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[/] [openrisc/] [trunk/] [or1ksim/] [peripheral/] [mc.c] - Blame information for rev 224

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/* mc.c -- Simulation of Memory Controller
 
   Copyright (C) 2001 by Marko Mlinar, markom@opencores.org
   Copyright (C) 2008 Embecosm Limited
 
   Contributor Jeremy Bennett <jeremy.bennett@embecosm.com>
 
   This file is part of Or1ksim, the OpenRISC 1000 Architectural Simulator.
 
   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 3 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, see <http://www.gnu.org/licenses/>.  */
 
/* This program is commented throughout in a fashion suitable for processing
   with Doxygen. */
 
 
/* Enable memory controller, via:
  section mc
    enable = 1
    POC = 0x13243545
  end
 
   Limitations:
    - memory refresh is not simulated
*/
 
 
/* Autoconf and/or portability configuration */
#include "config.h"
#include "port.h"
 
/* System includes */
#include <stdlib.h>
 
/* Package includes */
#include "arch.h"
#include "abstract.h"
#include "sim-config.h"
#include "toplevel-support.h"
#include "sim-cmd.h"
#include "mc.h"
 
 
struct mc_area
{
  struct dev_memarea *mem;
  unsigned int cs;
  int mc;
  struct mc_area *next;
};
 
struct mc
{
  uint32_t csr;
  uint32_t poc;
  uint32_t ba_mask;
  uint32_t csc[N_CE];
  uint32_t tms[N_CE];
  oraddr_t baseaddr;
  int enabled;
 
  /* Index of this memory controler amongst all the memory controlers */
  int index;
  /* List of memory devices under this mc's control */
  struct mc_area *mc_areas;
 
  struct mc *next;
};
 
static struct mc *mcs = NULL;
 
/* List used to temporarily hold memory areas registered with the mc, while the
 * mc configureation has not been loaded */
static struct mc_area *mc_areas = NULL;
 
void
set_csc_tms (int cs, uint32_t csc, uint32_t tms, struct mc *mc)
{
  struct mc_area *cur = mc->mc_areas;
 
  while (cur)
    {
      if (cur->cs == cs)
        {
          /* FIXME: No peripheral should _ever_ acess a dev_memarea structure
           * directly */
          cur->mem->addr_mask = mc->ba_mask << 22;
          cur->mem->addr_compare =
            ((csc >> MC_CSC_SEL_OFFSET) /* & 0xff */ ) << 22;
          set_mem_valid (cur->mem, (csc >> MC_CSC_EN_OFFSET) & 0x01);
 
          if ((csc >> MC_CSC_MEMTYPE_OFFSET) && 0x07 == MC_CSC_MEMTYPE_ASYNC)
            {
              adjust_rw_delay (cur->mem, (tms & 0xff) + ((tms >> 8) & 0x0f),
                               ((tms >> 12) & 0x0f) + ((tms >> 16) & 0x0f) +
                               ((tms >> 20) & 0x3f));
            }
          else if ((csc >> MC_CSC_MEMTYPE_OFFSET)
                   && 0x07 == MC_CSC_MEMTYPE_SDRAM)
            {
              adjust_rw_delay (cur->mem, 3 + ((tms >> 4) & 0x03),
                               3 + ((tms >> 4) & 0x03));
            }
          else if ((csc >> MC_CSC_MEMTYPE_OFFSET)
                   && 0x07 == MC_CSC_MEMTYPE_SSRAM)
            {
              adjust_rw_delay (cur->mem, 2, 2);
            }
          else if ((csc >> MC_CSC_MEMTYPE_OFFSET)
                   && 0x07 == MC_CSC_MEMTYPE_SYNC)
            {
              adjust_rw_delay (cur->mem, 2, 2);
            }
          return;
        }
      cur = cur->next;
    }
}
 
/* Set a specific MC register with value. */
void
mc_write_word (oraddr_t addr, uint32_t value, void *dat)
{
  struct mc *mc = dat;
  int chipsel;
 
  switch (addr)
    {
    case MC_CSR:
      mc->csr = value;
      break;
    case MC_POC:
      fprintf (stderr, "Warning: write to MC's POC register!");
      break;
    case MC_BA_MASK:
      mc->ba_mask = value & MC_BA_MASK_VALID;
      for (chipsel = 0; chipsel < N_CE; chipsel++)
        set_csc_tms (chipsel, mc->csc[chipsel], mc->tms[chipsel], mc);
      break;
    default:
      if (addr >= MC_CSC (0) && addr <= MC_TMS (N_CE - 1))
        {
          addr -= MC_CSC (0);
          if ((addr >> 2) & 1)
            mc->tms[addr >> 3] = value;
          else
            mc->csc[addr >> 3] = value;
 
          set_csc_tms (addr >> 3, mc->csc[addr >> 3], mc->tms[addr >> 3], mc);
          break;
        }
    }
}
 
/* Read a specific MC register. */
uint32_t
mc_read_word (oraddr_t addr, void *dat)
{
  struct mc *mc = dat;
  uint32_t value = 0;
 
  switch (addr)
    {
    case MC_CSR:
      value = mc->csr;
      break;
    case MC_POC:
      value = mc->poc;
      break;
    case MC_BA_MASK:
      value = mc->ba_mask;
      break;
    default:
      if (addr >= MC_CSC (0) && addr <= MC_TMS (N_CE - 1))
        {
          addr -= MC_CSC (0);
          if ((addr >> 2) & 1)
            value = mc->tms[addr >> 3];
          else
            value = mc->csc[addr >> 3];
        }
 
      break;
    }
  return value;
}
 
/* Read POC register and init memory controler regs. */
void
mc_reset (void *dat)
{
  struct mc *mc = dat;
  struct mc_area *cur, *prev, *tmp;
 
  PRINTF ("Resetting memory controller.\n");
 
  memset (mc->csc, 0, sizeof (mc->csc));
  memset (mc->tms, 0, sizeof (mc->tms));
 
  mc->csr = 0;
  mc->ba_mask = 0;
 
  /* Set CS0 */
  mc->csc[0] =
    (((mc->poc & 0x0c) >> 2) << MC_CSC_MEMTYPE_OFFSET) | ((mc->
                                                           poc & 0x03) <<
                                                          MC_CSC_BW_OFFSET) |
    1;
 
  if ((mc->csc[0] >> MC_CSC_MEMTYPE_OFFSET) && 0x07 == MC_CSC_MEMTYPE_ASYNC)
    {
      mc->tms[0] = MC_TMS_ASYNC_VALID;
    }
  else if ((mc->csc[0] >> MC_CSC_MEMTYPE_OFFSET)
           && 0x07 == MC_CSC_MEMTYPE_SDRAM)
    {
      mc->tms[0] = MC_TMS_SDRAM_VALID;
    }
  else if ((mc->csc[0] >> MC_CSC_MEMTYPE_OFFSET)
           && 0x07 == MC_CSC_MEMTYPE_SSRAM)
    {
      mc->tms[0] = MC_TMS_SSRAM_VALID;
    }
  else if ((mc->csc[0] >> MC_CSC_MEMTYPE_OFFSET)
           && 0x07 == MC_CSC_MEMTYPE_SYNC)
    {
      mc->tms[0] = MC_TMS_SYNC_VALID;
    }
 
  /* Grab control over all the devices we are destined to control */
  cur = mc_areas;
  prev = NULL;
  while (cur)
    {
      if (cur->mc == mc->index)
        {
          if (prev)
            prev->next = cur->next;
          else
            mc_areas = cur->next;
          prev = cur;
          tmp = cur->next;
          cur->next = mc->mc_areas;
          mc->mc_areas = cur;
          cur = tmp;
        }
      else
        {
          prev = cur;
          cur = cur->next;
        }
    }
 
  for (cur = mc->mc_areas; cur; cur = cur->next)
    set_mem_valid (cur->mem, 0);
 
  set_csc_tms (0, mc->csc[0], mc->tms[0], mc);
}
 
/*---------------------------------------------------------------------------*/
/*!Free all allocated memory                                                 */
/*---------------------------------------------------------------------------*/
void
mc_done ()
{
  while (NULL != mc_areas)
    {
      struct mc_area *next = mc_areas->next;
 
      free (mc_areas);
      mc_areas = next;
    }
}       /* mc_done () */
 
 
void
mc_status (void *dat)
{
  struct mc *mc = dat;
  int i;
 
  PRINTF ("\nMemory Controller at 0x%" PRIxADDR ":\n", mc->baseaddr);
  PRINTF ("POC: 0x%" PRIx32 "\n", mc->poc);
  PRINTF ("BAS: 0x%" PRIx32 "\n", mc->ba_mask);
  PRINTF ("CSR: 0x%" PRIx32 "\n", mc->csr);
 
  for (i = 0; i < N_CE; i++)
    {
      PRINTF ("CE %02d -  CSC: 0x%" PRIx32 "  TMS: 0x%" PRIx32 "\n", i,
              mc->csc[i], mc->tms[i]);
    }
}
 
/*--------------------------------------------[ Peripheral<->MC interface ]---*/
/* Registers some memory to be under the memory controllers control */
void
mc_reg_mem_area (struct dev_memarea *mem, unsigned int cs, int mc)
{
  struct mc_area *new = malloc (sizeof (struct mc_area));
 
  if (NULL == new)
    {
      fprintf (stderr, "Out-of-memory\n");
      exit (-1);
    }
 
  new->cs   = cs;
  new->mem  = mem;
  new->mc   = mc;
 
  new->next = mc_areas;
 
  mc_areas  = new;
}
 
/*-----------------------------------------------------[ MC configuration ]---*/
static void
mc_enabled (union param_val val, void *dat)
{
  struct mc *mc = dat;
  mc->enabled = val.int_val;
}
 
static void
mc_baseaddr (union param_val val, void *dat)
{
  struct mc *mc = dat;
  mc->baseaddr = val.addr_val;
}
 
 
/*---------------------------------------------------------------------------*/
/*!Set the power on configuration state
 
   Only the bottom 4 bits are signficant. Other bits are truncated with a
   warning.
 
   @param[in] val  The value to use
   @param[in] dat  The config data structure                                 */
/*---------------------------------------------------------------------------*/
static void
mc_poc (union param_val  val,
        void            *dat)
{
  struct mc *mc = dat;
 
  if (val.int_val > 0xf)
    {
      fprintf (stderr, "Warning: memory controller PoC > 4 bits: truncated\n");
    }
 
  mc->poc = val.int_val & 0xf;
 
}       /* mc_poc() */
 
 
static void
mc_index (union param_val val, void *dat)
{
  struct mc *mc = dat;
  mc->index = val.int_val;
}
 
/*---------------------------------------------------------------------------*/
/*!Initialize a new memory controller configuration
 
   ALL parameters are set explicitly to default values.                      */
/*---------------------------------------------------------------------------*/
static void *
mc_sec_start ()
{
  struct mc *new = malloc (sizeof (struct mc));
 
  if (!new)
    {
      fprintf (stderr, "Peripheral MC: Run out of memory\n");
      exit (-1);
    }
 
  new->enabled  = 1;
  new->baseaddr = 0;
  new->poc      = 0;
  new->index    = 0;
 
  new->mc_areas = NULL;
 
  return new;
}
 
static void
mc_sec_end (void *dat)
{
  struct mc *mc = dat;
  struct mem_ops ops;
 
  if (!mc->enabled)
    {
      free (dat);
      return;
    }
 
  /* FIXME: Check to see that the index given to this mc is unique */
 
  mc->next = mcs;
  mcs = mc;
 
  memset (&ops, 0, sizeof (struct mem_ops));
 
  ops.readfunc32 = mc_read_word;
  ops.writefunc32 = mc_write_word;
  ops.write_dat32 = dat;
  ops.read_dat32 = dat;
 
  /* FIXME: Correct delays? */
  ops.delayr = 2;
  ops.delayw = 2;
 
  reg_mem_area (mc->baseaddr, MC_ADDR_SPACE, 1, &ops);
  reg_sim_reset (mc_reset, dat);
  reg_sim_stat (mc_status, dat);
}
 
void
reg_mc_sec (void)
{
  struct config_section *sec =
    reg_config_sec ("mc", mc_sec_start, mc_sec_end);
 
  reg_config_param (sec, "enabled",  PARAMT_INT, mc_enabled);
  reg_config_param (sec, "baseaddr", PARAMT_ADDR, mc_baseaddr);
  reg_config_param (sec, "POC",      PARAMT_INT, mc_poc);
  reg_config_param (sec, "index",    PARAMT_INT, mc_index);
}

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[/] [openrisc/] [trunk/] [or1ksim/] [peripheral/] [mc.c] - Blame information for rev 224

Line No.	Rev	Author	Line
1	19	jeremybenn	`/* mc.c -- Simulation of Memory Controller`
2
3			`Copyright (C) 2001 by Marko Mlinar, markom@opencores.org`
4			`Copyright (C) 2008 Embecosm Limited`
5
6			`Contributor Jeremy Bennett <jeremy.bennett@embecosm.com>`
7
8			`This file is part of Or1ksim, the OpenRISC 1000 Architectural Simulator.`
9
10			`This program is free software; you can redistribute it and/or modify it`
11			`under the terms of the GNU General Public License as published by the Free`
12			`Software Foundation; either version 3 of the License, or (at your option)`
13			`any later version.`
14
15			`This program is distributed in the hope that it will be useful, but WITHOUT`
16			`ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or`
17			`FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for`
18			`more details.`
19
20			`You should have received a copy of the GNU General Public License along`
21			`with this program. If not, see <http://www.gnu.org/licenses/>. */`
22
23			`/* This program is commented throughout in a fashion suitable for processing`
24			`with Doxygen. */`
25
26
27			`/* Enable memory controller, via:`
28			`section mc`
29			`enable = 1`
30			`POC = 0x13243545`
31			`end`
32
33			`Limitations:`
34			`- memory refresh is not simulated`
35			`*/`
36
37
38			`/* Autoconf and/or portability configuration */`
39			`#include "config.h"`
40			`#include "port.h"`
41
42			`/* System includes */`
43			`#include <stdlib.h>`
44
45			`/* Package includes */`
46			`#include "arch.h"`
47			`#include "abstract.h"`
48			`#include "sim-config.h"`
49			`#include "toplevel-support.h"`
50			`#include "sim-cmd.h"`
51	82	jeremybenn	`#include "mc.h"`
52	19	jeremybenn
53
54			`struct mc_area`
55			`{`
56			`struct dev_memarea *mem;`
57			`unsigned int cs;`
58			`int mc;`
59			`struct mc_area *next;`
60			`};`
61
62			`struct mc`
63			`{`
64			`uint32_t csr;`
65			`uint32_t poc;`
66			`uint32_t ba_mask;`
67			`uint32_t csc[N_CE];`
68			`uint32_t tms[N_CE];`
69			`oraddr_t baseaddr;`
70			`int enabled;`
71
72			`/* Index of this memory controler amongst all the memory controlers */`
73			`int index;`
74			`/* List of memory devices under this mc's control */`
75			`struct mc_area *mc_areas;`
76
77			`struct mc *next;`
78			`};`
79
80			`static struct mc *mcs = NULL;`
81
82			`/* List used to temporarily hold memory areas registered with the mc, while the`
83			`* mc configureation has not been loaded */`
84			`static struct mc_area *mc_areas = NULL;`
85
86			`void`
87			`set_csc_tms (int cs, uint32_t csc, uint32_t tms, struct mc *mc)`
88			`{`
89			`struct mc_area *cur = mc->mc_areas;`
90
91			`while (cur)`
92			`{`
93			`if (cur->cs == cs)`
94			`{`
95			`/* FIXME: No peripheral should _ever_ acess a dev_memarea structure`
96			`* directly */`
97			`cur->mem->addr_mask = mc->ba_mask << 22;`
98			`cur->mem->addr_compare =`
99			`((csc >> MC_CSC_SEL_OFFSET) /* & 0xff */ ) << 22;`
100			`set_mem_valid (cur->mem, (csc >> MC_CSC_EN_OFFSET) & 0x01);`
101
102			`if ((csc >> MC_CSC_MEMTYPE_OFFSET) && 0x07 == MC_CSC_MEMTYPE_ASYNC)`
103			`{`
104			`adjust_rw_delay (cur->mem, (tms & 0xff) + ((tms >> 8) & 0x0f),`
105			`((tms >> 12) & 0x0f) + ((tms >> 16) & 0x0f) +`
106			`((tms >> 20) & 0x3f));`
107			`}`
108			`else if ((csc >> MC_CSC_MEMTYPE_OFFSET)`
109			`&& 0x07 == MC_CSC_MEMTYPE_SDRAM)`
110			`{`
111			`adjust_rw_delay (cur->mem, 3 + ((tms >> 4) & 0x03),`
112			`3 + ((tms >> 4) & 0x03));`
113			`}`
114			`else if ((csc >> MC_CSC_MEMTYPE_OFFSET)`
115			`&& 0x07 == MC_CSC_MEMTYPE_SSRAM)`
116			`{`
117			`adjust_rw_delay (cur->mem, 2, 2);`
118			`}`
119			`else if ((csc >> MC_CSC_MEMTYPE_OFFSET)`
120			`&& 0x07 == MC_CSC_MEMTYPE_SYNC)`
121			`{`
122			`adjust_rw_delay (cur->mem, 2, 2);`
123			`}`
124			`return;`
125			`}`
126			`cur = cur->next;`
127			`}`
128			`}`
129
130			`/* Set a specific MC register with value. */`
131			`void`
132			`mc_write_word (oraddr_t addr, uint32_t value, void *dat)`
133			`{`
134			`struct mc *mc = dat;`
135			`int chipsel;`
136
137			`switch (addr)`
138			`{`
139			`case MC_CSR:`
140			`mc->csr = value;`
141			`break;`
142			`case MC_POC:`
143			`fprintf (stderr, "Warning: write to MC's POC register!");`
144			`break;`
145			`case MC_BA_MASK:`
146			`mc->ba_mask = value & MC_BA_MASK_VALID;`
147			`for (chipsel = 0; chipsel < N_CE; chipsel++)`
148			`set_csc_tms (chipsel, mc->csc[chipsel], mc->tms[chipsel], mc);`
149			`break;`
150			`default:`
151			`if (addr >= MC_CSC (0) && addr <= MC_TMS (N_CE - 1))`
152			`{`
153			`addr -= MC_CSC (0);`
154			`if ((addr >> 2) & 1)`
155			`mc->tms[addr >> 3] = value;`
156			`else`
157			`mc->csc[addr >> 3] = value;`
158
159			`set_csc_tms (addr >> 3, mc->csc[addr >> 3], mc->tms[addr >> 3], mc);`
160			`break;`
161			`}`
162			`}`
163			`}`
164
165			`/* Read a specific MC register. */`
166			`uint32_t`
167			`mc_read_word (oraddr_t addr, void *dat)`
168			`{`
169			`struct mc *mc = dat;`
170			`uint32_t value = 0;`
171
172			`switch (addr)`
173			`{`
174			`case MC_CSR:`
175			`value = mc->csr;`
176			`break;`
177			`case MC_POC:`
178			`value = mc->poc;`
179			`break;`
180			`case MC_BA_MASK:`
181			`value = mc->ba_mask;`
182			`break;`
183			`default:`
184			`if (addr >= MC_CSC (0) && addr <= MC_TMS (N_CE - 1))`
185			`{`
186			`addr -= MC_CSC (0);`
187			`if ((addr >> 2) & 1)`
188			`value = mc->tms[addr >> 3];`
189			`else`
190			`value = mc->csc[addr >> 3];`
191			`}`
192
193			`break;`
194			`}`
195			`return value;`
196			`}`
197
198			`/* Read POC register and init memory controler regs. */`
199			`void`
200			`mc_reset (void *dat)`
201			`{`
202			`struct mc *mc = dat;`
203			`struct mc_area cur, prev, *tmp;`
204
205			`PRINTF ("Resetting memory controller.\n");`
206
207			`memset (mc->csc, 0, sizeof (mc->csc));`
208			`memset (mc->tms, 0, sizeof (mc->tms));`
209
210			`mc->csr = 0;`
211			`mc->ba_mask = 0;`
212
213			`/* Set CS0 */`
214			`mc->csc[0] =`
215			`(((mc->poc & 0x0c) >> 2) << MC_CSC_MEMTYPE_OFFSET) \| ((mc->`
216			`poc & 0x03) <<`
217			`MC_CSC_BW_OFFSET) \|`
218			`1;`
219
220			`if ((mc->csc[0] >> MC_CSC_MEMTYPE_OFFSET) && 0x07 == MC_CSC_MEMTYPE_ASYNC)`
221			`{`
222			`mc->tms[0] = MC_TMS_ASYNC_VALID;`
223			`}`
224			`else if ((mc->csc[0] >> MC_CSC_MEMTYPE_OFFSET)`
225			`&& 0x07 == MC_CSC_MEMTYPE_SDRAM)`
226			`{`
227			`mc->tms[0] = MC_TMS_SDRAM_VALID;`
228			`}`
229			`else if ((mc->csc[0] >> MC_CSC_MEMTYPE_OFFSET)`
230			`&& 0x07 == MC_CSC_MEMTYPE_SSRAM)`
231			`{`
232			`mc->tms[0] = MC_TMS_SSRAM_VALID;`
233			`}`
234			`else if ((mc->csc[0] >> MC_CSC_MEMTYPE_OFFSET)`
235			`&& 0x07 == MC_CSC_MEMTYPE_SYNC)`
236			`{`
237			`mc->tms[0] = MC_TMS_SYNC_VALID;`
238			`}`
239
240			`/* Grab control over all the devices we are destined to control */`
241			`cur = mc_areas;`
242			`prev = NULL;`
243			`while (cur)`
244			`{`
245			`if (cur->mc == mc->index)`
246			`{`
247			`if (prev)`
248			`prev->next = cur->next;`
249			`else`
250			`mc_areas = cur->next;`
251			`prev = cur;`
252			`tmp = cur->next;`
253			`cur->next = mc->mc_areas;`
254			`mc->mc_areas = cur;`
255			`cur = tmp;`
256			`}`
257			`else`
258			`{`
259			`prev = cur;`
260			`cur = cur->next;`
261			`}`
262			`}`
263
264			`for (cur = mc->mc_areas; cur; cur = cur->next)`
265			`set_mem_valid (cur->mem, 0);`
266
267			`set_csc_tms (0, mc->csc[0], mc->tms[0], mc);`
268			`}`
269
270			`/---------------------------------------------------------------------------/`
271			`/!Free all allocated memory /`
272			`/---------------------------------------------------------------------------/`
273			`void`
274			`mc_done ()`
275			`{`
276			`while (NULL != mc_areas)`
277			`{`
278			`struct mc_area *next = mc_areas->next;`
279
280			`free (mc_areas);`
281			`mc_areas = next;`
282			`}`
283			`} /* mc_done () */`
284
285
286			`void`
287			`mc_status (void *dat)`
288			`{`
289			`struct mc *mc = dat;`
290			`int i;`
291
292			`PRINTF ("\nMemory Controller at 0x%" PRIxADDR ":\n", mc->baseaddr);`
293			`PRINTF ("POC: 0x%" PRIx32 "\n", mc->poc);`
294			`PRINTF ("BAS: 0x%" PRIx32 "\n", mc->ba_mask);`
295			`PRINTF ("CSR: 0x%" PRIx32 "\n", mc->csr);`
296
297			`for (i = 0; i < N_CE; i++)`
298			`{`
299			`PRINTF ("CE %02d - CSC: 0x%" PRIx32 " TMS: 0x%" PRIx32 "\n", i,`
300			`mc->csc[i], mc->tms[i]);`
301			`}`
302			`}`
303
304			`/--------------------------------------------[ Peripheral<->MC interface ]---/`
305			`/* Registers some memory to be under the memory controllers control */`
306			`void`
307			`mc_reg_mem_area (struct dev_memarea *mem, unsigned int cs, int mc)`
308			`{`
309			`struct mc_area *new = malloc (sizeof (struct mc_area));`
310
311			`if (NULL == new)`
312			`{`
313			`fprintf (stderr, "Out-of-memory\n");`
314			`exit (-1);`
315			`}`
316
317			`new->cs = cs;`
318			`new->mem = mem;`
319			`new->mc = mc;`
320
321			`new->next = mc_areas;`
322
323			`mc_areas = new;`
324			`}`
325
326			`/-----------------------------------------------------[ MC configuration ]---/`
327			`static void`
328			`mc_enabled (union param_val val, void *dat)`
329			`{`
330			`struct mc *mc = dat;`
331			`mc->enabled = val.int_val;`
332			`}`
333
334			`static void`
335			`mc_baseaddr (union param_val val, void *dat)`
336			`{`
337			`struct mc *mc = dat;`
338			`mc->baseaddr = val.addr_val;`
339			`}`
340
341
342			`/---------------------------------------------------------------------------/`
343			`/*!Set the power on configuration state`
344
345			`Only the bottom 4 bits are signficant. Other bits are truncated with a`
346			`warning.`
347
348			`@param[in] val The value to use`
349			`@param[in] dat The config data structure */`
350			`/---------------------------------------------------------------------------/`
351			`static void`
352			`mc_poc (union param_val val,`
353			`void *dat)`
354			`{`
355			`struct mc *mc = dat;`
356
357			`if (val.int_val > 0xf)`
358			`{`
359			`fprintf (stderr, "Warning: memory controller PoC > 4 bits: truncated\n");`
360			`}`
361
362			`mc->poc = val.int_val & 0xf;`
363
364			`} /* mc_poc() */`
365
366
367			`static void`
368			`mc_index (union param_val val, void *dat)`
369			`{`
370			`struct mc *mc = dat;`
371			`mc->index = val.int_val;`
372			`}`
373
374			`/---------------------------------------------------------------------------/`
375			`/*!Initialize a new memory controller configuration`
376
377			`ALL parameters are set explicitly to default values. */`
378			`/---------------------------------------------------------------------------/`
379			`static void *`
380			`mc_sec_start ()`
381			`{`
382			`struct mc *new = malloc (sizeof (struct mc));`
383
384			`if (!new)`
385			`{`
386			`fprintf (stderr, "Peripheral MC: Run out of memory\n");`
387			`exit (-1);`
388			`}`
389
390			`new->enabled = 1;`
391			`new->baseaddr = 0;`
392			`new->poc = 0;`
393			`new->index = 0;`
394
395			`new->mc_areas = NULL;`
396
397			`return new;`
398			`}`
399
400			`static void`
401			`mc_sec_end (void *dat)`
402			`{`
403			`struct mc *mc = dat;`
404			`struct mem_ops ops;`
405
406			`if (!mc->enabled)`
407			`{`
408			`free (dat);`
409			`return;`
410			`}`
411
412			`/* FIXME: Check to see that the index given to this mc is unique */`
413
414			`mc->next = mcs;`
415			`mcs = mc;`
416
417			`memset (&ops, 0, sizeof (struct mem_ops));`
418
419			`ops.readfunc32 = mc_read_word;`
420			`ops.writefunc32 = mc_write_word;`
421			`ops.write_dat32 = dat;`
422			`ops.read_dat32 = dat;`
423
424			`/* FIXME: Correct delays? */`
425			`ops.delayr = 2;`
426			`ops.delayw = 2;`
427
428			`reg_mem_area (mc->baseaddr, MC_ADDR_SPACE, 1, &ops);`
429			`reg_sim_reset (mc_reset, dat);`
430			`reg_sim_stat (mc_status, dat);`
431			`}`
432
433			`void`
434			`reg_mc_sec (void)`
435			`{`
436			`struct config_section *sec =`
437			`reg_config_sec ("mc", mc_sec_start, mc_sec_end);`
438
439	224	jeremybenn	`reg_config_param (sec, "enabled", PARAMT_INT, mc_enabled);`
440			`reg_config_param (sec, "baseaddr", PARAMT_ADDR, mc_baseaddr);`
441			`reg_config_param (sec, "POC", PARAMT_INT, mc_poc);`
442			`reg_config_param (sec, "index", PARAMT_INT, mc_index);`
443	19	jeremybenn	`}`