/[dynamips]/upstream/dynamips-0.2.5/dev_c7200_iofpga.c
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Contents of /upstream/dynamips-0.2.5/dev_c7200_iofpga.c

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Revision 1 - (show annotations)
Sat Oct 6 16:01:44 2007 UTC (16 years, 5 months ago) by dpavlin
File MIME type: text/plain
File size: 18654 byte(s)
import 0.2.5 from upstream

1 /*
2 * Cisco 7200 (Predator) simulation platform.
3 * Copyright (c) 2005,2006 Christophe Fillot (cf@utc.fr)
4 *
5 * Cisco C7200 (Predator) I/O FPGA:
6 * - Simulates a NMC93C46 Serial EEPROM as CPU and Midplane EEPROM.
7 * - Simulates a DALLAS DS1620 for Temperature Sensors.
8 * - Simulates voltage sensors.
9 * - Simulates console and AUX ports.
10 */
11
12 #include <stdio.h>
13 #include <stdlib.h>
14 #include <string.h>
15 #include <unistd.h>
16 #include <sys/types.h>
17
18 #include <termios.h>
19 #include <fcntl.h>
20 #include <pthread.h>
21
22 #include "ptask.h"
23 #include "mips64.h"
24 #include "dynamips.h"
25 #include "memory.h"
26 #include "device.h"
27 #include "dev_vtty.h"
28 #include "nmc93c46.h"
29 #include "ds1620.h"
30 #include "dev_c7200.h"
31
32 /* Debugging flags */
33 #define DEBUG_UNKNOWN 1
34 #define DEBUG_ACCESS 0
35 #define DEBUG_LED 0
36 #define DEBUG_IO_CTL 0
37 #define DEBUG_ENVM 0
38
39 /* DUART RX/TX status (SRA/SRB) */
40 #define DUART_RX_READY 0x01
41 #define DUART_TX_READY 0x04
42
43 /* DUART RX/TX Interrupt Status/Mask */
44 #define DUART_TXRDYA 0x01
45 #define DUART_RXRDYA 0x02
46 #define DUART_TXRDYB 0x10
47 #define DUART_RXRDYB 0x20
48
49 /* Definitions for CPU and Midplane Serial EEPROMs */
50 #define DO2_DATA_OUT_MIDPLANE 7
51 #define DO1_DATA_OUT_CPU 6
52 #define CS2_CHIP_SEL_MIDPLANE 5
53 #define SK2_CLOCK_MIDPLANE 4
54 #define DI2_DATA_IN_MIDPLANE 3
55 #define CS1_CHIP_SEL_CPU 2
56 #define SK1_CLOCK_CPU 1
57 #define DI1_DATA_IN_CPU 0
58
59 /* Definitions for PEM (NPE-B) Serial EEPROM */
60 #define DO1_DATA_OUT_PEM 3
61 #define DI1_DATA_IN_PEM 2
62 #define CS1_CHIP_SEL_PEM 1
63 #define SK1_CLOCK_PEM 0
64
65 /* Pack the NVRAM */
66 #define NVRAM_PACKED 0x04
67
68 /* 4 temperature sensors in a C7200 */
69 #define C7200_TEMP_SENSORS 4
70 #define C7200_DEFAULT_TEMP 22 /* default temperature: 22°C */
71
72 /* Voltages */
73 #define C7200_A2D_SAMPLES 9
74
75 /*
76 * A2D MUX Select definitions.
77 */
78 #define C7200_MUX_PS0 0x00 /* Power Supply 0 */
79 #define C7200_MUX_PS1 0x02 /* Power Supply 1 */
80 #define C7200_MUX_P3V 0x04 /* +3V */
81 #define C7200_MUX_P12V 0x08 /* +12V */
82 #define C7200_MUX_P5V 0x0a /* +5V */
83 #define C7200_MUX_N12V 0x0c /* -12V */
84
85 /* Analog To Digital Converters samples */
86 #define C7200_A2D_PS0 1150
87 #define C7200_A2D_PS1 1150
88
89 /* Voltage Samples */
90 #define C7200_A2D_P3V 1150
91 #define C7200_A2D_P12V 1150
92 #define C7200_A2D_P5V 1150
93 #define C7200_A2D_N12V 1150
94
95 /* IO FPGA structure */
96 struct iofpga_data {
97 vm_obj_t vm_obj;
98 struct vdevice dev;
99 c7200_t *router;
100
101 /* Lock test */
102 pthread_mutex_t lock;
103
104 /* Periodic task to trigger dummy DUART IRQ */
105 ptask_id_t duart_irq_tid;
106
107 /* DUART & Console Management */
108 u_int duart_isr,duart_imr,duart_irq_seq;
109
110 /* IO control register */
111 u_int io_ctrl_reg;
112
113 /* Temperature Control */
114 u_int temp_cfg_reg[C7200_TEMP_SENSORS];
115 u_int temp_deg_reg[C7200_TEMP_SENSORS];
116 u_int temp_clk_low;
117
118 u_int temp_cmd;
119 u_int temp_cmd_pos;
120
121 u_int temp_data;
122 u_int temp_data_pos;
123
124 /* Voltages */
125 u_int mux;
126 };
127
128 #define IOFPGA_LOCK(d) pthread_mutex_lock(&(d)->lock)
129 #define IOFPGA_UNLOCK(d) pthread_mutex_unlock(&(d)->lock)
130
131 /* Empty EEPROM */
132 static const m_uint16_t eeprom_empty_data[16] = {
133 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF,
134 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF,
135 };
136
137 /* CPU EEPROM definition */
138 static const struct nmc93c46_eeprom_def eeprom_cpu_def = {
139 SK1_CLOCK_CPU, CS1_CHIP_SEL_CPU,
140 DI1_DATA_IN_CPU, DO1_DATA_OUT_CPU,
141 NULL, 0,
142 };
143
144 /* Midplane EEPROM definition */
145 static const struct nmc93c46_eeprom_def eeprom_midplane_def = {
146 SK2_CLOCK_MIDPLANE, CS2_CHIP_SEL_MIDPLANE,
147 DI2_DATA_IN_MIDPLANE, DO2_DATA_OUT_MIDPLANE,
148 NULL, 0,
149 };
150
151 /* PEM (NPE-B) EEPROM definition */
152 static const struct nmc93c46_eeprom_def eeprom_pem_def = {
153 SK1_CLOCK_PEM, CS1_CHIP_SEL_PEM, DI1_DATA_IN_PEM, DO1_DATA_OUT_PEM,
154 (m_uint16_t *)eeprom_empty_data, (sizeof(eeprom_empty_data) / 2),
155 };
156
157 /* IOFPGA manages simultaneously CPU and Midplane EEPROM */
158 static const struct nmc93c46_group eeprom_cpu_midplane = {
159 2, 0, "CPU and Midplane EEPROM", 0,
160 { NULL, NULL, }, { { 0, 0, 0, 0, 0}, { 0, 0, 0, 0, 0} },
161 };
162
163 /*
164 * IOFPGA manages also PEM EEPROM (for NPE-B)
165 * PEM stands for "Power Entry Module":
166 * http://www.cisco.com/en/US/products/hw/routers/ps341/products_field_notice09186a00801cb26d.shtml
167 */
168 static const struct nmc93c46_group eeprom_pem_npeb = {
169 1, 0, "PEM (NPE-B) EEPROM", 0, { NULL }, { { 0, 0, 0, 0, 0} },
170 };
171
172 /* Reset DS1620 */
173 static void temp_reset(struct iofpga_data *d)
174 {
175 d->temp_cmd_pos = 0;
176 d->temp_cmd = 0;
177
178 d->temp_data_pos = 0;
179 d->temp_data = 0;
180 }
181
182 /* Write the temperature control data */
183 static void temp_write_ctrl(struct iofpga_data *d,u_char val)
184 {
185 switch(val) {
186 case DS1620_RESET_ON:
187 temp_reset(d);
188 break;
189
190 case DS1620_CLK_LOW:
191 d->temp_clk_low = 1;
192 break;
193
194 case DS1620_CLK_HIGH:
195 d->temp_clk_low = 0;
196 break;
197 }
198 }
199
200 /* Read a temperature control data */
201 static u_int temp_read_data(struct iofpga_data *d)
202 {
203 u_int i,data = 0;
204
205 switch(d->temp_cmd) {
206 case DS1620_READ_CONFIG:
207 for(i=0;i<C7200_TEMP_SENSORS;i++)
208 data |= ((d->temp_cfg_reg[i] >> d->temp_data_pos) & 1) << i;
209
210 d->temp_data_pos++;
211
212 if (d->temp_data_pos == DS1620_CONFIG_READ_SIZE)
213 temp_reset(d);
214
215 break;
216
217 case DS1620_READ_TEMP:
218 for(i=0;i<C7200_TEMP_SENSORS;i++)
219 data |= ((d->temp_deg_reg[i] >> d->temp_data_pos) & 1) << i;
220
221 d->temp_data_pos++;
222
223 if (d->temp_data_pos == DS1620_DATA_READ_SIZE)
224 temp_reset(d);
225
226 break;
227
228 default:
229 vm_log(d->router->vm,"IO_FPGA","temp_sensors: CMD = 0x%x\n",
230 d->temp_cmd);
231 }
232
233 return(data);
234 }
235
236 /* Write the temperature data write register */
237 static void temp_write_data(struct iofpga_data *d,u_char val)
238 {
239 if (val == DS1620_ENABLE_READ) {
240 d->temp_data_pos = 0;
241 return;
242 }
243
244 if (!d->temp_clk_low)
245 return;
246
247 /* Write a command */
248 if (d->temp_cmd_pos < DS1620_WRITE_SIZE)
249 {
250 if (val == DS1620_DATA_HIGH)
251 d->temp_cmd |= 1 << d->temp_cmd_pos;
252
253 d->temp_cmd_pos++;
254
255 if (d->temp_cmd_pos == DS1620_WRITE_SIZE) {
256 switch(d->temp_cmd) {
257 case DS1620_START_CONVT:
258 //printf("temp_sensors: IOS enabled continuous monitoring.\n");
259 temp_reset(d);
260 break;
261 case DS1620_READ_CONFIG:
262 case DS1620_READ_TEMP:
263 break;
264 default:
265 vm_log(d->router->vm,"IO_FPGA",
266 "temp_sensors: IOS sent command 0x%x.\n",
267 d->temp_cmd);
268 }
269 }
270 }
271 else
272 {
273 if (val == DS1620_DATA_HIGH)
274 d->temp_data |= 1 << d->temp_data_pos;
275
276 d->temp_data_pos++;
277 }
278 }
279
280 /* Console port input */
281 static void tty_con_input(vtty_t *vtty)
282 {
283 struct iofpga_data *d = vtty->priv_data;
284
285 IOFPGA_LOCK(d);
286 if (d->duart_imr & DUART_RXRDYA) {
287 d->duart_isr |= DUART_RXRDYA;
288 vm_set_irq(d->router->vm,C7200_DUART_IRQ);
289 }
290 IOFPGA_UNLOCK(d);
291 }
292
293 /* AUX port input */
294 static void tty_aux_input(vtty_t *vtty)
295 {
296 struct iofpga_data *d = vtty->priv_data;
297
298 IOFPGA_LOCK(d);
299 if (d->duart_imr & DUART_RXRDYB) {
300 d->duart_isr |= DUART_RXRDYB;
301 vm_set_irq(d->router->vm,C7200_DUART_IRQ);
302 }
303 IOFPGA_UNLOCK(d);
304 }
305
306 /* IRQ trickery for Console and AUX ports */
307 static int tty_trigger_dummy_irq(struct iofpga_data *d,void *arg)
308 {
309 u_int mask;
310
311 IOFPGA_LOCK(d);
312 d->duart_irq_seq++;
313
314 if (d->duart_irq_seq == 2) {
315 mask = DUART_TXRDYA|DUART_TXRDYB;
316 if (d->duart_imr & mask) {
317 d->duart_isr |= DUART_TXRDYA|DUART_TXRDYB;
318 vm_set_irq(d->router->vm,C7200_DUART_IRQ);
319 }
320
321 d->duart_irq_seq = 0;
322 }
323
324 IOFPGA_UNLOCK(d);
325 return(0);
326 }
327
328 /*
329 * dev_c7200_iofpga_access()
330 */
331 void *dev_c7200_iofpga_access(cpu_mips_t *cpu,struct vdevice *dev,
332 m_uint32_t offset,u_int op_size,u_int op_type,
333 m_uint64_t *data)
334 {
335 struct iofpga_data *d = dev->priv_data;
336 vm_instance_t *vm = d->router->vm;
337 u_char odata;
338
339 if (op_type == MTS_READ)
340 *data = 0x0;
341
342 #if DEBUG_ACCESS
343 if (op_type == MTS_READ) {
344 cpu_log(cpu,"IO_FPGA","reading reg 0x%x at pc=0x%llx\n",offset,cpu->pc);
345 } else {
346 cpu_log(cpu,"IO_FPGA","writing reg 0x%x at pc=0x%llx, data=0x%llx\n",
347 offset,cpu->pc,*data);
348 }
349 #endif
350
351 IOFPGA_LOCK(d);
352
353 switch(offset) {
354 case 0x294:
355 /*
356 * Unknown, seen in 12.4(6)T, and seems to be read at each
357 * network interrupt.
358 */
359 if (op_type == MTS_READ)
360 *data = 0x0;
361 break;
362
363 /* NPE-G1 test - unknown (value written: 0x01) */
364 case 0x338:
365 break;
366
367 /* NPE-G1 test - has influence on slot 0 / flash / pcmcia ... */
368 case 0x390:
369 if (op_type == MTS_READ)
370 *data = 0x0FFF0000; //0xFFFF0000;
371 break;
372
373 /* I/O control register */
374 case 0x204:
375 if (op_type == MTS_WRITE) {
376 #if DEBUG_IO_CTL
377 vm_log(vm,"IO_FPGA","setting value 0x%llx in io_ctrl_reg\n",*data);
378 #endif
379 d->io_ctrl_reg = *data;
380 }
381 else {
382 *data = d->io_ctrl_reg;
383 *data |= NVRAM_PACKED; /* Packed NVRAM */
384 }
385 break;
386
387 /* CPU/Midplane EEPROMs */
388 case 0x21c:
389 if (op_type == MTS_WRITE)
390 nmc93c46_write(&d->router->sys_eeprom_g1,(u_int)(*data));
391 else
392 *data = nmc93c46_read(&d->router->sys_eeprom_g1);
393 break;
394
395 /* PEM (NPE-B) EEPROM */
396 case 0x388:
397 if (op_type == MTS_WRITE)
398 nmc93c46_write(&d->router->sys_eeprom_g2,(u_int)(*data));
399 else
400 *data = nmc93c46_read(&d->router->sys_eeprom_g2);
401 break;
402
403 /* Watchdog */
404 case 0x234:
405 break;
406
407 /*
408 * FPGA release/presence ? Flash SIMM size:
409 * 0x0001: 2048K Flash (2 banks)
410 * 0x0504: 8192K Flash (2 banks)
411 * 0x0704: 16384K Flash (2 banks)
412 * 0x0904: 32768K Flash (2 banks)
413 * 0x0B04: 65536K Flash (2 banks)
414 * 0x2001: 1024K Flash (1 bank)
415 * 0x2504: 4096K Flash (1 bank)
416 * 0x2704: 8192K Flash (1 bank)
417 * 0x2904: 16384K Flash (1 bank)
418 * 0x2B04: 32768K Flash (1 bank)
419 *
420 * Number of Flash SIMM banks + size.
421 * Touching some lower bits causes problems with environmental monitor.
422 *
423 * It is displayed by command "sh bootflash: chips"
424 */
425 case 0x23c:
426 if (op_type == MTS_READ)
427 *data = 0x2704;
428 break;
429
430 /* LEDs */
431 case 0x244:
432 #if DEBUG_LED
433 vm_log(vm,"IO_FPGA","LED register is now 0x%x (0x%x)\n",
434 *data,(~*data) & 0x0F);
435 #endif
436 break;
437
438 /* ==== DUART SCN2681 (console/aux) ==== */
439 case 0x404: /* Mode Register A (MRA) */
440 break;
441
442 case 0x40c: /* Status Register A (SRA) */
443 if (op_type == MTS_READ) {
444 odata = 0;
445
446 if (vtty_is_char_avail(vm->vtty_con))
447 odata |= DUART_RX_READY;
448
449 odata |= DUART_TX_READY;
450
451 vm_clear_irq(vm,C7200_DUART_IRQ);
452 *data = odata;
453 }
454 break;
455
456 case 0x414: /* Command Register A (CRA) */
457 /* Disable TX = High */
458 if ((op_type == MTS_WRITE) && (*data & 0x8)) {
459 vm->vtty_con->managed_flush = TRUE;
460 vtty_flush(vm->vtty_con);
461 }
462 break;
463
464 case 0x41c: /* RX/TX Holding Register A (RHRA/THRA) */
465 if (op_type == MTS_WRITE) {
466 vtty_put_char(vm->vtty_con,(char)*data);
467 d->duart_isr &= ~DUART_TXRDYA;
468 } else {
469 *data = vtty_get_char(vm->vtty_con);
470 d->duart_isr &= ~DUART_RXRDYA;
471 }
472 break;
473
474 case 0x424: /* WRITE: Aux Control Register (ACR) */
475 break;
476
477 case 0x42c: /* Interrupt Status/Mask Register (ISR/IMR) */
478 if (op_type == MTS_WRITE) {
479 d->duart_imr = *data;
480 } else
481 *data = d->duart_isr;
482 break;
483
484 case 0x434: /* Counter/Timer Upper Value (CTU) */
485 case 0x43c: /* Counter/Timer Lower Value (CTL) */
486 case 0x444: /* Mode Register B (MRB) */
487 break;
488
489 case 0x44c: /* Status Register B (SRB) */
490 if (op_type == MTS_READ) {
491 odata = 0;
492
493 if (vtty_is_char_avail(vm->vtty_aux))
494 odata |= DUART_RX_READY;
495
496 odata |= DUART_TX_READY;
497
498 //vm_clear_irq(vm,C7200_DUART_IRQ);
499 *data = odata;
500 }
501 break;
502
503 case 0x454: /* Command Register B (CRB) */
504 /* Disable TX = High */
505 if ((op_type == MTS_WRITE) && (*data & 0x8)) {
506 vm->vtty_aux->managed_flush = TRUE;
507 vtty_flush(vm->vtty_aux);
508 }
509 break;
510
511 case 0x45c: /* RX/TX Holding Register B (RHRB/THRB) */
512 if (op_type == MTS_WRITE) {
513 vtty_put_char(vm->vtty_aux,(char)*data);
514 d->duart_isr &= ~DUART_TXRDYA;
515 } else {
516 *data = vtty_get_char(vm->vtty_aux);
517 d->duart_isr &= ~DUART_RXRDYB;
518 }
519 break;
520
521 case 0x46c: /* WRITE: Output Port Configuration Register (OPCR) */
522 case 0x474: /* READ: Start Counter Command; */
523 /* WRITE: Set Output Port Bits Command */
524 case 0x47c: /* WRITE: Reset Output Port Bits Command */
525 break;
526
527 /* ==== DS 1620 (temp sensors) ==== */
528 case 0x20c: /* Temperature Control */
529 if (op_type == MTS_WRITE)
530 temp_write_ctrl(d,*data);
531 break;
532
533 case 0x214: /* Temperature data write */
534 if (op_type == MTS_WRITE) {
535 temp_write_data(d,*data);
536 d->mux = *data;
537 }
538 break;
539
540 case 0x22c: /* Temperature data read */
541 if (op_type == MTS_READ)
542 *data = temp_read_data(d);
543 break;
544
545 /*
546 * NPE-G1 - Voltages + Power Supplies.
547 * I don't understand exactly how it works, it seems that the low
548 * part must be equal to the high part to have the better values.
549 */
550 case 0x254:
551 #if DEBUG_ENVM
552 vm_log(vm,"ENVM","access to envm a/d converter - mux = %u\n",d->mux);
553 #endif
554 if (op_type == MTS_READ)
555 *data = 0xFFFFFFFF;
556 break;
557
558 case 0x257: /* ENVM A/D Converter */
559 #if DEBUG_ENVM
560 vm_log(vm,"ENVM","access to envm a/d converter - mux = %u\n",d->mux);
561 #endif
562 if (op_type == MTS_READ) {
563 switch(d->mux) {
564 case C7200_MUX_PS0:
565 *data = C7200_A2D_PS0;
566 break;
567
568 case C7200_MUX_PS1:
569 *data = C7200_A2D_PS1;
570 break;
571
572 case C7200_MUX_P3V:
573 *data = C7200_A2D_P3V;
574 break;
575
576 case C7200_MUX_P12V:
577 *data = C7200_A2D_P12V;
578 break;
579
580 case C7200_MUX_P5V:
581 *data = C7200_A2D_P5V;
582 break;
583
584 case C7200_MUX_N12V:
585 *data = C7200_A2D_N12V;
586 break;
587
588 default:
589 *data = 0;
590 }
591
592 *data = *data / C7200_A2D_SAMPLES;
593 }
594 break;
595
596 #if DEBUG_UNKNOWN
597 default:
598 if (op_type == MTS_READ) {
599 cpu_log(cpu,"IO_FPGA","read from addr 0x%x, pc=0x%llx (size=%u)\n",
600 offset,cpu->pc,op_size);
601 } else {
602 cpu_log(cpu,"IO_FPGA","write to addr 0x%x, value=0x%llx, "
603 "pc=0x%llx (size=%u)\n",offset,*data,cpu->pc,op_size);
604 }
605 #endif
606 }
607
608 IOFPGA_UNLOCK(d);
609 return NULL;
610 }
611
612 /* Initialize EEPROM groups */
613 void c7200_init_eeprom_groups(c7200_t *router)
614 {
615 struct nmc93c46_group *g;
616
617 /* Copy EEPROM definitions */
618 memcpy(&router->cpu_eeprom,&eeprom_cpu_def,sizeof(eeprom_cpu_def));
619 memcpy(&router->mp_eeprom,&eeprom_midplane_def,sizeof(eeprom_midplane_def));
620 memcpy(&router->pem_eeprom,&eeprom_pem_def,sizeof(eeprom_pem_def));
621
622 /* Initialize groups */
623 g = &router->sys_eeprom_g1;
624 memcpy(g,&eeprom_cpu_midplane,sizeof(eeprom_cpu_midplane));
625 g->def[0] = &router->cpu_eeprom;
626 g->def[1] = &router->mp_eeprom;
627
628 g = &router->sys_eeprom_g2;
629 memcpy(g,&eeprom_pem_npeb,sizeof(eeprom_pem_npeb));
630 g->def[0] = &router->pem_eeprom;
631 }
632
633 /* Shutdown the IO FPGA device */
634 void dev_c7200_iofpga_shutdown(vm_instance_t *vm,struct iofpga_data *d)
635 {
636 if (d != NULL) {
637 IOFPGA_LOCK(d);
638 vm->vtty_con->read_notifier = NULL;
639 vm->vtty_aux->read_notifier = NULL;
640 IOFPGA_UNLOCK(d);
641
642 /* Remove the dummy IRQ periodic task */
643 ptask_remove(d->duart_irq_tid);
644
645 /* Remove the device */
646 dev_remove(vm,&d->dev);
647
648 /* Free the structure itself */
649 free(d);
650 }
651 }
652
653 /*
654 * dev_c7200_iofpga_init()
655 */
656 int dev_c7200_iofpga_init(c7200_t *router,m_uint64_t paddr,m_uint32_t len)
657 {
658 vm_instance_t *vm = router->vm;
659 struct iofpga_data *d;
660 u_int i;
661
662 /* Allocate private data structure */
663 if (!(d = malloc(sizeof(*d)))) {
664 fprintf(stderr,"IO_FPGA: out of memory\n");
665 return(-1);
666 }
667
668 memset(d,0,sizeof(*d));
669
670 pthread_mutex_init(&d->lock,NULL);
671 d->router = router;
672
673 for(i=0;i<C7200_TEMP_SENSORS;i++) {
674 d->temp_cfg_reg[i] = DS1620_CONFIG_STATUS_CPU;
675 d->temp_deg_reg[i] = C7200_DEFAULT_TEMP * 2;
676 }
677
678 vm_object_init(&d->vm_obj);
679 d->vm_obj.name = "io_fpga";
680 d->vm_obj.data = d;
681 d->vm_obj.shutdown = (vm_shutdown_t)dev_c7200_iofpga_shutdown;
682
683 /* Set device properties */
684 dev_init(&d->dev);
685 d->dev.name = "io_fpga";
686 d->dev.phys_addr = paddr;
687 d->dev.phys_len = len;
688 d->dev.handler = dev_c7200_iofpga_access;
689 d->dev.priv_data = d;
690
691 /* Set console and AUX port notifying functions */
692 vm->vtty_con->priv_data = d;
693 vm->vtty_aux->priv_data = d;
694 vm->vtty_con->read_notifier = tty_con_input;
695 vm->vtty_aux->read_notifier = tty_aux_input;
696
697 /* Trigger periodically a dummy IRQ to flush buffers */
698 d->duart_irq_tid = ptask_add((ptask_callback)tty_trigger_dummy_irq,d,NULL);
699
700 /* Map this device to the VM */
701 vm_bind_device(vm,&d->dev);
702 vm_object_add(vm,&d->vm_obj);
703 return(0);
704 }

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