io_byte (sd, "PACTL", pactl_desc, val, base + M6811_PACTL);
  print_io_byte (sd, "PACTL", pactl_desc, val, base + M6811_PACTL);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  val = cpu->ios[M6811_PACNT];
  val = cpu->ios[M6811_PACNT];
  print_io_byte (sd, "PACNT", 0, val, base + M6811_PACNT);
  print_io_byte (sd, "PACNT", 0, val, base + M6811_PACNT);
  sim_io_printf (sd, "\n");
  sim_io_printf (sd, "\n");
 
 
  /* Give info about the next timer interrupts.  */
  /* Give info about the next timer interrupts.  */
  m68hc11tim_print_timer (me, "RTI", controller->rti_timer_event);
  m68hc11tim_print_timer (me, "RTI", controller->rti_timer_event);
  m68hc11tim_print_timer (me, "COP", controller->cop_timer_event);
  m68hc11tim_print_timer (me, "COP", controller->cop_timer_event);
  m68hc11tim_print_timer (me, "OVERFLOW", controller->tof_timer_event);
  m68hc11tim_print_timer (me, "OVERFLOW", controller->tof_timer_event);
  m68hc11tim_print_timer (me, "COMPARE", controller->cmp_timer_event);
  m68hc11tim_print_timer (me, "COMPARE", controller->cmp_timer_event);
}
}
 
 
static int
static int
m68hc11tim_ioctl (struct hw *me,
m68hc11tim_ioctl (struct hw *me,
                  hw_ioctl_request request,
                  hw_ioctl_request request,
                  va_list ap)
                  va_list ap)
{
{
  m68hc11tim_info (me);
  m68hc11tim_info (me);
  return 0;
  return 0;
}
}
 
 
/* generic read/write */
/* generic read/write */
 
 
static unsigned
static unsigned
m68hc11tim_io_read_buffer (struct hw *me,
m68hc11tim_io_read_buffer (struct hw *me,
                           void *dest,
                           void *dest,
                           int space,
                           int space,
                           unsigned_word base,
                           unsigned_word base,
                           unsigned nr_bytes)
                           unsigned nr_bytes)
{
{
  SIM_DESC sd;
  SIM_DESC sd;
  struct m68hc11tim *controller;
  struct m68hc11tim *controller;
  sim_cpu *cpu;
  sim_cpu *cpu;
  unsigned8 val;
  unsigned8 val;
  unsigned cnt = 0;
  unsigned cnt = 0;
 
 
  HW_TRACE ((me, "read 0x%08lx %d", (long) base, (int) nr_bytes));
  HW_TRACE ((me, "read 0x%08lx %d", (long) base, (int) nr_bytes));
 
 
  sd  = hw_system (me);
  sd  = hw_system (me);
  cpu = STATE_CPU (sd, 0);
  cpu = STATE_CPU (sd, 0);
  controller = hw_data (me);
  controller = hw_data (me);
 
 
  while (nr_bytes)
  while (nr_bytes)
    {
    {
      switch (base)
      switch (base)
        {
        {
          /* The cpu_absolute_cycle is updated after each instruction.
          /* The cpu_absolute_cycle is updated after each instruction.
             Reading in a 16-bit register will be split in two accesses
             Reading in a 16-bit register will be split in two accesses
             but this will be atomic within the simulator.  */
             but this will be atomic within the simulator.  */
        case M6811_TCTN_H:
        case M6811_TCTN_H:
          val = (uint8) ((cpu->cpu_absolute_cycle - controller->tcnt_adjust)
          val = (uint8) ((cpu->cpu_absolute_cycle - controller->tcnt_adjust)
                         / (controller->clock_prescaler * 256));
                         / (controller->clock_prescaler * 256));
          break;
          break;
 
 
        case M6811_TCTN_L:
        case M6811_TCTN_L:
          val = (uint8) ((cpu->cpu_absolute_cycle - controller->tcnt_adjust)
          val = (uint8) ((cpu->cpu_absolute_cycle - controller->tcnt_adjust)
                         / controller->clock_prescaler);
                         / controller->clock_prescaler);
          break;
          break;
 
 
        default:
        default:
          val = cpu->ios[base];
          val = cpu->ios[base];
          break;
          break;
        }
        }
      *((unsigned8*) dest) = val;
      *((unsigned8*) dest) = val;
      dest = (char*) dest + 1;
      dest = (char*) dest + 1;
      base++;
      base++;
      nr_bytes--;
      nr_bytes--;
      cnt++;
      cnt++;
    }
    }
  return cnt;
  return cnt;
}
}
 
 
static unsigned
static unsigned
m68hc11tim_io_write_buffer (struct hw *me,
m68hc11tim_io_write_buffer (struct hw *me,
                            const void *source,
                            const void *source,
                            int space,
                            int space,
                            unsigned_word base,
                            unsigned_word base,
                            unsigned nr_bytes)
                            unsigned nr_bytes)
{
{
  SIM_DESC sd;
  SIM_DESC sd;
  struct m68hc11tim *controller;
  struct m68hc11tim *controller;
  sim_cpu *cpu;
  sim_cpu *cpu;
  unsigned8 val, n;
  unsigned8 val, n;
  signed64 adj;
  signed64 adj;
  int reset_compare = 0;
  int reset_compare = 0;
  int reset_overflow = 0;
  int reset_overflow = 0;
  int cnt = 0;
  int cnt = 0;
 
 
  HW_TRACE ((me, "write 0x%08lx %d", (long) base, (int) nr_bytes));
  HW_TRACE ((me, "write 0x%08lx %d", (long) base, (int) nr_bytes));
 
 
  sd  = hw_system (me);
  sd  = hw_system (me);
  cpu = STATE_CPU (sd, 0);
  cpu = STATE_CPU (sd, 0);
  controller = hw_data (me);
  controller = hw_data (me);
 
 
  while (nr_bytes)
  while (nr_bytes)
    {
    {
      val = *((const unsigned8*) source);
      val = *((const unsigned8*) source);
      switch (base)
      switch (base)
        {
        {
          /* Set the timer counter low part, trying to preserve the low part.
          /* Set the timer counter low part, trying to preserve the low part.
             We compute the absolute cycle adjustment that we have to apply
             We compute the absolute cycle adjustment that we have to apply
             to obtain the timer current value.  Computation must be made
             to obtain the timer current value.  Computation must be made
             in 64-bit to avoid overflow problems.  */
             in 64-bit to avoid overflow problems.  */
        case M6811_TCTN_L:
        case M6811_TCTN_L:
          adj = ((cpu->cpu_absolute_cycle - controller->tcnt_adjust)
          adj = ((cpu->cpu_absolute_cycle - controller->tcnt_adjust)
                 / (controller->clock_prescaler * (signed64) 256)) & 0x0FF;
                 / (controller->clock_prescaler * (signed64) 256)) & 0x0FF;
          adj = cpu->cpu_absolute_cycle
          adj = cpu->cpu_absolute_cycle
            - (adj * controller->clock_prescaler * (signed64) 256)
            - (adj * controller->clock_prescaler * (signed64) 256)
            - ((signed64) adj * controller->clock_prescaler);
            - ((signed64) adj * controller->clock_prescaler);
          controller->tcnt_adjust = adj;
          controller->tcnt_adjust = adj;
          reset_compare = 1;
          reset_compare = 1;
          reset_overflow = 1;
          reset_overflow = 1;
          break;
          break;
 
 
        case M6811_TCTN_H:
        case M6811_TCTN_H:
          adj = ((cpu->cpu_absolute_cycle - controller->tcnt_adjust)
          adj = ((cpu->cpu_absolute_cycle - controller->tcnt_adjust)
                 / controller->clock_prescaler) & 0x0ff;
                 / controller->clock_prescaler) & 0x0ff;
          adj = cpu->cpu_absolute_cycle
          adj = cpu->cpu_absolute_cycle
            - ((signed64) val * controller->clock_prescaler * (signed64) 256)
            - ((signed64) val * controller->clock_prescaler * (signed64) 256)
            - (adj * controller->clock_prescaler);
            - (adj * controller->clock_prescaler);
          controller->tcnt_adjust = adj;
          controller->tcnt_adjust = adj;
          reset_compare = 1;
          reset_compare = 1;
          reset_overflow = 1;
          reset_overflow = 1;
          break;
          break;
 
 
        case M6811_TMSK2:
        case M6811_TMSK2:
 
 
          /* Timer prescaler cannot be changed after 64 bus cycles.  */
          /* Timer prescaler cannot be changed after 64 bus cycles.  */
          if (cpu->cpu_absolute_cycle >= 64)
          if (cpu->cpu_absolute_cycle >= 64)
            {
            {
              val &= ~(M6811_PR1 | M6811_PR0);
              val &= ~(M6811_PR1 | M6811_PR0);
              val |= cpu->ios[M6811_TMSK2] & (M6811_PR1 | M6811_PR0);
              val |= cpu->ios[M6811_TMSK2] & (M6811_PR1 | M6811_PR0);
            }
            }
          switch (val & (M6811_PR1 | M6811_PR0))
          switch (val & (M6811_PR1 | M6811_PR0))
            {
            {
            case 0:
            case 0:
              n = 1;
              n = 1;
              break;
              break;
            case M6811_PR0:
            case M6811_PR0:
              n = 4;
              n = 4;
              break;
              break;
            case M6811_PR1:
            case M6811_PR1:
              n = 8;
              n = 8;
              break;
              break;
            default:
            default:
            case M6811_PR1 | M6811_PR0:
            case M6811_PR1 | M6811_PR0:
              n = 16;
              n = 16;
              break;
              break;
            }
            }
          if (cpu->cpu_absolute_cycle < 64)
          if (cpu->cpu_absolute_cycle < 64)
            {
            {
              reset_overflow = 1;
              reset_overflow = 1;
              controller->clock_prescaler = n;
              controller->clock_prescaler = n;
            }
            }
          cpu->ios[base] = val;
          cpu->ios[base] = val;
          interrupts_update_pending (&cpu->cpu_interrupts);
          interrupts_update_pending (&cpu->cpu_interrupts);
          break;
          break;
 
 
        case M6811_PACTL:
        case M6811_PACTL:
          n = (1 << ((val & (M6811_RTR1 | M6811_RTR0))));
          n = (1 << ((val & (M6811_RTR1 | M6811_RTR0))));
          cpu->ios[base] = val;
          cpu->ios[base] = val;
 
 
          controller->rti_delay = (long) (n) * 8192;
          controller->rti_delay = (long) (n) * 8192;
          m68hc11tim_timer_event (me, (void*) (RTI_EVENT| 0x100));
          m68hc11tim_timer_event (me, (void*) (RTI_EVENT| 0x100));
          break;
          break;
 
 
        case M6811_TFLG2:
        case M6811_TFLG2:
          val &= cpu->ios[M6811_TFLG2];
          val &= cpu->ios[M6811_TFLG2];
          cpu->ios[M6811_TFLG2] &= ~val;
          cpu->ios[M6811_TFLG2] &= ~val;
          interrupts_update_pending (&cpu->cpu_interrupts);
          interrupts_update_pending (&cpu->cpu_interrupts);
          break;
          break;
 
 
        case M6811_TMSK1:
        case M6811_TMSK1:
          cpu->ios[M6811_TMSK1] = val;
          cpu->ios[M6811_TMSK1] = val;
          interrupts_update_pending (&cpu->cpu_interrupts);
          interrupts_update_pending (&cpu->cpu_interrupts);
          reset_compare = 1;
          reset_compare = 1;
          break;
          break;
 
 
        case M6811_TFLG1:
        case M6811_TFLG1:
          val &= cpu->ios[M6811_TFLG1];
          val &= cpu->ios[M6811_TFLG1];
          cpu->ios[M6811_TFLG1] &= ~val;
          cpu->ios[M6811_TFLG1] &= ~val;
          interrupts_update_pending (&cpu->cpu_interrupts);
          interrupts_update_pending (&cpu->cpu_interrupts);
          break;
          break;
 
 
        case M6811_TOC1:
        case M6811_TOC1:
        case M6811_TOC2:
        case M6811_TOC2:
        case M6811_TOC3:
        case M6811_TOC3:
        case M6811_TOC4:
        case M6811_TOC4:
        case M6811_TOC5:
        case M6811_TOC5:
          cpu->ios[base] = val;
          cpu->ios[base] = val;
          reset_compare = 1;
          reset_compare = 1;
          break;
          break;
 
 
        case M6811_TCTL1:
        case M6811_TCTL1:
        case M6811_TCTL2:
        case M6811_TCTL2:
          cpu->ios[base] = val;
          cpu->ios[base] = val;
          break;
          break;
 
 
        default:
        default:
          cpu->ios[base] = val;
          cpu->ios[base] = val;
          break;
          break;
        }
        }
 
 
      base++;
      base++;
      nr_bytes--;
      nr_bytes--;
      cnt++;
      cnt++;
      source = (char*) source + 1;
      source = (char*) source + 1;
    }
    }
 
 
  /* Re-compute the next timer compare event.  */
  /* Re-compute the next timer compare event.  */
  if (reset_compare)
  if (reset_compare)
    {
    {
      m68hc11tim_timer_event (me, (void*) (COMPARE_EVENT));
      m68hc11tim_timer_event (me, (void*) (COMPARE_EVENT));
    }
    }
  if (reset_overflow)
  if (reset_overflow)
    {
    {
      m68hc11tim_timer_event (me, (void*) (OVERFLOW_EVENT| 0x100));
      m68hc11tim_timer_event (me, (void*) (OVERFLOW_EVENT| 0x100));
    }
    }
  return cnt;
  return cnt;
}
}
 
 
 
 
const struct hw_descriptor dv_m68hc11tim_descriptor[] = {
const struct hw_descriptor dv_m68hc11tim_descriptor[] = {
  { "m68hc11tim", m68hc11tim_finish },
  { "m68hc11tim", m68hc11tim_finish },
  { "m68hc12tim", m68hc11tim_finish },
  { "m68hc12tim", m68hc11tim_finish },
  { NULL },
  { NULL },
};
};
 
 
 
 

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