Support for timers for mn103002. Still needs more testing/debugging.
authorJoyce Janczyn <janczyn@cygnus>
Mon, 8 Jun 1998 21:57:42 +0000 (21:57 +0000)
committerJoyce Janczyn <janczyn@cygnus>
Mon, 8 Jun 1998 21:57:42 +0000 (21:57 +0000)
sim/mn10300/dv-mn103tim.c [new file with mode: 0644]

diff --git a/sim/mn10300/dv-mn103tim.c b/sim/mn10300/dv-mn103tim.c
new file mode 100644 (file)
index 0000000..6347db6
--- /dev/null
@@ -0,0 +1,823 @@
+/*  This file is part of the program GDB, the GNU debugger.
+    
+    Copyright (C) 1998 Free Software Foundation, Inc.
+    Contributed by Cygnus Solutions.
+    
+    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
+    the Free Software Foundation; either version 2 of the License, or
+    (at your option) any later version.
+    
+    This program 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 this program; if not, write to the Free Software
+    Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
+    
+    */
+
+#include "sim-main.h"
+#include "hw-main.h"
+
+/* DEVICE
+
+   
+   mn103tim - mn103002 timers (8 and 16 bit)
+
+   
+   DESCRIPTION
+   
+   Implements the mn103002 8 and 16 bit timers as described in the mn103002 user guide.
+
+
+   PROPERTIES   
+
+   reg = <8bit-timers-addr> <8bit-timers-size> <16bit-timers-addr> <16bit-timers-size>
+
+
+   BUGS
+
+   */
+
+
+/* The timers' register address blocks */
+
+struct mn103tim_block {
+  unsigned_word base;
+  unsigned_word bound;
+};
+
+enum { TIMER8_BLOCK, TIMER16_BLOCK, NR_TIMER_BLOCKS };
+
+enum timer_register_types {
+  FIRST_MODE_REG = 0,
+  TM0MD = FIRST_MODE_REG,
+  TM1MD,
+  TM2MD,
+  TM3MD,
+  TM4MD,
+  TM5MD,
+  TM6MD,
+  LAST_MODE_REG = TM6MD,
+  FIRST_BASE_REG,
+  TM0BR = FIRST_BASE_REG,
+  TM1BR,
+  TM2BR,
+  TM3BR,
+  TM4BR,
+  TM5BR,
+  LAST_BASE_REG = TM5BR,
+  FIRST_COUNTER,
+  TM0BC = FIRST_COUNTER,
+  TM1BC,
+  TM2BC,
+  TM3BC,
+  TM4BC,
+  TM5BC,
+  TM6BC,
+  LAST_COUNTER = TM6BC,
+  TM6MDA,
+  TM6MDB,
+  TM6CA,
+  TM6CB,
+};
+
+
+/* Don't include timer 6 because it's handled specially. */
+#define NR_8BIT_TIMERS 4
+#define NR_16BIT_TIMERS 2
+#define NR_TIMERS 6
+
+typedef struct _mn10300_timer {
+  unsigned32 div_ratio, start, base;
+  unsigned8  mode;
+  struct hw_event *event;
+} mn10300_timer;
+
+
+struct mn103tim {
+  struct mn103tim_block block[NR_TIMER_BLOCKS];
+  mn10300_timer timer[NR_TIMERS];
+
+  /* treat timer 6 registers specially. */
+  unsigned16   tm6md, tm6bc, tm6mca, tm6mcb; 
+  unsigned8  tm6mda, tm6mdb;  /* compare/capture mode regs for timer 6 */
+  struct hw_event *event6;
+};
+
+/* output port ID's */
+
+/* for mn103002 */
+enum {
+  TIMER0_UFLOW,
+  TIMER1_UFLOW,
+  TIMER2_UFLOW,
+  TIMER3_UFLOW,
+  TIMER4_UFLOW,
+  TIMER5_UFLOW,
+  TIMER6_UFLOW,
+  TIMER6_CMPA,
+  TIMER6_CMPB,
+};
+
+
+static const struct hw_port_descriptor mn103tim_ports[] = {
+
+  { "timer-0-underflow", TIMER0_UFLOW, 0, output_port, },
+  { "timer-1-underflow", TIMER1_UFLOW, 0, output_port, },
+  { "timer-2-underflow", TIMER2_UFLOW, 0, output_port, },
+  { "timer-3-underflow", TIMER3_UFLOW, 0, output_port, },
+  { "timer-4-underflow", TIMER4_UFLOW, 0, output_port, },
+  { "timer-5-underflow", TIMER5_UFLOW, 0, output_port, },
+
+  { "timer-6-underflow", TIMER6_UFLOW, 0, output_port, },
+  { "timer-6-compare-a", TIMER6_CMPA, 0, output_port, },
+  { "timer-6-compare-b", TIMER6_CMPB, 0, output_port, },
+
+  { NULL, },
+};
+
+#define bits2to5_mask 0x3c
+#define load_mask     0x40
+#define count_mask    0x80
+#define count_and_load_mask (load_mask | count_mask)
+#define clock_mask    0x03
+#define clk_ioclk    0x00
+#define clk_cascaded 0x03
+
+
+/* Finish off the partially created hw device.  Attach our local
+   callbacks.  Wire up our port names etc */
+
+static hw_io_read_buffer_method mn103tim_io_read_buffer;
+static hw_io_write_buffer_method mn103tim_io_write_buffer;
+
+static void
+attach_mn103tim_regs (struct hw *me,
+                     struct mn103tim *timers)
+{
+  int i;
+  if (hw_find_property (me, "reg") == NULL)
+    hw_abort (me, "Missing \"reg\" property");
+  for (i = 0; i < NR_TIMER_BLOCKS; i++)
+    {
+      unsigned_word attach_address;
+      int attach_space;
+      unsigned attach_size;
+      reg_property_spec reg;
+      if (!hw_find_reg_array_property (me, "reg", i, &reg))
+       hw_abort (me, "\"reg\" property must contain three addr/size entries");
+      hw_unit_address_to_attach_address (hw_parent (me),
+                                        &reg.address,
+                                        &attach_space,
+                                        &attach_address,
+                                        me);
+      timers->block[i].base = attach_address;
+      hw_unit_size_to_attach_size (hw_parent (me),
+                                  &reg.size,
+                                  &attach_size, me);
+      timers->block[i].bound = attach_address + (attach_size - 1);
+      hw_attach_address (hw_parent (me),
+                        0,
+                        attach_space, attach_address, attach_size,
+                        me);
+    }
+}
+
+static void
+mn103tim_finish (struct hw *me)
+{
+  struct mn103tim *timers;
+  int i;
+
+  timers = HW_ZALLOC (me, struct mn103tim);
+  set_hw_data (me, timers);
+  set_hw_io_read_buffer (me, mn103tim_io_read_buffer);
+  set_hw_io_write_buffer (me, mn103tim_io_write_buffer);
+  set_hw_ports (me, mn103tim_ports);
+
+  /* Attach ourself to our parent bus */
+  attach_mn103tim_regs (me, timers);
+
+  /* Initialize the timers */
+  for ( i=0; i < NR_TIMERS; ++i )
+    {
+      timers->timer[i].event = NULL;
+      timers->timer[i].mode = 0x00;
+      timers->timer[i].base = 0;
+      timers->timer[i].div_ratio = 0;
+      timers->timer[i].start = 0;
+    }
+  timers->tm6md = 0x0000;
+  timers->tm6bc = 0x0000;
+  timers->tm6mca = 0x0000;
+  timers->tm6mcb = 0x0000;
+  timers->tm6mda = 0x00;
+  timers->tm6mdb = 0x00;
+}
+
+
+
+/* read and write */
+
+static int
+decode_addr (struct hw *me,
+            struct mn103tim *timers,
+            unsigned_word address)
+{
+  unsigned_word offset;
+  offset = address - timers->block[0].base;
+
+  switch (offset)
+    {
+    case 0x00: return TM0MD;
+    case 0x01: return TM1MD;
+    case 0x02: return TM2MD;
+    case 0x03: return TM3MD;
+    case 0x10: return TM0BR;
+    case 0x11: return TM1BR;
+    case 0x12: return TM2BR;
+    case 0x13: return TM3BR;
+    case 0x20: return TM0BC;
+    case 0x21: return TM1BC;
+    case 0x22: return TM2BC;
+    case 0x23: return TM3BC;
+    case 0x80: return TM4MD;
+    case 0x82: return TM5MD;
+    case 0x84: return TM6MD;
+    case 0x90: return TM4BR;
+    case 0x92: return TM5BR;
+    case 0xa0: return TM4BC;
+    case 0xa2: return TM5BC;
+    case 0xa4: return TM6BC;
+    case 0xb4: return TM6MDA;
+    case 0xb5: return TM6MDB;
+    case 0xc4: return TM6CA;
+    case 0xd4: return TM6CB;
+    default: 
+      {
+       hw_abort (me, "bad address");
+       return -1;
+      }
+    }
+}
+
+static void
+read_mode_reg (struct hw *me,
+              struct mn103tim *timers,
+              int timer_nr,
+              void *dest,
+              unsigned nr_bytes)
+{
+  unsigned16 val16;
+  unsigned32 val32;
+
+  switch ( nr_bytes )
+    {
+    case 1:
+      /* Accessing 1 byte is ok for all mode registers. */
+      *(unsigned8*)dest = timers->timer[timer_nr].mode;
+      break;
+
+    case 2:
+      if ( timer_nr == 6 )
+       {
+         *(unsigned16 *)dest = timers->tm6md;
+       }
+      else if ( timer_nr == 0 || timer_nr == 2 )
+       {
+         val16 = (timers->timer[timer_nr].mode << 8)
+           | timers->timer[timer_nr+1].mode;
+         *(unsigned16*)dest = val16;
+       }
+      else
+       {
+         hw_abort (me, "bad read size of 2 bytes to TM%dMD.", timer_nr);
+       }
+      break;
+
+    case 4:
+      if ( timer_nr == 0 )
+       {
+         val32 = (timers->timer[0].mode << 24 )
+           | (timers->timer[1].mode << 16)
+           | (timers->timer[2].mode << 8)
+           | timers->timer[3].mode;
+         *(unsigned32*)dest = val32;
+       }
+      else
+       {
+         hw_abort (me, "bad read size of 4 bytes to TM%dMD.", timer_nr);
+       }
+      break;
+
+    default:
+      hw_abort (me, "bad read size of %d bytes to TM%dMD.",
+               nr_bytes, timer_nr);
+    }
+}
+
+
+static void
+read_base_reg (struct hw *me,
+              struct mn103tim *timers,
+              int timer_nr,
+              void *dest,
+              unsigned  nr_bytes)
+{
+  unsigned16 val16;
+  unsigned32 val32;
+
+  /* Check nr_bytes: accesses of 1, 2 and 4 bytes allowed depending on timer. */
+  switch ( nr_bytes )
+    {
+    case 1:
+      /* Reading 1 byte is ok for all registers. */
+      if ( timer_nr < NR_8BIT_TIMERS )
+       {
+         *(unsigned8*)dest = timers->timer[timer_nr].base;
+       }
+      break;
+
+    case 2:
+      if ( timer_nr == 1 || timer_nr == 3 )
+       {
+         hw_abort (me, "bad read size of 2 bytes to TM%dBR.", timer_nr);
+       }
+      else
+       {
+         if ( timer_nr < NR_8BIT_TIMERS )
+           {
+             val16 = (timers->timer[timer_nr].base<<8)
+               | timers->timer[timer_nr+1].base;
+           }
+         else 
+           {
+             val16 = timers->timer[timer_nr].base;
+           }
+         *(unsigned16*)dest = val16;
+       }
+      break;
+
+    case 4:
+      if ( timer_nr == 0 )
+       {
+         val32 = (timers->timer[0].base << 24) | (timers->timer[1].base << 16)
+           | (timers->timer[2].base << 8) | timers->timer[3].base;
+         *(unsigned32*)dest = val32;
+       }
+      else if ( timer_nr == 4 ) 
+       {
+         val32 = (timers->timer[4].base << 16) | timers->timer[5].base;
+         *(unsigned32*)dest = val32;
+       }
+      else
+       {
+         hw_abort (me, "bad read size of 4 bytes to TM%dBR.", timer_nr);
+       }
+      break;
+
+    default:
+      hw_abort (me, "bad read size must of %d bytes to TM%dBR.",
+               nr_bytes, timer_nr); 
+    }
+}
+
+
+static void
+read_counter (struct hw *me,
+             struct mn103tim *timers,
+             int timer_nr,
+             void *dest,
+             unsigned  nr_bytes)
+{
+  unsigned32 val;
+
+  if ( NULL == timers->timer[timer_nr].event )
+    {
+      /* Timer is not counting, use value in base register. */
+      val = timers->timer[timer_nr].base;
+    }
+  else
+    {
+      /* ticks left = start time + div ratio - curr time */
+      /* Cannot use base register because it can be written during counting and it
+        doesn't affect counter until underflow occurs. */
+
+      val = timers->timer[timer_nr].start + timers->timer[timer_nr].div_ratio
+       - hw_event_queue_time(me);
+    }
+
+  switch (nr_bytes) {
+  case 1:
+    *(unsigned8 *)dest = val;
+    break;
+    
+  case 2:
+    *(unsigned16 *)dest = val;
+    break;
+
+  case 4:
+    *(unsigned32 *)dest = val;
+    break;
+
+  default:
+    hw_abort(me, "bad read size for reading counter");
+  }
+      
+}
+
+
+static unsigned
+mn103tim_io_read_buffer (struct hw *me,
+                        void *dest,
+                        int space,
+                        unsigned_word base,
+                        unsigned nr_bytes)
+{
+  struct mn103tim *timers = hw_data (me);
+  enum timer_register_types timer_reg;
+
+  HW_TRACE ((me, "read 0x%08lx %d", (long) base, (int) nr_bytes));
+
+  timer_reg = decode_addr (me, timers, base);
+
+  /* It can be either a mode register, a base register or a binary counter. */
+  /* Check in that order. */
+  if ( timer_reg >= FIRST_MODE_REG && timer_reg <= LAST_MODE_REG )
+    {
+      read_mode_reg(me, timers, timer_reg-FIRST_MODE_REG, dest, nr_bytes);
+    }
+  else if ( timer_reg <= LAST_BASE_REG )
+    {
+      read_base_reg(me, timers, timer_reg-FIRST_BASE_REG, dest, nr_bytes);
+    }
+  else if ( timer_reg <= LAST_COUNTER )
+    {
+      read_counter(me, timers, timer_reg-FIRST_COUNTER, dest, nr_bytes);
+    }
+  else
+    {
+      hw_abort(me, "invalid timer register address.");
+    }
+
+  return nr_bytes;
+}     
+
+
+static void
+do_counter_event (struct hw *me,
+                 void *data)
+{
+  struct mn103tim *timers = hw_data(me);
+  int timer_nr = (int) data;
+
+  /* Check if counting is still enabled. */
+  if ( (timers->timer[timer_nr].mode & count_mask) != 0 )
+    {
+      /* Generate an interrupt for the timer underflow (TIMERn_UFLOW). */
+      hw_port_event (me, timer_nr /*uflow_port[timer_nr]*/, 1 /* level */);
+
+      /* Schedule next timeout.  */
+
+      timers->timer[timer_nr].start = hw_event_queue_time(me);
+      /* FIX: Check if div_ ratio has changed and if it's now 0. */
+      timers->timer[timer_nr].event
+       = hw_event_queue_schedule (me, timers->timer[timer_nr].div_ratio,
+                                  do_counter_event, (void *)timer_nr);
+    }
+
+}
+
+static void
+write_base_reg (struct hw *me,
+               struct mn103tim *timers,
+               int timer_nr,
+               const void *source,
+               unsigned  nr_bytes)
+{
+  unsigned i;
+  const unsigned8 *buf8 = source;
+  const unsigned16 *buf16 = source;
+  unsigned8 mode_val;
+
+  /* If TMnCNE == 0 (counting is off),  writing to the base register
+     (TMnBR) causes a simultaneous write to the counter reg (TMnBC).
+     Else, the TMnBC is reloaded with the value from TMnBR when
+     underflow occurs.  Since the counter register is not explicitly
+     maintained, this functionality is handled in read_counter. */
+
+  mode_val = timers->timer[timer_nr].mode;
+
+  /* Check nr_bytes: write of 1, 2 or 4 bytes allowed depending on timer. */
+  switch ( nr_bytes )
+    {
+    case 1:
+      /* Storing 1 byte is ok for all registers. */
+      timers->timer[timer_nr].base = buf8[0];
+      break;
+
+    case 2:
+      if ( timer_nr == 1 || timer_nr == 3 )
+       {
+         hw_abort (me, "bad write size of 2 bytes to TM%dBR.", timer_nr);
+       }
+      else
+       {
+         if ( timer_nr < NR_8BIT_TIMERS )
+           {
+             timers->timer[timer_nr].base = buf8[0];
+             timers->timer[timer_nr+1].base = buf8[1];
+           }
+         else 
+           {
+             timers->timer[timer_nr].base = buf16[0];
+           }
+       }
+      break;
+
+    case 4:
+      if ( timer_nr == 0 )
+       {
+         ASSERT(0);
+         timers->timer[0].base = buf8[0];
+         timers->timer[1].base = buf8[1];
+         timers->timer[2].base = buf8[2];
+         timers->timer[3].base = buf8[3];
+       }
+      else if ( timer_nr == 4 )
+       {
+         timers->timer[4].base = buf16[0];
+         timers->timer[5].base = buf16[1];
+       }
+      else
+       {
+         hw_abort (me, "bad write size of 4 bytes to TM%dBR.", timer_nr);
+       }
+      break;
+
+    default:
+      hw_abort (me, "bad write size must of %d bytes to TM%dBR.",
+               nr_bytes, timer_nr);
+    }
+     
+}
+
+static void
+write_8bit_mode_reg (struct hw *me,
+                    struct mn103tim *timers,
+                    int timer_nr,
+                    const void *source,
+                    unsigned nr_bytes)
+     /* for timers 0 to 3 */
+{
+  unsigned i;
+  unsigned8 mode_val, next_mode_val;
+  unsigned32 div_ratio;
+
+  if ( nr_bytes != 1 )
+    {
+      hw_abort (me, "bad write size of %d bytes to TM%dMD.", nr_bytes, timer_nr);
+    }
+
+  mode_val = *(unsigned8 *)source;
+  timers->timer[timer_nr].mode = mode_val;
+      
+  if ( ( mode_val & count_and_load_mask ) == count_and_load_mask )
+    {
+      hw_abort(me, "Cannot load base reg and start counting simultaneously.");
+    }
+  if ( ( mode_val & bits2to5_mask ) != 0 )
+    {
+      hw_abort(me, "Cannot write to bits 2 to 5 of mode register");
+    }
+      
+  if ( mode_val & count_mask )
+    {
+      /* - de-schedule any previous event. */
+      /* - add new event to queue to start counting. */
+      /* - assert that counter == base reg? */
+
+      /* For cascaded timers, */
+      if ( (mode_val & clock_mask) == clk_cascaded )
+       {
+         if ( timer_nr == 0 )
+           {
+             hw_abort(me, "Timer 0 cannot be cascaded.");
+           }
+       }
+      else
+       {
+         div_ratio = timers->timer[timer_nr].base;
+
+         /* Check for cascading. */
+         next_mode_val = timers->timer[timer_nr+1].mode;
+         if ( ( next_mode_val & clock_mask ) == clk_cascaded )
+           {
+             /* Check that CNE is on. */
+             if ( ( next_mode_val & count_mask ) == 0 ) 
+               {
+                 hw_abort (me, "cascaded timer not ready for counting");
+               }
+             ASSERT(timers->timer[timer_nr+1].event == NULL);
+             ASSERT(timers->timer[timer_nr+1].div_ratio == 0);
+             div_ratio = div_ratio | (timers->timer[timer_nr+1].base << 8);
+           }
+
+         timers->timer[timer_nr].div_ratio = div_ratio;
+
+         if ( NULL != timers->timer[timer_nr].event )
+           {
+             hw_event_queue_deschedule (me, timers->timer[timer_nr].event);
+             timers->timer[timer_nr].event = NULL;
+           }
+
+         if ( div_ratio > 0 )
+           {
+             /* Set start time. */
+             timers->timer[timer_nr].start = hw_event_queue_time(me);
+             
+             timers->timer[timer_nr].event
+               = hw_event_queue_schedule(me, div_ratio,
+                                         do_counter_event,
+                                         (void *)(timer_nr)); 
+           }
+       }
+    }
+  else
+    {
+      /* Turn off counting */
+      if ( NULL != timers->timer[timer_nr].event )
+       {
+         ASSERT((timers->timer[timer_nr].mode & clock_mask) != clk_cascaded);
+         hw_event_queue_deschedule (me, timers->timer[timer_nr].event);
+         timers->timer[timer_nr].event = NULL;
+       }
+      else
+       {
+         if ( (timers->timer[timer_nr].mode & clock_mask) == clk_cascaded )
+           {
+             ASSERT(timers->timer[timer_nr].event == NULL);
+           }
+       }
+      
+    }
+
+}
+
+static void
+write_16bit_mode_reg (struct hw *me,
+                     struct mn103tim *timers,
+                     int timer_nr,
+                     const void *source,
+                     unsigned nr_bytes)
+     /* for timers 4 and 5, not 6 */
+{
+  unsigned i;
+  unsigned8 mode_val, next_mode_val;
+  unsigned32 div_ratio;
+
+  if ( nr_bytes != 1 )
+    {
+      hw_abort (me, "bad write size of %d bytes to TM%dMD.", nr_bytes, timer_nr);
+    }
+
+  mode_val = *(unsigned8 *)source;
+  timers->timer[timer_nr].mode = mode_val;
+      
+  if ( ( mode_val & count_and_load_mask ) == count_and_load_mask )
+    {
+      hw_abort(me, "Cannot load base reg and start counting simultaneously.");
+    }
+  if ( ( mode_val & bits2to5_mask ) != 0 )
+    {
+      hw_abort(me, "Cannot write to bits 2 to 5 of mode register");
+    }
+
+     
+  if ( mode_val & count_mask )
+    {
+      /* - de-schedule any previous event. */
+      /* - add new event to queue to start counting. */
+      /* - assert that counter == base reg? */
+
+      /* For cascaded timers, */
+      if ( (mode_val & clock_mask) == clk_cascaded )
+       {
+         if ( timer_nr == 4 )
+           {
+             hw_abort(me, "Timer 4 cannot be cascaded.");
+           }
+       }
+      else
+       {
+         div_ratio = timers->timer[timer_nr].base;
+         
+         /* Check for cascading. */
+         next_mode_val = timers->timer[timer_nr+1].mode;
+         if ( ( next_mode_val & clock_mask ) == clk_cascaded )
+           {
+             /* Check that CNE is on. */
+             if ( ( next_mode_val & count_mask ) == 0 ) 
+               {
+                 hw_abort (me, "cascaded timer not ready for counting");
+               }
+             ASSERT(timers->timer[timer_nr+1].event == NULL);
+             ASSERT(timers->timer[timer_nr+1].div_ratio == 0);
+             div_ratio = div_ratio | (timers->timer[timer_nr+1].base << 16);
+           }
+
+         timers->timer[timer_nr].div_ratio = div_ratio;
+      
+         if ( NULL != timers->timer[timer_nr].event )
+           {
+             hw_event_queue_deschedule (me, timers->timer[timer_nr].event);
+             timers->timer[timer_nr].event = NULL;
+           }
+
+         if ( div_ratio > 0 )
+           {
+             /* Set start time. */
+             timers->timer[timer_nr].start = hw_event_queue_time(me);
+             
+             timers->timer[timer_nr].event
+               = hw_event_queue_schedule(me, div_ratio, do_counter_event,
+                                         (void *)(timer_nr));
+           }
+       }
+    }
+  else
+    {
+      /* Turn off counting */
+      if ( NULL != timers->timer[timer_nr].event )
+       {
+         ASSERT((timers->timer[timer_nr].mode & clock_mask) != clk_cascaded);
+         hw_event_queue_deschedule (me, timers->timer[timer_nr].event);
+         timers->timer[timer_nr].event = NULL;
+       }
+      else
+       {
+         if ( (timers->timer[timer_nr].mode & clock_mask) == clk_cascaded )
+           {
+             ASSERT(timers->timer[timer_nr].event == NULL);
+           }
+       }
+      
+    }
+
+}
+
+static unsigned
+mn103tim_io_write_buffer (struct hw *me,
+                         const void *source,
+                         int space,
+                         unsigned_word base,
+                         unsigned nr_bytes)
+{
+  struct mn103tim *timers = hw_data (me);
+  enum timer_register_types timer_reg;
+
+  HW_TRACE ((me, "write to 0x%08lx length %d with 0x%x", (long) base,
+            (int) nr_bytes, *(unsigned32 *)source));
+
+  timer_reg = decode_addr (me, timers, base);
+
+  /* It can be either a mode register, a base register or a binary counter. */
+  /* Check in that order. */
+  if ( timer_reg <= LAST_MODE_REG )
+    {
+      if ( timer_reg > 3 )
+       {
+         write_16bit_mode_reg(me, timers, timer_reg-FIRST_MODE_REG,
+                              source, nr_bytes);
+       }
+      else
+       {
+         write_8bit_mode_reg(me, timers, timer_reg-FIRST_MODE_REG,
+                              source, nr_bytes);
+       }
+    }
+  else if ( timer_reg <= LAST_BASE_REG )
+    {
+      write_base_reg(me, timers, timer_reg-FIRST_BASE_REG, source, nr_bytes);
+    }
+  else if ( timer_reg <= LAST_COUNTER )
+    {
+      hw_abort(me, "cannot write to counter");
+    }
+  else
+    {
+      hw_abort(me, "invalid reg type");
+    }
+
+  return nr_bytes;
+}     
+
+
+const struct hw_descriptor dv_mn103tim_descriptor[] = {
+  { "mn103tim", mn103tim_finish, },
+  { NULL },
+};