[target] ixp4xx: add missing config symbol for 2.6.30
[openwrt.git] / target / linux / coldfire / patches / 045-m547x_8x_fec_dma.patch
1 From b778a60aba67d29857fc7016c8c2f2d87a23de1f Mon Sep 17 00:00:00 2001
2 From: Kurt Mahan <kmahan@freescale.com>
3 Date: Sun, 9 Mar 2008 22:14:05 -0600
4 Subject: [PATCH] Add DMA and FEC.
5
6 LTIBName: m547x-8x-fec-dma
7 Signed-off-by: Kurt Mahan <kmahan@freescale.com>
8 ---
9 arch/m68k/Kconfig | 9 +
10 arch/m68k/coldfire/Makefile | 2 +
11 arch/m68k/coldfire/dma.c | 537 +++++++++
12 drivers/Makefile | 2 +
13 drivers/dma/MCD_dma.h | 408 +++++++
14 drivers/dma/MCD_dmaApi.c | 968 +++++++++++++++++
15 drivers/dma/MCD_progCheck.h | 33 +
16 drivers/dma/MCD_tasks.c | 2452 ++++++++++++++++++++++++++++++++++++++++++
17 drivers/dma/MCD_tasksInit.c | 284 +++++
18 drivers/dma/MCD_tasksInit.h | 73 ++
19 drivers/dma/Makefile | 2 +
20 drivers/net/Kconfig | 2 +
21 drivers/net/Makefile | 2 +
22 drivers/net/fec/Kconfig | 25 +
23 drivers/net/fec/Makefile | 7 +
24 drivers/net/fec/fec.c | 1375 +++++++++++++++++++++++
25 drivers/net/fec/fec.h | 162 +++
26 drivers/net/fec/ks8721.c | 125 +++
27 drivers/net/fec/ks8721.h | 21 +
28 include/asm-m68k/MCD_dma.h | 408 +++++++
29 include/asm-m68k/coldfire.h | 1 +
30 include/asm-m68k/dma.h | 106 ++-
31 include/asm-m68k/m5485dma.h | 97 ++
32 include/asm-m68k/m5485sram.h | 12 +
33 24 files changed, 7112 insertions(+), 1 deletions(-)
34 create mode 100644 arch/m68k/coldfire/dma.c
35 create mode 100644 drivers/dma/MCD_dma.h
36 create mode 100644 drivers/dma/MCD_dmaApi.c
37 create mode 100644 drivers/dma/MCD_progCheck.h
38 create mode 100644 drivers/dma/MCD_tasks.c
39 create mode 100644 drivers/dma/MCD_tasksInit.c
40 create mode 100644 drivers/dma/MCD_tasksInit.h
41 create mode 100644 drivers/net/fec/Kconfig
42 create mode 100644 drivers/net/fec/Makefile
43 create mode 100755 drivers/net/fec/fec.c
44 create mode 100755 drivers/net/fec/fec.h
45 create mode 100644 drivers/net/fec/ks8721.c
46 create mode 100644 drivers/net/fec/ks8721.h
47 create mode 100644 include/asm-m68k/MCD_dma.h
48 create mode 100644 include/asm-m68k/m5485dma.h
49 create mode 100644 include/asm-m68k/m5485sram.h
50
51 --- a/arch/m68k/Kconfig
52 +++ b/arch/m68k/Kconfig
53 @@ -141,6 +141,15 @@ config CFV4E
54 select MMU_CFV4E if MMU
55 default y
56
57 +config MCD_DMA
58 + bool "ColdFire MCD DMA support"
59 + depends on CFV4E
60 + default y
61 + help
62 + This enables support for the ColdFire 547x/548x family
63 + multichannel DMA support. Many drivers need it.
64 + If you want it, say Y
65 +
66 config AMIGA
67 bool "Amiga support"
68 depends on !MMU_SUN3
69 --- a/arch/m68k/coldfire/Makefile
70 +++ b/arch/m68k/coldfire/Makefile
71 @@ -10,3 +10,5 @@ endif
72
73 obj-$(CONFIG_PCI) += pci.o mcf5445x-pci.o iomap.o
74 obj-$(CONFIG_M54455) += mcf5445x-devices.o
75 +
76 +obj-$(CONFIG_MCD_DMA) += dma.o
77 --- /dev/null
78 +++ b/arch/m68k/coldfire/dma.c
79 @@ -0,0 +1,537 @@
80 +#include <linux/kernel.h>
81 +#include <linux/sched.h>
82 +#include <linux/mm.h>
83 +#include <linux/init.h>
84 +#include <linux/interrupt.h>
85 +#include <asm/io.h>
86 +#include <asm/irq.h>
87 +#include <asm/dma.h>
88 +#include <asm/coldfire.h>
89 +#include <asm/m5485sram.h>
90 +#include <asm/mcfsim.h>
91 +
92 +
93 +
94 +void dma_interrupt_handler(int irq, void *dev_id, struct pt_regs *regs);
95 +
96 +/*
97 + * This global keeps track of which initiators have been
98 + * used of the available assignments. Initiators 0-15 are
99 + * hardwired. Initiators 16-31 are multiplexed and controlled
100 + * via the Initiatior Mux Control Registe (IMCR). The
101 + * assigned requestor is stored with the associated initiator
102 + * number.
103 + */
104 +static int used_reqs[32] = {
105 + DMA_ALWAYS, DMA_DSPI_RX, DMA_DSPI_TX, DMA_DREQ0,
106 + DMA_PSC0_RX, DMA_PSC0_TX, DMA_USBEP0, DMA_USBEP1,
107 + DMA_USBEP2, DMA_USBEP3, DMA_PCI_TX, DMA_PCI_RX,
108 + DMA_PSC1_RX, DMA_PSC1_TX, DMA_I2C_RX, DMA_I2C_TX,
109 + 0, 0, 0, 0,
110 + 0, 0, 0, 0,
111 + 0, 0, 0, 0,
112 + 0, 0, 0, 0
113 +};
114 +
115 +/*
116 + * This global keeps track of which channels have been assigned
117 + * to tasks. This methology assumes that no single initiator
118 + * will be tied to more than one task/channel
119 + */
120 +static char used_channel[16] = {
121 + -1, -1, -1, -1, -1, -1, -1, -1,
122 + -1, -1, -1, -1, -1, -1, -1, -1
123 +};
124 +
125 +unsigned int connected_channel[16] = {
126 + 0, 0, 0, 0, 0, 0, 0, 0,
127 + 0, 0, 0, 0, 0, 0, 0, 0
128 +};
129 +
130 +/********************************************************************/
131 +/*
132 + * Attempt to enable the provided Initiator in the Initiator
133 + * Mux Control Register
134 + *
135 + * Parameters:
136 + * initiator Initiator identifier
137 + *
138 + * Return Value:
139 + * 1 if unable to make the assignment
140 + * 0 successful
141 + */
142 +int
143 +dma_set_initiator(int initiator)
144 +{
145 + switch (initiator) { /*
146 + * These initiators are always active
147 + */
148 + case DMA_ALWAYS:
149 + case DMA_DSPI_RX:
150 + case DMA_DSPI_TX:
151 + case DMA_DREQ0:
152 + case DMA_PSC0_RX:
153 + case DMA_PSC0_TX:
154 + case DMA_USBEP0:
155 + case DMA_USBEP1:
156 + case DMA_USBEP2:
157 + case DMA_USBEP3:
158 + case DMA_PCI_TX:
159 + case DMA_PCI_RX:
160 + case DMA_PSC1_RX:
161 + case DMA_PSC1_TX:
162 + case DMA_I2C_RX:
163 + case DMA_I2C_TX:
164 + break;
165 +
166 + case DMA_FEC0_RX:
167 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC16(3))
168 + | MCF_DMA_IMCR_SRC16_FEC0RX;
169 + used_reqs[16] = DMA_FEC0_RX;
170 + break;
171 +
172 + case DMA_FEC0_TX:
173 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC17(3))
174 + | MCF_DMA_IMCR_SRC17_FEC0TX;
175 + used_reqs[17] = DMA_FEC0_TX;
176 + break;
177 +
178 + case DMA_FEC1_RX:
179 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC20(3))
180 + | MCF_DMA_IMCR_SRC20_FEC1RX;
181 + used_reqs[20] = DMA_FEC1_RX;
182 + break;
183 +
184 + case DMA_FEC1_TX:
185 + if (used_reqs[21] == 0) {
186 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC21(3))
187 + | MCF_DMA_IMCR_SRC21_FEC1TX;
188 + used_reqs[21] = DMA_FEC1_TX;
189 + } else if (used_reqs[25] == 0) {
190 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC25(3))
191 + | MCF_DMA_IMCR_SRC25_FEC1TX;
192 + used_reqs[25] = DMA_FEC1_TX;
193 + } else if (used_reqs[31] == 0) {
194 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC31(3))
195 + | MCF_DMA_IMCR_SRC31_FEC1TX;
196 + used_reqs[31] = DMA_FEC1_TX;
197 + } else /* No empty slots */
198 + return 1;
199 + break;
200 +
201 + case DMA_DREQ1:
202 + if (used_reqs[29] == 0) {
203 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC29(3))
204 + | MCF_DMA_IMCR_SRC29_DREQ1;
205 + used_reqs[29] = DMA_DREQ1;
206 + } else if (used_reqs[21] == 0) {
207 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC21(3))
208 + | MCF_DMA_IMCR_SRC21_DREQ1;
209 + used_reqs[21] = DMA_DREQ1;
210 + } else /* No empty slots */
211 + return 1;
212 + break;
213 +
214 + case DMA_CTM0:
215 + if (used_reqs[24] == 0) {
216 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC24(3))
217 + | MCF_DMA_IMCR_SRC24_CTM0;
218 + used_reqs[24] = DMA_CTM0;
219 + } else /* No empty slots */
220 + return 1;
221 + break;
222 +
223 + case DMA_CTM1:
224 + if (used_reqs[25] == 0) {
225 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC25(3))
226 + | MCF_DMA_IMCR_SRC25_CTM1;
227 + used_reqs[25] = DMA_CTM1;
228 + } else /* No empty slots */
229 + return 1;
230 + break;
231 +
232 + case DMA_CTM2:
233 + if (used_reqs[26] == 0) {
234 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC26(3))
235 + | MCF_DMA_IMCR_SRC26_CTM2;
236 + used_reqs[26] = DMA_CTM2;
237 + } else /* No empty slots */
238 + return 1;
239 + break;
240 +
241 + case DMA_CTM3:
242 + if (used_reqs[27] == 0) {
243 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC27(3))
244 + | MCF_DMA_IMCR_SRC27_CTM3;
245 + used_reqs[27] = DMA_CTM3;
246 + } else /* No empty slots */
247 + return 1;
248 + break;
249 +
250 + case DMA_CTM4:
251 + if (used_reqs[28] == 0) {
252 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC28(3))
253 + | MCF_DMA_IMCR_SRC28_CTM4;
254 + used_reqs[28] = DMA_CTM4;
255 + } else /* No empty slots */
256 + return 1;
257 + break;
258 +
259 + case DMA_CTM5:
260 + if (used_reqs[29] == 0) {
261 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC29(3))
262 + | MCF_DMA_IMCR_SRC29_CTM5;
263 + used_reqs[29] = DMA_CTM5;
264 + } else /* No empty slots */
265 + return 1;
266 + break;
267 +
268 + case DMA_CTM6:
269 + if (used_reqs[30] == 0) {
270 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC30(3))
271 + | MCF_DMA_IMCR_SRC30_CTM6;
272 + used_reqs[30] = DMA_CTM6;
273 + } else /* No empty slots */
274 + return 1;
275 + break;
276 +
277 + case DMA_CTM7:
278 + if (used_reqs[31] == 0) {
279 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC31(3))
280 + | MCF_DMA_IMCR_SRC31_CTM7;
281 + used_reqs[31] = DMA_CTM7;
282 + } else /* No empty slots */
283 + return 1;
284 + break;
285 +
286 + case DMA_USBEP4:
287 + if (used_reqs[26] == 0) {
288 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC26(3))
289 + | MCF_DMA_IMCR_SRC26_USBEP4;
290 + used_reqs[26] = DMA_USBEP4;
291 + } else /* No empty slots */
292 + return 1;
293 + break;
294 +
295 + case DMA_USBEP5:
296 + if (used_reqs[27] == 0) {
297 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC27(3))
298 + | MCF_DMA_IMCR_SRC27_USBEP5;
299 + used_reqs[27] = DMA_USBEP5;
300 + } else /* No empty slots */
301 + return 1;
302 + break;
303 +
304 + case DMA_USBEP6:
305 + if (used_reqs[28] == 0) {
306 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC28(3))
307 + | MCF_DMA_IMCR_SRC28_USBEP6;
308 + used_reqs[28] = DMA_USBEP6;
309 + } else /* No empty slots */
310 + return 1;
311 + break;
312 +
313 + case DMA_PSC2_RX:
314 + if (used_reqs[28] == 0) {
315 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC28(3))
316 + | MCF_DMA_IMCR_SRC28_PSC2RX;
317 + used_reqs[28] = DMA_PSC2_RX;
318 + } else /* No empty slots */
319 + return 1;
320 + break;
321 +
322 + case DMA_PSC2_TX:
323 + if (used_reqs[29] == 0) {
324 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC29(3))
325 + | MCF_DMA_IMCR_SRC29_PSC2TX;
326 + used_reqs[29] = DMA_PSC2_TX;
327 + } else /* No empty slots */
328 + return 1;
329 + break;
330 +
331 + case DMA_PSC3_RX:
332 + if (used_reqs[30] == 0) {
333 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC30(3))
334 + | MCF_DMA_IMCR_SRC30_PSC3RX;
335 + used_reqs[30] = DMA_PSC3_RX;
336 + } else /* No empty slots */
337 + return 1;
338 + break;
339 +
340 + case DMA_PSC3_TX:
341 + if (used_reqs[31] == 0) {
342 + MCF_DMA_IMCR = (MCF_DMA_IMCR & ~MCF_DMA_IMCR_SRC31(3))
343 + | MCF_DMA_IMCR_SRC31_PSC3TX;
344 + used_reqs[31] = DMA_PSC3_TX;
345 + } else /* No empty slots */
346 + return 1;
347 + break;
348 +
349 + default:
350 + return 1;
351 + }
352 + return 0;
353 +}
354 +
355 +/********************************************************************/
356 +/*
357 + * Return the initiator number for the given requestor
358 + *
359 + * Parameters:
360 + * requestor Initiator/Requestor identifier
361 + *
362 + * Return Value:
363 + * The initiator number (0-31) if initiator has been assigned
364 + * 0 (always initiator) otherwise
365 + */
366 +unsigned int
367 +dma_get_initiator(int requestor)
368 +{
369 + u32 i;
370 +
371 + for (i = 0; i < sizeof (used_reqs); ++i) {
372 + if (used_reqs[i] == requestor)
373 + return i;
374 + }
375 + return 0;
376 +}
377 +
378 +/********************************************************************/
379 +/*
380 + * Remove the given initiator from the active list
381 + *
382 + * Parameters:
383 + * requestor Initiator/Requestor identifier
384 + */
385 +void
386 +dma_remove_initiator(int requestor)
387 +{
388 + u32 i;
389 +
390 + for (i = 0; i < sizeof (used_reqs); ++i) {
391 + if (used_reqs[i] == requestor) {
392 + used_reqs[i] = -1;
393 + break;
394 + }
395 + }
396 +}
397 +
398 +/********************************************************************/
399 +/*
400 + * Attempt to find an available channel for FEC and mark is as used
401 + *
402 + * Parameters:
403 + * requestor Initiator/Requestor identifier
404 + *
405 + * Return Value:
406 + * First available channel (from 0 to 5) or -1 if they are all occupied
407 + */
408 +int
409 +dma_set_channel_fec(int requestor)
410 +{
411 + u32 i, t;
412 +
413 +#ifdef CONFIG_FEC_548x_ENABLE_FEC2
414 + t = 4;
415 +#else
416 + t = 2;
417 +#endif
418 +
419 +
420 +
421 + for (i = 0; i < t ; ++i)
422 + if (used_channel[i] == -1) {
423 + used_channel[i] = requestor;
424 + return i;
425 + }
426 + /* All channels taken */
427 + return -1;
428 +}
429 +
430 +/********************************************************************/
431 +/*
432 + * Attempt to find an available channel and mark is as used
433 + *
434 + * Parameters:
435 + * requestor Initiator/Requestor identifier
436 + *
437 + * Return Value:
438 + * First available channel (from 6 to 15) or -1 if they are all occupied
439 + */
440 +int
441 +dma_set_channel(int requestor)
442 +{
443 + u32 i;
444 +#ifdef CONFIG_NET_FEC2
445 + i = 4;
446 +#else
447 + i = 2;
448 +#endif
449 +
450 + for (; i < 16; ++i)
451 + if (used_channel[i] == -1) {
452 + used_channel[i] = requestor;
453 + return i;
454 + }
455 +
456 + /* All channels taken */
457 + return -1;
458 +}
459 +
460 +/********************************************************************/
461 +/*
462 + * Return the channel being initiated by the given requestor
463 + *
464 + * Parameters:
465 + * requestor Initiator/Requestor identifier
466 + */
467 +int
468 +dma_get_channel(int requestor)
469 +{
470 + u32 i;
471 +
472 + for (i = 0; i < sizeof (used_channel); ++i) {
473 + if (used_channel[i] == requestor)
474 + return i;
475 + }
476 + return -1;
477 +}
478 +
479 +/********************************************************************/
480 +/*
481 + * Connects a channel with reference on your data
482 + *
483 + * Parameters:
484 + * channel channel number
485 + * reference addres of your data
486 + */
487 +int
488 +dma_connect(int channel, int address)
489 +{
490 + if ((channel < 16) && (channel >= 0))
491 + connected_channel[channel] = address;
492 + else
493 + return -1;
494 + return 0;
495 +}
496 +
497 +/********************************************************************/
498 +/*
499 + * Disconnects a channel with reference on your data
500 + *
501 + * Parameters:
502 + * channel channel number
503 +*/
504 +int
505 +dma_disconnect(int channel)
506 +{
507 + if ((channel < 16) && (channel >= 0))
508 + connected_channel[channel] = 0;
509 + else
510 + return -1;
511 + return 0;
512 +}
513 +
514 +/********************************************************************/
515 +/*
516 + * Remove the channel being initiated by the given requestor from
517 + * the active list
518 + *
519 + * Parameters:
520 + * requestor Initiator/Requestor identifier
521 + */
522 +void
523 +dma_remove_channel(int requestor)
524 +{
525 + u32 i;
526 +
527 + for (i = 0; i < sizeof (used_channel); ++i) {
528 + if (used_channel[i] == requestor) {
529 + used_channel[i] = -1;
530 + break;
531 + }
532 + }
533 +}
534 +
535 +/********************************************************************/
536 +/*
537 + * This is the catch-all interrupt handler for the mult-channel DMA
538 + */
539 +volatile u8 dma_iflag[16];
540 +u32 tx = 0;
541 +
542 +void
543 +dma_interrupt_handler(int irq, void *dev_id, struct pt_regs *regs)
544 +{
545 + u32 i, interrupts/*, mask, temp*/;
546 +
547 + /*
548 + * Determine which interrupt(s) triggered by AND'ing the
549 + * pending interrupts with those that aren't masked.
550 + */
551 +/* mask = MCF_DMA_DIMR;
552 + MCF_DMA_DIMR = 0xffffffff;
553 +*/
554 + interrupts = MCF_DMA_DIPR;
555 + MCF_DMA_DIPR |= interrupts;
556 +// temp = interrupts;
557 +
558 + //MCF_DMA_DIPR = interrupts;
559 + for (i = 0; i < 16; ++i, interrupts >>= 1)
560 + if (interrupts & 0x1)
561 + if (connected_channel[i] != 0)
562 + ((void (*)(void)) (connected_channel[i])) ();
563 +
564 +/* MCF_DMA_DIPR |= temp;
565 + MCF_DMA_DIMR = mask;*/
566 +}
567 +
568 +void
569 +dma_remove_channel_by_number(int channel)
570 +{
571 + if (channel < sizeof (used_channel) && channel >= 0)
572 + used_channel[channel] = -1;
573 +}
574 +
575 +int __devinit
576 +dma_init()
577 +{
578 + int result;
579 + char *dma_version_str;
580 +
581 + MCD_getVersion(&dma_version_str);
582 + printk("Initialize %s\n", dma_version_str);
583 +
584 + if (request_irq
585 + (64 + ISC_DMA,
586 + dma_interrupt_handler,
587 + IRQF_DISABLED,
588 + "MCD-DMA",
589 + NULL)) {
590 + printk("Cannot allocate the DMA IRQ(48)\n");
591 + return 1;
592 + }
593 +
594 + MCF_DMA_DIMR = 0;
595 + MCF_DMA_DIPR = 0xFFFFFFFF;
596 +
597 + MCF_ICR(ISC_DMA) = ILP_DMA;
598 +#if 0
599 +// JKM
600 + enable_irq( 64 + ISC_DMA );
601 +#endif
602 +
603 + result =
604 + MCD_initDma((dmaRegs *) (MCF_MBAR + 0x8000),
605 + (void *) SYS_SRAM_DMA_START, MCD_RELOC_TASKS);
606 + if (result != MCD_OK) {
607 + printk("Cannot perform DMA initialization\n");
608 + free_irq(64 + ISC_DMA, NULL);
609 + return 1;
610 + }
611 +
612 + return 0;
613 +}
614 +
615 +device_initcall(dma_init);
616 +
617 --- a/drivers/Makefile
618 +++ b/drivers/Makefile
619 @@ -93,3 +93,5 @@ obj-$(CONFIG_PPC_PS3) += ps3/
620 obj-$(CONFIG_OF) += of/
621 obj-$(CONFIG_SSB) += ssb/
622 obj-$(CONFIG_VIRTIO) += virtio/
623 +
624 +obj-$(CONFIG_MCD_DMA) += dma/
625 --- /dev/null
626 +++ b/drivers/dma/MCD_dma.h
627 @@ -0,0 +1,408 @@
628 +/*********************************************************************
629 + *
630 + * Copyright (C) 2004 Motorola, Inc.
631 + * MOTOROLA, INC. All Rights Reserved.
632 + * You are hereby granted a copyright license to use
633 + * the SOFTWARE so long as this entire notice is
634 + * retained without alteration in any modified and/or redistributed
635 + * versions, and that such modified versions are clearly identified
636 + * as such. No licenses are granted by implication, estoppel or
637 + * otherwise under any patents or trademarks of Motorola, Inc. This
638 + * software is provided on an "AS IS" basis and without warranty.
639 + *
640 + * To the maximum extent permitted by applicable law, MOTOROLA
641 + * DISCLAIMS ALL WARRANTIES WHETHER EXPRESS OR IMPLIED, INCLUDING
642 + * IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR
643 + * PURPOSE AND ANY WARRANTY AGAINST INFRINGEMENT WITH REGARD TO THE
644 + * SOFTWARE (INCLUDING ANY MODIFIED VERSIONS THEREOF) AND ANY
645 + * ACCOMPANYING WRITTEN MATERIALS.
646 + *
647 + * To the maximum extent permitted by applicable law, IN NO EVENT
648 + * SHALL MOTOROLA BE LIABLE FOR ANY DAMAGES WHATSOEVER (INCLUDING
649 + * WITHOUT LIMITATION, DAMAGES FOR LOSS OF BUSINESS PROFITS, BUSINESS
650 + * INTERRUPTION, LOSS OF BUSINESS INFORMATION, OR OTHER PECUNIARY
651 + * LOSS) ARISING OF THE USE OR INABILITY TO USE THE SOFTWARE.
652 + *
653 + * Motorola assumes no responsibility for the maintenance and support
654 + * of this software
655 + ********************************************************************/
656 +
657 +/*
658 + * File: MCD_dma.h
659 + * Purpose: Main header file for multi-channel DMA API.
660 + *
661 + * Notes:
662 + *
663 + * Modifications:
664 + */
665 +#ifndef _MCD_API_H
666 +#define _MCD_API_H
667 +
668 +#include <asm/types.h>
669 +
670 +/*
671 + * Turn Execution Unit tasks ON (#define) or OFF (#undef)
672 + */
673 +#undef MCD_INCLUDE_EU
674 +
675 +/*
676 + * Number of DMA channels
677 + */
678 +#define NCHANNELS 16
679 +
680 +/*
681 + * Total number of variants
682 + */
683 +#ifdef MCD_INCLUDE_EU
684 +#define NUMOFVARIANTS 6
685 +#else
686 +#define NUMOFVARIANTS 4
687 +#endif
688 +
689 +/*
690 + * Define sizes of the various tables
691 + */
692 +#define TASK_TABLE_SIZE (NCHANNELS*32)
693 +#define VAR_TAB_SIZE (128)
694 +#define CONTEXT_SAVE_SIZE (128)
695 +#define FUNCDESC_TAB_SIZE (256)
696 +
697 +#ifdef MCD_INCLUDE_EU
698 +#define FUNCDESC_TAB_NUM 16
699 +#else
700 +#define FUNCDESC_TAB_NUM 1
701 +#endif
702 +
703 +
704 +#ifndef DEFINESONLY
705 +
706 +/*
707 + * Portability typedefs
708 + */
709 + /*
710 +#ifndef s32
711 +typedef int s32;
712 +#endif
713 +#ifndef u32
714 +typedef unsigned int u32;
715 +#endif
716 +#ifndef s16
717 +typedef short s16;
718 +#endif
719 +#ifndef u16
720 +typedef unsigned short u16;
721 +#endif
722 +#ifndef s8
723 +typedef char s8;
724 +#endif
725 +#ifndef u8
726 +typedef unsigned char u8;
727 +#endif
728 +*/
729 +/*
730 + * These structures represent the internal registers of the
731 + * multi-channel DMA
732 + */
733 +struct dmaRegs_s {
734 + u32 taskbar; /* task table base address register */
735 + u32 currPtr;
736 + u32 endPtr;
737 + u32 varTablePtr;
738 + u16 dma_rsvd0;
739 + u16 ptdControl; /* ptd control */
740 + u32 intPending; /* interrupt pending register */
741 + u32 intMask; /* interrupt mask register */
742 + u16 taskControl[16]; /* task control registers */
743 + u8 priority[32]; /* priority registers */
744 + u32 initiatorMux; /* initiator mux control */
745 + u32 taskSize0; /* task size control register 0. */
746 + u32 taskSize1; /* task size control register 1. */
747 + u32 dma_rsvd1; /* reserved */
748 + u32 dma_rsvd2; /* reserved */
749 + u32 debugComp1; /* debug comparator 1 */
750 + u32 debugComp2; /* debug comparator 2 */
751 + u32 debugControl; /* debug control */
752 + u32 debugStatus; /* debug status */
753 + u32 ptdDebug; /* priority task decode debug */
754 + u32 dma_rsvd3[31]; /* reserved */
755 +};
756 +typedef volatile struct dmaRegs_s dmaRegs;
757 +
758 +#endif
759 +
760 +/*
761 + * PTD contrl reg bits
762 + */
763 +#define PTD_CTL_TSK_PRI 0x8000
764 +#define PTD_CTL_COMM_PREFETCH 0x0001
765 +
766 +/*
767 + * Task Control reg bits and field masks
768 + */
769 +#define TASK_CTL_EN 0x8000
770 +#define TASK_CTL_VALID 0x4000
771 +#define TASK_CTL_ALWAYS 0x2000
772 +#define TASK_CTL_INIT_MASK 0x1f00
773 +#define TASK_CTL_ASTRT 0x0080
774 +#define TASK_CTL_HIPRITSKEN 0x0040
775 +#define TASK_CTL_HLDINITNUM 0x0020
776 +#define TASK_CTL_ASTSKNUM_MASK 0x000f
777 +
778 +/*
779 + * Priority reg bits and field masks
780 + */
781 +#define PRIORITY_HLD 0x80
782 +#define PRIORITY_PRI_MASK 0x07
783 +
784 +/*
785 + * Debug Control reg bits and field masks
786 + */
787 +#define DBG_CTL_BLOCK_TASKS_MASK 0xffff0000
788 +#define DBG_CTL_AUTO_ARM 0x00008000
789 +#define DBG_CTL_BREAK 0x00004000
790 +#define DBG_CTL_COMP1_TYP_MASK 0x00003800
791 +#define DBG_CTL_COMP2_TYP_MASK 0x00000070
792 +#define DBG_CTL_EXT_BREAK 0x00000004
793 +#define DBG_CTL_INT_BREAK 0x00000002
794 +
795 +/*
796 + * PTD Debug reg selector addresses
797 + * This reg must be written with a value to show the contents of
798 + * one of the desired internal register.
799 + */
800 +#define PTD_DBG_REQ 0x00 /* shows the state of 31 initiators */
801 +#define PTD_DBG_TSK_VLD_INIT 0x01 /* shows which 16 tasks are valid and
802 + have initiators asserted */
803 +
804 +
805 +/*
806 + * General return values
807 + */
808 +#define MCD_OK 0
809 +#define MCD_ERROR -1
810 +#define MCD_TABLE_UNALIGNED -2
811 +#define MCD_CHANNEL_INVALID -3
812 +
813 +/*
814 + * MCD_initDma input flags
815 + */
816 +#define MCD_RELOC_TASKS 0x00000001
817 +#define MCD_NO_RELOC_TASKS 0x00000000
818 +#define MCD_COMM_PREFETCH_EN 0x00000002 /* Commbus Prefetching - MCF547x/548x ONLY */
819 +
820 +/*
821 + * MCD_dmaStatus Status Values for each channel
822 + */
823 +#define MCD_NO_DMA 1 /* No DMA has been requested since reset */
824 +#define MCD_IDLE 2 /* DMA active, but the initiator is currently inactive */
825 +#define MCD_RUNNING 3 /* DMA active, and the initiator is currently active */
826 +#define MCD_PAUSED 4 /* DMA active but it is currently paused */
827 +#define MCD_HALTED 5 /* the most recent DMA has been killed with MCD_killTask() */
828 +#define MCD_DONE 6 /* the most recent DMA has completed. */
829 +
830 +
831 +/*
832 + * MCD_startDma parameter defines
833 + */
834 +
835 +/*
836 + * Constants for the funcDesc parameter
837 + */
838 +/* Byte swapping: */
839 +#define MCD_NO_BYTE_SWAP 0x00045670 /* to disable byte swapping. */
840 +#define MCD_BYTE_REVERSE 0x00076540 /* to reverse the bytes of each u32 of the DMAed data. */
841 +#define MCD_U16_REVERSE 0x00067450 /* to reverse the 16-bit halves of
842 + each 32-bit data value being DMAed.*/
843 +#define MCD_U16_BYTE_REVERSE 0x00054760 /* to reverse the byte halves of each
844 + 16-bit half of each 32-bit data value DMAed */
845 +#define MCD_NO_BIT_REV 0x00000000 /* do not reverse the bits of each byte DMAed. */
846 +#define MCD_BIT_REV 0x00088880 /* reverse the bits of each byte DMAed */
847 +/* CRCing: */
848 +#define MCD_CRC16 0xc0100000 /* to perform CRC-16 on DMAed data. */
849 +#define MCD_CRCCCITT 0xc0200000 /* to perform CRC-CCITT on DMAed data. */
850 +#define MCD_CRC32 0xc0300000 /* to perform CRC-32 on DMAed data. */
851 +#define MCD_CSUMINET 0xc0400000 /* to perform internet checksums on DMAed data.*/
852 +#define MCD_NO_CSUM 0xa0000000 /* to perform no checksumming. */
853 +
854 +#define MCD_FUNC_NOEU1 (MCD_NO_BYTE_SWAP | MCD_NO_BIT_REV | MCD_NO_CSUM)
855 +#define MCD_FUNC_NOEU2 (MCD_NO_BYTE_SWAP | MCD_NO_CSUM)
856 +
857 +/*
858 + * Constants for the flags parameter
859 + */
860 +#define MCD_TT_FLAGS_RL 0x00000001 /* Read line */
861 +#define MCD_TT_FLAGS_CW 0x00000002 /* Combine Writes */
862 +#define MCD_TT_FLAGS_SP 0x00000004 /* Speculative prefetch(XLB) MCF547x/548x ONLY */
863 +#define MCD_TT_FLAGS_MASK 0x000000ff
864 +#define MCD_TT_FLAGS_DEF (MCD_TT_FLAGS_RL | MCD_TT_FLAGS_CW)
865 +
866 +#define MCD_SINGLE_DMA 0x00000100 /* Unchained DMA */
867 +#define MCD_CHAIN_DMA /* TBD */
868 +#define MCD_EU_DMA /* TBD */
869 +#define MCD_FECTX_DMA 0x00001000 /* FEC TX ring DMA */
870 +#define MCD_FECRX_DMA 0x00002000 /* FEC RX ring DMA */
871 +
872 +
873 +/* these flags are valid for MCD_startDma and the chained buffer descriptors */
874 +#define MCD_BUF_READY 0x80000000 /* indicates that this buffer is now under the DMA's control */
875 +#define MCD_WRAP 0x20000000 /* to tell the FEC Dmas to wrap to the first BD */
876 +#define MCD_INTERRUPT 0x10000000 /* to generate an interrupt after completion of the DMA. */
877 +#define MCD_END_FRAME 0x08000000 /* tell the DMA to end the frame when transferring
878 + last byte of data in buffer */
879 +#define MCD_CRC_RESTART 0x40000000 /* to empty out the accumulated checksum
880 + prior to performing the DMA. */
881 +
882 +/* Defines for the FEC buffer descriptor control/status word*/
883 +#define MCD_FEC_BUF_READY 0x8000
884 +#define MCD_FEC_WRAP 0x2000
885 +#define MCD_FEC_INTERRUPT 0x1000
886 +#define MCD_FEC_END_FRAME 0x0800
887 +
888 +
889 +/*
890 + * Defines for general intuitiveness
891 + */
892 +
893 +#define MCD_TRUE 1
894 +#define MCD_FALSE 0
895 +
896 +/*
897 + * Three different cases for destination and source.
898 + */
899 +#define MINUS1 -1
900 +#define ZERO 0
901 +#define PLUS1 1
902 +
903 +#ifndef DEFINESONLY
904 +
905 +/* Task Table Entry struct*/
906 +typedef struct {
907 + u32 TDTstart; /* task descriptor table start */
908 + u32 TDTend; /* task descriptor table end */
909 + u32 varTab; /* variable table start */
910 + u32 FDTandFlags; /* function descriptor table start and flags */
911 + volatile u32 descAddrAndStatus;
912 + volatile u32 modifiedVarTab;
913 + u32 contextSaveSpace; /* context save space start */
914 + u32 literalBases;
915 +} TaskTableEntry;
916 +
917 +
918 +/* Chained buffer descriptor */
919 +typedef volatile struct MCD_bufDesc_struct MCD_bufDesc;
920 +struct MCD_bufDesc_struct {
921 + u32 flags; /* flags describing the DMA */
922 + u32 csumResult; /* checksum from checksumming performed since last checksum reset */
923 + s8 *srcAddr; /* the address to move data from */
924 + s8 *destAddr; /* the address to move data to */
925 + s8 *lastDestAddr; /* the last address written to */
926 + u32 dmaSize; /* the number of bytes to transfer independent of the transfer size */
927 + MCD_bufDesc *next; /* next buffer descriptor in chain */
928 + u32 info; /* private information about this descriptor; DMA does not affect it */
929 +};
930 +
931 +/* Progress Query struct */
932 +typedef volatile struct MCD_XferProg_struct {
933 + s8 *lastSrcAddr; /* the most-recent or last, post-increment source address */
934 + s8 *lastDestAddr; /* the most-recent or last, post-increment destination address */
935 + u32 dmaSize; /* the amount of data transferred for the current buffer */
936 + MCD_bufDesc *currBufDesc;/* pointer to the current buffer descriptor being DMAed */
937 +} MCD_XferProg;
938 +
939 +
940 +/* FEC buffer descriptor */
941 +typedef volatile struct MCD_bufDescFec_struct {
942 + u16 statCtrl;
943 + u16 length;
944 + u32 dataPointer;
945 +} MCD_bufDescFec;
946 +
947 +
948 +/*************************************************************************/
949 +/*
950 + * API function Prototypes - see MCD_dmaApi.c for further notes
951 + */
952 +
953 +/*
954 + * MCD_startDma starts a particular kind of DMA .
955 + */
956 +int MCD_startDma (
957 + int channel, /* the channel on which to run the DMA */
958 + s8 *srcAddr, /* the address to move data from, or buffer-descriptor address */
959 + s16 srcIncr, /* the amount to increment the source address per transfer */
960 + s8 *destAddr, /* the address to move data to */
961 + s16 destIncr, /* the amount to increment the destination address per transfer */
962 + u32 dmaSize, /* the number of bytes to transfer independent of the transfer size */
963 + u32 xferSize, /* the number bytes in of each data movement (1, 2, or 4) */
964 + u32 initiator, /* what device initiates the DMA */
965 + int priority, /* priority of the DMA */
966 + u32 flags, /* flags describing the DMA */
967 + u32 funcDesc /* a description of byte swapping, bit swapping, and CRC actions */
968 +);
969 +
970 +/*
971 + * MCD_initDma() initializes the DMA API by setting up a pointer to the DMA
972 + * registers, relocating and creating the appropriate task structures, and
973 + * setting up some global settings
974 + */
975 +int MCD_initDma (dmaRegs *sDmaBarAddr, void *taskTableDest, u32 flags);
976 +
977 +/*
978 + * MCD_dmaStatus() returns the status of the DMA on the requested channel.
979 + */
980 +int MCD_dmaStatus (int channel);
981 +
982 +/*
983 + * MCD_XferProgrQuery() returns progress of DMA on requested channel
984 + */
985 +int MCD_XferProgrQuery (int channel, MCD_XferProg *progRep);
986 +
987 +/*
988 + * MCD_killDma() halts the DMA on the requested channel, without any
989 + * intention of resuming the DMA.
990 + */
991 +int MCD_killDma (int channel);
992 +
993 +/*
994 + * MCD_continDma() continues a DMA which as stopped due to encountering an
995 + * unready buffer descriptor.
996 + */
997 +int MCD_continDma (int channel);
998 +
999 +/*
1000 + * MCD_pauseDma() pauses the DMA on the given channel ( if any DMA is
1001 + * running on that channel).
1002 + */
1003 +int MCD_pauseDma (int channel);
1004 +
1005 +/*
1006 + * MCD_resumeDma() resumes the DMA on a given channel (if any DMA is
1007 + * running on that channel).
1008 + */
1009 +int MCD_resumeDma (int channel);
1010 +
1011 +/*
1012 + * MCD_csumQuery provides the checksum/CRC after performing a non-chained DMA
1013 + */
1014 +int MCD_csumQuery (int channel, u32 *csum);
1015 +
1016 +/*
1017 + * MCD_getCodeSize provides the packed size required by the microcoded task
1018 + * and structures.
1019 + */
1020 +int MCD_getCodeSize(void);
1021 +
1022 +/*
1023 + * MCD_getVersion provides a pointer to a version string and returns a
1024 + * version number.
1025 + */
1026 +int MCD_getVersion(char **longVersion);
1027 +
1028 +/* macro for setting a location in the variable table */
1029 +#define MCD_SET_VAR(taskTab,idx,value) ((u32 *)(taskTab)->varTab)[idx] = value
1030 + /* Note that MCD_SET_VAR() is invoked many times in firing up a DMA function,
1031 + so I'm avoiding surrounding it with "do {} while(0)" */
1032 +
1033 +#endif /* DEFINESONLY */
1034 +
1035 +#endif /* _MCD_API_H */
1036 --- /dev/null
1037 +++ b/drivers/dma/MCD_dmaApi.c
1038 @@ -0,0 +1,968 @@
1039 +/*********************************************************************
1040 + *
1041 + * Copyright (C) 2004 Motorola, Inc.
1042 + * MOTOROLA, INC. All Rights Reserved.
1043 + * You are hereby granted a copyright license to use
1044 + * the SOFTWARE so long as this entire notice is
1045 + * retained without alteration in any modified and/or redistributed
1046 + * versions, and that such modified versions are clearly identified
1047 + * as such. No licenses are granted by implication, estoppel or
1048 + * otherwise under any patents or trademarks of Motorola, Inc. This
1049 + * software is provided on an "AS IS" basis and without warranty.
1050 + *
1051 + * To the maximum extent permitted by applicable law, MOTOROLA
1052 + * DISCLAIMS ALL WARRANTIES WHETHER EXPRESS OR IMPLIED, INCLUDING
1053 + * IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR
1054 + * PURPOSE AND ANY WARRANTY AGAINST INFRINGEMENT WITH REGARD TO THE
1055 + * SOFTWARE (INCLUDING ANY MODIFIED VERSIONS THEREOF) AND ANY
1056 + * ACCOMPANYING WRITTEN MATERIALS.
1057 + *
1058 + * To the maximum extent permitted by applicable law, IN NO EVENT
1059 + * SHALL MOTOROLA BE LIABLE FOR ANY DAMAGES WHATSOEVER (INCLUDING
1060 + * WITHOUT LIMITATION, DAMAGES FOR LOSS OF BUSINESS PROFITS, BUSINESS
1061 + * INTERRUPTION, LOSS OF BUSINESS INFORMATION, OR OTHER PECUNIARY
1062 + * LOSS) ARISING OF THE USE OR INABILITY TO USE THE SOFTWARE.
1063 + *
1064 + * Motorola assumes no responsibility for the maintenance and support
1065 + * of this software
1066 + ********************************************************************/
1067 +
1068 +/*
1069 + * File: MCD_dmaApi.c
1070 + * Purpose: Main C file for multi-channel DMA API.
1071 + *
1072 + * Notes:
1073 + *
1074 + *
1075 + * Modifications:
1076 + *
1077 + *
1078 + */
1079 +#include <asm/types.h>
1080 +#include <asm/MCD_dma.h>
1081 +#include <asm/virtconvert.h>
1082 +#include "MCD_tasksInit.h"
1083 +#include "MCD_progCheck.h"
1084 +
1085 +/********************************************************************/
1086 +/*
1087 + * This is an API-internal pointer to the DMA's registers
1088 + */
1089 +dmaRegs *MCD_dmaBar;
1090 +
1091 +/*
1092 + * These are the real and model task tables as generated by the
1093 + * build process
1094 + */
1095 +extern TaskTableEntry MCD_realTaskTableSrc[NCHANNELS];
1096 +extern TaskTableEntry MCD_modelTaskTableSrc[NUMOFVARIANTS];
1097 +
1098 +/*
1099 + * However, this (usually) gets relocated to on-chip SRAM, at which
1100 + * point we access them as these tables
1101 + */
1102 +volatile TaskTableEntry *MCD_taskTable;
1103 +TaskTableEntry *MCD_modelTaskTable;
1104 +
1105 +
1106 +/*
1107 + * MCD_chStatus[] is an array of status indicators for remembering
1108 + * whether a DMA has ever been attempted on each channel, pausing
1109 + * status, etc.
1110 + */
1111 +static int MCD_chStatus[NCHANNELS] =
1112 +{
1113 + MCD_NO_DMA, MCD_NO_DMA, MCD_NO_DMA, MCD_NO_DMA,
1114 + MCD_NO_DMA, MCD_NO_DMA, MCD_NO_DMA, MCD_NO_DMA,
1115 + MCD_NO_DMA, MCD_NO_DMA, MCD_NO_DMA, MCD_NO_DMA,
1116 + MCD_NO_DMA, MCD_NO_DMA, MCD_NO_DMA, MCD_NO_DMA
1117 +};
1118 +
1119 +/*
1120 + * Prototypes for local functions
1121 + */
1122 +static void MCD_memcpy (int *dest, int *src, u32 size);
1123 +static void MCD_resmActions (int channel);
1124 +
1125 +/*
1126 + * Buffer descriptors used for storage of progress info for single Dmas
1127 + * Also used as storage for the DMA for CRCs for single DMAs
1128 + * Otherwise, the DMA does not parse these buffer descriptors
1129 + */
1130 +#ifdef MCD_INCLUDE_EU
1131 +extern MCD_bufDesc MCD_singleBufDescs[NCHANNELS];
1132 +#else
1133 +MCD_bufDesc MCD_singleBufDescs[NCHANNELS];
1134 +#endif
1135 +MCD_bufDesc *MCD_relocBuffDesc;
1136 +
1137 +
1138 +/*
1139 + * Defines for the debug control register's functions
1140 + */
1141 +#define DBG_CTL_COMP1_TASK (0x00002000) /* have comparator 1 look for a task # */
1142 +#define DBG_CTL_ENABLE (DBG_CTL_AUTO_ARM | \
1143 + DBG_CTL_BREAK | \
1144 + DBG_CTL_INT_BREAK | \
1145 + DBG_CTL_COMP1_TASK)
1146 +#define DBG_CTL_DISABLE (DBG_CTL_AUTO_ARM | \
1147 + DBG_CTL_INT_BREAK | \
1148 + DBG_CTL_COMP1_TASK)
1149 +#define DBG_KILL_ALL_STAT (0xFFFFFFFF)
1150 +
1151 +/*
1152 + * Offset to context save area where progress info is stored
1153 + */
1154 +#define CSAVE_OFFSET 10
1155 +
1156 +/*
1157 + * Defines for Byte Swapping
1158 + */
1159 +#define MCD_BYTE_SWAP_KILLER 0xFFF8888F
1160 +#define MCD_NO_BYTE_SWAP_ATALL 0x00040000
1161 +
1162 +/*
1163 + * Execution Unit Identifiers
1164 + */
1165 +#define MAC 0 /* legacy - not used */
1166 +#define LUAC 1 /* legacy - not used */
1167 +#define CRC 2 /* legacy - not used */
1168 +#define LURC 3 /* Logic Unit with CRC */
1169 +
1170 +/*
1171 + * Task Identifiers
1172 + */
1173 +#define TASK_CHAINNOEU 0
1174 +#define TASK_SINGLENOEU 1
1175 +#ifdef MCD_INCLUDE_EU
1176 +#define TASK_CHAINEU 2
1177 +#define TASK_SINGLEEU 3
1178 +#define TASK_FECRX 4
1179 +#define TASK_FECTX 5
1180 +#else
1181 +#define TASK_CHAINEU 0
1182 +#define TASK_SINGLEEU 1
1183 +#define TASK_FECRX 2
1184 +#define TASK_FECTX 3
1185 +#endif
1186 +
1187 +/*
1188 + * Structure to remember which variant is on which channel
1189 + * TBD- need this?
1190 + */
1191 +typedef struct MCD_remVariants_struct MCD_remVariant;
1192 +struct MCD_remVariants_struct
1193 +{
1194 + int remDestRsdIncr[NCHANNELS]; /* -1,0,1 */
1195 + int remSrcRsdIncr[NCHANNELS]; /* -1,0,1 */
1196 + s16 remDestIncr[NCHANNELS]; /* DestIncr */
1197 + s16 remSrcIncr[NCHANNELS]; /* srcIncr */
1198 + u32 remXferSize[NCHANNELS]; /* xferSize */
1199 +};
1200 +
1201 +/*
1202 + * Structure to remember the startDma parameters for each channel
1203 + */
1204 +MCD_remVariant MCD_remVariants;
1205 +/********************************************************************/
1206 +/*
1207 + * Function: MCD_initDma
1208 + * Purpose: Initializes the DMA API by setting up a pointer to the DMA
1209 + * registers, relocating and creating the appropriate task
1210 + * structures, and setting up some global settings
1211 + * Arguments:
1212 + * dmaBarAddr - pointer to the multichannel DMA registers
1213 + * taskTableDest - location to move DMA task code and structs to
1214 + * flags - operational parameters
1215 + * Return Value:
1216 + * MCD_TABLE_UNALIGNED if taskTableDest is not 512-byte aligned
1217 + * MCD_OK otherwise
1218 + */
1219 +extern u32 MCD_funcDescTab0[];
1220 +
1221 +int MCD_initDma (dmaRegs *dmaBarAddr, void *taskTableDest, u32 flags)
1222 +{
1223 + int i;
1224 + TaskTableEntry *entryPtr;
1225 +
1226 + /* setup the local pointer to register set */
1227 + MCD_dmaBar = dmaBarAddr;
1228 +
1229 + /* do we need to move/create a task table */
1230 + if ((flags & MCD_RELOC_TASKS) != 0)
1231 + {
1232 + int fixedSize;
1233 + u32 *fixedPtr;
1234 + /*int *tablePtr = taskTableDest;TBD*/
1235 + int varTabsOffset, funcDescTabsOffset, contextSavesOffset;
1236 + int taskDescTabsOffset;
1237 + int taskTableSize, varTabsSize, funcDescTabsSize, contextSavesSize;
1238 + int taskDescTabSize;
1239 +
1240 + int i;
1241 +
1242 + /* check if physical address is aligned on 512 byte boundary */
1243 + if (((u32)taskTableDest & 0x000001ff) != 0)
1244 + return(MCD_TABLE_UNALIGNED);
1245 +
1246 + MCD_taskTable = taskTableDest; /* set up local pointer to task Table */
1247 +
1248 + /*
1249 + * Create a task table:
1250 + * - compute aligned base offsets for variable tables and
1251 + * function descriptor tables, then
1252 + * - loop through the task table and setup the pointers
1253 + * - copy over model task table with the the actual task descriptor
1254 + * tables
1255 + */
1256 +
1257 + taskTableSize = NCHANNELS * sizeof(TaskTableEntry);
1258 + /* align variable tables to size */
1259 + varTabsOffset = taskTableSize + (u32)taskTableDest;
1260 + if ((varTabsOffset & (VAR_TAB_SIZE - 1)) != 0)
1261 + varTabsOffset = (varTabsOffset + VAR_TAB_SIZE) & (~VAR_TAB_SIZE);
1262 + /* align function descriptor tables */
1263 + varTabsSize = NCHANNELS * VAR_TAB_SIZE;
1264 + funcDescTabsOffset = varTabsOffset + varTabsSize;
1265 +
1266 + if ((funcDescTabsOffset & (FUNCDESC_TAB_SIZE - 1)) != 0)
1267 + funcDescTabsOffset = (funcDescTabsOffset + FUNCDESC_TAB_SIZE) &
1268 + (~FUNCDESC_TAB_SIZE);
1269 +
1270 + funcDescTabsSize = FUNCDESC_TAB_NUM * FUNCDESC_TAB_SIZE;
1271 + contextSavesOffset = funcDescTabsOffset + funcDescTabsSize;
1272 + contextSavesSize = (NCHANNELS * CONTEXT_SAVE_SIZE);
1273 + fixedSize = taskTableSize + varTabsSize + funcDescTabsSize +
1274 + contextSavesSize;
1275 +
1276 + /* zero the thing out */
1277 + fixedPtr = (u32 *)taskTableDest;
1278 + for (i = 0;i<(fixedSize/4);i++)
1279 + fixedPtr[i] = 0;
1280 +
1281 + entryPtr = (TaskTableEntry*)MCD_taskTable;
1282 + /* set up fixed pointers */
1283 + for (i = 0; i < NCHANNELS; i++)
1284 + {
1285 + entryPtr[i].varTab = (u32)varTabsOffset; /* update ptr to local value */
1286 + entryPtr[i].FDTandFlags = (u32)funcDescTabsOffset | MCD_TT_FLAGS_DEF;
1287 + entryPtr[i].contextSaveSpace = (u32)contextSavesOffset;
1288 + varTabsOffset += VAR_TAB_SIZE;
1289 +#ifdef MCD_INCLUDE_EU /* if not there is only one, just point to the same one */
1290 + funcDescTabsOffset += FUNCDESC_TAB_SIZE;
1291 +#endif
1292 + contextSavesOffset += CONTEXT_SAVE_SIZE;
1293 + }
1294 + /* copy over the function descriptor table */
1295 + for ( i = 0; i < FUNCDESC_TAB_NUM; i++)
1296 + {
1297 + MCD_memcpy((void*)(entryPtr[i].FDTandFlags & ~MCD_TT_FLAGS_MASK),
1298 + (void*)MCD_funcDescTab0, FUNCDESC_TAB_SIZE);
1299 + }
1300 +
1301 + /* copy model task table to where the context saves stuff leaves off*/
1302 + MCD_modelTaskTable = (TaskTableEntry*)contextSavesOffset;
1303 +
1304 + MCD_memcpy ((void*)MCD_modelTaskTable, (void*)MCD_modelTaskTableSrc,
1305 + NUMOFVARIANTS * sizeof(TaskTableEntry));
1306 +
1307 + entryPtr = MCD_modelTaskTable; /* point to local version of
1308 + model task table */
1309 + taskDescTabsOffset = (u32)MCD_modelTaskTable +
1310 + (NUMOFVARIANTS * sizeof(TaskTableEntry));
1311 +
1312 + /* copy actual task code and update TDT ptrs in local model task table */
1313 + for (i = 0; i < NUMOFVARIANTS; i++)
1314 + {
1315 + taskDescTabSize = entryPtr[i].TDTend - entryPtr[i].TDTstart + 4;
1316 + MCD_memcpy ((void*)taskDescTabsOffset, (void*)entryPtr[i].TDTstart, taskDescTabSize);
1317 + entryPtr[i].TDTstart = (u32)taskDescTabsOffset;
1318 + taskDescTabsOffset += taskDescTabSize;
1319 + entryPtr[i].TDTend = (u32)taskDescTabsOffset - 4;
1320 + }
1321 +#ifdef MCD_INCLUDE_EU /* Tack single DMA BDs onto end of code so API controls
1322 + where they are since DMA might write to them */
1323 + MCD_relocBuffDesc = (MCD_bufDesc*)(entryPtr[NUMOFVARIANTS - 1].TDTend + 4);
1324 +#else /* DMA does not touch them so they can be wherever and we don't need to
1325 + waste SRAM on them */
1326 + MCD_relocBuffDesc = MCD_singleBufDescs;
1327 +#endif
1328 + }
1329 + else
1330 + {
1331 + /* point the would-be relocated task tables and the
1332 + buffer descriptors to the ones the linker generated */
1333 +
1334 + if (((u32)MCD_realTaskTableSrc & 0x000001ff) != 0)
1335 + return(MCD_TABLE_UNALIGNED);
1336 +
1337 + /* need to add code to make sure that every thing else is aligned properly TBD*/
1338 + /* this is problematic if we init more than once or after running tasks,
1339 + need to add variable to see if we have aleady init'd */
1340 + entryPtr = MCD_realTaskTableSrc;
1341 + for (i = 0; i < NCHANNELS; i++)
1342 + {
1343 + if (((entryPtr[i].varTab & (VAR_TAB_SIZE - 1)) != 0) ||
1344 + ((entryPtr[i].FDTandFlags & (FUNCDESC_TAB_SIZE - 1)) != 0))
1345 + return(MCD_TABLE_UNALIGNED);
1346 + }
1347 +
1348 + MCD_taskTable = MCD_realTaskTableSrc;
1349 + MCD_modelTaskTable = MCD_modelTaskTableSrc;
1350 + MCD_relocBuffDesc = MCD_singleBufDescs;
1351 + }
1352 +
1353 +
1354 + /* Make all channels as totally inactive, and remember them as such: */
1355 +
1356 + MCD_dmaBar->taskbar = (u32) MCD_taskTable;
1357 + for (i = 0; i < NCHANNELS; i++)
1358 + {
1359 + MCD_dmaBar->taskControl[i] = 0x0;
1360 + MCD_chStatus[i] = MCD_NO_DMA;
1361 + }
1362 +
1363 + /* Set up pausing mechanism to inactive state: */
1364 + MCD_dmaBar->debugComp1 = 0; /* no particular values yet for either comparator registers */
1365 + MCD_dmaBar->debugComp2 = 0;
1366 + MCD_dmaBar->debugControl = DBG_CTL_DISABLE;
1367 + MCD_dmaBar->debugStatus = DBG_KILL_ALL_STAT;
1368 +
1369 + /* enable or disable commbus prefetch, really need an ifdef or
1370 + something to keep from trying to set this in the 8220 */
1371 + if ((flags & MCD_COMM_PREFETCH_EN) != 0)
1372 + MCD_dmaBar->ptdControl &= ~PTD_CTL_COMM_PREFETCH;
1373 + else
1374 + MCD_dmaBar->ptdControl |= PTD_CTL_COMM_PREFETCH;
1375 +
1376 + return(MCD_OK);
1377 +}
1378 +/*********************** End of MCD_initDma() ***********************/
1379 +
1380 +/********************************************************************/
1381 +/* Function: MCD_dmaStatus
1382 + * Purpose: Returns the status of the DMA on the requested channel
1383 + * Arguments: channel - channel number
1384 + * Returns: Predefined status indicators
1385 + */
1386 +int MCD_dmaStatus (int channel)
1387 +{
1388 + u16 tcrValue;
1389 +
1390 + if((channel < 0) || (channel >= NCHANNELS))
1391 + return(MCD_CHANNEL_INVALID);
1392 +
1393 + tcrValue = MCD_dmaBar->taskControl[channel];
1394 + if ((tcrValue & TASK_CTL_EN) == 0)
1395 + { /* nothing running */
1396 + /* if last reported with task enabled */
1397 + if ( MCD_chStatus[channel] == MCD_RUNNING
1398 + || MCD_chStatus[channel] == MCD_IDLE)
1399 + MCD_chStatus[channel] = MCD_DONE;
1400 + }
1401 + else /* something is running */
1402 + {
1403 + /* There are three possibilities: paused, running or idle. */
1404 + if ( MCD_chStatus[channel] == MCD_RUNNING
1405 + || MCD_chStatus[channel] == MCD_IDLE)
1406 + {
1407 + MCD_dmaBar->ptdDebug = PTD_DBG_TSK_VLD_INIT;
1408 + /* This register is selected to know which initiator is
1409 + actually asserted. */
1410 + if ((MCD_dmaBar->ptdDebug >> channel ) & 0x1 )
1411 + MCD_chStatus[channel] = MCD_RUNNING;
1412 + else
1413 + MCD_chStatus[channel] = MCD_IDLE;
1414 + /* do not change the status if it is already paused. */
1415 + }
1416 + }
1417 + return MCD_chStatus[channel];
1418 +}
1419 +/******************** End of MCD_dmaStatus() ************************/
1420 +
1421 +/********************************************************************/
1422 +/* Function: MCD_startDma
1423 + * Ppurpose: Starts a particular kind of DMA
1424 + * Arguments: see below
1425 + * Returns: MCD_CHANNEL_INVALID if channel is invalid, else MCD_OK
1426 + */
1427 +
1428 +int MCD_startDma (
1429 + int channel, /* the channel on which to run the DMA */
1430 + s8 *srcAddr, /* the address to move data from, or physical buffer-descriptor address */
1431 + s16 srcIncr, /* the amount to increment the source address per transfer */
1432 + s8 *destAddr, /* the address to move data to */
1433 + s16 destIncr, /* the amount to increment the destination address per transfer */
1434 + u32 dmaSize, /* the number of bytes to transfer independent of the transfer size */
1435 + u32 xferSize, /* the number bytes in of each data movement (1, 2, or 4) */
1436 + u32 initiator, /* what device initiates the DMA */
1437 + int priority, /* priority of the DMA */
1438 + u32 flags, /* flags describing the DMA */
1439 + u32 funcDesc /* a description of byte swapping, bit swapping, and CRC actions */
1440 +#ifdef MCD_NEED_ADDR_TRANS
1441 + s8 *srcAddrVirt /* virtual buffer descriptor address TBD*/
1442 +#endif
1443 +)
1444 +{
1445 + int srcRsdIncr, destRsdIncr;
1446 + int *cSave;
1447 + short xferSizeIncr;
1448 + int tcrCount = 0;
1449 +#ifdef MCD_INCLUDE_EU
1450 + u32 *realFuncArray;
1451 +#endif
1452 +
1453 + if((channel < 0) || (channel >= NCHANNELS))
1454 + return(MCD_CHANNEL_INVALID);
1455 +
1456 + /* tbd - need to determine the proper response to a bad funcDesc when not
1457 + including EU functions, for now, assign a benign funcDesc, but maybe
1458 + should return an error */
1459 +#ifndef MCD_INCLUDE_EU
1460 + funcDesc = MCD_FUNC_NOEU1;
1461 +#endif
1462 +
1463 +#ifdef MCD_DEBUG
1464 +printf("startDma:Setting up params\n");
1465 +#endif
1466 + /* Set us up for task-wise priority. We don't technically need to do this on every start, but
1467 + since the register involved is in the same longword as other registers that users are in control
1468 + of, setting it more than once is probably preferable. That since the documentation doesn't seem
1469 + to be completely consistent about the nature of the PTD control register. */
1470 + MCD_dmaBar->ptdControl |= (u16) 0x8000;
1471 +#if 1 /* Not sure what we need to keep here rtm TBD */
1472 + /* Calculate additional parameters to the regular DMA calls. */
1473 + srcRsdIncr = srcIncr < 0 ? -1 : (srcIncr > 0 ? 1 : 0);
1474 + destRsdIncr = destIncr < 0 ? -1 : (destIncr > 0 ? 1 : 0);
1475 +
1476 + xferSizeIncr = (xferSize & 0xffff) | 0x20000000;
1477 +
1478 + /* Remember for each channel which variant is running. */
1479 + MCD_remVariants.remSrcRsdIncr[channel] = srcRsdIncr;
1480 + MCD_remVariants.remDestRsdIncr[channel] = destRsdIncr;
1481 + MCD_remVariants.remDestIncr[channel] = destIncr;
1482 + MCD_remVariants.remSrcIncr[channel] = srcIncr;
1483 + MCD_remVariants.remXferSize[channel] = xferSize;
1484 +#endif
1485 +
1486 + cSave = (int*)(MCD_taskTable[channel].contextSaveSpace) + CSAVE_OFFSET + CURRBD;
1487 +
1488 +#ifdef MCD_INCLUDE_EU /* may move this to EU specific calls */
1489 + realFuncArray = (u32 *) (MCD_taskTable[channel].FDTandFlags & 0xffffff00);
1490 + /* Modify the LURC's normal and byte-residue-loop functions according to parameter. */
1491 + realFuncArray[(LURC*16)] = xferSize == 4 ?
1492 + funcDesc : xferSize == 2 ?
1493 + funcDesc & 0xfffff00f : funcDesc & 0xffff000f;
1494 + realFuncArray[(LURC*16+1)] = (funcDesc & MCD_BYTE_SWAP_KILLER) | MCD_NO_BYTE_SWAP_ATALL;
1495 +#endif
1496 + /* Write the initiator field in the TCR, and also set the initiator-hold
1497 + bit. Note that,due to a hardware quirk, this could collide with an
1498 + MDE access to the initiator-register file, so we have to verify that the write
1499 + reads back correctly. */
1500 +
1501 + MCD_dmaBar->taskControl[channel] =
1502 + (initiator << 8) | TASK_CTL_HIPRITSKEN | TASK_CTL_HLDINITNUM;
1503 +
1504 + while(((MCD_dmaBar->taskControl[channel] & 0x1fff) !=
1505 + ((initiator << 8) | TASK_CTL_HIPRITSKEN | TASK_CTL_HLDINITNUM)) &&
1506 + (tcrCount < 1000))
1507 + {
1508 + tcrCount++;
1509 + /*MCD_dmaBar->ptd_tcr[channel] = (initiator << 8) | 0x0020;*/
1510 + MCD_dmaBar->taskControl[channel] =
1511 + (initiator << 8) | TASK_CTL_HIPRITSKEN | TASK_CTL_HLDINITNUM;
1512 + }
1513 +
1514 + MCD_dmaBar->priority[channel] = (u8)priority & PRIORITY_PRI_MASK;
1515 + /* should be albe to handle this stuff with only one write to ts reg - tbd */
1516 + if (channel < 8 && channel >= 0)
1517 + {
1518 + MCD_dmaBar->taskSize0 &= ~(0xf << (7-channel)*4);
1519 + MCD_dmaBar->taskSize0 |= (xferSize & 3) << (((7 - channel)*4) + 2);
1520 + MCD_dmaBar->taskSize0 |= (xferSize & 3) << ((7 - channel)*4);
1521 + }
1522 + else
1523 + {
1524 + MCD_dmaBar->taskSize1 &= ~(0xf << (15-channel)*4);
1525 + MCD_dmaBar->taskSize1 |= (xferSize & 3) << (((15 - channel)*4) + 2);
1526 + MCD_dmaBar->taskSize1 |= (xferSize & 3) << ((15 - channel)*4);
1527 + }
1528 +
1529 + /* setup task table flags/options which mostly control the line buffers */
1530 + MCD_taskTable[channel].FDTandFlags &= ~MCD_TT_FLAGS_MASK;
1531 + MCD_taskTable[channel].FDTandFlags |= (MCD_TT_FLAGS_MASK & flags);
1532 +
1533 + if (flags & MCD_FECTX_DMA)
1534 + {
1535 + /* TDTStart and TDTEnd */
1536 + MCD_taskTable[channel].TDTstart = MCD_modelTaskTable[TASK_FECTX].TDTstart;
1537 + MCD_taskTable[channel].TDTend = MCD_modelTaskTable[TASK_FECTX].TDTend;
1538 + MCD_startDmaENetXmit(srcAddr, srcAddr, destAddr, MCD_taskTable, channel);
1539 + }
1540 + else if (flags & MCD_FECRX_DMA)
1541 + {
1542 + /* TDTStart and TDTEnd */
1543 + MCD_taskTable[channel].TDTstart = MCD_modelTaskTable[TASK_FECRX].TDTstart;
1544 + MCD_taskTable[channel].TDTend = MCD_modelTaskTable[TASK_FECRX].TDTend;
1545 + MCD_startDmaENetRcv(srcAddr, srcAddr, destAddr, MCD_taskTable, channel);
1546 + }
1547 + else if(flags & MCD_SINGLE_DMA)
1548 + {
1549 + /* this buffer descriptor is used for storing off initial parameters for later
1550 + progress query calculation and for the DMA to write the resulting checksum
1551 + The DMA does not use this to determine how to operate, that info is passed
1552 + with the init routine*/
1553 + MCD_relocBuffDesc[channel].srcAddr = srcAddr;
1554 + MCD_relocBuffDesc[channel].destAddr = destAddr;
1555 + MCD_relocBuffDesc[channel].lastDestAddr = destAddr; /* definitely not its final value */
1556 + MCD_relocBuffDesc[channel].dmaSize = dmaSize;
1557 + MCD_relocBuffDesc[channel].flags = 0; /* not used */
1558 + MCD_relocBuffDesc[channel].csumResult = 0; /* not used */
1559 + MCD_relocBuffDesc[channel].next = 0; /* not used */
1560 +
1561 + /* Initialize the progress-querying stuff to show no progress:*/
1562 + ((volatile int *)MCD_taskTable[channel].contextSaveSpace)[SRCPTR + CSAVE_OFFSET] = (int)srcAddr;
1563 + ((volatile int *)MCD_taskTable[channel].contextSaveSpace)[DESTPTR + CSAVE_OFFSET] = (int)destAddr;
1564 + ((volatile int *)MCD_taskTable[channel].contextSaveSpace)[DCOUNT + CSAVE_OFFSET] = 0;
1565 + ((volatile int *)MCD_taskTable[channel].contextSaveSpace)[CURRBD + CSAVE_OFFSET] =
1566 + (u32) &(MCD_relocBuffDesc[channel]);
1567 + /* tbd - need to keep the user from trying to call the EU routine
1568 + when MCD_INCLUDE_EU is not defined */
1569 + if( funcDesc == MCD_FUNC_NOEU1 || funcDesc == MCD_FUNC_NOEU2)
1570 + {
1571 + /* TDTStart and TDTEnd */
1572 + MCD_taskTable[channel].TDTstart = MCD_modelTaskTable[TASK_SINGLENOEU].TDTstart;
1573 + MCD_taskTable[channel].TDTend = MCD_modelTaskTable[TASK_SINGLENOEU].TDTend;
1574 + MCD_startDmaSingleNoEu(srcAddr, srcIncr, destAddr, destIncr, dmaSize, dmaSize,
1575 + xferSizeIncr, flags, (int *)&(MCD_relocBuffDesc[channel]), cSave,
1576 + MCD_taskTable, channel);
1577 + }
1578 + else
1579 + {
1580 + /* TDTStart and TDTEnd */
1581 + MCD_taskTable[channel].TDTstart = MCD_modelTaskTable[TASK_SINGLEEU].TDTstart;
1582 + MCD_taskTable[channel].TDTend = MCD_modelTaskTable[TASK_SINGLEEU].TDTend;
1583 + MCD_startDmaSingleEu(srcAddr, srcIncr, destAddr, destIncr, dmaSize, dmaSize,
1584 + xferSizeIncr, flags, (int *)&(MCD_relocBuffDesc[channel]), cSave,
1585 + MCD_taskTable, channel);
1586 + }
1587 + }
1588 + else
1589 + { /* chained DMAS */
1590 + /* Initialize the progress-querying stuff to show no progress:*/
1591 +#if 1 /* (!defined(MCD_NEED_ADDR_TRANS)) */
1592 + ((volatile int *)MCD_taskTable[channel].contextSaveSpace)[SRCPTR + CSAVE_OFFSET]
1593 + = (int)((MCD_bufDesc*) phys_to_virt(srcAddr))->srcAddr;
1594 + ((volatile int *)MCD_taskTable[channel].contextSaveSpace)[DESTPTR + CSAVE_OFFSET]
1595 + = (int)((MCD_bufDesc*) phys_to_virt(srcAddr))->destAddr;
1596 +#else /* if using address translation, need the virtual addr of the first buffdesc */
1597 + ((volatile int *)MCD_taskTable[channel].contextSaveSpace)[SRCPTR + CSAVE_OFFSET]
1598 + = (int)((MCD_bufDesc*) srcAddrVirt)->srcAddr;
1599 + ((volatile int *)MCD_taskTable[channel].contextSaveSpace)[DESTPTR + CSAVE_OFFSET]
1600 + = (int)((MCD_bufDesc*) srcAddrVirt)->destAddr;
1601 +#endif
1602 + ((volatile int *)MCD_taskTable[channel].contextSaveSpace)[DCOUNT + CSAVE_OFFSET] = 0;
1603 + ((volatile int *)MCD_taskTable[channel].contextSaveSpace)[CURRBD + CSAVE_OFFSET] = (u32) srcAddr;
1604 +
1605 + if( funcDesc == MCD_FUNC_NOEU1 || funcDesc == MCD_FUNC_NOEU2)
1606 + {
1607 + /*TDTStart and TDTEnd*/
1608 + MCD_taskTable[channel].TDTstart = MCD_modelTaskTable[TASK_CHAINNOEU].TDTstart;
1609 + MCD_taskTable[channel].TDTend = MCD_modelTaskTable[TASK_CHAINNOEU].TDTend;
1610 + MCD_startDmaChainNoEu((int *)srcAddr, srcIncr, destIncr, xferSize,
1611 + xferSizeIncr, cSave, MCD_taskTable, channel);
1612 + }
1613 + else
1614 + {
1615 + /*TDTStart and TDTEnd*/
1616 + MCD_taskTable[channel].TDTstart = MCD_modelTaskTable[TASK_CHAINEU].TDTstart;
1617 + MCD_taskTable[channel].TDTend = MCD_modelTaskTable[TASK_CHAINEU].TDTend;
1618 + MCD_startDmaChainEu((int *)srcAddr, srcIncr, destIncr, xferSize,
1619 + xferSizeIncr, cSave, MCD_taskTable, channel);
1620 + }
1621 + }
1622 + MCD_chStatus[channel] = MCD_IDLE;
1623 + return(MCD_OK);
1624 +}
1625 +
1626 +/************************ End of MCD_startDma() *********************/
1627 +
1628 +/********************************************************************/
1629 +/* Function: MCD_XferProgrQuery
1630 + * Purpose: Returns progress of DMA on requested channel
1631 + * Arguments: channel - channel to retrieve progress for
1632 + * progRep - pointer to user supplied MCD_XferProg struct
1633 + * Returns: MCD_CHANNEL_INVALID if channel is invalid, else MCD_OK
1634 + *
1635 + * Notes:
1636 + * MCD_XferProgrQuery() upon completing or after aborting a DMA, or
1637 + * while the DMA is in progress, this function returns the first
1638 + * DMA-destination address not (or not yet) used in the DMA. When
1639 + * encountering a non-ready buffer descriptor, the information for
1640 + * the last completed descriptor is returned.
1641 + *
1642 + * MCD_XferProgQuery() has to avoid the possibility of getting
1643 + * partially-updated information in the event that we should happen
1644 + * to query DMA progress just as the DMA is updating it. It does that
1645 + * by taking advantage of the fact context is not saved frequently for
1646 + * the most part. We therefore read it at least twice until we get the
1647 + * same information twice in a row.
1648 + *
1649 + * Because a small, but not insignificant, amount of time is required
1650 + * to write out the progress-query information, especially upon
1651 + * completion of the DMA, it would be wise to guarantee some time lag
1652 + * between successive readings of the progress-query information.
1653 + */
1654 +
1655 +/*
1656 + * How many iterations of the loop below to execute to stabilize values
1657 + */
1658 +#define STABTIME 0
1659 +
1660 +int MCD_XferProgrQuery (int channel, MCD_XferProg *progRep)
1661 +{
1662 + MCD_XferProg prevRep;
1663 + int again; /* true if we are to try again to get consistent results */
1664 + int i; /* used as a time-waste counter */
1665 + int destDiffBytes; /* Total number of bytes that we think actually got xfered. */
1666 + int numIterations; /* number of iterations */
1667 + int bytesNotXfered; /* bytes that did not get xfered. */
1668 + s8 *LWAlignedInitDestAddr, *LWAlignedCurrDestAddr;
1669 + int subModVal, addModVal; /* Mode values to added and subtracted from the
1670 + final destAddr */
1671 +
1672 + if((channel < 0) || (channel >= NCHANNELS))
1673 + return(MCD_CHANNEL_INVALID);
1674 +
1675 + /* Read a trial value for the progress-reporting values*/
1676 + prevRep.lastSrcAddr =
1677 + (s8 *) ((volatile int*) MCD_taskTable[channel].contextSaveSpace)[SRCPTR + CSAVE_OFFSET];
1678 + prevRep.lastDestAddr =
1679 + (s8 *) ((volatile int*) MCD_taskTable[channel].contextSaveSpace)[DESTPTR + CSAVE_OFFSET];
1680 + prevRep.dmaSize = ((volatile int*) MCD_taskTable[channel].contextSaveSpace)[DCOUNT + CSAVE_OFFSET];
1681 + prevRep.currBufDesc =
1682 + (MCD_bufDesc*) ((volatile int*) MCD_taskTable[channel].contextSaveSpace)[CURRBD + CSAVE_OFFSET];
1683 + /* Repeatedly reread those values until they match previous values: */
1684 + do {
1685 + /* Waste a little bit of time to ensure stability: */
1686 + for (i = 0; i < STABTIME; i++)
1687 + i += i >> 2; /* make sure this loop does something so that it doesn't get optimized out */
1688 + /* Check them again: */
1689 + progRep->lastSrcAddr =
1690 + (s8 *) ((volatile int*) MCD_taskTable[channel].contextSaveSpace)[SRCPTR + CSAVE_OFFSET];
1691 + progRep->lastDestAddr =
1692 + (s8 *) ((volatile int*) MCD_taskTable[channel].contextSaveSpace)[DESTPTR + CSAVE_OFFSET];
1693 + progRep->dmaSize = ((volatile int*) MCD_taskTable[channel].contextSaveSpace)[DCOUNT + CSAVE_OFFSET];
1694 + progRep->currBufDesc =
1695 + (MCD_bufDesc*) ((volatile int*) MCD_taskTable[channel].contextSaveSpace)[CURRBD + CSAVE_OFFSET];
1696 + /* See if they match: */
1697 + if ( prevRep.lastSrcAddr != progRep->lastSrcAddr
1698 + || prevRep.lastDestAddr != progRep->lastDestAddr
1699 + || prevRep.dmaSize != progRep->dmaSize
1700 + || prevRep.currBufDesc != progRep->currBufDesc)
1701 + {
1702 + /* If they don't match, remember previous values and try again:*/
1703 + prevRep.lastSrcAddr = progRep->lastSrcAddr;
1704 + prevRep.lastDestAddr = progRep->lastDestAddr;
1705 + prevRep.dmaSize = progRep->dmaSize;
1706 + prevRep.currBufDesc = progRep->currBufDesc;
1707 + again = MCD_TRUE;
1708 + }
1709 + else
1710 + again = MCD_FALSE;
1711 + } while (again == MCD_TRUE);
1712 +
1713 +
1714 + /* Update the dCount, srcAddr and destAddr */
1715 + /* To calculate dmaCount, we consider destination address. C
1716 + overs M1,P1,Z for destination */
1717 + switch(MCD_remVariants.remDestRsdIncr[channel]) {
1718 + case MINUS1:
1719 + subModVal = ((int)progRep->lastDestAddr) & ((MCD_remVariants.remXferSize[channel]) - 1);
1720 + addModVal = ((int)progRep->currBufDesc->destAddr) & ((MCD_remVariants.remXferSize[channel]) - 1);
1721 + LWAlignedInitDestAddr = (progRep->currBufDesc->destAddr) - addModVal;
1722 + LWAlignedCurrDestAddr = (progRep->lastDestAddr) - subModVal;
1723 + destDiffBytes = LWAlignedInitDestAddr - LWAlignedCurrDestAddr;
1724 + bytesNotXfered = (destDiffBytes/MCD_remVariants.remDestIncr[channel]) *
1725 + ( MCD_remVariants.remDestIncr[channel]
1726 + + MCD_remVariants.remXferSize[channel]);
1727 + progRep->dmaSize = destDiffBytes - bytesNotXfered + addModVal - subModVal;
1728 + break;
1729 + case ZERO:
1730 + progRep->lastDestAddr = progRep->currBufDesc->destAddr;
1731 + break;
1732 + case PLUS1:
1733 + /* This value has to be subtracted from the final calculated dCount. */
1734 + subModVal = ((int)progRep->currBufDesc->destAddr) & ((MCD_remVariants.remXferSize[channel]) - 1);
1735 + /* These bytes are already in lastDestAddr. */
1736 + addModVal = ((int)progRep->lastDestAddr) & ((MCD_remVariants.remXferSize[channel]) - 1);
1737 + LWAlignedInitDestAddr = (progRep->currBufDesc->destAddr) - subModVal;
1738 + LWAlignedCurrDestAddr = (progRep->lastDestAddr) - addModVal;
1739 + destDiffBytes = (progRep->lastDestAddr - LWAlignedInitDestAddr);
1740 + numIterations = ( LWAlignedCurrDestAddr - LWAlignedInitDestAddr)/MCD_remVariants.remDestIncr[channel];
1741 + bytesNotXfered = numIterations *
1742 + ( MCD_remVariants.remDestIncr[channel]
1743 + - MCD_remVariants.remXferSize[channel]);
1744 + progRep->dmaSize = destDiffBytes - bytesNotXfered - subModVal;
1745 + break;
1746 + default:
1747 + break;
1748 + }
1749 +
1750 + /* This covers M1,P1,Z for source */
1751 + switch(MCD_remVariants.remSrcRsdIncr[channel]) {
1752 + case MINUS1:
1753 + progRep->lastSrcAddr =
1754 + progRep->currBufDesc->srcAddr +
1755 + ( MCD_remVariants.remSrcIncr[channel] *
1756 + (progRep->dmaSize/MCD_remVariants.remXferSize[channel]));
1757 + break;
1758 + case ZERO:
1759 + progRep->lastSrcAddr = progRep->currBufDesc->srcAddr;
1760 + break;
1761 + case PLUS1:
1762 + progRep->lastSrcAddr =
1763 + progRep->currBufDesc->srcAddr +
1764 + ( MCD_remVariants.remSrcIncr[channel] *
1765 + (progRep->dmaSize/MCD_remVariants.remXferSize[channel]));
1766 + break;
1767 + default: break;
1768 + }
1769 +
1770 + return(MCD_OK);
1771 +}
1772 +/******************* End of MCD_XferProgrQuery() ********************/
1773 +
1774 +/********************************************************************/
1775 +/* MCD_resmActions() does the majority of the actions of a DMA resume.
1776 + * It is called from MCD_killDma() and MCD_resumeDma(). It has to be
1777 + * a separate function because the kill function has to negate the task
1778 + * enable before resuming it, but the resume function has to do nothing
1779 + * if there is no DMA on that channel (i.e., if the enable bit is 0).
1780 + */
1781 +static void MCD_resmActions (int channel)
1782 +{
1783 + MCD_dmaBar->debugControl = DBG_CTL_DISABLE;
1784 + MCD_dmaBar->debugStatus = MCD_dmaBar->debugStatus;
1785 + MCD_dmaBar->ptdDebug = PTD_DBG_TSK_VLD_INIT; /* This register is selected to know
1786 + which initiator is actually asserted. */
1787 + if((MCD_dmaBar->ptdDebug >> channel ) & 0x1)
1788 + MCD_chStatus[channel] = MCD_RUNNING;
1789 + else
1790 + MCD_chStatus[channel] = MCD_IDLE;
1791 +}
1792 +/********************* End of MCD_resmActions() *********************/
1793 +
1794 +/********************************************************************/
1795 +/* Function: MCD_killDma
1796 + * Purpose: Halt the DMA on the requested channel, without any
1797 + * intention of resuming the DMA.
1798 + * Arguments: channel - requested channel
1799 + * Returns: MCD_CHANNEL_INVALID if channel is invalid, else MCD_OK
1800 + *
1801 + * Notes:
1802 + * A DMA may be killed from any state, including paused state, and it
1803 + * always goes to the MCD_HALTED state even if it is killed while in
1804 + * the MCD_NO_DMA or MCD_IDLE states.
1805 + */
1806 +int MCD_killDma (int channel)
1807 +{
1808 + /* MCD_XferProg progRep; */
1809 +
1810 + if((channel < 0) || (channel >= NCHANNELS))
1811 + return(MCD_CHANNEL_INVALID);
1812 +
1813 + MCD_dmaBar->taskControl[channel] = 0x0;
1814 + MCD_resumeDma (channel);
1815 + /*
1816 + * This must be after the write to the TCR so that the task doesn't
1817 + * start up again momentarily, and before the status assignment so
1818 + * as to override whatever MCD_resumeDma() may do to the channel
1819 + * status.
1820 + */
1821 + MCD_chStatus[channel] = MCD_HALTED;
1822 +
1823 + /*
1824 + * Update the current buffer descriptor's lastDestAddr field
1825 + *
1826 + * MCD_XferProgrQuery (channel, &progRep);
1827 + * progRep.currBufDesc->lastDestAddr = progRep.lastDestAddr;
1828 + */
1829 + return(MCD_OK);
1830 +}
1831 +/************************ End of MCD_killDma() **********************/
1832 +
1833 +/********************************************************************/
1834 +/* Function: MCD_continDma
1835 + * Purpose: Continue a DMA which as stopped due to encountering an
1836 + * unready buffer descriptor.
1837 + * Arguments: channel - channel to continue the DMA on
1838 + * Returns: MCD_CHANNEL_INVALID if channel is invalid, else MCD_OK
1839 + *
1840 + * Notes:
1841 + * This routine does not check to see if there is a task which can
1842 + * be continued. Also this routine should not be used with single DMAs.
1843 + */
1844 +int MCD_continDma (int channel)
1845 +{
1846 + if((channel < 0) || (channel >= NCHANNELS))
1847 + return(MCD_CHANNEL_INVALID);
1848 +
1849 + MCD_dmaBar->taskControl[channel] |= TASK_CTL_EN;
1850 + MCD_chStatus[channel] = MCD_RUNNING;
1851 +
1852 + return(MCD_OK);
1853 +}
1854 +/********************** End of MCD_continDma() **********************/
1855 +
1856 +/*********************************************************************
1857 + * MCD_pauseDma() and MCD_resumeDma() below use the DMA's debug unit
1858 + * to freeze a task and resume it. We freeze a task by breakpointing
1859 + * on the stated task. That is, not any specific place in the task,
1860 + * but any time that task executes. In particular, when that task
1861 + * executes, we want to freeze that task and only that task.
1862 + *
1863 + * The bits of the debug control register influence interrupts vs.
1864 + * breakpoints as follows:
1865 + * - Bits 14 and 0 enable or disable debug functions. If enabled, you
1866 + * will get the interrupt but you may or may not get a breakpoint.
1867 + * - Bits 2 and 1 decide whether you also get a breakpoint in addition
1868 + * to an interrupt.
1869 + *
1870 + * The debug unit can do these actions in response to either internally
1871 + * detected breakpoint conditions from the comparators, or in response
1872 + * to the external breakpoint pin, or both.
1873 + * - Bits 14 and 1 perform the above-described functions for
1874 + * internally-generated conditions, i.e., the debug comparators.
1875 + * - Bits 0 and 2 perform the above-described functions for external
1876 + * conditions, i.e., the breakpoint external pin.
1877 + *
1878 + * Note that, although you "always" get the interrupt when you turn
1879 + * the debug functions, the interrupt can nevertheless, if desired, be
1880 + * masked by the corresponding bit in the PTD's IMR. Note also that
1881 + * this means that bits 14 and 0 must enable debug functions before
1882 + * bits 1 and 2, respectively, have any effect.
1883 + *
1884 + * NOTE: It's extremely important to not pause more than one DMA channel
1885 + * at a time.
1886 + ********************************************************************/
1887 +
1888 +/********************************************************************/
1889 +/* Function: MCD_pauseDma
1890 + * Purpose: Pauses the DMA on a given channel (if any DMA is running
1891 + * on that channel).
1892 + * Arguments: channel
1893 + * Returns: MCD_CHANNEL_INVALID if channel is invalid, else MCD_OK
1894 + */
1895 +int MCD_pauseDma (int channel)
1896 +{
1897 + /* MCD_XferProg progRep; */
1898 +
1899 + if((channel < 0) || (channel >= NCHANNELS))
1900 + return(MCD_CHANNEL_INVALID);
1901 +
1902 + if (MCD_dmaBar->taskControl[channel] & TASK_CTL_EN)
1903 + {
1904 + MCD_dmaBar->debugComp1 = channel;
1905 + MCD_dmaBar->debugControl = DBG_CTL_ENABLE | (1 << (channel + 16));
1906 + MCD_chStatus[channel] = MCD_PAUSED;
1907 +
1908 + /*
1909 + * Update the current buffer descriptor's lastDestAddr field
1910 + *
1911 + * MCD_XferProgrQuery (channel, &progRep);
1912 + * progRep.currBufDesc->lastDestAddr = progRep.lastDestAddr;
1913 + */
1914 + }
1915 + return(MCD_OK);
1916 +}
1917 +/************************* End of MCD_pauseDma() ********************/
1918 +
1919 +/********************************************************************/
1920 +/* Function: MCD_resumeDma
1921 + * Purpose: Resumes the DMA on a given channel (if any DMA is
1922 + * running on that channel).
1923 + * Arguments: channel - channel on which to resume DMA
1924 + * Returns: MCD_CHANNEL_INVALID if channel is invalid, else MCD_OK
1925 + */
1926 +int MCD_resumeDma (int channel)
1927 +{
1928 + if((channel < 0) || (channel >= NCHANNELS))
1929 + return(MCD_CHANNEL_INVALID);
1930 +
1931 + if (MCD_dmaBar->taskControl[channel] & TASK_CTL_EN)
1932 + MCD_resmActions (channel);
1933 +
1934 + return(MCD_OK);
1935 +}
1936 +/************************ End of MCD_resumeDma() ********************/
1937 +
1938 +/********************************************************************/
1939 +/* Function: MCD_csumQuery
1940 + * Purpose: Provide the checksum after performing a non-chained DMA
1941 + * Arguments: channel - channel to report on
1942 + * csum - pointer to where to write the checksum/CRC
1943 + * Returns: MCD_ERROR if the channel is invalid, else MCD_OK
1944 + *
1945 + * Notes:
1946 + *
1947 + */
1948 +int MCD_csumQuery (int channel, u32 *csum)
1949 +{
1950 +#ifdef MCD_INCLUDE_EU
1951 + if((channel < 0) || (channel >= NCHANNELS))
1952 + return(MCD_CHANNEL_INVALID);
1953 +
1954 + *csum = MCD_relocBuffDesc[channel].csumResult;
1955 + return(MCD_OK);
1956 +#else
1957 + return(MCD_ERROR);
1958 +#endif
1959 +}
1960 +/*********************** End of MCD_resumeDma() *********************/
1961 +
1962 +/********************************************************************/
1963 +/* Function: MCD_getCodeSize
1964 + * Purpose: Provide the size requirements of the microcoded tasks
1965 + * Returns: Size in bytes
1966 + */
1967 +int MCD_getCodeSize(void)
1968 +{
1969 +#ifdef MCD_INCLUDE_EU
1970 + return(0x2b5c);
1971 +#else
1972 + return(0x173c);
1973 +#endif
1974 +}
1975 +/********************** End of MCD_getCodeSize() ********************/
1976 +
1977 +/********************************************************************/
1978 +/* Function: MCD_getVersion
1979 + * Purpose: Provide the version string and number
1980 + * Arguments: longVersion - user supplied pointer to a pointer to a char
1981 + * which points to the version string
1982 + * Returns: Version number and version string (by reference)
1983 + */
1984 +char MCD_versionString[] = "Multi-channel DMA API Alpha v0.3 (2004-04-26)";
1985 +#define MCD_REV_MAJOR 0x00
1986 +#define MCD_REV_MINOR 0x03
1987 +
1988 +int MCD_getVersion(char **longVersion)
1989 +{
1990 + *longVersion = MCD_versionString;
1991 + return((MCD_REV_MAJOR << 8) | MCD_REV_MINOR);
1992 +}
1993 +/********************** End of MCD_getVersion() *********************/
1994 +
1995 +/********************************************************************/
1996 +/* Private version of memcpy()
1997 + * Note that everything this is used for is longword-aligned.
1998 + */
1999 +static void MCD_memcpy (int *dest, int *src, u32 size)
2000 +{
2001 + u32 i;
2002 +
2003 + for (i = 0; i < size; i += sizeof(int), dest++, src++)
2004 + *dest = *src;
2005 +}
2006 +/********************************************************************/
2007 --- /dev/null
2008 +++ b/drivers/dma/MCD_progCheck.h
2009 @@ -0,0 +1,33 @@
2010 +/*********************************************************************
2011 + *
2012 + * Copyright (C) 2004 Motorola, Inc.
2013 + * MOTOROLA, INC. All Rights Reserved.
2014 + * You are hereby granted a copyright license to use
2015 + * the SOFTWARE so long as this entire notice is
2016 + * retained without alteration in any modified and/or redistributed
2017 + * versions, and that such modified versions are clearly identified
2018 + * as such. No licenses are granted by implication, estoppel or
2019 + * otherwise under any patents or trademarks of Motorola, Inc. This
2020 + * software is provided on an "AS IS" basis and without warranty.
2021 + *
2022 + * To the maximum extent permitted by applicable law, MOTOROLA
2023 + * DISCLAIMS ALL WARRANTIES WHETHER EXPRESS OR IMPLIED, INCLUDING
2024 + * IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR
2025 + * PURPOSE AND ANY WARRANTY AGAINST INFRINGEMENT WITH REGARD TO THE
2026 + * SOFTWARE (INCLUDING ANY MODIFIED VERSIONS THEREOF) AND ANY
2027 + * ACCOMPANYING WRITTEN MATERIALS.
2028 + *
2029 + * To the maximum extent permitted by applicable law, IN NO EVENT
2030 + * SHALL MOTOROLA BE LIABLE FOR ANY DAMAGES WHATSOEVER (INCLUDING
2031 + * WITHOUT LIMITATION, DAMAGES FOR LOSS OF BUSINESS PROFITS, BUSINESS
2032 + * INTERRUPTION, LOSS OF BUSINESS INFORMATION, OR OTHER PECUNIARY
2033 + * LOSS) ARISING OF THE USE OR INABILITY TO USE THE SOFTWARE.
2034 + *
2035 + * Motorola assumes no responsibility for the maintenance and support
2036 + * of this software
2037 + ********************************************************************/
2038 + /* This file is autogenerated. Do not change */
2039 +#define CURRBD 4
2040 +#define DCOUNT 6
2041 +#define DESTPTR 5
2042 +#define SRCPTR 7
2043 --- /dev/null
2044 +++ b/drivers/dma/MCD_tasks.c
2045 @@ -0,0 +1,2452 @@
2046 +/*********************************************************************
2047 + *
2048 + * Copyright (C) 2004 Motorola, Inc.
2049 + * MOTOROLA, INC. All Rights Reserved.
2050 + * You are hereby granted a copyright license to use
2051 + * the SOFTWARE so long as this entire notice is
2052 + * retained without alteration in any modified and/or redistributed
2053 + * versions, and that such modified versions are clearly identified
2054 + * as such. No licenses are granted by implication, estoppel or
2055 + * otherwise under any patents or trademarks of Motorola, Inc. This
2056 + * software is provided on an "AS IS" basis and without warranty.
2057 + *
2058 + * To the maximum extent permitted by applicable law, MOTOROLA
2059 + * DISCLAIMS ALL WARRANTIES WHETHER EXPRESS OR IMPLIED, INCLUDING
2060 + * IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR
2061 + * PURPOSE AND ANY WARRANTY AGAINST INFRINGEMENT WITH REGARD TO THE
2062 + * SOFTWARE (INCLUDING ANY MODIFIED VERSIONS THEREOF) AND ANY
2063 + * ACCOMPANYING WRITTEN MATERIALS.
2064 + *
2065 + * To the maximum extent permitted by applicable law, IN NO EVENT
2066 + * SHALL MOTOROLA BE LIABLE FOR ANY DAMAGES WHATSOEVER (INCLUDING
2067 + * WITHOUT LIMITATION, DAMAGES FOR LOSS OF BUSINESS PROFITS, BUSINESS
2068 + * INTERRUPTION, LOSS OF BUSINESS INFORMATION, OR OTHER PECUNIARY
2069 + * LOSS) ARISING OF THE USE OR INABILITY TO USE THE SOFTWARE.
2070 + *
2071 + * Motorola assumes no responsibility for the maintenance and support
2072 + * of this software
2073 + ********************************************************************/
2074 +/*
2075 + * File: MCD_tasks.c
2076 + * Purpose: Contains task code and structures for Multi-channel DMA
2077 + *
2078 + * Notes:
2079 + *
2080 + *
2081 + * Modifications:
2082 + *
2083 + *
2084 + */
2085 +
2086 +#include <asm/MCD_dma.h>
2087 +
2088 +u32 MCD_varTab0[];
2089 +u32 MCD_varTab1[];
2090 +u32 MCD_varTab2[];
2091 +u32 MCD_varTab3[];
2092 +u32 MCD_varTab4[];
2093 +u32 MCD_varTab5[];
2094 +u32 MCD_varTab6[];
2095 +u32 MCD_varTab7[];
2096 +u32 MCD_varTab8[];
2097 +u32 MCD_varTab9[];
2098 +u32 MCD_varTab10[];
2099 +u32 MCD_varTab11[];
2100 +u32 MCD_varTab12[];
2101 +u32 MCD_varTab13[];
2102 +u32 MCD_varTab14[];
2103 +u32 MCD_varTab15[];
2104 +
2105 +u32 MCD_funcDescTab0[];
2106 +#ifdef MCD_INCLUDE_EU
2107 +u32 MCD_funcDescTab1[];
2108 +u32 MCD_funcDescTab2[];
2109 +u32 MCD_funcDescTab3[];
2110 +u32 MCD_funcDescTab4[];
2111 +u32 MCD_funcDescTab5[];
2112 +u32 MCD_funcDescTab6[];
2113 +u32 MCD_funcDescTab7[];
2114 +u32 MCD_funcDescTab8[];
2115 +u32 MCD_funcDescTab9[];
2116 +u32 MCD_funcDescTab10[];
2117 +u32 MCD_funcDescTab11[];
2118 +u32 MCD_funcDescTab12[];
2119 +u32 MCD_funcDescTab13[];
2120 +u32 MCD_funcDescTab14[];
2121 +u32 MCD_funcDescTab15[];
2122 +#endif
2123 +
2124 +u32 MCD_contextSave0[];
2125 +u32 MCD_contextSave1[];
2126 +u32 MCD_contextSave2[];
2127 +u32 MCD_contextSave3[];
2128 +u32 MCD_contextSave4[];
2129 +u32 MCD_contextSave5[];
2130 +u32 MCD_contextSave6[];
2131 +u32 MCD_contextSave7[];
2132 +u32 MCD_contextSave8[];
2133 +u32 MCD_contextSave9[];
2134 +u32 MCD_contextSave10[];
2135 +u32 MCD_contextSave11[];
2136 +u32 MCD_contextSave12[];
2137 +u32 MCD_contextSave13[];
2138 +u32 MCD_contextSave14[];
2139 +u32 MCD_contextSave15[];
2140 +
2141 +u32 MCD_realTaskTableSrc[] =
2142 +{
2143 + 0x00000000,
2144 + 0x00000000,
2145 + (u32)MCD_varTab0, /* Task 0 Variable Table */
2146 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2147 + 0x00000000,
2148 + 0x00000000,
2149 + (u32)MCD_contextSave0, /* Task 0 context save space */
2150 + 0x00000000,
2151 + 0x00000000,
2152 + 0x00000000,
2153 + (u32)MCD_varTab1, /* Task 1 Variable Table */
2154 +#ifdef MCD_INCLUDE_EU
2155 + (u32)MCD_funcDescTab1, /* Task 1 Function Descriptor Table & Flags */
2156 +#else
2157 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2158 +#endif
2159 + 0x00000000,
2160 + 0x00000000,
2161 + (u32)MCD_contextSave1, /* Task 1 context save space */
2162 + 0x00000000,
2163 + 0x00000000,
2164 + 0x00000000,
2165 + (u32)MCD_varTab2, /* Task 2 Variable Table */
2166 +#ifdef MCD_INCLUDE_EU
2167 + (u32)MCD_funcDescTab2, /* Task 2 Function Descriptor Table & Flags */
2168 +#else
2169 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2170 +#endif
2171 + 0x00000000,
2172 + 0x00000000,
2173 + (u32)MCD_contextSave2, /* Task 2 context save space */
2174 + 0x00000000,
2175 + 0x00000000,
2176 + 0x00000000,
2177 + (u32)MCD_varTab3, /* Task 3 Variable Table */
2178 +#ifdef MCD_INCLUDE_EU
2179 + (u32)MCD_funcDescTab3, /* Task 3 Function Descriptor Table & Flags */
2180 +#else
2181 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2182 +#endif
2183 + 0x00000000,
2184 + 0x00000000,
2185 + (u32)MCD_contextSave3, /* Task 3 context save space */
2186 + 0x00000000,
2187 + 0x00000000,
2188 + 0x00000000,
2189 + (u32)MCD_varTab4, /* Task 4 Variable Table */
2190 +#ifdef MCD_INCLUDE_EU
2191 + (u32)MCD_funcDescTab4, /* Task 4 Function Descriptor Table & Flags */
2192 +#else
2193 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2194 +#endif
2195 + 0x00000000,
2196 + 0x00000000,
2197 + (u32)MCD_contextSave4, /* Task 4 context save space */
2198 + 0x00000000,
2199 + 0x00000000,
2200 + 0x00000000,
2201 + (u32)MCD_varTab5, /* Task 5 Variable Table */
2202 +#ifdef MCD_INCLUDE_EU
2203 + (u32)MCD_funcDescTab5, /* Task 5 Function Descriptor Table & Flags */
2204 +#else
2205 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2206 +#endif
2207 + 0x00000000,
2208 + 0x00000000,
2209 + (u32)MCD_contextSave5, /* Task 5 context save space */
2210 + 0x00000000,
2211 + 0x00000000,
2212 + 0x00000000,
2213 + (u32)MCD_varTab6, /* Task 6 Variable Table */
2214 +#ifdef MCD_INCLUDE_EU
2215 + (u32)MCD_funcDescTab6, /* Task 6 Function Descriptor Table & Flags */
2216 +#else
2217 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2218 +#endif
2219 + 0x00000000,
2220 + 0x00000000,
2221 + (u32)MCD_contextSave6, /* Task 6 context save space */
2222 + 0x00000000,
2223 + 0x00000000,
2224 + 0x00000000,
2225 + (u32)MCD_varTab7, /* Task 7 Variable Table */
2226 +#ifdef MCD_INCLUDE_EU
2227 + (u32)MCD_funcDescTab7, /* Task 7 Function Descriptor Table & Flags */
2228 +#else
2229 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2230 +#endif
2231 + 0x00000000,
2232 + 0x00000000,
2233 + (u32)MCD_contextSave7, /* Task 7 context save space */
2234 + 0x00000000,
2235 + 0x00000000,
2236 + 0x00000000,
2237 + (u32)MCD_varTab8, /* Task 8 Variable Table */
2238 +#ifdef MCD_INCLUDE_EU
2239 + (u32)MCD_funcDescTab8, /* Task 8 Function Descriptor Table & Flags */
2240 +#else
2241 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2242 +#endif
2243 + 0x00000000,
2244 + 0x00000000,
2245 + (u32)MCD_contextSave8, /* Task 8 context save space */
2246 + 0x00000000,
2247 + 0x00000000,
2248 + 0x00000000,
2249 + (u32)MCD_varTab9, /* Task 9 Variable Table */
2250 +#ifdef MCD_INCLUDE_EU
2251 + (u32)MCD_funcDescTab9, /* Task 9 Function Descriptor Table & Flags */
2252 +#else
2253 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2254 +#endif
2255 + 0x00000000,
2256 + 0x00000000,
2257 + (u32)MCD_contextSave9, /* Task 9 context save space */
2258 + 0x00000000,
2259 + 0x00000000,
2260 + 0x00000000,
2261 + (u32)MCD_varTab10, /* Task 10 Variable Table */
2262 +#ifdef MCD_INCLUDE_EU
2263 + (u32)MCD_funcDescTab10, /* Task 10 Function Descriptor Table & Flags */
2264 +#else
2265 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2266 +#endif
2267 + 0x00000000,
2268 + 0x00000000,
2269 + (u32)MCD_contextSave10, /* Task 10 context save space */
2270 + 0x00000000,
2271 + 0x00000000,
2272 + 0x00000000,
2273 + (u32)MCD_varTab11, /* Task 11 Variable Table */
2274 +#ifdef MCD_INCLUDE_EU
2275 + (u32)MCD_funcDescTab11, /* Task 11 Function Descriptor Table & Flags */
2276 +#else
2277 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2278 +#endif
2279 + 0x00000000,
2280 + 0x00000000,
2281 + (u32)MCD_contextSave11, /* Task 11 context save space */
2282 + 0x00000000,
2283 + 0x00000000,
2284 + 0x00000000,
2285 + (u32)MCD_varTab12, /* Task 12 Variable Table */
2286 +#ifdef MCD_INCLUDE_EU
2287 + (u32)MCD_funcDescTab12, /* Task 12 Function Descriptor Table & Flags */
2288 +#else
2289 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2290 +#endif
2291 + 0x00000000,
2292 + 0x00000000,
2293 + (u32)MCD_contextSave12, /* Task 12 context save space */
2294 + 0x00000000,
2295 + 0x00000000,
2296 + 0x00000000,
2297 + (u32)MCD_varTab13, /* Task 13 Variable Table */
2298 +#ifdef MCD_INCLUDE_EU
2299 + (u32)MCD_funcDescTab13, /* Task 13 Function Descriptor Table & Flags */
2300 +#else
2301 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2302 +#endif
2303 + 0x00000000,
2304 + 0x00000000,
2305 + (u32)MCD_contextSave13, /* Task 13 context save space */
2306 + 0x00000000,
2307 + 0x00000000,
2308 + 0x00000000,
2309 + (u32)MCD_varTab14, /* Task 14 Variable Table */
2310 +#ifdef MCD_INCLUDE_EU
2311 + (u32)MCD_funcDescTab14, /* Task 14 Function Descriptor Table & Flags */
2312 +#else
2313 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2314 +#endif
2315 + 0x00000000,
2316 + 0x00000000,
2317 + (u32)MCD_contextSave14, /* Task 14 context save space */
2318 + 0x00000000,
2319 + 0x00000000,
2320 + 0x00000000,
2321 + (u32)MCD_varTab15, /* Task 15 Variable Table */
2322 +#ifdef MCD_INCLUDE_EU
2323 + (u32)MCD_funcDescTab15, /* Task 15 Function Descriptor Table & Flags */
2324 +#else
2325 + (u32)MCD_funcDescTab0, /* Task 0 Function Descriptor Table & Flags */
2326 +#endif
2327 + 0x00000000,
2328 + 0x00000000,
2329 + (u32)MCD_contextSave15, /* Task 15 context save space */
2330 + 0x00000000,
2331 +};
2332 +
2333 +
2334 +u32 MCD_varTab0[] =
2335 +{ /* Task 0 Variable Table */
2336 + 0x00000000, /* var[0] */
2337 + 0x00000000, /* var[1] */
2338 + 0x00000000, /* var[2] */
2339 + 0x00000000, /* var[3] */
2340 + 0x00000000, /* var[4] */
2341 + 0x00000000, /* var[5] */
2342 + 0x00000000, /* var[6] */
2343 + 0x00000000, /* var[7] */
2344 + 0x00000000, /* var[8] */
2345 + 0x00000000, /* var[9] */
2346 + 0x00000000, /* var[10] */
2347 + 0x00000000, /* var[11] */
2348 + 0x00000000, /* var[12] */
2349 + 0x00000000, /* var[13] */
2350 + 0x00000000, /* var[14] */
2351 + 0x00000000, /* var[15] */
2352 + 0x00000000, /* var[16] */
2353 + 0x00000000, /* var[17] */
2354 + 0x00000000, /* var[18] */
2355 + 0x00000000, /* var[19] */
2356 + 0x00000000, /* var[20] */
2357 + 0x00000000, /* var[21] */
2358 + 0x00000000, /* var[22] */
2359 + 0x00000000, /* var[23] */
2360 + 0xe0000000, /* inc[0] */
2361 + 0x20000000, /* inc[1] */
2362 + 0x2000ffff, /* inc[2] */
2363 + 0x00000000, /* inc[3] */
2364 + 0x00000000, /* inc[4] */
2365 + 0x00000000, /* inc[5] */
2366 + 0x00000000, /* inc[6] */
2367 + 0x00000000, /* inc[7] */
2368 +};
2369 +
2370 +
2371 +u32 MCD_varTab1[] =
2372 +{ /* Task 1 Variable Table */
2373 + 0x00000000, /* var[0] */
2374 + 0x00000000, /* var[1] */
2375 + 0x00000000, /* var[2] */
2376 + 0x00000000, /* var[3] */
2377 + 0x00000000, /* var[4] */
2378 + 0x00000000, /* var[5] */
2379 + 0x00000000, /* var[6] */
2380 + 0x00000000, /* var[7] */
2381 + 0x00000000, /* var[8] */
2382 + 0x00000000, /* var[9] */
2383 + 0x00000000, /* var[10] */
2384 + 0x00000000, /* var[11] */
2385 + 0x00000000, /* var[12] */
2386 + 0x00000000, /* var[13] */
2387 + 0x00000000, /* var[14] */
2388 + 0x00000000, /* var[15] */
2389 + 0x00000000, /* var[16] */
2390 + 0x00000000, /* var[17] */
2391 + 0x00000000, /* var[18] */
2392 + 0x00000000, /* var[19] */
2393 + 0x00000000, /* var[20] */
2394 + 0x00000000, /* var[21] */
2395 + 0x00000000, /* var[22] */
2396 + 0x00000000, /* var[23] */
2397 + 0xe0000000, /* inc[0] */
2398 + 0x20000000, /* inc[1] */
2399 + 0x2000ffff, /* inc[2] */
2400 + 0x00000000, /* inc[3] */
2401 + 0x00000000, /* inc[4] */
2402 + 0x00000000, /* inc[5] */
2403 + 0x00000000, /* inc[6] */
2404 + 0x00000000, /* inc[7] */
2405 +};
2406 +
2407 +u32 MCD_varTab2[]=
2408 +{ /* Task 2 Variable Table */
2409 + 0x00000000, /* var[0] */
2410 + 0x00000000, /* var[1] */
2411 + 0x00000000, /* var[2] */
2412 + 0x00000000, /* var[3] */
2413 + 0x00000000, /* var[4] */
2414 + 0x00000000, /* var[5] */
2415 + 0x00000000, /* var[6] */
2416 + 0x00000000, /* var[7] */
2417 + 0x00000000, /* var[8] */
2418 + 0x00000000, /* var[9] */
2419 + 0x00000000, /* var[10] */
2420 + 0x00000000, /* var[11] */
2421 + 0x00000000, /* var[12] */
2422 + 0x00000000, /* var[13] */
2423 + 0x00000000, /* var[14] */
2424 + 0x00000000, /* var[15] */
2425 + 0x00000000, /* var[16] */
2426 + 0x00000000, /* var[17] */
2427 + 0x00000000, /* var[18] */
2428 + 0x00000000, /* var[19] */
2429 + 0x00000000, /* var[20] */
2430 + 0x00000000, /* var[21] */
2431 + 0x00000000, /* var[22] */
2432 + 0x00000000, /* var[23] */
2433 + 0xe0000000, /* inc[0] */
2434 + 0x20000000, /* inc[1] */
2435 + 0x2000ffff, /* inc[2] */
2436 + 0x00000000, /* inc[3] */
2437 + 0x00000000, /* inc[4] */
2438 + 0x00000000, /* inc[5] */
2439 + 0x00000000, /* inc[6] */
2440 + 0x00000000, /* inc[7] */
2441 +};
2442 +
2443 +u32 MCD_varTab3[]=
2444 +{ /* Task 3 Variable Table */
2445 + 0x00000000, /* var[0] */
2446 + 0x00000000, /* var[1] */
2447 + 0x00000000, /* var[2] */
2448 + 0x00000000, /* var[3] */
2449 + 0x00000000, /* var[4] */
2450 + 0x00000000, /* var[5] */
2451 + 0x00000000, /* var[6] */
2452 + 0x00000000, /* var[7] */
2453 + 0x00000000, /* var[8] */
2454 + 0x00000000, /* var[9] */
2455 + 0x00000000, /* var[10] */
2456 + 0x00000000, /* var[11] */
2457 + 0x00000000, /* var[12] */
2458 + 0x00000000, /* var[13] */
2459 + 0x00000000, /* var[14] */
2460 + 0x00000000, /* var[15] */
2461 + 0x00000000, /* var[16] */
2462 + 0x00000000, /* var[17] */
2463 + 0x00000000, /* var[18] */
2464 + 0x00000000, /* var[19] */
2465 + 0x00000000, /* var[20] */
2466 + 0x00000000, /* var[21] */
2467 + 0x00000000, /* var[22] */
2468 + 0x00000000, /* var[23] */
2469 + 0xe0000000, /* inc[0] */
2470 + 0x20000000, /* inc[1] */
2471 + 0x2000ffff, /* inc[2] */
2472 + 0x00000000, /* inc[3] */
2473 + 0x00000000, /* inc[4] */
2474 + 0x00000000, /* inc[5] */
2475 + 0x00000000, /* inc[6] */
2476 + 0x00000000, /* inc[7] */
2477 +};
2478 +
2479 +u32 MCD_varTab4[]=
2480 +{ /* Task 4 Variable Table */
2481 + 0x00000000, /* var[0] */
2482 + 0x00000000, /* var[1] */
2483 + 0x00000000, /* var[2] */
2484 + 0x00000000, /* var[3] */
2485 + 0x00000000, /* var[4] */
2486 + 0x00000000, /* var[5] */
2487 + 0x00000000, /* var[6] */
2488 + 0x00000000, /* var[7] */
2489 + 0x00000000, /* var[8] */
2490 + 0x00000000, /* var[9] */
2491 + 0x00000000, /* var[10] */
2492 + 0x00000000, /* var[11] */
2493 + 0x00000000, /* var[12] */
2494 + 0x00000000, /* var[13] */
2495 + 0x00000000, /* var[14] */
2496 + 0x00000000, /* var[15] */
2497 + 0x00000000, /* var[16] */
2498 + 0x00000000, /* var[17] */
2499 + 0x00000000, /* var[18] */
2500 + 0x00000000, /* var[19] */
2501 + 0x00000000, /* var[20] */
2502 + 0x00000000, /* var[21] */
2503 + 0x00000000, /* var[22] */
2504 + 0x00000000, /* var[23] */
2505 + 0xe0000000, /* inc[0] */
2506 + 0x20000000, /* inc[1] */
2507 + 0x2000ffff, /* inc[2] */
2508 + 0x00000000, /* inc[3] */
2509 + 0x00000000, /* inc[4] */
2510 + 0x00000000, /* inc[5] */
2511 + 0x00000000, /* inc[6] */
2512 + 0x00000000, /* inc[7] */
2513 +};
2514 +
2515 +u32 MCD_varTab5[]=
2516 +{ /* Task 5 Variable Table */
2517 + 0x00000000, /* var[0] */
2518 + 0x00000000, /* var[1] */
2519 + 0x00000000, /* var[2] */
2520 + 0x00000000, /* var[3] */
2521 + 0x00000000, /* var[4] */
2522 + 0x00000000, /* var[5] */
2523 + 0x00000000, /* var[6] */
2524 + 0x00000000, /* var[7] */
2525 + 0x00000000, /* var[8] */
2526 + 0x00000000, /* var[9] */
2527 + 0x00000000, /* var[10] */
2528 + 0x00000000, /* var[11] */
2529 + 0x00000000, /* var[12] */
2530 + 0x00000000, /* var[13] */
2531 + 0x00000000, /* var[14] */
2532 + 0x00000000, /* var[15] */
2533 + 0x00000000, /* var[16] */
2534 + 0x00000000, /* var[17] */
2535 + 0x00000000, /* var[18] */
2536 + 0x00000000, /* var[19] */
2537 + 0x00000000, /* var[20] */
2538 + 0x00000000, /* var[21] */
2539 + 0x00000000, /* var[22] */
2540 + 0x00000000, /* var[23] */
2541 + 0xe0000000, /* inc[0] */
2542 + 0x20000000, /* inc[1] */
2543 + 0x2000ffff, /* inc[2] */
2544 + 0x00000000, /* inc[3] */
2545 + 0x00000000, /* inc[4] */
2546 + 0x00000000, /* inc[5] */
2547 + 0x00000000, /* inc[6] */
2548 + 0x00000000, /* inc[7] */
2549 +};
2550 +
2551 +u32 MCD_varTab6[]=
2552 +{ /* Task 6 Variable Table */
2553 + 0x00000000, /* var[0] */
2554 + 0x00000000, /* var[1] */
2555 + 0x00000000, /* var[2] */
2556 + 0x00000000, /* var[3] */
2557 + 0x00000000, /* var[4] */
2558 + 0x00000000, /* var[5] */
2559 + 0x00000000, /* var[6] */
2560 + 0x00000000, /* var[7] */
2561 + 0x00000000, /* var[8] */
2562 + 0x00000000, /* var[9] */
2563 + 0x00000000, /* var[10] */
2564 + 0x00000000, /* var[11] */
2565 + 0x00000000, /* var[12] */
2566 + 0x00000000, /* var[13] */
2567 + 0x00000000, /* var[14] */
2568 + 0x00000000, /* var[15] */
2569 + 0x00000000, /* var[16] */
2570 + 0x00000000, /* var[17] */
2571 + 0x00000000, /* var[18] */
2572 + 0x00000000, /* var[19] */
2573 + 0x00000000, /* var[20] */
2574 + 0x00000000, /* var[21] */
2575 + 0x00000000, /* var[22] */
2576 + 0x00000000, /* var[23] */
2577 + 0xe0000000, /* inc[0] */
2578 + 0x20000000, /* inc[1] */
2579 + 0x2000ffff, /* inc[2] */
2580 + 0x00000000, /* inc[3] */
2581 + 0x00000000, /* inc[4] */
2582 + 0x00000000, /* inc[5] */
2583 + 0x00000000, /* inc[6] */
2584 + 0x00000000, /* inc[7] */
2585 +};
2586 +
2587 +u32 MCD_varTab7[]=
2588 +{ /* Task 7 Variable Table */
2589 + 0x00000000, /* var[0] */
2590 + 0x00000000, /* var[1] */
2591 + 0x00000000, /* var[2] */
2592 + 0x00000000, /* var[3] */
2593 + 0x00000000, /* var[4] */
2594 + 0x00000000, /* var[5] */
2595 + 0x00000000, /* var[6] */
2596 + 0x00000000, /* var[7] */
2597 + 0x00000000, /* var[8] */
2598 + 0x00000000, /* var[9] */
2599 + 0x00000000, /* var[10] */
2600 + 0x00000000, /* var[11] */
2601 + 0x00000000, /* var[12] */
2602 + 0x00000000, /* var[13] */
2603 + 0x00000000, /* var[14] */
2604 + 0x00000000, /* var[15] */
2605 + 0x00000000, /* var[16] */
2606 + 0x00000000, /* var[17] */
2607 + 0x00000000, /* var[18] */
2608 + 0x00000000, /* var[19] */
2609 + 0x00000000, /* var[20] */
2610 + 0x00000000, /* var[21] */
2611 + 0x00000000, /* var[22] */
2612 + 0x00000000, /* var[23] */
2613 + 0xe0000000, /* inc[0] */
2614 + 0x20000000, /* inc[1] */
2615 + 0x2000ffff, /* inc[2] */
2616 + 0x00000000, /* inc[3] */
2617 + 0x00000000, /* inc[4] */
2618 + 0x00000000, /* inc[5] */
2619 + 0x00000000, /* inc[6] */
2620 + 0x00000000, /* inc[7] */
2621 +};
2622 +
2623 +u32 MCD_varTab8[]=
2624 +{ /* Task 8 Variable Table */
2625 + 0x00000000, /* var[0] */
2626 + 0x00000000, /* var[1] */
2627 + 0x00000000, /* var[2] */
2628 + 0x00000000, /* var[3] */
2629 + 0x00000000, /* var[4] */
2630 + 0x00000000, /* var[5] */
2631 + 0x00000000, /* var[6] */
2632 + 0x00000000, /* var[7] */
2633 + 0x00000000, /* var[8] */
2634 + 0x00000000, /* var[9] */
2635 + 0x00000000, /* var[10] */
2636 + 0x00000000, /* var[11] */
2637 + 0x00000000, /* var[12] */
2638 + 0x00000000, /* var[13] */
2639 + 0x00000000, /* var[14] */
2640 + 0x00000000, /* var[15] */
2641 + 0x00000000, /* var[16] */
2642 + 0x00000000, /* var[17] */
2643 + 0x00000000, /* var[18] */
2644 + 0x00000000, /* var[19] */
2645 + 0x00000000, /* var[20] */
2646 + 0x00000000, /* var[21] */
2647 + 0x00000000, /* var[22] */
2648 + 0x00000000, /* var[23] */
2649 + 0xe0000000, /* inc[0] */
2650 + 0x20000000, /* inc[1] */
2651 + 0x2000ffff, /* inc[2] */
2652 + 0x00000000, /* inc[3] */
2653 + 0x00000000, /* inc[4] */
2654 + 0x00000000, /* inc[5] */
2655 + 0x00000000, /* inc[6] */
2656 + 0x00000000, /* inc[7] */
2657 +};
2658 +
2659 +u32 MCD_varTab9[]=
2660 +{ /* Task 9 Variable Table */
2661 + 0x00000000, /* var[0] */
2662 + 0x00000000, /* var[1] */
2663 + 0x00000000, /* var[2] */
2664 + 0x00000000, /* var[3] */
2665 + 0x00000000, /* var[4] */
2666 + 0x00000000, /* var[5] */
2667 + 0x00000000, /* var[6] */
2668 + 0x00000000, /* var[7] */
2669 + 0x00000000, /* var[8] */
2670 + 0x00000000, /* var[9] */
2671 + 0x00000000, /* var[10] */
2672 + 0x00000000, /* var[11] */
2673 + 0x00000000, /* var[12] */
2674 + 0x00000000, /* var[13] */
2675 + 0x00000000, /* var[14] */
2676 + 0x00000000, /* var[15] */
2677 + 0x00000000, /* var[16] */
2678 + 0x00000000, /* var[17] */
2679 + 0x00000000, /* var[18] */
2680 + 0x00000000, /* var[19] */
2681 + 0x00000000, /* var[20] */
2682 + 0x00000000, /* var[21] */
2683 + 0x00000000, /* var[22] */
2684 + 0x00000000, /* var[23] */
2685 + 0xe0000000, /* inc[0] */
2686 + 0x20000000, /* inc[1] */
2687 + 0x2000ffff, /* inc[2] */
2688 + 0x00000000, /* inc[3] */
2689 + 0x00000000, /* inc[4] */
2690 + 0x00000000, /* inc[5] */
2691 + 0x00000000, /* inc[6] */
2692 + 0x00000000, /* inc[7] */
2693 +};
2694 +
2695 +u32 MCD_varTab10[]=
2696 +{ /* Task 10 Variable Table */
2697 + 0x00000000, /* var[0] */
2698 + 0x00000000, /* var[1] */
2699 + 0x00000000, /* var[2] */
2700 + 0x00000000, /* var[3] */
2701 + 0x00000000, /* var[4] */
2702 + 0x00000000, /* var[5] */
2703 + 0x00000000, /* var[6] */
2704 + 0x00000000, /* var[7] */
2705 + 0x00000000, /* var[8] */
2706 + 0x00000000, /* var[9] */
2707 + 0x00000000, /* var[10] */
2708 + 0x00000000, /* var[11] */
2709 + 0x00000000, /* var[12] */
2710 + 0x00000000, /* var[13] */
2711 + 0x00000000, /* var[14] */
2712 + 0x00000000, /* var[15] */
2713 + 0x00000000, /* var[16] */
2714 + 0x00000000, /* var[17] */
2715 + 0x00000000, /* var[18] */
2716 + 0x00000000, /* var[19] */
2717 + 0x00000000, /* var[20] */
2718 + 0x00000000, /* var[21] */
2719 + 0x00000000, /* var[22] */
2720 + 0x00000000, /* var[23] */
2721 + 0xe0000000, /* inc[0] */
2722 + 0x20000000, /* inc[1] */
2723 + 0x2000ffff, /* inc[2] */
2724 + 0x00000000, /* inc[3] */
2725 + 0x00000000, /* inc[4] */
2726 + 0x00000000, /* inc[5] */
2727 + 0x00000000, /* inc[6] */
2728 + 0x00000000, /* inc[7] */
2729 +};
2730 +
2731 +u32 MCD_varTab11[]=
2732 +{ /* Task 11 Variable Table */
2733 + 0x00000000, /* var[0] */
2734 + 0x00000000, /* var[1] */
2735 + 0x00000000, /* var[2] */
2736 + 0x00000000, /* var[3] */
2737 + 0x00000000, /* var[4] */
2738 + 0x00000000, /* var[5] */
2739 + 0x00000000, /* var[6] */
2740 + 0x00000000, /* var[7] */
2741 + 0x00000000, /* var[8] */
2742 + 0x00000000, /* var[9] */
2743 + 0x00000000, /* var[10] */
2744 + 0x00000000, /* var[11] */
2745 + 0x00000000, /* var[12] */
2746 + 0x00000000, /* var[13] */
2747 + 0x00000000, /* var[14] */
2748 + 0x00000000, /* var[15] */
2749 + 0x00000000, /* var[16] */
2750 + 0x00000000, /* var[17] */
2751 + 0x00000000, /* var[18] */
2752 + 0x00000000, /* var[19] */
2753 + 0x00000000, /* var[20] */
2754 + 0x00000000, /* var[21] */
2755 + 0x00000000, /* var[22] */
2756 + 0x00000000, /* var[23] */
2757 + 0xe0000000, /* inc[0] */
2758 + 0x20000000, /* inc[1] */
2759 + 0x2000ffff, /* inc[2] */
2760 + 0x00000000, /* inc[3] */
2761 + 0x00000000, /* inc[4] */
2762 + 0x00000000, /* inc[5] */
2763 + 0x00000000, /* inc[6] */
2764 + 0x00000000, /* inc[7] */
2765 +};
2766 +
2767 +u32 MCD_varTab12[]=
2768 +{ /* Task 12 Variable Table */
2769 + 0x00000000, /* var[0] */
2770 + 0x00000000, /* var[1] */
2771 + 0x00000000, /* var[2] */
2772 + 0x00000000, /* var[3] */
2773 + 0x00000000, /* var[4] */
2774 + 0x00000000, /* var[5] */
2775 + 0x00000000, /* var[6] */
2776 + 0x00000000, /* var[7] */
2777 + 0x00000000, /* var[8] */
2778 + 0x00000000, /* var[9] */
2779 + 0x00000000, /* var[10] */
2780 + 0x00000000, /* var[11] */
2781 + 0x00000000, /* var[12] */
2782 + 0x00000000, /* var[13] */
2783 + 0x00000000, /* var[14] */
2784 + 0x00000000, /* var[15] */
2785 + 0x00000000, /* var[16] */
2786 + 0x00000000, /* var[17] */
2787 + 0x00000000, /* var[18] */
2788 + 0x00000000, /* var[19] */
2789 + 0x00000000, /* var[20] */
2790 + 0x00000000, /* var[21] */
2791 + 0x00000000, /* var[22] */
2792 + 0x00000000, /* var[23] */
2793 + 0xe0000000, /* inc[0] */
2794 + 0x20000000, /* inc[1] */
2795 + 0x2000ffff, /* inc[2] */
2796 + 0x00000000, /* inc[3] */
2797 + 0x00000000, /* inc[4] */
2798 + 0x00000000, /* inc[5] */
2799 + 0x00000000, /* inc[6] */
2800 + 0x00000000, /* inc[7] */
2801 +};
2802 +
2803 +u32 MCD_varTab13[]=
2804 +{ /* Task 13 Variable Table */
2805 + 0x00000000, /* var[0] */
2806 + 0x00000000, /* var[1] */
2807 + 0x00000000, /* var[2] */
2808 + 0x00000000, /* var[3] */
2809 + 0x00000000, /* var[4] */
2810 + 0x00000000, /* var[5] */
2811 + 0x00000000, /* var[6] */
2812 + 0x00000000, /* var[7] */
2813 + 0x00000000, /* var[8] */
2814 + 0x00000000, /* var[9] */
2815 + 0x00000000, /* var[10] */
2816 + 0x00000000, /* var[11] */
2817 + 0x00000000, /* var[12] */
2818 + 0x00000000, /* var[13] */
2819 + 0x00000000, /* var[14] */
2820 + 0x00000000, /* var[15] */
2821 + 0x00000000, /* var[16] */
2822 + 0x00000000, /* var[17] */
2823 + 0x00000000, /* var[18] */
2824 + 0x00000000, /* var[19] */
2825 + 0x00000000, /* var[20] */
2826 + 0x00000000, /* var[21] */
2827 + 0x00000000, /* var[22] */
2828 + 0x00000000, /* var[23] */
2829 + 0xe0000000, /* inc[0] */
2830 + 0x20000000, /* inc[1] */
2831 + 0x2000ffff, /* inc[2] */
2832 + 0x00000000, /* inc[3] */
2833 + 0x00000000, /* inc[4] */
2834 + 0x00000000, /* inc[5] */
2835 + 0x00000000, /* inc[6] */
2836 + 0x00000000, /* inc[7] */
2837 +};
2838 +
2839 +u32 MCD_varTab14[]=
2840 +{ /* Task 14 Variable Table */
2841 + 0x00000000, /* var[0] */
2842 + 0x00000000, /* var[1] */
2843 + 0x00000000, /* var[2] */
2844 + 0x00000000, /* var[3] */
2845 + 0x00000000, /* var[4] */
2846 + 0x00000000, /* var[5] */
2847 + 0x00000000, /* var[6] */
2848 + 0x00000000, /* var[7] */
2849 + 0x00000000, /* var[8] */
2850 + 0x00000000, /* var[9] */
2851 + 0x00000000, /* var[10] */
2852 + 0x00000000, /* var[11] */
2853 + 0x00000000, /* var[12] */
2854 + 0x00000000, /* var[13] */
2855 + 0x00000000, /* var[14] */
2856 + 0x00000000, /* var[15] */
2857 + 0x00000000, /* var[16] */
2858 + 0x00000000, /* var[17] */
2859 + 0x00000000, /* var[18] */
2860 + 0x00000000, /* var[19] */
2861 + 0x00000000, /* var[20] */
2862 + 0x00000000, /* var[21] */
2863 + 0x00000000, /* var[22] */
2864 + 0x00000000, /* var[23] */
2865 + 0xe0000000, /* inc[0] */
2866 + 0x20000000, /* inc[1] */
2867 + 0x2000ffff, /* inc[2] */
2868 + 0x00000000, /* inc[3] */
2869 + 0x00000000, /* inc[4] */
2870 + 0x00000000, /* inc[5] */
2871 + 0x00000000, /* inc[6] */
2872 + 0x00000000, /* inc[7] */
2873 +};
2874 +
2875 +u32 MCD_varTab15[]=
2876 +{ /* Task 15 Variable Table */
2877 + 0x00000000, /* var[0] */
2878 + 0x00000000, /* var[1] */
2879 + 0x00000000, /* var[2] */
2880 + 0x00000000, /* var[3] */
2881 + 0x00000000, /* var[4] */
2882 + 0x00000000, /* var[5] */
2883 + 0x00000000, /* var[6] */
2884 + 0x00000000, /* var[7] */
2885 + 0x00000000, /* var[8] */
2886 + 0x00000000, /* var[9] */
2887 + 0x00000000, /* var[10] */
2888 + 0x00000000, /* var[11] */
2889 + 0x00000000, /* var[12] */
2890 + 0x00000000, /* var[13] */
2891 + 0x00000000, /* var[14] */
2892 + 0x00000000, /* var[15] */
2893 + 0x00000000, /* var[16] */
2894 + 0x00000000, /* var[17] */
2895 + 0x00000000, /* var[18] */
2896 + 0x00000000, /* var[19] */
2897 + 0x00000000, /* var[20] */
2898 + 0x00000000, /* var[21] */
2899 + 0x00000000, /* var[22] */
2900 + 0x00000000, /* var[23] */
2901 + 0xe0000000, /* inc[0] */
2902 + 0x20000000, /* inc[1] */
2903 + 0x2000ffff, /* inc[2] */
2904 + 0x00000000, /* inc[3] */
2905 + 0x00000000, /* inc[4] */
2906 + 0x00000000, /* inc[5] */
2907 + 0x00000000, /* inc[6] */
2908 + 0x00000000, /* inc[7] */
2909 +};
2910 +
2911 +u32 MCD_funcDescTab0[]=
2912 +{ /* Task 0 Function Descriptor Table */
2913 + 0x00000000,
2914 + 0x00000000,
2915 + 0x00000000,
2916 + 0x00000000,
2917 + 0x00000000,
2918 + 0x00000000,
2919 + 0x00000000,
2920 + 0x00000000,
2921 + 0x00000000,
2922 + 0x00000000,
2923 + 0x00000000,
2924 + 0x00000000,
2925 + 0x00000000,
2926 + 0x00000000,
2927 + 0x00000000,
2928 + 0x00000000,
2929 + 0x00000000,
2930 + 0x00000000,
2931 + 0x00000000,
2932 + 0x00000000,
2933 + 0x00000000,
2934 + 0x00000000,
2935 + 0x00000000,
2936 + 0x00000000,
2937 + 0x00000000,
2938 + 0x00000000,
2939 + 0x00000000,
2940 + 0x00000000,
2941 + 0x00000000,
2942 + 0x00000000,
2943 + 0x00000000,
2944 + 0x00000000,
2945 + 0x00000000,
2946 + 0x00000000,
2947 + 0x00000000,
2948 + 0x00000000,
2949 + 0x00000000,
2950 + 0x00000000,
2951 + 0x00000000,
2952 + 0x00000000,
2953 + 0x00000000,
2954 + 0x00000000,
2955 + 0x00000000,
2956 + 0x00000000,
2957 + 0x00000000,
2958 + 0x00000000,
2959 + 0x00000000,
2960 + 0x00000000,
2961 + 0xa0045670, /* mainFunc(), EU# 3 */
2962 + 0xa0000000, /* rsduFunc(), EU# 3 */
2963 + 0xa0000000, /* crcAccumVal(), EU# 3 */
2964 + 0x20000000, /* setCrcAccum(), EU# 3 */
2965 + 0x21800000, /* and(), EU# 3 */
2966 + 0x21e00000, /* or(), EU# 3 */
2967 + 0x20400000, /* add(), EU# 3 */
2968 + 0x20500000, /* sub(), EU# 3 */
2969 + 0x205a0000, /* andNot(), EU# 3 */
2970 + 0x202fa000, /* andReadyBit(), EU# 3 */
2971 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
2972 + 0x202ea000, /* andWrapBit(), EU# 3 */
2973 + 0x202da000, /* andEndFrameBit(), EU# 3 */
2974 + 0x202e2000, /* andInterruptBit(), EU# 3 */
2975 + 0x202f2000, /* andLoopBit(), EU# 3 */
2976 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
2977 +};
2978 +
2979 +#ifdef MCD_INCLUDE_EU
2980 +u32 MCD_funcDescTab1[]=
2981 +{ /* Task 1 Function Descriptor Table */
2982 + 0x00000000,
2983 + 0x00000000,
2984 + 0x00000000,
2985 + 0x00000000,
2986 + 0x00000000,
2987 + 0x00000000,
2988 + 0x00000000,
2989 + 0x00000000,
2990 + 0x00000000,
2991 + 0x00000000,
2992 + 0x00000000,
2993 + 0x00000000,
2994 + 0x00000000,
2995 + 0x00000000,
2996 + 0x00000000,
2997 + 0x00000000,
2998 + 0x00000000,
2999 + 0x00000000,
3000 + 0x00000000,
3001 + 0x00000000,
3002 + 0x00000000,
3003 + 0x00000000,
3004 + 0x00000000,
3005 + 0x00000000,
3006 + 0x00000000,
3007 + 0x00000000,
3008 + 0x00000000,
3009 + 0x00000000,
3010 + 0x00000000,
3011 + 0x00000000,
3012 + 0x00000000,
3013 + 0x00000000,
3014 + 0x00000000,
3015 + 0x00000000,
3016 + 0x00000000,
3017 + 0x00000000,
3018 + 0x00000000,
3019 + 0x00000000,
3020 + 0x00000000,
3021 + 0x00000000,
3022 + 0x00000000,
3023 + 0x00000000,
3024 + 0x00000000,
3025 + 0x00000000,
3026 + 0x00000000,
3027 + 0x00000000,
3028 + 0x00000000,
3029 + 0x00000000,
3030 + 0xa0045670, /* mainFunc(), EU# 3 */
3031 + 0xa0000000, /* rsduFunc(), EU# 3 */
3032 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3033 + 0x20000000, /* setCrcAccum(), EU# 3 */
3034 + 0x21800000, /* and(), EU# 3 */
3035 + 0x21e00000, /* or(), EU# 3 */
3036 + 0x20400000, /* add(), EU# 3 */
3037 + 0x20500000, /* sub(), EU# 3 */
3038 + 0x205a0000, /* andNot(), EU# 3 */
3039 + 0x202fa000, /* andReadyBit(), EU# 3 */
3040 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3041 + 0x202ea000, /* andWrapBit(), EU# 3 */
3042 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3043 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3044 + 0x202f2000, /* andLoopBit(), EU# 3 */
3045 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3046 +};
3047 +
3048 +u32 MCD_funcDescTab2[]=
3049 +{ /* Task 2 Function Descriptor Table */
3050 + 0x00000000,
3051 + 0x00000000,
3052 + 0x00000000,
3053 + 0x00000000,
3054 + 0x00000000,
3055 + 0x00000000,
3056 + 0x00000000,
3057 + 0x00000000,
3058 + 0x00000000,
3059 + 0x00000000,
3060 + 0x00000000,
3061 + 0x00000000,
3062 + 0x00000000,
3063 + 0x00000000,
3064 + 0x00000000,
3065 + 0x00000000,
3066 + 0x00000000,
3067 + 0x00000000,
3068 + 0x00000000,
3069 + 0x00000000,
3070 + 0x00000000,
3071 + 0x00000000,
3072 + 0x00000000,
3073 + 0x00000000,
3074 + 0x00000000,
3075 + 0x00000000,
3076 + 0x00000000,
3077 + 0x00000000,
3078 + 0x00000000,
3079 + 0x00000000,
3080 + 0x00000000,
3081 + 0x00000000,
3082 + 0x00000000,
3083 + 0x00000000,
3084 + 0x00000000,
3085 + 0x00000000,
3086 + 0x00000000,
3087 + 0x00000000,
3088 + 0x00000000,
3089 + 0x00000000,
3090 + 0x00000000,
3091 + 0x00000000,
3092 + 0x00000000,
3093 + 0x00000000,
3094 + 0x00000000,
3095 + 0x00000000,
3096 + 0x00000000,
3097 + 0x00000000,
3098 + 0xa0045670, /* mainFunc(), EU# 3 */
3099 + 0xa0000000, /* rsduFunc(), EU# 3 */
3100 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3101 + 0x20000000, /* setCrcAccum(), EU# 3 */
3102 + 0x21800000, /* and(), EU# 3 */
3103 + 0x21e00000, /* or(), EU# 3 */
3104 + 0x20400000, /* add(), EU# 3 */
3105 + 0x20500000, /* sub(), EU# 3 */
3106 + 0x205a0000, /* andNot(), EU# 3 */
3107 + 0x202fa000, /* andReadyBit(), EU# 3 */
3108 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3109 + 0x202ea000, /* andWrapBit(), EU# 3 */
3110 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3111 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3112 + 0x202f2000, /* andLoopBit(), EU# 3 */
3113 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3114 +};
3115 +
3116 +u32 MCD_funcDescTab3[]=
3117 +{ /* Task 3 Function Descriptor Table */
3118 + 0x00000000,
3119 + 0x00000000,
3120 + 0x00000000,
3121 + 0x00000000,
3122 + 0x00000000,
3123 + 0x00000000,
3124 + 0x00000000,
3125 + 0x00000000,
3126 + 0x00000000,
3127 + 0x00000000,
3128 + 0x00000000,
3129 + 0x00000000,
3130 + 0x00000000,
3131 + 0x00000000,
3132 + 0x00000000,
3133 + 0x00000000,
3134 + 0x00000000,
3135 + 0x00000000,
3136 + 0x00000000,
3137 + 0x00000000,
3138 + 0x00000000,
3139 + 0x00000000,
3140 + 0x00000000,
3141 + 0x00000000,
3142 + 0x00000000,
3143 + 0x00000000,
3144 + 0x00000000,
3145 + 0x00000000,
3146 + 0x00000000,
3147 + 0x00000000,
3148 + 0x00000000,
3149 + 0x00000000,
3150 + 0x00000000,
3151 + 0x00000000,
3152 + 0x00000000,
3153 + 0x00000000,
3154 + 0x00000000,
3155 + 0x00000000,
3156 + 0x00000000,
3157 + 0x00000000,
3158 + 0x00000000,
3159 + 0x00000000,
3160 + 0x00000000,
3161 + 0x00000000,
3162 + 0x00000000,
3163 + 0x00000000,
3164 + 0x00000000,
3165 + 0x00000000,
3166 + 0xa0045670, /* mainFunc(), EU# 3 */
3167 + 0xa0000000, /* rsduFunc(), EU# 3 */
3168 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3169 + 0x20000000, /* setCrcAccum(), EU# 3 */
3170 + 0x21800000, /* and(), EU# 3 */
3171 + 0x21e00000, /* or(), EU# 3 */
3172 + 0x20400000, /* add(), EU# 3 */
3173 + 0x20500000, /* sub(), EU# 3 */
3174 + 0x205a0000, /* andNot(), EU# 3 */
3175 + 0x202fa000, /* andReadyBit(), EU# 3 */
3176 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3177 + 0x202ea000, /* andWrapBit(), EU# 3 */
3178 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3179 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3180 + 0x202f2000, /* andLoopBit(), EU# 3 */
3181 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3182 +};
3183 +
3184 +u32 MCD_funcDescTab4[]=
3185 +{ /* Task 4 Function Descriptor Table */
3186 + 0x00000000,
3187 + 0x00000000,
3188 + 0x00000000,
3189 + 0x00000000,
3190 + 0x00000000,
3191 + 0x00000000,
3192 + 0x00000000,
3193 + 0x00000000,
3194 + 0x00000000,
3195 + 0x00000000,
3196 + 0x00000000,
3197 + 0x00000000,
3198 + 0x00000000,
3199 + 0x00000000,
3200 + 0x00000000,
3201 + 0x00000000,
3202 + 0x00000000,
3203 + 0x00000000,
3204 + 0x00000000,
3205 + 0x00000000,
3206 + 0x00000000,
3207 + 0x00000000,
3208 + 0x00000000,
3209 + 0x00000000,
3210 + 0x00000000,
3211 + 0x00000000,
3212 + 0x00000000,
3213 + 0x00000000,
3214 + 0x00000000,
3215 + 0x00000000,
3216 + 0x00000000,
3217 + 0x00000000,
3218 + 0x00000000,
3219 + 0x00000000,
3220 + 0x00000000,
3221 + 0x00000000,
3222 + 0x00000000,
3223 + 0x00000000,
3224 + 0x00000000,
3225 + 0x00000000,
3226 + 0x00000000,
3227 + 0x00000000,
3228 + 0x00000000,
3229 + 0x00000000,
3230 + 0x00000000,
3231 + 0x00000000,
3232 + 0x00000000,
3233 + 0x00000000,
3234 + 0xa0045670, /* mainFunc(), EU# 3 */
3235 + 0xa0000000, /* rsduFunc(), EU# 3 */
3236 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3237 + 0x20000000, /* setCrcAccum(), EU# 3 */
3238 + 0x21800000, /* and(), EU# 3 */
3239 + 0x21e00000, /* or(), EU# 3 */
3240 + 0x20400000, /* add(), EU# 3 */
3241 + 0x20500000, /* sub(), EU# 3 */
3242 + 0x205a0000, /* andNot(), EU# 3 */
3243 + 0x202fa000, /* andReadyBit(), EU# 3 */
3244 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3245 + 0x202ea000, /* andWrapBit(), EU# 3 */
3246 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3247 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3248 + 0x202f2000, /* andLoopBit(), EU# 3 */
3249 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3250 +};
3251 +
3252 +u32 MCD_funcDescTab5[]=
3253 +{ /* Task 5 Function Descriptor Table */
3254 + 0x00000000,
3255 + 0x00000000,
3256 + 0x00000000,
3257 + 0x00000000,
3258 + 0x00000000,
3259 + 0x00000000,
3260 + 0x00000000,
3261 + 0x00000000,
3262 + 0x00000000,
3263 + 0x00000000,
3264 + 0x00000000,
3265 + 0x00000000,
3266 + 0x00000000,
3267 + 0x00000000,
3268 + 0x00000000,
3269 + 0x00000000,
3270 + 0x00000000,
3271 + 0x00000000,
3272 + 0x00000000,
3273 + 0x00000000,
3274 + 0x00000000,
3275 + 0x00000000,
3276 + 0x00000000,
3277 + 0x00000000,
3278 + 0x00000000,
3279 + 0x00000000,
3280 + 0x00000000,
3281 + 0x00000000,
3282 + 0x00000000,
3283 + 0x00000000,
3284 + 0x00000000,
3285 + 0x00000000,
3286 + 0x00000000,
3287 + 0x00000000,
3288 + 0x00000000,
3289 + 0x00000000,
3290 + 0x00000000,
3291 + 0x00000000,
3292 + 0x00000000,
3293 + 0x00000000,
3294 + 0x00000000,
3295 + 0x00000000,
3296 + 0x00000000,
3297 + 0x00000000,
3298 + 0x00000000,
3299 + 0x00000000,
3300 + 0x00000000,
3301 + 0x00000000,
3302 + 0xa0045670, /* mainFunc(), EU# 3 */
3303 + 0xa0000000, /* rsduFunc(), EU# 3 */
3304 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3305 + 0x20000000, /* setCrcAccum(), EU# 3 */
3306 + 0x21800000, /* and(), EU# 3 */
3307 + 0x21e00000, /* or(), EU# 3 */
3308 + 0x20400000, /* add(), EU# 3 */
3309 + 0x20500000, /* sub(), EU# 3 */
3310 + 0x205a0000, /* andNot(), EU# 3 */
3311 + 0x202fa000, /* andReadyBit(), EU# 3 */
3312 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3313 + 0x202ea000, /* andWrapBit(), EU# 3 */
3314 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3315 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3316 + 0x202f2000, /* andLoopBit(), EU# 3 */
3317 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3318 +};
3319 +
3320 +u32 MCD_funcDescTab6[]=
3321 +{ /* Task 6 Function Descriptor Table */
3322 + 0x00000000,
3323 + 0x00000000,
3324 + 0x00000000,
3325 + 0x00000000,
3326 + 0x00000000,
3327 + 0x00000000,
3328 + 0x00000000,
3329 + 0x00000000,
3330 + 0x00000000,
3331 + 0x00000000,
3332 + 0x00000000,
3333 + 0x00000000,
3334 + 0x00000000,
3335 + 0x00000000,
3336 + 0x00000000,
3337 + 0x00000000,
3338 + 0x00000000,
3339 + 0x00000000,
3340 + 0x00000000,
3341 + 0x00000000,
3342 + 0x00000000,
3343 + 0x00000000,
3344 + 0x00000000,
3345 + 0x00000000,
3346 + 0x00000000,
3347 + 0x00000000,
3348 + 0x00000000,
3349 + 0x00000000,
3350 + 0x00000000,
3351 + 0x00000000,
3352 + 0x00000000,
3353 + 0x00000000,
3354 + 0x00000000,
3355 + 0x00000000,
3356 + 0x00000000,
3357 + 0x00000000,
3358 + 0x00000000,
3359 + 0x00000000,
3360 + 0x00000000,
3361 + 0x00000000,
3362 + 0x00000000,
3363 + 0x00000000,
3364 + 0x00000000,
3365 + 0x00000000,
3366 + 0x00000000,
3367 + 0x00000000,
3368 + 0x00000000,
3369 + 0x00000000,
3370 + 0xa0045670, /* mainFunc(), EU# 3 */
3371 + 0xa0000000, /* rsduFunc(), EU# 3 */
3372 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3373 + 0x20000000, /* setCrcAccum(), EU# 3 */
3374 + 0x21800000, /* and(), EU# 3 */
3375 + 0x21e00000, /* or(), EU# 3 */
3376 + 0x20400000, /* add(), EU# 3 */
3377 + 0x20500000, /* sub(), EU# 3 */
3378 + 0x205a0000, /* andNot(), EU# 3 */
3379 + 0x202fa000, /* andReadyBit(), EU# 3 */
3380 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3381 + 0x202ea000, /* andWrapBit(), EU# 3 */
3382 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3383 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3384 + 0x202f2000, /* andLoopBit(), EU# 3 */
3385 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3386 +};
3387 +
3388 +u32 MCD_funcDescTab7[]=
3389 +{ /* Task 7 Function Descriptor Table */
3390 + 0x00000000,
3391 + 0x00000000,
3392 + 0x00000000,
3393 + 0x00000000,
3394 + 0x00000000,
3395 + 0x00000000,
3396 + 0x00000000,
3397 + 0x00000000,
3398 + 0x00000000,
3399 + 0x00000000,
3400 + 0x00000000,
3401 + 0x00000000,
3402 + 0x00000000,
3403 + 0x00000000,
3404 + 0x00000000,
3405 + 0x00000000,
3406 + 0x00000000,
3407 + 0x00000000,
3408 + 0x00000000,
3409 + 0x00000000,
3410 + 0x00000000,
3411 + 0x00000000,
3412 + 0x00000000,
3413 + 0x00000000,
3414 + 0x00000000,
3415 + 0x00000000,
3416 + 0x00000000,
3417 + 0x00000000,
3418 + 0x00000000,
3419 + 0x00000000,
3420 + 0x00000000,
3421 + 0x00000000,
3422 + 0x00000000,
3423 + 0x00000000,
3424 + 0x00000000,
3425 + 0x00000000,
3426 + 0x00000000,
3427 + 0x00000000,
3428 + 0x00000000,
3429 + 0x00000000,
3430 + 0x00000000,
3431 + 0x00000000,
3432 + 0x00000000,
3433 + 0x00000000,
3434 + 0x00000000,
3435 + 0x00000000,
3436 + 0x00000000,
3437 + 0x00000000,
3438 + 0xa0045670, /* mainFunc(), EU# 3 */
3439 + 0xa0000000, /* rsduFunc(), EU# 3 */
3440 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3441 + 0x20000000, /* setCrcAccum(), EU# 3 */
3442 + 0x21800000, /* and(), EU# 3 */
3443 + 0x21e00000, /* or(), EU# 3 */
3444 + 0x20400000, /* add(), EU# 3 */
3445 + 0x20500000, /* sub(), EU# 3 */
3446 + 0x205a0000, /* andNot(), EU# 3 */
3447 + 0x202fa000, /* andReadyBit(), EU# 3 */
3448 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3449 + 0x202ea000, /* andWrapBit(), EU# 3 */
3450 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3451 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3452 + 0x202f2000, /* andLoopBit(), EU# 3 */
3453 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3454 +};
3455 +
3456 +u32 MCD_funcDescTab8[]=
3457 +{ /* Task 8 Function Descriptor Table */
3458 + 0x00000000,
3459 + 0x00000000,
3460 + 0x00000000,
3461 + 0x00000000,
3462 + 0x00000000,
3463 + 0x00000000,
3464 + 0x00000000,
3465 + 0x00000000,
3466 + 0x00000000,
3467 + 0x00000000,
3468 + 0x00000000,
3469 + 0x00000000,
3470 + 0x00000000,
3471 + 0x00000000,
3472 + 0x00000000,
3473 + 0x00000000,
3474 + 0x00000000,
3475 + 0x00000000,
3476 + 0x00000000,
3477 + 0x00000000,
3478 + 0x00000000,
3479 + 0x00000000,
3480 + 0x00000000,
3481 + 0x00000000,
3482 + 0x00000000,
3483 + 0x00000000,
3484 + 0x00000000,
3485 + 0x00000000,
3486 + 0x00000000,
3487 + 0x00000000,
3488 + 0x00000000,
3489 + 0x00000000,
3490 + 0x00000000,
3491 + 0x00000000,
3492 + 0x00000000,
3493 + 0x00000000,
3494 + 0x00000000,
3495 + 0x00000000,
3496 + 0x00000000,
3497 + 0x00000000,
3498 + 0x00000000,
3499 + 0x00000000,
3500 + 0x00000000,
3501 + 0x00000000,
3502 + 0x00000000,
3503 + 0x00000000,
3504 + 0x00000000,
3505 + 0x00000000,
3506 + 0xa0045670, /* mainFunc(), EU# 3 */
3507 + 0xa0000000, /* rsduFunc(), EU# 3 */
3508 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3509 + 0x20000000, /* setCrcAccum(), EU# 3 */
3510 + 0x21800000, /* and(), EU# 3 */
3511 + 0x21e00000, /* or(), EU# 3 */
3512 + 0x20400000, /* add(), EU# 3 */
3513 + 0x20500000, /* sub(), EU# 3 */
3514 + 0x205a0000, /* andNot(), EU# 3 */
3515 + 0x202fa000, /* andReadyBit(), EU# 3 */
3516 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3517 + 0x202ea000, /* andWrapBit(), EU# 3 */
3518 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3519 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3520 + 0x202f2000, /* andLoopBit(), EU# 3 */
3521 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3522 +};
3523 +
3524 +u32 MCD_funcDescTab9[]=
3525 +{ /* Task 9 Function Descriptor Table */
3526 + 0x00000000,
3527 + 0x00000000,
3528 + 0x00000000,
3529 + 0x00000000,
3530 + 0x00000000,
3531 + 0x00000000,
3532 + 0x00000000,
3533 + 0x00000000,
3534 + 0x00000000,
3535 + 0x00000000,
3536 + 0x00000000,
3537 + 0x00000000,
3538 + 0x00000000,
3539 + 0x00000000,
3540 + 0x00000000,
3541 + 0x00000000,
3542 + 0x00000000,
3543 + 0x00000000,
3544 + 0x00000000,
3545 + 0x00000000,
3546 + 0x00000000,
3547 + 0x00000000,
3548 + 0x00000000,
3549 + 0x00000000,
3550 + 0x00000000,
3551 + 0x00000000,
3552 + 0x00000000,
3553 + 0x00000000,
3554 + 0x00000000,
3555 + 0x00000000,
3556 + 0x00000000,
3557 + 0x00000000,
3558 + 0x00000000,
3559 + 0x00000000,
3560 + 0x00000000,
3561 + 0x00000000,
3562 + 0x00000000,
3563 + 0x00000000,
3564 + 0x00000000,
3565 + 0x00000000,
3566 + 0x00000000,
3567 + 0x00000000,
3568 + 0x00000000,
3569 + 0x00000000,
3570 + 0x00000000,
3571 + 0x00000000,
3572 + 0x00000000,
3573 + 0x00000000,
3574 + 0xa0045670, /* mainFunc(), EU# 3 */
3575 + 0xa0000000, /* rsduFunc(), EU# 3 */
3576 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3577 + 0x20000000, /* setCrcAccum(), EU# 3 */
3578 + 0x21800000, /* and(), EU# 3 */
3579 + 0x21e00000, /* or(), EU# 3 */
3580 + 0x20400000, /* add(), EU# 3 */
3581 + 0x20500000, /* sub(), EU# 3 */
3582 + 0x205a0000, /* andNot(), EU# 3 */
3583 + 0x202fa000, /* andReadyBit(), EU# 3 */
3584 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3585 + 0x202ea000, /* andWrapBit(), EU# 3 */
3586 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3587 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3588 + 0x202f2000, /* andLoopBit(), EU# 3 */
3589 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3590 +};
3591 +
3592 +u32 MCD_funcDescTab10[]=
3593 +{ /* Task 10 Function Descriptor Table */
3594 + 0x00000000,
3595 + 0x00000000,
3596 + 0x00000000,
3597 + 0x00000000,
3598 + 0x00000000,
3599 + 0x00000000,
3600 + 0x00000000,
3601 + 0x00000000,
3602 + 0x00000000,
3603 + 0x00000000,
3604 + 0x00000000,
3605 + 0x00000000,
3606 + 0x00000000,
3607 + 0x00000000,
3608 + 0x00000000,
3609 + 0x00000000,
3610 + 0x00000000,
3611 + 0x00000000,
3612 + 0x00000000,
3613 + 0x00000000,
3614 + 0x00000000,
3615 + 0x00000000,
3616 + 0x00000000,
3617 + 0x00000000,
3618 + 0x00000000,
3619 + 0x00000000,
3620 + 0x00000000,
3621 + 0x00000000,
3622 + 0x00000000,
3623 + 0x00000000,
3624 + 0x00000000,
3625 + 0x00000000,
3626 + 0x00000000,
3627 + 0x00000000,
3628 + 0x00000000,
3629 + 0x00000000,
3630 + 0x00000000,
3631 + 0x00000000,
3632 + 0x00000000,
3633 + 0x00000000,
3634 + 0x00000000,
3635 + 0x00000000,
3636 + 0x00000000,
3637 + 0x00000000,
3638 + 0x00000000,
3639 + 0x00000000,
3640 + 0x00000000,
3641 + 0x00000000,
3642 + 0xa0045670, /* mainFunc(), EU# 3 */
3643 + 0xa0000000, /* rsduFunc(), EU# 3 */
3644 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3645 + 0x20000000, /* setCrcAccum(), EU# 3 */
3646 + 0x21800000, /* and(), EU# 3 */
3647 + 0x21e00000, /* or(), EU# 3 */
3648 + 0x20400000, /* add(), EU# 3 */
3649 + 0x20500000, /* sub(), EU# 3 */
3650 + 0x205a0000, /* andNot(), EU# 3 */
3651 + 0x202fa000, /* andReadyBit(), EU# 3 */
3652 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3653 + 0x202ea000, /* andWrapBit(), EU# 3 */
3654 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3655 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3656 + 0x202f2000, /* andLoopBit(), EU# 3 */
3657 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3658 +};
3659 +
3660 +u32 MCD_funcDescTab11[]=
3661 +{ /* Task 11 Function Descriptor Table */
3662 + 0x00000000,
3663 + 0x00000000,
3664 + 0x00000000,
3665 + 0x00000000,
3666 + 0x00000000,
3667 + 0x00000000,
3668 + 0x00000000,
3669 + 0x00000000,
3670 + 0x00000000,
3671 + 0x00000000,
3672 + 0x00000000,
3673 + 0x00000000,
3674 + 0x00000000,
3675 + 0x00000000,
3676 + 0x00000000,
3677 + 0x00000000,
3678 + 0x00000000,
3679 + 0x00000000,
3680 + 0x00000000,
3681 + 0x00000000,
3682 + 0x00000000,
3683 + 0x00000000,
3684 + 0x00000000,
3685 + 0x00000000,
3686 + 0x00000000,
3687 + 0x00000000,
3688 + 0x00000000,
3689 + 0x00000000,
3690 + 0x00000000,
3691 + 0x00000000,
3692 + 0x00000000,
3693 + 0x00000000,
3694 + 0x00000000,
3695 + 0x00000000,
3696 + 0x00000000,
3697 + 0x00000000,
3698 + 0x00000000,
3699 + 0x00000000,
3700 + 0x00000000,
3701 + 0x00000000,
3702 + 0x00000000,
3703 + 0x00000000,
3704 + 0x00000000,
3705 + 0x00000000,
3706 + 0x00000000,
3707 + 0x00000000,
3708 + 0x00000000,
3709 + 0x00000000,
3710 + 0xa0045670, /* mainFunc(), EU# 3 */
3711 + 0xa0000000, /* rsduFunc(), EU# 3 */
3712 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3713 + 0x20000000, /* setCrcAccum(), EU# 3 */
3714 + 0x21800000, /* and(), EU# 3 */
3715 + 0x21e00000, /* or(), EU# 3 */
3716 + 0x20400000, /* add(), EU# 3 */
3717 + 0x20500000, /* sub(), EU# 3 */
3718 + 0x205a0000, /* andNot(), EU# 3 */
3719 + 0x202fa000, /* andReadyBit(), EU# 3 */
3720 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3721 + 0x202ea000, /* andWrapBit(), EU# 3 */
3722 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3723 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3724 + 0x202f2000, /* andLoopBit(), EU# 3 */
3725 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3726 +};
3727 +
3728 +u32 MCD_funcDescTab12[]=
3729 +{ /* Task 12 Function Descriptor Table */
3730 + 0x00000000,
3731 + 0x00000000,
3732 + 0x00000000,
3733 + 0x00000000,
3734 + 0x00000000,
3735 + 0x00000000,
3736 + 0x00000000,
3737 + 0x00000000,
3738 + 0x00000000,
3739 + 0x00000000,
3740 + 0x00000000,
3741 + 0x00000000,
3742 + 0x00000000,
3743 + 0x00000000,
3744 + 0x00000000,
3745 + 0x00000000,
3746 + 0x00000000,
3747 + 0x00000000,
3748 + 0x00000000,
3749 + 0x00000000,
3750 + 0x00000000,
3751 + 0x00000000,
3752 + 0x00000000,
3753 + 0x00000000,
3754 + 0x00000000,
3755 + 0x00000000,
3756 + 0x00000000,
3757 + 0x00000000,
3758 + 0x00000000,
3759 + 0x00000000,
3760 + 0x00000000,
3761 + 0x00000000,
3762 + 0x00000000,
3763 + 0x00000000,
3764 + 0x00000000,
3765 + 0x00000000,
3766 + 0x00000000,
3767 + 0x00000000,
3768 + 0x00000000,
3769 + 0x00000000,
3770 + 0x00000000,
3771 + 0x00000000,
3772 + 0x00000000,
3773 + 0x00000000,
3774 + 0x00000000,
3775 + 0x00000000,
3776 + 0x00000000,
3777 + 0x00000000,
3778 + 0xa0045670, /* mainFunc(), EU# 3 */
3779 + 0xa0000000, /* rsduFunc(), EU# 3 */
3780 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3781 + 0x20000000, /* setCrcAccum(), EU# 3 */
3782 + 0x21800000, /* and(), EU# 3 */
3783 + 0x21e00000, /* or(), EU# 3 */
3784 + 0x20400000, /* add(), EU# 3 */
3785 + 0x20500000, /* sub(), EU# 3 */
3786 + 0x205a0000, /* andNot(), EU# 3 */
3787 + 0x202fa000, /* andReadyBit(), EU# 3 */
3788 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3789 + 0x202ea000, /* andWrapBit(), EU# 3 */
3790 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3791 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3792 + 0x202f2000, /* andLoopBit(), EU# 3 */
3793 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3794 +};
3795 +
3796 +u32 MCD_funcDescTab13[]=
3797 +{ /* Task 13 Function Descriptor Table */
3798 + 0x00000000,
3799 + 0x00000000,
3800 + 0x00000000,
3801 + 0x00000000,
3802 + 0x00000000,
3803 + 0x00000000,
3804 + 0x00000000,
3805 + 0x00000000,
3806 + 0x00000000,
3807 + 0x00000000,
3808 + 0x00000000,
3809 + 0x00000000,
3810 + 0x00000000,
3811 + 0x00000000,
3812 + 0x00000000,
3813 + 0x00000000,
3814 + 0x00000000,
3815 + 0x00000000,
3816 + 0x00000000,
3817 + 0x00000000,
3818 + 0x00000000,
3819 + 0x00000000,
3820 + 0x00000000,
3821 + 0x00000000,
3822 + 0x00000000,
3823 + 0x00000000,
3824 + 0x00000000,
3825 + 0x00000000,
3826 + 0x00000000,
3827 + 0x00000000,
3828 + 0x00000000,
3829 + 0x00000000,
3830 + 0x00000000,
3831 + 0x00000000,
3832 + 0x00000000,
3833 + 0x00000000,
3834 + 0x00000000,
3835 + 0x00000000,
3836 + 0x00000000,
3837 + 0x00000000,
3838 + 0x00000000,
3839 + 0x00000000,
3840 + 0x00000000,
3841 + 0x00000000,
3842 + 0x00000000,
3843 + 0x00000000,
3844 + 0x00000000,
3845 + 0x00000000,
3846 + 0xa0045670, /* mainFunc(), EU# 3 */
3847 + 0xa0000000, /* rsduFunc(), EU# 3 */
3848 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3849 + 0x20000000, /* setCrcAccum(), EU# 3 */
3850 + 0x21800000, /* and(), EU# 3 */
3851 + 0x21e00000, /* or(), EU# 3 */
3852 + 0x20400000, /* add(), EU# 3 */
3853 + 0x20500000, /* sub(), EU# 3 */
3854 + 0x205a0000, /* andNot(), EU# 3 */
3855 + 0x202fa000, /* andReadyBit(), EU# 3 */
3856 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3857 + 0x202ea000, /* andWrapBit(), EU# 3 */
3858 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3859 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3860 + 0x202f2000, /* andLoopBit(), EU# 3 */
3861 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3862 +};
3863 +
3864 +u32 MCD_funcDescTab14[]=
3865 +{ /* Task 14 Function Descriptor Table */
3866 + 0x00000000,
3867 + 0x00000000,
3868 + 0x00000000,
3869 + 0x00000000,
3870 + 0x00000000,
3871 + 0x00000000,
3872 + 0x00000000,
3873 + 0x00000000,
3874 + 0x00000000,
3875 + 0x00000000,
3876 + 0x00000000,
3877 + 0x00000000,
3878 + 0x00000000,
3879 + 0x00000000,
3880 + 0x00000000,
3881 + 0x00000000,
3882 + 0x00000000,
3883 + 0x00000000,
3884 + 0x00000000,
3885 + 0x00000000,
3886 + 0x00000000,
3887 + 0x00000000,
3888 + 0x00000000,
3889 + 0x00000000,
3890 + 0x00000000,
3891 + 0x00000000,
3892 + 0x00000000,
3893 + 0x00000000,
3894 + 0x00000000,
3895 + 0x00000000,
3896 + 0x00000000,
3897 + 0x00000000,
3898 + 0x00000000,
3899 + 0x00000000,
3900 + 0x00000000,
3901 + 0x00000000,
3902 + 0x00000000,
3903 + 0x00000000,
3904 + 0x00000000,
3905 + 0x00000000,
3906 + 0x00000000,
3907 + 0x00000000,
3908 + 0x00000000,
3909 + 0x00000000,
3910 + 0x00000000,
3911 + 0x00000000,
3912 + 0x00000000,
3913 + 0x00000000,
3914 + 0xa0045670, /* mainFunc(), EU# 3 */
3915 + 0xa0000000, /* rsduFunc(), EU# 3 */
3916 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3917 + 0x20000000, /* setCrcAccum(), EU# 3 */
3918 + 0x21800000, /* and(), EU# 3 */
3919 + 0x21e00000, /* or(), EU# 3 */
3920 + 0x20400000, /* add(), EU# 3 */
3921 + 0x20500000, /* sub(), EU# 3 */
3922 + 0x205a0000, /* andNot(), EU# 3 */
3923 + 0x202fa000, /* andReadyBit(), EU# 3 */
3924 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3925 + 0x202ea000, /* andWrapBit(), EU# 3 */
3926 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3927 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3928 + 0x202f2000, /* andLoopBit(), EU# 3 */
3929 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3930 +};
3931 +
3932 +u32 MCD_funcDescTab15[]=
3933 +{ /* Task 15 Function Descriptor Table */
3934 + 0x00000000,
3935 + 0x00000000,
3936 + 0x00000000,
3937 + 0x00000000,
3938 + 0x00000000,
3939 + 0x00000000,
3940 + 0x00000000,
3941 + 0x00000000,
3942 + 0x00000000,
3943 + 0x00000000,
3944 + 0x00000000,
3945 + 0x00000000,
3946 + 0x00000000,
3947 + 0x00000000,
3948 + 0x00000000,
3949 + 0x00000000,
3950 + 0x00000000,
3951 + 0x00000000,
3952 + 0x00000000,
3953 + 0x00000000,
3954 + 0x00000000,
3955 + 0x00000000,
3956 + 0x00000000,
3957 + 0x00000000,
3958 + 0x00000000,
3959 + 0x00000000,
3960 + 0x00000000,
3961 + 0x00000000,
3962 + 0x00000000,
3963 + 0x00000000,
3964 + 0x00000000,
3965 + 0x00000000,
3966 + 0x00000000,
3967 + 0x00000000,
3968 + 0x00000000,
3969 + 0x00000000,
3970 + 0x00000000,
3971 + 0x00000000,
3972 + 0x00000000,
3973 + 0x00000000,
3974 + 0x00000000,
3975 + 0x00000000,
3976 + 0x00000000,
3977 + 0x00000000,
3978 + 0x00000000,
3979 + 0x00000000,
3980 + 0x00000000,
3981 + 0x00000000,
3982 + 0xa0045670, /* mainFunc(), EU# 3 */
3983 + 0xa0000000, /* rsduFunc(), EU# 3 */
3984 + 0xa0000000, /* crcAccumVal(), EU# 3 */
3985 + 0x20000000, /* setCrcAccum(), EU# 3 */
3986 + 0x21800000, /* and(), EU# 3 */
3987 + 0x21e00000, /* or(), EU# 3 */
3988 + 0x20400000, /* add(), EU# 3 */
3989 + 0x20500000, /* sub(), EU# 3 */
3990 + 0x205a0000, /* andNot(), EU# 3 */
3991 + 0x202fa000, /* andReadyBit(), EU# 3 */
3992 + 0x202f9000, /* andNotReadyBit(), EU# 3 */
3993 + 0x202ea000, /* andWrapBit(), EU# 3 */
3994 + 0x202da000, /* andEndFrameBit(), EU# 3 */
3995 + 0x202e2000, /* andInterruptBit(), EU# 3 */
3996 + 0x202f2000, /* andLoopBit(), EU# 3 */
3997 + 0x2020a000, /* andCrcRestartBit(), EU# 3 */
3998 +};
3999 +#endif /*MCD_INCLUDE_EU*/
4000 +
4001 +u32 MCD_contextSave0[128]; /* Task 0 context save space */
4002 +u32 MCD_contextSave1[128]; /* Task 1 context save space */
4003 +u32 MCD_contextSave2[128]; /* Task 2 context save space */
4004 +u32 MCD_contextSave3[128]; /* Task 3 context save space */
4005 +u32 MCD_contextSave4[128]; /* Task 4 context save space */
4006 +u32 MCD_contextSave5[128]; /* Task 5 context save space */
4007 +u32 MCD_contextSave6[128]; /* Task 6 context save space */
4008 +u32 MCD_contextSave7[128]; /* Task 7 context save space */
4009 +u32 MCD_contextSave8[128]; /* Task 8 context save space */
4010 +u32 MCD_contextSave9[128]; /* Task 9 context save space */
4011 +u32 MCD_contextSave10[128]; /* Task 10 context save space */
4012 +u32 MCD_contextSave11[128]; /* Task 11 context save space */
4013 +u32 MCD_contextSave12[128]; /* Task 12 context save space */
4014 +u32 MCD_contextSave13[128]; /* Task 13 context save space */
4015 +u32 MCD_contextSave14[128]; /* Task 14 context save space */
4016 +u32 MCD_contextSave15[128]; /* Task 15 context save space */
4017 +
4018 +/* Task Descriptor Tables - the guts */
4019 +u32 MCD_ChainNoEu_TDT[];
4020 +u32 MCD_SingleNoEu_TDT[];
4021 +#ifdef MCD_INCLUDE_EU
4022 +u32 MCD_ChainEu_TDT[];
4023 +u32 MCD_SingleEu_TDT[];
4024 +#endif
4025 +u32 MCD_ENetRcv_TDT[];
4026 +u32 MCD_ENetXmit_TDT[];
4027 +
4028 +u32 MCD_modelTaskTableSrc[]=
4029 +{
4030 + (u32)MCD_ChainNoEu_TDT,
4031 + (u32)&((u8*)MCD_ChainNoEu_TDT)[0x00000178],
4032 + 0x00000000,
4033 + 0x00000000,
4034 + 0x00000000,
4035 + 0x00000000,
4036 + 0x00000000,
4037 + 0x00000000,
4038 + (u32)MCD_SingleNoEu_TDT,
4039 + (u32)&((u8*)MCD_SingleNoEu_TDT)[0x000000d4],
4040 + 0x00000000,
4041 + 0x00000000,
4042 + 0x00000000,
4043 + 0x00000000,
4044 + 0x00000000,
4045 + 0x00000000,
4046 +#ifdef MCD_INCLUDE_EU
4047 + (u32)MCD_ChainEu_TDT,
4048 + (u32)&((u8*)MCD_ChainEu_TDT)[0x00000180],
4049 + 0x00000000,
4050 + 0x00000000,
4051 + 0x00000000,
4052 + 0x00000000,
4053 + 0x00000000,
4054 + 0x00000000,
4055 + (u32)MCD_SingleEu_TDT,
4056 + (u32)&((u8*)MCD_SingleEu_TDT)[0x000000dc],
4057 + 0x00000000,
4058 + 0x00000000,
4059 + 0x00000000,
4060 + 0x00000000,
4061 + 0x00000000,
4062 + 0x00000000,
4063 +#endif
4064 + (u32)MCD_ENetRcv_TDT,
4065 + (u32)&((u8*)MCD_ENetRcv_TDT)[0x0000009C],
4066 + 0x00000000,
4067 + 0x00000000,
4068 + 0x00000000,
4069 + 0x00000000,
4070 + 0x00000000,
4071 + 0x00000000,
4072 + (u32)MCD_ENetXmit_TDT,
4073 + (u32)&((u8*)MCD_ENetXmit_TDT)[0x000000d0],
4074 + 0x00000000,
4075 + 0x00000000,
4076 + 0x00000000,
4077 + 0x00000000,
4078 + 0x00000000,
4079 + 0x00000000,
4080 +};
4081 +
4082 +u32 MCD_ChainNoEu_TDT[]=
4083 +{
4084 + 0x80004000, /* 0000(:370): LCDEXT: idx0 = 0x00000000; ; */
4085 + 0x8118801b, /* 0004(:370): LCD: idx1 = var2; idx1 once var0; idx1 += inc3 */
4086 + 0xb8ca0018, /* 0008(:371): LCD: idx2 = *(idx1 + var20); idx2 once var0; idx2 += inc3 */
4087 + 0x10004b10, /* 000C(:372): DRD1A: var18 = idx2; FN=0 MORE init=0 WS=0 RS=0 */
4088 + 0x7000000c, /* 0010(:373): DRD2A: EU0=0 EU1=0 EU2=0 EU3=12 EXT MORE init=0 WS=0 RS=0 */
4089 + 0x024cf89f, /* 0014(:373): DRD2B1: var9 = EU3(); EU3(idx2) */
4090 + 0x60000009, /* 0018(:374): DRD2A: EU0=0 EU1=0 EU2=0 EU3=9 EXT init=0 WS=0 RS=0 */
4091 + 0x080cf89f, /* 001C(:374): DRD2B1: idx0 = EU3(); EU3(idx2) */
4092 + 0x000001f8, /* 0020(:0): NOP */
4093 + 0x98180524, /* 0024(:378): LCD: idx0 = idx0; idx0 != var20; idx0 += inc4 */
4094 + 0x8118801b, /* 0028(:380): LCD: idx1 = var2; idx1 once var0; idx1 += inc3 */
4095 + 0xf8ca001a, /* 002C(:381): LCDEXT: idx2 = *(idx1 + var20 + 8); idx2 once var0; idx2 += inc3 */
4096 + 0xb8ca601b, /* 0030(:382): LCD: idx3 = *(idx1 + var20 + 12); ; idx3 += inc3 */
4097 + 0x10004310, /* 0034(:384): DRD1A: var16 = idx2; FN=0 MORE init=0 WS=0 RS=0 */
4098 + 0x00001718, /* 0038(:385): DRD1A: var5 = idx3; FN=0 init=0 WS=0 RS=0 */
4099 + 0xb8ca001d, /* 003C(:387): LCD: idx2 = *(idx1 + var20 + 20); idx2 once var0; idx2 += inc3 */
4100 + 0x10001f10, /* 0040(:388): DRD1A: var7 = idx2; FN=0 MORE init=0 WS=0 RS=0 */
4101 + 0x60000007, /* 0044(:389): DRD2A: EU0=0 EU1=0 EU2=0 EU3=7 EXT init=0 WS=0 RS=0 */
4102 + 0x020cf893, /* 0048(:389): DRD2B1: var8 = EU3(); EU3(idx2,var19) */
4103 + 0x98ca001c, /* 004C(:391): LCD: idx2 = idx1 + var20 + 4; idx2 once var0; idx2 += inc3 */
4104 + 0x00000710, /* 0050(:392): DRD1A: var1 = idx2; FN=0 init=0 WS=0 RS=0 */
4105 + 0x98ca8018, /* 0054(:393): LCD: idx2 = idx1 + var21; idx2 once var0; idx2 += inc3 */
4106 + 0x10002b10, /* 0058(:394): DRD1A: var10 = idx2; FN=0 MORE init=0 WS=0 RS=0 */
4107 + 0x0000c828, /* 005C(:395): DRD1A: *idx2 = var5; FN=0 init=0 WS=0 RS=0 */
4108 + 0x000001f8, /* 0060(:0): NOP */
4109 + 0xc14ae018, /* 0064(:399): LCDEXT: idx1 = var2 + var21; ; idx1 += inc3 */
4110 + 0xc004a51d, /* 0068(:399): LCDEXT: idx2 = var0, idx3 = var9; idx3 == var20; idx2 += inc3, idx3 += inc5 */
4111 + 0x811a601b, /* 006C(:400): LCD: idx4 = var2; ; idx4 += inc3 */
4112 + 0xc28a21c2, /* 0070(:403): LCDEXT: idx5 = var5, idx6 = var20; idx6 < var7; idx5 += inc0, idx6 += inc2 */
4113 + 0x881be009, /* 0074(:403): LCD: idx7 = var16; ; idx7 += inc1 */
4114 + 0x03fed7b8, /* 0078(:406): DRD1A: *idx7; FN=0 init=31 WS=3 RS=3 */
4115 + 0xda9b001b, /* 007C(:408): LCDEXT: idx5 = idx5, idx6 = idx6; idx5 once var0; idx5 += inc3, idx6 += inc3 */
4116 + 0x9b9be01b, /* 0080(:408): LCD: idx7 = idx7; ; idx7 += inc3 */
4117 + 0x1000cb20, /* 0084(:409): DRD1A: *idx2 = idx4; FN=0 MORE init=0 WS=0 RS=0 */
4118 + 0x70000006, /* 0088(:410): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4119 + 0x088cf896, /* 008C(:410): DRD2B1: idx2 = EU3(); EU3(idx2,var22) */
4120 + 0x1000cb28, /* 0090(:411): DRD1A: *idx2 = idx5; FN=0 MORE init=0 WS=0 RS=0 */
4121 + 0x70000006, /* 0094(:412): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4122 + 0x088cf896, /* 0098(:412): DRD2B1: idx2 = EU3(); EU3(idx2,var22) */
4123 + 0x1000cb30, /* 009C(:413): DRD1A: *idx2 = idx6; FN=0 MORE init=0 WS=0 RS=0 */
4124 + 0x70000006, /* 00A0(:414): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4125 + 0x088cf896, /* 00A4(:414): DRD2B1: idx2 = EU3(); EU3(idx2,var22) */
4126 + 0x1000cb38, /* 00A8(:415): DRD1A: *idx2 = idx7; FN=0 MORE init=0 WS=0 RS=0 */
4127 + 0x0000c728, /* 00AC(:416): DRD1A: *idx1 = idx5; FN=0 init=0 WS=0 RS=0 */
4128 + 0x000001f8, /* 00B0(:0): NOP */
4129 + 0xc14ae018, /* 00B4(:420): LCDEXT: idx1 = var2 + var21; ; idx1 += inc3 */
4130 + 0xc004a5dd, /* 00B8(:420): LCDEXT: idx2 = var0, idx3 = var9; idx3 == var23; idx2 += inc3, idx3 += inc5 */
4131 + 0x811a601b, /* 00BC(:421): LCD: idx4 = var2; ; idx4 += inc3 */
4132 + 0xda9b001b, /* 00C0(:424): LCDEXT: idx5 = idx5, idx6 = idx6; idx5 once var0; idx5 += inc3, idx6 += inc3 */
4133 + 0x9b9be01b, /* 00C4(:424): LCD: idx7 = idx7; ; idx7 += inc3 */
4134 + 0x0000d3a0, /* 00C8(:425): DRD1A: *idx4; FN=0 init=0 WS=0 RS=0 */
4135 + 0xc28a21c2, /* 00CC(:427): LCDEXT: idx5 = var5, idx6 = var20; idx6 < var7; idx5 += inc0, idx6 += inc2 */
4136 + 0x881be009, /* 00D0(:427): LCD: idx7 = var16; ; idx7 += inc1 */
4137 + 0x0bfed7b8, /* 00D4(:430): DRD1A: *idx7; FN=0 TFD init=31 WS=3 RS=3 */
4138 + 0xda9b001b, /* 00D8(:432): LCDEXT: idx5 = idx5, idx6 = idx6; idx5 once var0; idx5 += inc3, idx6 += inc3 */
4139 + 0x9b9be01b, /* 00DC(:432): LCD: idx7 = idx7; ; idx7 += inc3 */
4140 + 0x1000cb20, /* 00E0(:433): DRD1A: *idx2 = idx4; FN=0 MORE init=0 WS=0 RS=0 */
4141 + 0x70000006, /* 00E4(:434): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4142 + 0x088cf896, /* 00E8(:434): DRD2B1: idx2 = EU3(); EU3(idx2,var22) */
4143 + 0x1000cb28, /* 00EC(:435): DRD1A: *idx2 = idx5; FN=0 MORE init=0 WS=0 RS=0 */
4144 + 0x70000006, /* 00F0(:436): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4145 + 0x088cf896, /* 00F4(:436): DRD2B1: idx2 = EU3(); EU3(idx2,var22) */
4146 + 0x1000cb30, /* 00F8(:437): DRD1A: *idx2 = idx6; FN=0 MORE init=0 WS=0 RS=0 */
4147 + 0x70000006, /* 00FC(:438): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4148 + 0x088cf896, /* 0100(:438): DRD2B1: idx2 = EU3(); EU3(idx2,var22) */
4149 + 0x1000cb38, /* 0104(:439): DRD1A: *idx2 = idx7; FN=0 MORE init=0 WS=0 RS=0 */
4150 + 0x0000c728, /* 0108(:440): DRD1A: *idx1 = idx5; FN=0 init=0 WS=0 RS=0 */
4151 + 0x000001f8, /* 010C(:0): NOP */
4152 + 0x8118801b, /* 0110(:444): LCD: idx1 = var2; idx1 once var0; idx1 += inc3 */
4153 + 0x8a19001b, /* 0114(:446): LCD: idx2 = var20; idx2 once var0; idx2 += inc3 */
4154 + 0x6000000e, /* 0118(:447): DRD2A: EU0=0 EU1=0 EU2=0 EU3=14 EXT init=0 WS=0 RS=0 */
4155 + 0x088cf49f, /* 011C(:447): DRD2B1: idx2 = EU3(); EU3(var18) */
4156 + 0xd9190536, /* 0120(:448): LCDEXT: idx2 = idx2; idx2 == var20; idx2 += inc6 */
4157 + 0x98ca0018, /* 0124(:448): LCD: idx3 = idx1 + var20; idx3 once var0; idx3 += inc3 */
4158 + 0x6000000a, /* 0128(:450): DRD2A: EU0=0 EU1=0 EU2=0 EU3=10 EXT init=0 WS=0 RS=0 */
4159 + 0x0cccfcdf, /* 012C(:450): DRD2B1: *idx3 = EU3(); EU3(*idx3) */
4160 + 0x000001f8, /* 0130(:0): NOP */
4161 + 0xa14a001e, /* 0134(:453): LCD: idx1 = *(var2 + var20 + 24); idx1 once var0; idx1 += inc3 */
4162 + 0x10000b08, /* 0138(:454): DRD1A: var2 = idx1; FN=0 MORE init=0 WS=0 RS=0 */
4163 + 0x10002c90, /* 013C(:455): DRD1A: var11 = var18; FN=0 MORE init=0 WS=0 RS=0 */
4164 + 0xb8ca0018, /* 0140(:456): LCD: idx2 = *(idx1 + var20); idx2 once var0; idx2 += inc3 */
4165 + 0x10004b10, /* 0144(:457): DRD1A: var18 = idx2; FN=0 MORE init=0 WS=0 RS=0 */
4166 + 0x70000009, /* 0148(:458): DRD2A: EU0=0 EU1=0 EU2=0 EU3=9 EXT MORE init=0 WS=0 RS=0 */
4167 + 0x080cf89f, /* 014C(:458): DRD2B1: idx0 = EU3(); EU3(idx2) */
4168 + 0x6000000c, /* 0150(:459): DRD2A: EU0=0 EU1=0 EU2=0 EU3=12 EXT init=0 WS=0 RS=0 */
4169 + 0x024cf89f, /* 0154(:459): DRD2B1: var9 = EU3(); EU3(idx2) */
4170 + 0x000001f8, /* 0158(:0): NOP */
4171 + 0x8a18801b, /* 015C(:465): LCD: idx1 = var20; idx1 once var0; idx1 += inc3 */
4172 + 0x7000000d, /* 0160(:466): DRD2A: EU0=0 EU1=0 EU2=0 EU3=13 EXT MORE init=0 WS=0 RS=0 */
4173 + 0x084cf2df, /* 0164(:466): DRD2B1: idx1 = EU3(); EU3(var11) */
4174 + 0xd899053f, /* 0168(:467): LCDEXT: idx2 = idx1; idx2 > var20; idx2 += inc7 */
4175 + 0x8019801b, /* 016C(:467): LCD: idx3 = var0; idx3 once var0; idx3 += inc3 */
4176 + 0x040001f8, /* 0170(:468): DRD1A: FN=0 INT init=0 WS=0 RS=0 */
4177 + 0x000001f8, /* 0174(:0): NOP */
4178 + 0x000001f8, /* 0178(:0): NOP */
4179 +};
4180 +u32 MCD_SingleNoEu_TDT[]=
4181 +{
4182 + 0x8318001b, /* 0000(:646): LCD: idx0 = var6; idx0 once var0; idx0 += inc3 */
4183 + 0x7000000c, /* 0004(:647): DRD2A: EU0=0 EU1=0 EU2=0 EU3=12 EXT MORE init=0 WS=0 RS=0 */
4184 + 0x080cf81f, /* 0008(:647): DRD2B1: idx0 = EU3(); EU3(idx0) */
4185 + 0x8318801b, /* 000C(:648): LCD: idx1 = var6; idx1 once var0; idx1 += inc3 */
4186 + 0x6000000d, /* 0010(:649): DRD2A: EU0=0 EU1=0 EU2=0 EU3=13 EXT init=0 WS=0 RS=0 */
4187 + 0x084cf85f, /* 0014(:649): DRD2B1: idx1 = EU3(); EU3(idx1) */
4188 + 0x000001f8, /* 0018(:0): NOP */
4189 + 0x8498001b, /* 001C(:653): LCD: idx0 = var9; idx0 once var0; idx0 += inc3 */
4190 + 0x7000000c, /* 0020(:654): DRD2A: EU0=0 EU1=0 EU2=0 EU3=12 EXT MORE init=0 WS=0 RS=0 */
4191 + 0x020cf81f, /* 0024(:654): DRD2B1: var8 = EU3(); EU3(idx0) */
4192 + 0x6000000d, /* 0028(:655): DRD2A: EU0=0 EU1=0 EU2=0 EU3=13 EXT init=0 WS=0 RS=0 */
4193 + 0x028cf81f, /* 002C(:655): DRD2B1: var10 = EU3(); EU3(idx0) */
4194 + 0xc404601b, /* 0030(:658): LCDEXT: idx0 = var8, idx1 = var8; ; idx0 += inc3, idx1 += inc3 */
4195 + 0xc00423dc, /* 0034(:658): LCDEXT: idx2 = var0, idx3 = var8; idx3 == var15; idx2 += inc3, idx3 += inc4 */
4196 + 0x809a601b, /* 0038(:659): LCD: idx4 = var1; ; idx4 += inc3 */
4197 + 0xc207a182, /* 003C(:662): LCDEXT: idx5 = var4, idx6 = var15; idx6 < var6; idx5 += inc0, idx6 += inc2 */
4198 + 0x869be009, /* 0040(:662): LCD: idx7 = var13; ; idx7 += inc1 */
4199 + 0x03fed7b8, /* 0044(:665): DRD1A: *idx7; FN=0 init=31 WS=3 RS=3 */
4200 + 0xda9b001b, /* 0048(:667): LCDEXT: idx5 = idx5, idx6 = idx6; idx5 once var0; idx5 += inc3, idx6 += inc3 */
4201 + 0x9b9be01b, /* 004C(:667): LCD: idx7 = idx7; ; idx7 += inc3 */
4202 + 0x70000006, /* 0050(:669): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4203 + 0x088cf890, /* 0054(:669): DRD2B1: idx2 = EU3(); EU3(idx2,var16) */
4204 + 0x1000cb28, /* 0058(:670): DRD1A: *idx2 = idx5; FN=0 MORE init=0 WS=0 RS=0 */
4205 + 0x70000006, /* 005C(:671): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4206 + 0x088cf890, /* 0060(:671): DRD2B1: idx2 = EU3(); EU3(idx2,var16) */
4207 + 0x1000cb30, /* 0064(:672): DRD1A: *idx2 = idx6; FN=0 MORE init=0 WS=0 RS=0 */
4208 + 0x70000006, /* 0068(:673): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4209 + 0x088cf890, /* 006C(:673): DRD2B1: idx2 = EU3(); EU3(idx2,var16) */
4210 + 0x0000cb38, /* 0070(:674): DRD1A: *idx2 = idx7; FN=0 init=0 WS=0 RS=0 */
4211 + 0x000001f8, /* 0074(:0): NOP */
4212 + 0xc404601b, /* 0078(:678): LCDEXT: idx0 = var8, idx1 = var8; ; idx0 += inc3, idx1 += inc3 */
4213 + 0xc004245c, /* 007C(:678): LCDEXT: idx2 = var0, idx3 = var8; idx3 == var17; idx2 += inc3, idx3 += inc4 */
4214 + 0x809a601b, /* 0080(:679): LCD: idx4 = var1; ; idx4 += inc3 */
4215 + 0xda9b001b, /* 0084(:682): LCDEXT: idx5 = idx5, idx6 = idx6; idx5 once var0; idx5 += inc3, idx6 += inc3 */
4216 + 0x9b9be01b, /* 0088(:682): LCD: idx7 = idx7; ; idx7 += inc3 */
4217 + 0x0000d3a0, /* 008C(:683): DRD1A: *idx4; FN=0 init=0 WS=0 RS=0 */
4218 + 0xc207a182, /* 0090(:685): LCDEXT: idx5 = var4, idx6 = var15; idx6 < var6; idx5 += inc0, idx6 += inc2 */
4219 + 0x869be009, /* 0094(:685): LCD: idx7 = var13; ; idx7 += inc1 */
4220 + 0x0bfed7b8, /* 0098(:688): DRD1A: *idx7; FN=0 TFD init=31 WS=3 RS=3 */
4221 + 0xda9b001b, /* 009C(:690): LCDEXT: idx5 = idx5, idx6 = idx6; idx5 once var0; idx5 += inc3, idx6 += inc3 */
4222 + 0x9b9be01b, /* 00A0(:690): LCD: idx7 = idx7; ; idx7 += inc3 */
4223 + 0x70000006, /* 00A4(:692): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4224 + 0x088cf890, /* 00A8(:692): DRD2B1: idx2 = EU3(); EU3(idx2,var16) */
4225 + 0x1000cb28, /* 00AC(:693): DRD1A: *idx2 = idx5; FN=0 MORE init=0 WS=0 RS=0 */
4226 + 0x70000006, /* 00B0(:694): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4227 + 0x088cf890, /* 00B4(:694): DRD2B1: idx2 = EU3(); EU3(idx2,var16) */
4228 + 0x1000cb30, /* 00B8(:695): DRD1A: *idx2 = idx6; FN=0 MORE init=0 WS=0 RS=0 */
4229 + 0x70000006, /* 00BC(:696): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4230 + 0x088cf890, /* 00C0(:696): DRD2B1: idx2 = EU3(); EU3(idx2,var16) */
4231 + 0x0000cb38, /* 00C4(:697): DRD1A: *idx2 = idx7; FN=0 init=0 WS=0 RS=0 */
4232 + 0x000001f8, /* 00C8(:0): NOP */
4233 + 0xc51803ed, /* 00CC(:701): LCDEXT: idx0 = var10; idx0 > var15; idx0 += inc5 */
4234 + 0x8018801b, /* 00D0(:701): LCD: idx1 = var0; idx1 once var0; idx1 += inc3 */
4235 + 0x040001f8, /* 00D4(:702): DRD1A: FN=0 INT init=0 WS=0 RS=0 */
4236 +};
4237 +#ifdef MCD_INCLUDE_EU
4238 +u32 MCD_ChainEu_TDT[]=
4239 +{
4240 + 0x80004000, /* 0000(:928): LCDEXT: idx0 = 0x00000000; ; */
4241 + 0x8118801b, /* 0004(:928): LCD: idx1 = var2; idx1 once var0; idx1 += inc3 */
4242 + 0xb8ca0018, /* 0008(:929): LCD: idx2 = *(idx1 + var20); idx2 once var0; idx2 += inc3 */
4243 + 0x10004b10, /* 000C(:930): DRD1A: var18 = idx2; FN=0 MORE init=0 WS=0 RS=0 */
4244 + 0x7000000c, /* 0010(:931): DRD2A: EU0=0 EU1=0 EU2=0 EU3=12 EXT MORE init=0 WS=0 RS=0 */
4245 + 0x024cf89f, /* 0014(:931): DRD2B1: var9 = EU3(); EU3(idx2) */
4246 + 0x60000009, /* 0018(:932): DRD2A: EU0=0 EU1=0 EU2=0 EU3=9 EXT init=0 WS=0 RS=0 */
4247 + 0x080cf89f, /* 001C(:932): DRD2B1: idx0 = EU3(); EU3(idx2) */
4248 + 0x000001f8, /* 0020(:0): NOP */
4249 + 0x98180524, /* 0024(:936): LCD: idx0 = idx0; idx0 != var20; idx0 += inc4 */
4250 + 0x8118801b, /* 0028(:938): LCD: idx1 = var2; idx1 once var0; idx1 += inc3 */
4251 + 0xf8ca001a, /* 002C(:939): LCDEXT: idx2 = *(idx1 + var20 + 8); idx2 once var0; idx2 += inc3 */
4252 + 0xb8ca601b, /* 0030(:940): LCD: idx3 = *(idx1 + var20 + 12); ; idx3 += inc3 */
4253 + 0x10004310, /* 0034(:942): DRD1A: var16 = idx2; FN=0 MORE init=0 WS=0 RS=0 */
4254 + 0x00001718, /* 0038(:943): DRD1A: var5 = idx3; FN=0 init=0 WS=0 RS=0 */
4255 + 0xb8ca001d, /* 003C(:945): LCD: idx2 = *(idx1 + var20 + 20); idx2 once var0; idx2 += inc3 */
4256 + 0x10001f10, /* 0040(:946): DRD1A: var7 = idx2; FN=0 MORE init=0 WS=0 RS=0 */
4257 + 0x60000007, /* 0044(:947): DRD2A: EU0=0 EU1=0 EU2=0 EU3=7 EXT init=0 WS=0 RS=0 */
4258 + 0x020cf893, /* 0048(:947): DRD2B1: var8 = EU3(); EU3(idx2,var19) */
4259 + 0x98ca001c, /* 004C(:949): LCD: idx2 = idx1 + var20 + 4; idx2 once var0; idx2 += inc3 */
4260 + 0x00000710, /* 0050(:950): DRD1A: var1 = idx2; FN=0 init=0 WS=0 RS=0 */
4261 + 0x98ca8018, /* 0054(:951): LCD: idx2 = idx1 + var21; idx2 once var0; idx2 += inc3 */
4262 + 0x10002b10, /* 0058(:952): DRD1A: var10 = idx2; FN=0 MORE init=0 WS=0 RS=0 */
4263 + 0x0000c828, /* 005C(:953): DRD1A: *idx2 = var5; FN=0 init=0 WS=0 RS=0 */
4264 + 0x000001f8, /* 0060(:0): NOP */
4265 + 0xc14ae018, /* 0064(:957): LCDEXT: idx1 = var2 + var21; ; idx1 += inc3 */
4266 + 0xc004a51d, /* 0068(:957): LCDEXT: idx2 = var0, idx3 = var9; idx3 == var20; idx2 += inc3, idx3 += inc5 */
4267 + 0x811a601b, /* 006C(:958): LCD: idx4 = var2; ; idx4 += inc3 */
4268 + 0xc28a21c2, /* 0070(:961): LCDEXT: idx5 = var5, idx6 = var20; idx6 < var7; idx5 += inc0, idx6 += inc2 */
4269 + 0x881be009, /* 0074(:961): LCD: idx7 = var16; ; idx7 += inc1 */
4270 + 0x63fe0000, /* 0078(:964): DRD2A: EU0=0 EU1=0 EU2=0 EU3=0 EXT init=31 WS=3 RS=3 */
4271 + 0x0d4cfddf, /* 007C(:964): DRD2B1: *idx5 = EU3(); EU3(*idx7) */
4272 + 0xda9b001b, /* 0080(:966): LCDEXT: idx5 = idx5, idx6 = idx6; idx5 once var0; idx5 += inc3, idx6 += inc3 */
4273 + 0x9b9be01b, /* 0084(:966): LCD: idx7 = idx7; ; idx7 += inc3 */
4274 + 0x1000cb20, /* 0088(:967): DRD1A: *idx2 = idx4; FN=0 MORE init=0 WS=0 RS=0 */
4275 + 0x70000006, /* 008C(:968): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4276 + 0x088cf896, /* 0090(:968): DRD2B1: idx2 = EU3(); EU3(idx2,var22) */
4277 + 0x1000cb28, /* 0094(:969): DRD1A: *idx2 = idx5; FN=0 MORE init=0 WS=0 RS=0 */
4278 + 0x70000006, /* 0098(:970): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4279 + 0x088cf896, /* 009C(:970): DRD2B1: idx2 = EU3(); EU3(idx2,var22) */
4280 + 0x1000cb30, /* 00A0(:971): DRD1A: *idx2 = idx6; FN=0 MORE init=0 WS=0 RS=0 */
4281 + 0x70000006, /* 00A4(:972): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4282 + 0x088cf896, /* 00A8(:972): DRD2B1: idx2 = EU3(); EU3(idx2,var22) */
4283 + 0x1000cb38, /* 00AC(:973): DRD1A: *idx2 = idx7; FN=0 MORE init=0 WS=0 RS=0 */
4284 + 0x0000c728, /* 00B0(:974): DRD1A: *idx1 = idx5; FN=0 init=0 WS=0 RS=0 */
4285 + 0x000001f8, /* 00B4(:0): NOP */
4286 + 0xc14ae018, /* 00B8(:978): LCDEXT: idx1 = var2 + var21; ; idx1 += inc3 */
4287 + 0xc004a5dd, /* 00BC(:978): LCDEXT: idx2 = var0, idx3 = var9; idx3 == var23; idx2 += inc3, idx3 += inc5 */
4288 + 0x811a601b, /* 00C0(:979): LCD: idx4 = var2; ; idx4 += inc3 */
4289 + 0xda9b001b, /* 00C4(:982): LCDEXT: idx5 = idx5, idx6 = idx6; idx5 once var0; idx5 += inc3, idx6 += inc3 */
4290 + 0x9b9be01b, /* 00C8(:982): LCD: idx7 = idx7; ; idx7 += inc3 */
4291 + 0x0000d3a0, /* 00CC(:983): DRD1A: *idx4; FN=0 init=0 WS=0 RS=0 */
4292 + 0xc28a21c2, /* 00D0(:985): LCDEXT: idx5 = var5, idx6 = var20; idx6 < var7; idx5 += inc0, idx6 += inc2 */
4293 + 0x881be009, /* 00D4(:985): LCD: idx7 = var16; ; idx7 += inc1 */
4294 + 0x6bfe0000, /* 00D8(:988): DRD2A: EU0=0 EU1=0 EU2=0 EU3=0 TFD EXT init=31 WS=3 RS=3 */
4295 + 0x0d4cfddf, /* 00DC(:988): DRD2B1: *idx5 = EU3(); EU3(*idx7) */
4296 + 0xda9b001b, /* 00E0(:990): LCDEXT: idx5 = idx5, idx6 = idx6; idx5 once var0; idx5 += inc3, idx6 += inc3 */
4297 + 0x9b9be01b, /* 00E4(:990): LCD: idx7 = idx7; ; idx7 += inc3 */
4298 + 0x1000cb20, /* 00E8(:991): DRD1A: *idx2 = idx4; FN=0 MORE init=0 WS=0 RS=0 */
4299 + 0x70000006, /* 00EC(:992): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4300 + 0x088cf896, /* 00F0(:992): DRD2B1: idx2 = EU3(); EU3(idx2,var22) */
4301 + 0x1000cb28, /* 00F4(:993): DRD1A: *idx2 = idx5; FN=0 MORE init=0 WS=0 RS=0 */
4302 + 0x70000006, /* 00F8(:994): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4303 + 0x088cf896, /* 00FC(:994): DRD2B1: idx2 = EU3(); EU3(idx2,var22) */
4304 + 0x1000cb30, /* 0100(:995): DRD1A: *idx2 = idx6; FN=0 MORE init=0 WS=0 RS=0 */
4305 + 0x70000006, /* 0104(:996): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4306 + 0x088cf896, /* 0108(:996): DRD2B1: idx2 = EU3(); EU3(idx2,var22) */
4307 + 0x1000cb38, /* 010C(:997): DRD1A: *idx2 = idx7; FN=0 MORE init=0 WS=0 RS=0 */
4308 + 0x0000c728, /* 0110(:998): DRD1A: *idx1 = idx5; FN=0 init=0 WS=0 RS=0 */
4309 + 0x000001f8, /* 0114(:0): NOP */
4310 + 0x8118801b, /* 0118(:1002): LCD: idx1 = var2; idx1 once var0; idx1 += inc3 */
4311 + 0x8a19001b, /* 011C(:1004): LCD: idx2 = var20; idx2 once var0; idx2 += inc3 */
4312 + 0x6000000e, /* 0120(:1005): DRD2A: EU0=0 EU1=0 EU2=0 EU3=14 EXT init=0 WS=0 RS=0 */
4313 + 0x088cf49f, /* 0124(:1005): DRD2B1: idx2 = EU3(); EU3(var18) */
4314 + 0xd9190536, /* 0128(:1006): LCDEXT: idx2 = idx2; idx2 == var20; idx2 += inc6 */
4315 + 0x98ca0018, /* 012C(:1006): LCD: idx3 = idx1 + var20; idx3 once var0; idx3 += inc3 */
4316 + 0x6000000a, /* 0130(:1008): DRD2A: EU0=0 EU1=0 EU2=0 EU3=10 EXT init=0 WS=0 RS=0 */
4317 + 0x0cccfcdf, /* 0134(:1008): DRD2B1: *idx3 = EU3(); EU3(*idx3) */
4318 + 0x000001f8, /* 0138(:0): NOP */
4319 + 0xa14a001e, /* 013C(:1011): LCD: idx1 = *(var2 + var20 + 24); idx1 once var0; idx1 += inc3 */
4320 + 0x10000b08, /* 0140(:1012): DRD1A: var2 = idx1; FN=0 MORE init=0 WS=0 RS=0 */
4321 + 0x10002c90, /* 0144(:1013): DRD1A: var11 = var18; FN=0 MORE init=0 WS=0 RS=0 */
4322 + 0xb8ca0018, /* 0148(:1014): LCD: idx2 = *(idx1 + var20); idx2 once var0; idx2 += inc3 */
4323 + 0x10004b10, /* 014C(:1015): DRD1A: var18 = idx2; FN=0 MORE init=0 WS=0 RS=0 */
4324 + 0x70000009, /* 0150(:1016): DRD2A: EU0=0 EU1=0 EU2=0 EU3=9 EXT MORE init=0 WS=0 RS=0 */
4325 + 0x080cf89f, /* 0154(:1016): DRD2B1: idx0 = EU3(); EU3(idx2) */
4326 + 0x6000000c, /* 0158(:1017): DRD2A: EU0=0 EU1=0 EU2=0 EU3=12 EXT init=0 WS=0 RS=0 */
4327 + 0x024cf89f, /* 015C(:1017): DRD2B1: var9 = EU3(); EU3(idx2) */
4328 + 0x000001f8, /* 0160(:0): NOP */
4329 + 0x8a18801b, /* 0164(:1023): LCD: idx1 = var20; idx1 once var0; idx1 += inc3 */
4330 + 0x7000000d, /* 0168(:1024): DRD2A: EU0=0 EU1=0 EU2=0 EU3=13 EXT MORE init=0 WS=0 RS=0 */
4331 + 0x084cf2df, /* 016C(:1024): DRD2B1: idx1 = EU3(); EU3(var11) */
4332 + 0xd899053f, /* 0170(:1025): LCDEXT: idx2 = idx1; idx2 > var20; idx2 += inc7 */
4333 + 0x8019801b, /* 0174(:1025): LCD: idx3 = var0; idx3 once var0; idx3 += inc3 */
4334 + 0x040001f8, /* 0178(:1026): DRD1A: FN=0 INT init=0 WS=0 RS=0 */
4335 + 0x000001f8, /* 017C(:0): NOP */
4336 + 0x000001f8, /* 0180(:0): NOP */
4337 +};
4338 +u32 MCD_SingleEu_TDT[]=
4339 +{
4340 + 0x8318001b, /* 0000(:1204): LCD: idx0 = var6; idx0 once var0; idx0 += inc3 */
4341 + 0x7000000c, /* 0004(:1205): DRD2A: EU0=0 EU1=0 EU2=0 EU3=12 EXT MORE init=0 WS=0 RS=0 */
4342 + 0x080cf81f, /* 0008(:1205): DRD2B1: idx0 = EU3(); EU3(idx0) */
4343 + 0x8318801b, /* 000C(:1206): LCD: idx1 = var6; idx1 once var0; idx1 += inc3 */
4344 + 0x6000000d, /* 0010(:1207): DRD2A: EU0=0 EU1=0 EU2=0 EU3=13 EXT init=0 WS=0 RS=0 */
4345 + 0x084cf85f, /* 0014(:1207): DRD2B1: idx1 = EU3(); EU3(idx1) */
4346 + 0x000001f8, /* 0018(:0): NOP */
4347 + 0x8498001b, /* 001C(:1211): LCD: idx0 = var9; idx0 once var0; idx0 += inc3 */
4348 + 0x7000000c, /* 0020(:1212): DRD2A: EU0=0 EU1=0 EU2=0 EU3=12 EXT MORE init=0 WS=0 RS=0 */
4349 + 0x020cf81f, /* 0024(:1212): DRD2B1: var8 = EU3(); EU3(idx0) */
4350 + 0x6000000d, /* 0028(:1213): DRD2A: EU0=0 EU1=0 EU2=0 EU3=13 EXT init=0 WS=0 RS=0 */
4351 + 0x028cf81f, /* 002C(:1213): DRD2B1: var10 = EU3(); EU3(idx0) */
4352 + 0xc404601b, /* 0030(:1216): LCDEXT: idx0 = var8, idx1 = var8; ; idx0 += inc3, idx1 += inc3 */
4353 + 0xc00423dc, /* 0034(:1216): LCDEXT: idx2 = var0, idx3 = var8; idx3 == var15; idx2 += inc3, idx3 += inc4 */
4354 + 0x809a601b, /* 0038(:1217): LCD: idx4 = var1; ; idx4 += inc3 */
4355 + 0xc207a182, /* 003C(:1220): LCDEXT: idx5 = var4, idx6 = var15; idx6 < var6; idx5 += inc0, idx6 += inc2 */
4356 + 0x869be009, /* 0040(:1220): LCD: idx7 = var13; ; idx7 += inc1 */
4357 + 0x63fe0000, /* 0044(:1223): DRD2A: EU0=0 EU1=0 EU2=0 EU3=0 EXT init=31 WS=3 RS=3 */
4358 + 0x0d4cfddf, /* 0048(:1223): DRD2B1: *idx5 = EU3(); EU3(*idx7) */
4359 + 0xda9b001b, /* 004C(:1225): LCDEXT: idx5 = idx5, idx6 = idx6; idx5 once var0; idx5 += inc3, idx6 += inc3 */
4360 + 0x9b9be01b, /* 0050(:1225): LCD: idx7 = idx7; ; idx7 += inc3 */
4361 + 0x70000006, /* 0054(:1227): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4362 + 0x088cf890, /* 0058(:1227): DRD2B1: idx2 = EU3(); EU3(idx2,var16) */
4363 + 0x1000cb28, /* 005C(:1228): DRD1A: *idx2 = idx5; FN=0 MORE init=0 WS=0 RS=0 */
4364 + 0x70000006, /* 0060(:1229): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4365 + 0x088cf890, /* 0064(:1229): DRD2B1: idx2 = EU3(); EU3(idx2,var16) */
4366 + 0x1000cb30, /* 0068(:1230): DRD1A: *idx2 = idx6; FN=0 MORE init=0 WS=0 RS=0 */
4367 + 0x70000006, /* 006C(:1231): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4368 + 0x088cf890, /* 0070(:1231): DRD2B1: idx2 = EU3(); EU3(idx2,var16) */
4369 + 0x0000cb38, /* 0074(:1232): DRD1A: *idx2 = idx7; FN=0 init=0 WS=0 RS=0 */
4370 + 0x000001f8, /* 0078(:0): NOP */
4371 + 0xc404601b, /* 007C(:1236): LCDEXT: idx0 = var8, idx1 = var8; ; idx0 += inc3, idx1 += inc3 */
4372 + 0xc004245c, /* 0080(:1236): LCDEXT: idx2 = var0, idx3 = var8; idx3 == var17; idx2 += inc3, idx3 += inc4 */
4373 + 0x809a601b, /* 0084(:1237): LCD: idx4 = var1; ; idx4 += inc3 */
4374 + 0xda9b001b, /* 0088(:1240): LCDEXT: idx5 = idx5, idx6 = idx6; idx5 once var0; idx5 += inc3, idx6 += inc3 */
4375 + 0x9b9be01b, /* 008C(:1240): LCD: idx7 = idx7; ; idx7 += inc3 */
4376 + 0x0000d3a0, /* 0090(:1241): DRD1A: *idx4; FN=0 init=0 WS=0 RS=0 */
4377 + 0xc207a182, /* 0094(:1243): LCDEXT: idx5 = var4, idx6 = var15; idx6 < var6; idx5 += inc0, idx6 += inc2 */
4378 + 0x869be009, /* 0098(:1243): LCD: idx7 = var13; ; idx7 += inc1 */
4379 + 0x6bfe0000, /* 009C(:1246): DRD2A: EU0=0 EU1=0 EU2=0 EU3=0 TFD EXT init=31 WS=3 RS=3 */
4380 + 0x0d4cfddf, /* 00A0(:1246): DRD2B1: *idx5 = EU3(); EU3(*idx7) */
4381 + 0xda9b001b, /* 00A4(:1248): LCDEXT: idx5 = idx5, idx6 = idx6; idx5 once var0; idx5 += inc3, idx6 += inc3 */
4382 + 0x9b9be01b, /* 00A8(:1248): LCD: idx7 = idx7; ; idx7 += inc3 */
4383 + 0x70000006, /* 00AC(:1250): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4384 + 0x088cf890, /* 00B0(:1250): DRD2B1: idx2 = EU3(); EU3(idx2,var16) */
4385 + 0x1000cb28, /* 00B4(:1251): DRD1A: *idx2 = idx5; FN=0 MORE init=0 WS=0 RS=0 */
4386 + 0x70000006, /* 00B8(:1252): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4387 + 0x088cf890, /* 00BC(:1252): DRD2B1: idx2 = EU3(); EU3(idx2,var16) */
4388 + 0x1000cb30, /* 00C0(:1253): DRD1A: *idx2 = idx6; FN=0 MORE init=0 WS=0 RS=0 */
4389 + 0x70000006, /* 00C4(:1254): DRD2A: EU0=0 EU1=0 EU2=0 EU3=6 EXT MORE init=0 WS=0 RS=0 */
4390 + 0x088cf890, /* 00C8(:1254): DRD2B1: idx2 = EU3(); EU3(idx2,var16) */
4391 + 0x0000cb38, /* 00CC(:1255): DRD1A: *idx2 = idx7; FN=0 init=0 WS=0 RS=0 */
4392 + 0x000001f8, /* 00D0(:0): NOP */
4393 + 0xc51803ed, /* 00D4(:1259): LCDEXT: idx0 = var10; idx0 > var15; idx0 += inc5 */
4394 + 0x8018801b, /* 00D8(:1259): LCD: idx1 = var0; idx1 once var0; idx1 += inc3 */
4395 + 0x040001f8, /* 00DC(:1260): DRD1A: FN=0 INT init=0 WS=0 RS=0 */
4396 +};
4397 +#endif
4398 +u32 MCD_ENetRcv_TDT[]=
4399 +{
4400 + 0x80004000, /* 0000(:1334): LCDEXT: idx0 = 0x00000000; ; */
4401 + 0x82188000, /* 0004(:1334): LCD: idx1 = var4; idx1 once var0; idx1 += inc0 */
4402 + 0x10000788, /* 0008(:1335): DRD1A: var1 = *idx1; FN=0 MORE init=0 WS=0 RS=0 */
4403 + 0x60000009, /* 000C(:1336): DRD2A: EU0=0 EU1=0 EU2=0 EU3=9 EXT init=0 WS=0 RS=0 */
4404 + 0x080cf05f, /* 0010(:1336): DRD2B1: idx0 = EU3(); EU3(var1) */
4405 + 0x98180249, /* 0014(:1339): LCD: idx0 = idx0; idx0 != var9; idx0 += inc1 */
4406 + 0x82448004, /* 0018(:1341): LCD: idx1 = var4 + var9 + 4; idx1 once var0; idx1 += inc0 */
4407 + 0x7000000d, /* 001C(:1342): DRD2A: EU0=0 EU1=0 EU2=0 EU3=13 EXT MORE init=0 WS=0 RS=0 */
4408 + 0x014cf05f, /* 0020(:1342): DRD2B1: var5 = EU3(); EU3(var1) */
4409 + 0x7000000b, /* 0024(:1343): DRD2A: EU0=0 EU1=0 EU2=0 EU3=11 EXT MORE init=0 WS=0 RS=0 */
4410 + 0x020cf05f, /* 0028(:1343): DRD2B1: var8 = EU3(); EU3(var1) */
4411 + 0x70000004, /* 002C(:1344): DRD2A: EU0=0 EU1=0 EU2=0 EU3=4 EXT MORE init=0 WS=0 RS=0 */
4412 + 0x018cf04a, /* 0030(:1344): DRD2B1: var6 = EU3(); EU3(var1,var10) */
4413 + 0x70000004, /* 0034(:1345): DRD2A: EU0=0 EU1=0 EU2=0 EU3=4 EXT MORE init=0 WS=0 RS=0 */
4414 + 0x004cf04b, /* 0038(:1345): DRD2B1: var1 = EU3(); EU3(var1,var11) */
4415 + 0x00000b88, /* 003C(:1348): DRD1A: var2 = *idx1; FN=0 init=0 WS=0 RS=0 */
4416 + 0xc4838190, /* 0040(:1351): LCDEXT: idx1 = var9, idx2 = var7; idx1 < var6; idx1 += inc2, idx2 += inc0 */
4417 + 0x8119e012, /* 0044(:1351): LCD: idx3 = var2; ; idx3 += inc2 */
4418 + 0x03e0cf90, /* 0048(:1354): DRD1A: *idx3 = *idx2; FN=0 init=31 WS=0 RS=0 */
4419 + 0x81188000, /* 004C(:1357): LCD: idx1 = var2; idx1 once var0; idx1 += inc0 */
4420 + 0x000ac788, /* 0050(:1358): DRD1A: *idx1 = *idx1; FN=0 init=0 WS=1 RS=1 */
4421 + 0xc4838000, /* 0054(:1360): LCDEXT: idx1 = var9, idx2 = var7; idx1 once var0; idx1 += inc0, idx2 += inc0 */
4422 + 0x8219e000, /* 0058(:1360): LCD: idx3 = var4; ; idx3 += inc0 */
4423 + 0x70000004, /* 005C(:1368): DRD2A: EU0=0 EU1=0 EU2=0 EU3=4 EXT MORE init=0 WS=0 RS=0 */
4424 + 0x084cfc8c, /* 0060(:1368): DRD2B1: idx1 = EU3(); EU3(*idx2,var12) */
4425 + 0x60000005, /* 0064(:1371): DRD2A: EU0=0 EU1=0 EU2=0 EU3=5 EXT init=0 WS=0 RS=0 */
4426 + 0x0cccf841, /* 0068(:1371): DRD2B1: *idx3 = EU3(); EU3(idx1,var1) */
4427 + 0x82468000, /* 006C(:1377): LCD: idx1 = var4 + var13; idx1 once var0; idx1 += inc0 */
4428 + 0xc419025b, /* 0070(:1379): LCDEXT: idx2 = var8; idx2 > var9; idx2 += inc3 */
4429 + 0x80198000, /* 0074(:1379): LCD: idx3 = var0; idx3 once var0; idx3 += inc0 */
4430 + 0x00008400, /* 0078(:1380): DRD1A: idx1 = var0; FN=0 init=0 WS=0 RS=0 */
4431 + 0x00001308, /* 007C(:1381): DRD1A: var4 = idx1; FN=0 init=0 WS=0 RS=0 */
4432 + 0x82188000, /* 0080(:1384): LCD: idx1 = var4; idx1 once var0; idx1 += inc0 */
4433 + 0x10000788, /* 0084(:1385): DRD1A: var1 = *idx1; FN=0 MORE init=0 WS=0 RS=0 */
4434 + 0x60000009, /* 0088(:1386): DRD2A: EU0=0 EU1=0 EU2=0 EU3=9 EXT init=0 WS=0 RS=0 */
4435 + 0x080cf05f, /* 008C(:1386): DRD2B1: idx0 = EU3(); EU3(var1) */
4436 + 0xc2988249, /* 0090(:1389): LCDEXT: idx1 = var5; idx1 != var9; idx1 += inc1 */
4437 + 0x80190000, /* 0094(:1389): LCD: idx2 = var0; idx2 once var0; idx2 += inc0 */
4438 + 0x040001f8, /* 0098(:1390): DRD1A: FN=0 INT init=0 WS=0 RS=0 */
4439 + 0x000001f8, /* 009C(:0): NOP */
4440 +};
4441 +u32 MCD_ENetXmit_TDT[]=
4442 +{
4443 + 0x80004000, /* 0000(:1465): LCDEXT: idx0 = 0x00000000; ; */
4444 + 0x81988000, /* 0004(:1465): LCD: idx1 = var3; idx1 once var0; idx1 += inc0 */
4445 + 0x10000788, /* 0008(:1466): DRD1A: var1 = *idx1; FN=0 MORE init=0 WS=0 RS=0 */
4446 + 0x60000009, /* 000C(:1467): DRD2A: EU0=0 EU1=0 EU2=0 EU3=9 EXT init=0 WS=0 RS=0 */
4447 + 0x080cf05f, /* 0010(:1467): DRD2B1: idx0 = EU3(); EU3(var1) */
4448 + 0x98180309, /* 0014(:1470): LCD: idx0 = idx0; idx0 != var12; idx0 += inc1 */
4449 + 0x80004003, /* 0018(:1472): LCDEXT: idx1 = 0x00000003; ; */
4450 + 0x81c60004, /* 001C(:1472): LCD: idx2 = var3 + var12 + 4; idx2 once var0; idx2 += inc0 */
4451 + 0x7000000d, /* 0020(:1473): DRD2A: EU0=0 EU1=0 EU2=0 EU3=13 EXT MORE init=0 WS=0 RS=0 */
4452 + 0x014cf05f, /* 0024(:1473): DRD2B1: var5 = EU3(); EU3(var1) */
4453 + 0x7000000b, /* 0028(:1474): DRD2A: EU0=0 EU1=0 EU2=0 EU3=11 EXT MORE init=0 WS=0 RS=0 */
4454 + 0x028cf05f, /* 002C(:1474): DRD2B1: var10 = EU3(); EU3(var1) */
4455 + 0x7000000c, /* 0030(:1475): DRD2A: EU0=0 EU1=0 EU2=0 EU3=12 EXT MORE init=0 WS=0 RS=0 */
4456 + 0x018cf05f, /* 0034(:1475): DRD2B1: var6 = EU3(); EU3(var1) */
4457 + 0x70000004, /* 0038(:1476): DRD2A: EU0=0 EU1=0 EU2=0 EU3=4 EXT MORE init=0 WS=0 RS=0 */
4458 + 0x01ccf04d, /* 003C(:1476): DRD2B1: var7 = EU3(); EU3(var1,var13) */
4459 + 0x10000b90, /* 0040(:1477): DRD1A: var2 = *idx2; FN=0 MORE init=0 WS=0 RS=0 */
4460 + 0x60000004, /* 0044(:1478): DRD2A: EU0=0 EU1=0 EU2=0 EU3=4 EXT init=0 WS=0 RS=0 */
4461 + 0x020cf0a1, /* 0048(:1478): DRD2B1: var8 = EU3(); EU3(var2,idx1) */
4462 + 0xc3188312, /* 004C(:1481): LCDEXT: idx1 = var6; idx1 > var12; idx1 += inc2 */
4463 + 0x83c70000, /* 0050(:1481): LCD: idx2 = var7 + var14; idx2 once var0; idx2 += inc0 */
4464 + 0x00001f10, /* 0054(:1482): DRD1A: var7 = idx2; FN=0 init=0 WS=0 RS=0 */
4465 + 0xc583a3c3, /* 0058(:1484): LCDEXT: idx1 = var11, idx2 = var7; idx2 >= var15; idx1 += inc0, idx2 += inc3 */
4466 + 0x81042325, /* 005C(:1484): LCD: idx3 = var2, idx4 = var8; idx4 == var12; idx3 += inc4, idx4 += inc5 */
4467 + 0x03e0c798, /* 0060(:1489): DRD1A: *idx1 = *idx3; FN=0 init=31 WS=0 RS=0 */
4468 + 0xd8990000, /* 0064(:1492): LCDEXT: idx1 = idx1, idx2 = idx2; idx1 once var0; idx1 += inc0, idx2 += inc0 */
4469 + 0x9999e000, /* 0068(:1492): LCD: idx3 = idx3; ; idx3 += inc0 */
4470 + 0x000acf98, /* 006C(:1493): DRD1A: *idx3 = *idx3; FN=0 init=0 WS=1 RS=1 */
4471 + 0xd8992306, /* 0070(:1495): LCDEXT: idx1 = idx1, idx2 = idx2; idx2 > var12; idx1 += inc0, idx2 += inc6 */
4472 + 0x9999e03f, /* 0074(:1495): LCD: idx3 = idx3; ; idx3 += inc7 */
4473 + 0x03eac798, /* 0078(:1498): DRD1A: *idx1 = *idx3; FN=0 init=31 WS=1 RS=1 */
4474 + 0xd8990000, /* 007C(:1501): LCDEXT: idx1 = idx1, idx2 = idx2; idx1 once var0; idx1 += inc0, idx2 += inc0 */
4475 + 0x9999e000, /* 0080(:1501): LCD: idx3 = idx3; ; idx3 += inc0 */
4476 + 0x000acf98, /* 0084(:1502): DRD1A: *idx3 = *idx3; FN=0 init=0 WS=1 RS=1 */
4477 + 0xd8990000, /* 0088(:1504): LCDEXT: idx1 = idx1, idx2 = idx2; idx1 once var0; idx1 += inc0, idx2 += inc0 */
4478 + 0x99832302, /* 008C(:1504): LCD: idx3 = idx3, idx4 = var6; idx4 > var12; idx3 += inc0, idx4 += inc2 */
4479 + 0x0beac798, /* 0090(:1507): DRD1A: *idx1 = *idx3; FN=0 TFD init=31 WS=1 RS=1 */
4480 + 0x81988000, /* 0094(:1509): LCD: idx1 = var3; idx1 once var0; idx1 += inc0 */
4481 + 0x6000000a, /* 0098(:1510): DRD2A: EU0=0 EU1=0 EU2=0 EU3=10 EXT init=0 WS=0 RS=0 */
4482 + 0x0c4cfc5f, /* 009C(:1510): DRD2B1: *idx1 = EU3(); EU3(*idx1) */
4483 + 0x81c80000, /* 00A0(:1512): LCD: idx1 = var3 + var16; idx1 once var0; idx1 += inc0 */
4484 + 0xc5190312, /* 00A4(:1514): LCDEXT: idx2 = var10; idx2 > var12; idx2 += inc2 */
4485 + 0x80198000, /* 00A8(:1514): LCD: idx3 = var0; idx3 once var0; idx3 += inc0 */
4486 + 0x00008400, /* 00AC(:1515): DRD1A: idx1 = var0; FN=0 init=0 WS=0 RS=0 */
4487 + 0x00000f08, /* 00B0(:1516): DRD1A: var3 = idx1; FN=0 init=0 WS=0 RS=0 */
4488 + 0x81988000, /* 00B4(:1519): LCD: idx1 = var3; idx1 once var0; idx1 += inc0 */
4489 + 0x10000788, /* 00B8(:1520): DRD1A: var1 = *idx1; FN=0 MORE init=0 WS=0 RS=0 */
4490 + 0x60000009, /* 00BC(:1521): DRD2A: EU0=0 EU1=0 EU2=0 EU3=9 EXT init=0 WS=0 RS=0 */
4491 + 0x080cf05f, /* 00C0(:1521): DRD2B1: idx0 = EU3(); EU3(var1) */
4492 + 0xc2988309, /* 00C4(:1524): LCDEXT: idx1 = var5; idx1 != var12; idx1 += inc1 */
4493 + 0x80190000, /* 00C8(:1524): LCD: idx2 = var0; idx2 once var0; idx2 += inc0 */
4494 + 0x040001f8, /* 00CC(:1525): DRD1A: FN=0 INT init=0 WS=0 RS=0 */
4495 + 0x000001f8, /* 00D0(:0): NOP */
4496 +};
4497 +
4498 --- /dev/null
4499 +++ b/drivers/dma/MCD_tasksInit.c
4500 @@ -0,0 +1,284 @@
4501 +/*********************************************************************
4502 + *
4503 + * Copyright (C) 2004 Motorola, Inc.
4504 + * MOTOROLA, INC. All Rights Reserved.
4505 + * You are hereby granted a copyright license to use
4506 + * the SOFTWARE so long as this entire notice is
4507 + * retained without alteration in any modified and/or redistributed
4508 + * versions, and that such modified versions are clearly identified
4509 + * as such. No licenses are granted by implication, estoppel or
4510 + * otherwise under any patents or trademarks of Motorola, Inc. This
4511 + * software is provided on an "AS IS" basis and without warranty.
4512 + *
4513 + * To the maximum extent permitted by applicable law, MOTOROLA
4514 + * DISCLAIMS ALL WARRANTIES WHETHER EXPRESS OR IMPLIED, INCLUDING
4515 + * IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR
4516 + * PURPOSE AND ANY WARRANTY AGAINST INFRINGEMENT WITH REGARD TO THE
4517 + * SOFTWARE (INCLUDING ANY MODIFIED VERSIONS THEREOF) AND ANY
4518 + * ACCOMPANYING WRITTEN MATERIALS.
4519 + *
4520 + * To the maximum extent permitted by applicable law, IN NO EVENT
4521 + * SHALL MOTOROLA BE LIABLE FOR ANY DAMAGES WHATSOEVER (INCLUDING
4522 + * WITHOUT LIMITATION, DAMAGES FOR LOSS OF BUSINESS PROFITS, BUSINESS
4523 + * INTERRUPTION, LOSS OF BUSINESS INFORMATION, OR OTHER PECUNIARY
4524 + * LOSS) ARISING OF THE USE OR INABILITY TO USE THE SOFTWARE.
4525 + *
4526 + * Motorola assumes no responsibility for the maintenance and support
4527 + * of this software
4528 + ********************************************************************/
4529 +/*
4530 + * Do not edit!
4531 + */
4532 + /*
4533 + * File: MCD_tasksInit.c
4534 + * Purpose: Function for initialize variable tables of different
4535 + * types of tasks.
4536 + *
4537 + * Notes:
4538 + *
4539 + *
4540 + * Modifications:
4541 + *
4542 + *
4543 + */
4544 +
4545 +#include <asm/MCD_dma.h>
4546 +
4547 +extern dmaRegs *MCD_dmaBar;
4548 +
4549 +/*
4550 + * Task 0
4551 + */
4552 +
4553 +void MCD_startDmaChainNoEu(int *currBD, short srcIncr, short destIncr, int xferSize, short xferSizeIncr, int *cSave, volatile TaskTableEntry *taskTable, int channel)
4554 +{
4555 +
4556 + MCD_SET_VAR(taskTable+channel, 2, (u32)currBD); /* var[2] */
4557 + MCD_SET_VAR(taskTable+channel, 25, (u32)(0xe000 << 16) | (0xffff & srcIncr)); /* inc[1] */
4558 + MCD_SET_VAR(taskTable+channel, 24, (u32)(0xe000 << 16) | (0xffff & destIncr)); /* inc[0] */
4559 + MCD_SET_VAR(taskTable+channel, 19, (u32)xferSize); /* var[19] */
4560 + MCD_SET_VAR(taskTable+channel, 26, (u32)(0x2000 << 16) | (0xffff & xferSizeIncr)); /* inc[2] */
4561 + MCD_SET_VAR(taskTable+channel, 0, (u32)cSave); /* var[0] */
4562 + MCD_SET_VAR(taskTable+channel, 1, (u32)0x00000000); /* var[1] */
4563 + MCD_SET_VAR(taskTable+channel, 3, (u32)0x00000000); /* var[3] */
4564 + MCD_SET_VAR(taskTable+channel, 4, (u32)0x00000000); /* var[4] */
4565 + MCD_SET_VAR(taskTable+channel, 5, (u32)0x00000000); /* var[5] */
4566 + MCD_SET_VAR(taskTable+channel, 6, (u32)0x00000000); /* var[6] */
4567 + MCD_SET_VAR(taskTable+channel, 7, (u32)0x00000000); /* var[7] */
4568 + MCD_SET_VAR(taskTable+channel, 8, (u32)0x00000000); /* var[8] */
4569 + MCD_SET_VAR(taskTable+channel, 9, (u32)0x00000000); /* var[9] */
4570 + MCD_SET_VAR(taskTable+channel, 10, (u32)0x00000000); /* var[10] */
4571 + MCD_SET_VAR(taskTable+channel, 11, (u32)0x00000000); /* var[11] */
4572 + MCD_SET_VAR(taskTable+channel, 12, (u32)0x00000000); /* var[12] */
4573 + MCD_SET_VAR(taskTable+channel, 13, (u32)0x00000000); /* var[13] */
4574 + MCD_SET_VAR(taskTable+channel, 14, (u32)0x00000000); /* var[14] */
4575 + MCD_SET_VAR(taskTable+channel, 15, (u32)0x00000000); /* var[15] */
4576 + MCD_SET_VAR(taskTable+channel, 16, (u32)0x00000000); /* var[16] */
4577 + MCD_SET_VAR(taskTable+channel, 17, (u32)0x00000000); /* var[17] */
4578 + MCD_SET_VAR(taskTable+channel, 18, (u32)0x00000000); /* var[18] */
4579 + MCD_SET_VAR(taskTable+channel, 20, (u32)0x00000000); /* var[20] */
4580 + MCD_SET_VAR(taskTable+channel, 21, (u32)0x00000010); /* var[21] */
4581 + MCD_SET_VAR(taskTable+channel, 22, (u32)0x00000004); /* var[22] */
4582 + MCD_SET_VAR(taskTable+channel, 23, (u32)0x00000080); /* var[23] */
4583 + MCD_SET_VAR(taskTable+channel, 27, (u32)0x00000000); /* inc[3] */
4584 + MCD_SET_VAR(taskTable+channel, 28, (u32)0x60000000); /* inc[4] */
4585 + MCD_SET_VAR(taskTable+channel, 29, (u32)0x80000001); /* inc[5] */
4586 + MCD_SET_VAR(taskTable+channel, 30, (u32)0x80000000); /* inc[6] */
4587 + MCD_SET_VAR(taskTable+channel, 31, (u32)0x40000000); /* inc[7] */
4588 +
4589 + /* Set the task's Enable bit in its Task Control Register */
4590 + MCD_dmaBar->taskControl[channel] |= (u16)0x8000; /* add a MACRO HERE TBD*/
4591 +
4592 +
4593 +}
4594 +
4595 +
4596 +/*
4597 + * Task 1
4598 + */
4599 +
4600 +void MCD_startDmaSingleNoEu(char *srcAddr, short srcIncr, char *destAddr, short destIncr, int dmaSize, int dmaSizeMXferSize, short xferSizeIncr, int flags, int *currBD, int *cSave, volatile TaskTableEntry *taskTable, int channel)
4601 +{
4602 +
4603 + MCD_SET_VAR(taskTable+channel, 13, (u32)srcAddr); /* var[13] */
4604 + MCD_SET_VAR(taskTable+channel, 25, (u32)(0xe000 << 16) | (0xffff & srcIncr)); /* inc[1] */
4605 + MCD_SET_VAR(taskTable+channel, 4, (u32)destAddr); /* var[4] */
4606 + MCD_SET_VAR(taskTable+channel, 24, (u32)(0xe000 << 16) | (0xffff & destIncr)); /* inc[0] */
4607 + MCD_SET_VAR(taskTable+channel, 6, (u32)dmaSize); /* var[6] */
4608 + MCD_SET_VAR(taskTable+channel, 7, (u32)dmaSizeMXferSize); /* var[7] */
4609 + MCD_SET_VAR(taskTable+channel, 26, (u32)(0x2000 << 16) | (0xffff & xferSizeIncr)); /* inc[2] */
4610 + MCD_SET_VAR(taskTable+channel, 9, (u32)flags); /* var[9] */
4611 + MCD_SET_VAR(taskTable+channel, 1, (u32)currBD); /* var[1] */
4612 + MCD_SET_VAR(taskTable+channel, 0, (u32)cSave); /* var[0] */
4613 + MCD_SET_VAR(taskTable+channel, 2, (u32)0x00000000); /* var[2] */
4614 + MCD_SET_VAR(taskTable+channel, 3, (u32)0x00000000); /* var[3] */
4615 + MCD_SET_VAR(taskTable+channel, 5, (u32)0x00000000); /* var[5] */
4616 + MCD_SET_VAR(taskTable+channel, 8, (u32)0x00000000); /* var[8] */
4617 + MCD_SET_VAR(taskTable+channel, 10, (u32)0x00000000); /* var[10] */
4618 + MCD_SET_VAR(taskTable+channel, 11, (u32)0x00000000); /* var[11] */
4619 + MCD_SET_VAR(taskTable+channel, 12, (u32)0x00000000); /* var[12] */
4620 + MCD_SET_VAR(taskTable+channel, 14, (u32)0x00000000); /* var[14] */
4621 + MCD_SET_VAR(taskTable+channel, 15, (u32)0x00000000); /* var[15] */
4622 + MCD_SET_VAR(taskTable+channel, 16, (u32)0x00000004); /* var[16] */
4623 + MCD_SET_VAR(taskTable+channel, 17, (u32)0x00000080); /* var[17] */
4624 + MCD_SET_VAR(taskTable+channel, 27, (u32)0x00000000); /* inc[3] */
4625 + MCD_SET_VAR(taskTable+channel, 28, (u32)0x80000001); /* inc[4] */
4626 + MCD_SET_VAR(taskTable+channel, 29, (u32)0x40000000); /* inc[5] */
4627 +
4628 +
4629 + /* enable the task */
4630 + MCD_dmaBar->taskControl[channel] |= (u16)0x8000; /* add a MACRO HERE TBD*/
4631 +}
4632 +
4633 +
4634 +/*
4635 + * Task 2
4636 + */
4637 +
4638 +void MCD_startDmaChainEu(int *currBD, short srcIncr, short destIncr, int xferSize, short xferSizeIncr, int *cSave, volatile TaskTableEntry *taskTable, int channel)
4639 +{
4640 +
4641 + MCD_SET_VAR(taskTable+channel, 2, (u32)currBD); /* var[2] */
4642 + MCD_SET_VAR(taskTable+channel, 25, (u32)(0xe000 << 16) | (0xffff & srcIncr)); /* inc[1] */
4643 + MCD_SET_VAR(taskTable+channel, 24, (u32)(0xe000 << 16) | (0xffff & destIncr)); /* inc[0] */
4644 + MCD_SET_VAR(taskTable+channel, 19, (u32)xferSize); /* var[19] */
4645 + MCD_SET_VAR(taskTable+channel, 26, (u32)(0x2000 << 16) | (0xffff & xferSizeIncr)); /* inc[2] */
4646 + MCD_SET_VAR(taskTable+channel, 0, (u32)cSave); /* var[0] */
4647 + MCD_SET_VAR(taskTable+channel, 1, (u32)0x00000000); /* var[1] */
4648 + MCD_SET_VAR(taskTable+channel, 3, (u32)0x00000000); /* var[3] */
4649 + MCD_SET_VAR(taskTable+channel, 4, (u32)0x00000000); /* var[4] */
4650 + MCD_SET_VAR(taskTable+channel, 5, (u32)0x00000000); /* var[5] */
4651 + MCD_SET_VAR(taskTable+channel, 6, (u32)0x00000000); /* var[6] */
4652 + MCD_SET_VAR(taskTable+channel, 7, (u32)0x00000000); /* var[7] */
4653 + MCD_SET_VAR(taskTable+channel, 8, (u32)0x00000000); /* var[8] */
4654 + MCD_SET_VAR(taskTable+channel, 9, (u32)0x00000000); /* var[9] */
4655 + MCD_SET_VAR(taskTable+channel, 10, (u32)0x00000000); /* var[10] */
4656 + MCD_SET_VAR(taskTable+channel, 11, (u32)0x00000000); /* var[11] */
4657 + MCD_SET_VAR(taskTable+channel, 12, (u32)0x00000000); /* var[12] */
4658 + MCD_SET_VAR(taskTable+channel, 13, (u32)0x00000000); /* var[13] */
4659 + MCD_SET_VAR(taskTable+channel, 14, (u32)0x00000000); /* var[14] */
4660 + MCD_SET_VAR(taskTable+channel, 15, (u32)0x00000000); /* var[15] */
4661 + MCD_SET_VAR(taskTable+channel, 16, (u32)0x00000000); /* var[16] */
4662 + MCD_SET_VAR(taskTable+channel, 17, (u32)0x00000000); /* var[17] */
4663 + MCD_SET_VAR(taskTable+channel, 18, (u32)0x00000000); /* var[18] */
4664 + MCD_SET_VAR(taskTable+channel, 20, (u32)0x00000000); /* var[20] */
4665 + MCD_SET_VAR(taskTable+channel, 21, (u32)0x00000010); /* var[21] */
4666 + MCD_SET_VAR(taskTable+channel, 22, (u32)0x00000004); /* var[22] */
4667 + MCD_SET_VAR(taskTable+channel, 23, (u32)0x00000080); /* var[23] */
4668 + MCD_SET_VAR(taskTable+channel, 27, (u32)0x00000000); /* inc[3] */
4669 + MCD_SET_VAR(taskTable+channel, 28, (u32)0x60000000); /* inc[4] */
4670 + MCD_SET_VAR(taskTable+channel, 29, (u32)0x80000001); /* inc[5] */
4671 + MCD_SET_VAR(taskTable+channel, 30, (u32)0x80000000); /* inc[6] */
4672 + MCD_SET_VAR(taskTable+channel, 31, (u32)0x40000000); /* inc[7] */
4673 +
4674 + /*enable the task*/
4675 + MCD_dmaBar->taskControl[channel] |= (u16)0x8000; /* add a MACRO HERE TBD*/
4676 +}
4677 +
4678 +
4679 +/*
4680 + * Task 3
4681 + */
4682 +
4683 +void MCD_startDmaSingleEu(char *srcAddr, short srcIncr, char *destAddr, short destIncr, int dmaSize, int dmaSizeMXferSize, short xferSizeIncr, int flags, int *currBD, int *cSave, volatile TaskTableEntry *taskTable, int channel)
4684 +{
4685 +
4686 + MCD_SET_VAR(taskTable+channel, 13, (u32)srcAddr); /* var[13] */
4687 + MCD_SET_VAR(taskTable+channel, 25, (u32)(0xe000 << 16) | (0xffff & srcIncr)); /* inc[1] */
4688 + MCD_SET_VAR(taskTable+channel, 4, (u32)destAddr); /* var[4] */
4689 + MCD_SET_VAR(taskTable+channel, 24, (u32)(0xe000 << 16) | (0xffff & destIncr)); /* inc[0] */
4690 + MCD_SET_VAR(taskTable+channel, 6, (u32)dmaSize); /* var[6] */
4691 + MCD_SET_VAR(taskTable+channel, 7, (u32)dmaSizeMXferSize); /* var[7] */
4692 + MCD_SET_VAR(taskTable+channel, 26, (u32)(0x2000 << 16) | (0xffff & xferSizeIncr)); /* inc[2] */
4693 + MCD_SET_VAR(taskTable+channel, 9, (u32)flags); /* var[9] */
4694 + MCD_SET_VAR(taskTable+channel, 1, (u32)currBD); /* var[1] */
4695 + MCD_SET_VAR(taskTable+channel, 0, (u32)cSave); /* var[0] */
4696 + MCD_SET_VAR(taskTable+channel, 2, (u32)0x00000000); /* var[2] */
4697 + MCD_SET_VAR(taskTable+channel, 3, (u32)0x00000000); /* var[3] */
4698 + MCD_SET_VAR(taskTable+channel, 5, (u32)0x00000000); /* var[5] */
4699 + MCD_SET_VAR(taskTable+channel, 8, (u32)0x00000000); /* var[8] */
4700 + MCD_SET_VAR(taskTable+channel, 10, (u32)0x00000000); /* var[10] */
4701 + MCD_SET_VAR(taskTable+channel, 11, (u32)0x00000000); /* var[11] */
4702 + MCD_SET_VAR(taskTable+channel, 12, (u32)0x00000000); /* var[12] */
4703 + MCD_SET_VAR(taskTable+channel, 14, (u32)0x00000000); /* var[14] */
4704 + MCD_SET_VAR(taskTable+channel, 15, (u32)0x00000000); /* var[15] */
4705 + MCD_SET_VAR(taskTable+channel, 16, (u32)0x00000004); /* var[16] */
4706 + MCD_SET_VAR(taskTable+channel, 17, (u32)0x00000080); /* var[17] */
4707 + MCD_SET_VAR(taskTable+channel, 27, (u32)0x00000000); /* inc[3] */
4708 + MCD_SET_VAR(taskTable+channel, 28, (u32)0x80000001); /* inc[4] */
4709 + MCD_SET_VAR(taskTable+channel, 29, (u32)0x40000000); /* inc[5] */
4710 +
4711 + /*enable the task*/
4712 + MCD_dmaBar->taskControl[channel] |= (u16)0x8000; /* add a MACRO HERE TBD*/
4713 +
4714 +}
4715 +
4716 +
4717 +/*
4718 + * Task 4
4719 + */
4720 +
4721 +void MCD_startDmaENetRcv(char *bDBase, char *currBD, char *rcvFifoPtr, volatile TaskTableEntry *taskTable, int channel)
4722 +{
4723 +
4724 + MCD_SET_VAR(taskTable+channel, 0, (u32)bDBase); /* var[0] */
4725 + MCD_SET_VAR(taskTable+channel, 4, (u32)currBD); /* var[4] */
4726 + MCD_SET_VAR(taskTable+channel, 7, (u32)rcvFifoPtr); /* var[7] */
4727 + MCD_SET_VAR(taskTable+channel, 1, (u32)0x00000000); /* var[1] */
4728 + MCD_SET_VAR(taskTable+channel, 2, (u32)0x00000000); /* var[2] */
4729 + MCD_SET_VAR(taskTable+channel, 3, (u32)0x00000000); /* var[3] */
4730 + MCD_SET_VAR(taskTable+channel, 5, (u32)0x00000000); /* var[5] */
4731 + MCD_SET_VAR(taskTable+channel, 6, (u32)0x00000000); /* var[6] */
4732 + MCD_SET_VAR(taskTable+channel, 8, (u32)0x00000000); /* var[8] */
4733 + MCD_SET_VAR(taskTable+channel, 9, (u32)0x00000000); /* var[9] */
4734 + MCD_SET_VAR(taskTable+channel, 10, (u32)0x0000ffff); /* var[10] */
4735 + MCD_SET_VAR(taskTable+channel, 11, (u32)0x30000000); /* var[11] */
4736 + MCD_SET_VAR(taskTable+channel, 12, (u32)0x0fffffff); /* var[12] */
4737 + MCD_SET_VAR(taskTable+channel, 13, (u32)0x00000008); /* var[13] */
4738 + MCD_SET_VAR(taskTable+channel, 24, (u32)0x00000000); /* inc[0] */
4739 + MCD_SET_VAR(taskTable+channel, 25, (u32)0x60000000); /* inc[1] */
4740 + MCD_SET_VAR(taskTable+channel, 26, (u32)0x20000004); /* inc[2] */
4741 + MCD_SET_VAR(taskTable+channel, 27, (u32)0x40000000); /* inc[3] */
4742 + /*enable the task*/
4743 + MCD_dmaBar->taskControl[channel] |= (u16)0x8000; /* add a MACRO HERE TBD*/
4744 +
4745 +}
4746 +
4747 +
4748 +/*
4749 + * Task 5
4750 + */
4751 +
4752 +void MCD_startDmaENetXmit(char *bDBase, char *currBD, char *xmitFifoPtr, volatile TaskTableEntry *taskTable, int channel)
4753 +{
4754 +
4755 + MCD_SET_VAR(taskTable+channel, 0, (u32)bDBase); /* var[0] */
4756 + MCD_SET_VAR(taskTable+channel, 3, (u32)currBD); /* var[3] */
4757 + MCD_SET_VAR(taskTable+channel, 11, (u32)xmitFifoPtr); /* var[11] */
4758 + MCD_SET_VAR(taskTable+channel, 1, (u32)0x00000000); /* var[1] */
4759 + MCD_SET_VAR(taskTable+channel, 2, (u32)0x00000000); /* var[2] */
4760 + MCD_SET_VAR(taskTable+channel, 4, (u32)0x00000000); /* var[4] */
4761 + MCD_SET_VAR(taskTable+channel, 5, (u32)0x00000000); /* var[5] */
4762 + MCD_SET_VAR(taskTable+channel, 6, (u32)0x00000000); /* var[6] */
4763 + MCD_SET_VAR(taskTable+channel, 7, (u32)0x00000000); /* var[7] */
4764 + MCD_SET_VAR(taskTable+channel, 8, (u32)0x00000000); /* var[8] */
4765 + MCD_SET_VAR(taskTable+channel, 9, (u32)0x00000000); /* var[9] */
4766 + MCD_SET_VAR(taskTable+channel, 10, (u32)0x00000000); /* var[10] */
4767 + MCD_SET_VAR(taskTable+channel, 12, (u32)0x00000000); /* var[12] */
4768 + MCD_SET_VAR(taskTable+channel, 13, (u32)0x0000ffff); /* var[13] */
4769 + MCD_SET_VAR(taskTable+channel, 14, (u32)0xffffffff); /* var[14] */
4770 + MCD_SET_VAR(taskTable+channel, 15, (u32)0x00000004); /* var[15] */
4771 + MCD_SET_VAR(taskTable+channel, 16, (u32)0x00000008); /* var[16] */
4772 + MCD_SET_VAR(taskTable+channel, 24, (u32)0x00000000); /* inc[0] */
4773 + MCD_SET_VAR(taskTable+channel, 25, (u32)0x60000000); /* inc[1] */
4774 + MCD_SET_VAR(taskTable+channel, 26, (u32)0x40000000); /* inc[2] */
4775 + MCD_SET_VAR(taskTable+channel, 27, (u32)0xc000fffc); /* inc[3] */
4776 + MCD_SET_VAR(taskTable+channel, 28, (u32)0xe0000004); /* inc[4] */
4777 + MCD_SET_VAR(taskTable+channel, 29, (u32)0x80000000); /* inc[5] */
4778 + MCD_SET_VAR(taskTable+channel, 30, (u32)0x4000ffff); /* inc[6] */
4779 + MCD_SET_VAR(taskTable+channel, 31, (u32)0xe0000001); /* inc[7] */
4780 +
4781 + /*enable the task*/
4782 + MCD_dmaBar->taskControl[channel] |= (u16)0x8000; /* add a MACRO HERE TBD*/
4783 +
4784 +}
4785 --- /dev/null
4786 +++ b/drivers/dma/MCD_tasksInit.h
4787 @@ -0,0 +1,73 @@
4788 +/*********************************************************************
4789 + *
4790 + * Copyright (C) 2004 Motorola, Inc.
4791 + * MOTOROLA, INC. All Rights Reserved.
4792 + * You are hereby granted a copyright license to use
4793 + * the SOFTWARE so long as this entire notice is
4794 + * retained without alteration in any modified and/or redistributed
4795 + * versions, and that such modified versions are clearly identified
4796 + * as such. No licenses are granted by implication, estoppel or
4797 + * otherwise under any patents or trademarks of Motorola, Inc. This
4798 + * software is provided on an "AS IS" basis and without warranty.
4799 + *
4800 + * To the maximum extent permitted by applicable law, MOTOROLA
4801 + * DISCLAIMS ALL WARRANTIES WHETHER EXPRESS OR IMPLIED, INCLUDING
4802 + * IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR
4803 + * PURPOSE AND ANY WARRANTY AGAINST INFRINGEMENT WITH REGARD TO THE
4804 + * SOFTWARE (INCLUDING ANY MODIFIED VERSIONS THEREOF) AND ANY
4805 + * ACCOMPANYING WRITTEN MATERIALS.
4806 + *
4807 + * To the maximum extent permitted by applicable law, IN NO EVENT
4808 + * SHALL MOTOROLA BE LIABLE FOR ANY DAMAGES WHATSOEVER (INCLUDING
4809 + * WITHOUT LIMITATION, DAMAGES FOR LOSS OF BUSINESS PROFITS, BUSINESS
4810 + * INTERRUPTION, LOSS OF BUSINESS INFORMATION, OR OTHER PECUNIARY
4811 + * LOSS) ARISING OF THE USE OR INABILITY TO USE THE SOFTWARE.
4812 + *
4813 + * Motorola assumes no responsibility for the maintenance and support
4814 + * of this software
4815 + ********************************************************************/
4816 +#ifndef MCD_TSK_INIT_H
4817 +#define MCD_TSK_INIT_H 1
4818 +
4819 +/*
4820 + * Do not edit!
4821 + */
4822 +
4823 +
4824 +
4825 +/*
4826 + * Task 0
4827 + */
4828 +void MCD_startDmaChainNoEu(int *currBD, short srcIncr, short destIncr, int xferSize, short xferSizeIncr, int *cSave, volatile TaskTableEntry *taskTable, int channel);
4829 +
4830 +
4831 +/*
4832 + * Task 1
4833 + */
4834 +void MCD_startDmaSingleNoEu(char *srcAddr, short srcIncr, char *destAddr, short destIncr, int dmaSize, int dmaSizeMXferSize, short xferSizeIncr, int flags, int *currBD, int *cSave, volatile TaskTableEntry *taskTable, int channel);
4835 +
4836 +
4837 +/*
4838 + * Task 2
4839 + */
4840 +void MCD_startDmaChainEu(int *currBD, short srcIncr, short destIncr, int xferSize, short xferSizeIncr, int *cSave, volatile TaskTableEntry *taskTable, int channel);
4841 +
4842 +
4843 +/*
4844 + * Task 3
4845 + */
4846 +void MCD_startDmaSingleEu(char *srcAddr, short srcIncr, char *destAddr, short destIncr, int dmaSize, int dmaSizeMXferSize, short xferSizeIncr, int flags, int *currBD, int *cSave, volatile TaskTableEntry *taskTable, int channel);
4847 +
4848 +
4849 +/*
4850 + * Task 4
4851 + */
4852 +void MCD_startDmaENetRcv(char *bDBase, char *currBD, char *rcvFifoPtr, volatile TaskTableEntry *taskTable, int channel);
4853 +
4854 +
4855 +/*
4856 + * Task 5
4857 + */
4858 +void MCD_startDmaENetXmit(char *bDBase, char *currBD, char *xmitFifoPtr, volatile TaskTableEntry *taskTable, int channel);
4859 +
4860 +#endif /* MCD_TSK_INIT_H */
4861 --- a/drivers/dma/Makefile
4862 +++ b/drivers/dma/Makefile
4863 @@ -4,3 +4,5 @@ obj-$(CONFIG_INTEL_IOATDMA) += ioatdma.o
4864 ioatdma-objs := ioat.o ioat_dma.o ioat_dca.o
4865 obj-$(CONFIG_INTEL_IOP_ADMA) += iop-adma.o
4866 obj-$(CONFIG_FSL_DMA) += fsldma.o
4867 +obj-$(CONFIG_MCD_DMA) += mcddma.o
4868 +mcddma-objs := MCD_dmaApi.o MCD_tasks.o MCD_tasksInit.o
4869 --- a/drivers/net/Kconfig
4870 +++ b/drivers/net/Kconfig
4871 @@ -351,6 +351,8 @@ config MACB
4872
4873 source "drivers/net/arm/Kconfig"
4874
4875 +source "drivers/net/fec/Kconfig"
4876 +
4877 config AX88796
4878 tristate "ASIX AX88796 NE2000 clone support"
4879 depends on ARM || MIPS || SUPERH
4880 --- a/drivers/net/Makefile
4881 +++ b/drivers/net/Makefile
4882 @@ -226,6 +226,8 @@ obj-$(CONFIG_ENC28J60) += enc28j60.o
4883
4884 obj-$(CONFIG_MACB) += macb.o
4885
4886 +obj-$(CONFIG_FEC_548x) += fec/
4887 +
4888 obj-$(CONFIG_ARM) += arm/
4889 obj-$(CONFIG_DEV_APPLETALK) += appletalk/
4890 obj-$(CONFIG_TR) += tokenring/
4891 --- /dev/null
4892 +++ b/drivers/net/fec/Kconfig
4893 @@ -0,0 +1,25 @@
4894 +config FEC_548x
4895 + tristate "MCF547x/MCF548x Fast Ethernet Controller support"
4896 + depends on M547X_8X
4897 + help
4898 + The MCF547x and MCF548x have a built-in Fast Ethernet Controller.
4899 + Saying Y here will include support for this device in the kernel.
4900 +
4901 + To compile this driver as a module, choose M here: the module
4902 + will be called fecm.
4903 +
4904 +config FEC_548x_AUTO_NEGOTIATION
4905 + bool "Enable Auto-Negotiation"
4906 + depends on FEC_548x
4907 + help
4908 + This option enables the FEC to automatically detect the
4909 + half/full duplex mode and the network speed at initialization
4910 + If you want this, say Y.
4911 +
4912 +config FEC_548x_ENABLE_FEC2
4913 + bool "Enable the second FEC"
4914 + depends on FEC_548x
4915 + help
4916 + This enables the second FEC on the 547x/548x. If you want to use
4917 + it, say Y.
4918 +
4919 --- /dev/null
4920 +++ b/drivers/net/fec/Makefile
4921 @@ -0,0 +1,7 @@
4922 +#
4923 +# Makefile for the FEC ethernet driver
4924 +#
4925 +
4926 +obj-$(CONFIG_FEC_548x) += fecm.o
4927 +
4928 +fecm-objs := fec.o ks8721.o
4929 --- /dev/null
4930 +++ b/drivers/net/fec/fec.c
4931 @@ -0,0 +1,1375 @@
4932 +/*
4933 + * Performance and stability improvements: (C) Copyright 2008,
4934 + * Daniel Krueger, SYSTEC electronic GmbH
4935 + *
4936 + * Code crunched to get it to work on 2.6.24 -- FEC cleanup coming
4937 + * soon -- Kurt Mahan
4938 + *
4939 + */
4940 +#include <linux/module.h>
4941 +#include <linux/kernel.h>
4942 +#include <linux/string.h>
4943 +#include <linux/ptrace.h>
4944 +#include <linux/errno.h>
4945 +#include <linux/ioport.h>
4946 +#include <linux/slab.h>
4947 +#include <linux/interrupt.h>
4948 +#include <linux/pci.h>
4949 +#include <linux/init.h>
4950 +#include <linux/delay.h>
4951 +#include <linux/netdevice.h>
4952 +#include <linux/etherdevice.h>
4953 +#include <linux/skbuff.h>
4954 +#include <linux/spinlock.h>
4955 +#include <linux/workqueue.h>
4956 +#include <linux/bitops.h>
4957 +
4958 +#include <asm/coldfire.h>
4959 +#include <asm/mcfsim.h>
4960 +
4961 +#include <asm/dma.h>
4962 +#include <asm/MCD_dma.h>
4963 +#include <asm/m5485sram.h>
4964 +#include <asm/virtconvert.h>
4965 +#include <asm/irq.h>
4966 +
4967 +#include "fec.h"
4968 +#include "ks8721.h"
4969 +
4970 +#ifdef CONFIG_FEC_548x_ENABLE_FEC2
4971 +#define FEC_MAX_PORTS 2
4972 +#define FEC_2
4973 +#else
4974 +#define FEC_MAX_PORTS 1
4975 +#undef FEC_2
4976 +#endif
4977 +
4978 +#define VERSION "0.13"
4979 +MODULE_DESCRIPTION( "DMA Fast Ethernet Controller driver ver " VERSION);
4980 +
4981 +// Private structure
4982 +struct fec_priv {
4983 + struct net_device *netdev; /* owning net device */
4984 + void* fecpriv_txbuf[FEC_TX_BUF_NUMBER]; //Array of transmission buffers
4985 + MCD_bufDescFec *fecpriv_txdesc; // Array of transmission descriptors
4986 + volatile unsigned int fecpriv_current_tx; // Inex of the transmission descriptor that is used by DMA
4987 + volatile unsigned int fecpriv_next_tx; // Inex of the transmission descriptor that can be used for new data
4988 + unsigned int fecpriv_current_rx; // Index of the reception descriptor that is used by DMA
4989 + MCD_bufDescFec *fecpriv_rxdesc; // Array of reception descriptors
4990 +// unsigned char *fecpriv_rxbuf; // Address of reception buffers
4991 + struct sk_buff *askb_rx[FEC_RX_BUF_NUMBER]; // Array of reception skb structure pointers
4992 + unsigned int fecpriv_initiator_rx; // Reception DMA initiator
4993 + unsigned int fecpriv_initiator_tx; // Transmission DMA initiator
4994 + int fecpriv_fec_rx_channel; // DMA reception channel
4995 + int fecpriv_fec_tx_channel; // DMA transmission channel
4996 + int fecpriv_rx_requestor; // DMA reception requestor
4997 + int fecpriv_tx_requestor; // DMA transmission requestor
4998 + void *fecpriv_interrupt_fec_rx_handler; // DMA reception handler
4999 + void *fecpriv_interrupt_fec_tx_handler; // DMA transmission handler
5000 + unsigned char *fecpriv_mac_addr; // Private copy of FEC address
5001 + struct net_device_stats fecpriv_stat; // Pointer to the statistical information
5002 + spinlock_t fecpriv_lock;
5003 + int fecpriv_rxflag;
5004 + struct tasklet_struct fecpriv_tasklet_reinit;
5005 + int index;
5006 +};
5007 +
5008 +struct net_device *fec_dev[FEC_MAX_PORTS];
5009 +
5010 +// FEC functions
5011 +int __init fec_init(void);
5012 +struct net_device_stats *fec_get_stat(struct net_device *dev);
5013 +
5014 +int fec_open(struct net_device *dev);
5015 +int fec_close(struct net_device *nd);
5016 +int fec_tx(struct sk_buff *skb, struct net_device *dev);
5017 +void fec_set_multicast_list(struct net_device *nd);
5018 +int fec_set_mac_address(struct net_device *dev, void *p);
5019 +void fec_tx_timeout(struct net_device *dev);
5020 +void fec_interrupt_fec_tx_handler(struct net_device *dev);
5021 +void fec_interrupt_fec_rx_handler(struct net_device *dev);
5022 +irqreturn_t fec_interrupt_handler(int irq, void *dev_id);
5023 +void fec_interrupt_fec_tx_handler_fec0(void);
5024 +void fec_interrupt_fec_rx_handler_fec0(void);
5025 +void fec_interrupt_fec_reinit(unsigned long data);
5026 +
5027 +unsigned char fec_mac_addr_fec0[6] = { 0x00, 0x11, 0x22, 0x33, 0x44, 0x50 }; // Default address of FEC0
5028 +
5029 +#ifdef FEC_2
5030 +unsigned char fec_mac_addr_fec1[6] = { 0x00, 0x11, 0x22, 0x33, 0x44, 0x51 }; // Default address of FEC1
5031 +#endif
5032 +
5033 +#ifndef MODULE
5034 +int fec_str_to_mac( char *str_mac, unsigned char* addr);
5035 +int __init fec_mac_setup0 (char *s);
5036 +#endif
5037 +
5038 +
5039 +#ifdef FEC_2
5040 +void fec_interrupt_fec_tx_handler_fec1(void);
5041 +void fec_interrupt_fec_rx_handler_fec1(void);
5042 +
5043 +#ifndef MODULE
5044 +int __init fec_mac_setup1 (char *s);
5045 +#endif
5046 +
5047 +#endif
5048 +int fec_read_mii(unsigned int base_addr, unsigned int pa, unsigned int ra, unsigned int *data);
5049 +int fec_write_mii(unsigned int base_addr, unsigned int pa, unsigned int ra, unsigned int data);
5050 +
5051 +module_init(fec_init);
5052 +/* module_exit(fec_cleanup); */
5053 +__setup("mac0=", fec_mac_setup0);
5054 +
5055 +#ifdef FEC_2
5056 +__setup("mac1=", fec_mac_setup1);
5057 +#endif
5058 +
5059 +/*
5060 + * Initialize a FEC device
5061 + */
5062 +int fec_enet_init(struct net_device *dev)
5063 +{
5064 + static int index = 0;
5065 + struct fec_priv *fp = netdev_priv(dev);
5066 + int i;
5067 +
5068 + fp->index = index;
5069 + fp->netdev = dev;
5070 + fec_dev[ index ] = dev;
5071 +printk(KERN_INFO "FEI: index=%d\n", index);
5072 +
5073 + if (index == 0) {
5074 + /* disable fec0 */
5075 + FEC_ECR(FEC_BASE_ADDR_FEC0) = FEC_ECR_DISABLE;
5076 +
5077 + /* setup the interrupt handler */
5078 + dev->irq = 64 + ISC_FEC0;
5079 +
5080 + if (request_irq(dev->irq, fec_interrupt_handler,
5081 + IRQF_DISABLED, "ColdFire FEC 0", dev)) {
5082 + dev->irq = 0;
5083 + printk("Cannot allocate FEC0 IRQ\n");
5084 + } else {
5085 + /* interrupt priority and level */
5086 + MCF_ICR(ISC_FEC0) = ILP_FEC0;
5087 + }
5088 +
5089 + /* fec base address */
5090 + dev->base_addr = FEC_BASE_ADDR_FEC0;
5091 +
5092 + /* requestor numbers */
5093 + fp->fecpriv_rx_requestor = DMA_FEC0_RX;
5094 + fp->fecpriv_tx_requestor = DMA_FEC0_TX;
5095 +
5096 + /* fec0 handlers */
5097 + fp->fecpriv_interrupt_fec_rx_handler = fec_interrupt_fec_rx_handler_fec0;
5098 + fp->fecpriv_interrupt_fec_tx_handler = fec_interrupt_fec_tx_handler_fec0;
5099 +
5100 + /* tx descriptors */
5101 + fp->fecpriv_txdesc = (void*)FEC_TX_DESC_FEC0;
5102 +
5103 + /* rx descriptors */
5104 + fp->fecpriv_rxdesc = (void*)FEC_RX_DESC_FEC0;
5105 +
5106 +printk(KERN_INFO "FEI: txdesc=0x%p rxdesc=0x%p\n", fp->fecpriv_txdesc, fp->fecpriv_rxdesc);
5107 +
5108 + /* mac addr */
5109 + fp->fecpriv_mac_addr = fec_mac_addr_fec0;
5110 + }
5111 + else {
5112 + /* disable fec1 */
5113 + FEC_ECR(FEC_BASE_ADDR_FEC1) = FEC_ECR_DISABLE;
5114 +#ifdef FEC_2
5115 + /* setup the interrupt handler */
5116 + dev->irq = 64 + ISC_FEC1;
5117 +
5118 + if (request_irq(dev->irq, fec_interrupt_handler,
5119 + IRQF_DISABLED, "ColdFire FEC 1", dev)) {
5120 + dev->irq = 0;
5121 + printk("Cannot allocate FEC1 IRQ\n");
5122 + } else {
5123 + /* interrupt priority and level */
5124 + MCF_ICR(ISC_FEC1) = ILP_FEC1;
5125 + }
5126 +
5127 + /* fec base address */
5128 + dev->base_addr = FEC_BASE_ADDR_FEC1;
5129 +
5130 + /* requestor numbers */
5131 + fp->fecpriv_rx_requestor = DMA_FEC1_RX;
5132 + fp->fecpriv_tx_requestor = DMA_FEC1_TX;
5133 +
5134 + /* fec1 handlers */
5135 + fp->fecpriv_interrupt_fec_rx_handler = fec_interrupt_fec_rx_handler_fec1;
5136 + fp->fecpriv_interrupt_fec_tx_handler = fec_interrupt_fec_tx_handler_fec1;
5137 +
5138 + /* tx descriptors */
5139 + fp->fecpriv_txdesc = (void*)FEC_TX_DESC_FEC1;
5140 +
5141 + /* rx descriptors */
5142 + fp->fecpriv_rxdesc = (void*)FEC_RX_DESC_FEC1;
5143 +
5144 + /* mac addr */
5145 + fp->fecpriv_mac_addr = fec_mac_addr_fec1;
5146 +#endif
5147 + }
5148 +
5149 +printk(KERN_INFO "FEI: index=%d base_addr=0x%lx\n", index, dev->base_addr);
5150 +
5151 + /* clear MIB */
5152 + memset((void *) (dev->base_addr + 0x200), 0, FEC_MIB_LEN);
5153 +
5154 + /* clear the statistics structure */
5155 + memset((void *) &(fp->fecpriv_stat), 0,
5156 + sizeof(struct net_device_stats));
5157 +
5158 + /* grab the FEC initiators */
5159 + dma_set_initiator(fp->fecpriv_tx_requestor);
5160 + fp->fecpriv_initiator_tx = dma_get_initiator(fp->fecpriv_tx_requestor);
5161 + dma_set_initiator(fp->fecpriv_rx_requestor);
5162 + fp->fecpriv_initiator_rx = dma_get_initiator(fp->fecpriv_rx_requestor);
5163 +
5164 + /* reset the DMA channels */
5165 + fp->fecpriv_fec_rx_channel = -1;
5166 + fp->fecpriv_fec_tx_channel = -1;
5167 +
5168 + for (i = 0; i < FEC_RX_BUF_NUMBER; i++)
5169 + fp->askb_rx[i] = NULL;
5170 +
5171 + /* initialize the pointers to the socket buffers */
5172 + for (i = 0; i < FEC_TX_BUF_NUMBER; i++)
5173 + fp->fecpriv_txbuf[i] = NULL;
5174 +
5175 + ether_setup(dev);
5176 +
5177 + dev->open = fec_open;
5178 + dev->stop = fec_close;
5179 + dev->hard_start_xmit = fec_tx;
5180 + dev->get_stats = fec_get_stat;
5181 + dev->set_multicast_list = fec_set_multicast_list;
5182 + dev->set_mac_address = fec_set_mac_address;
5183 + dev->tx_timeout = fec_tx_timeout;
5184 + dev->watchdog_timeo = FEC_TX_TIMEOUT * HZ;
5185 +
5186 + memcpy(dev->dev_addr, fp->fecpriv_mac_addr, ETH_ALEN);
5187 +
5188 + spin_lock_init(&fp->fecpriv_lock);
5189 +
5190 + // Initialize FEC/I2C/IRQ Pin Assignment Register
5191 + FEC_GPIO_PAR_FECI2CIRQ &= 0xF;
5192 + FEC_GPIO_PAR_FECI2CIRQ |= FEC_FECI2CIRQ;
5193 +
5194 + index++;
5195 + return 0;
5196 +}
5197 +
5198 +/*
5199 + * Module Initialization
5200 + */
5201 +int __init fec_init(void)
5202 +{
5203 + struct net_device *dev;
5204 + int i;
5205 + int err;
5206 + DECLARE_MAC_BUF(mac);
5207 +
5208 + printk(KERN_INFO "FEC ENET (DMA) Version .00\n");
5209 +
5210 +
5211 + for (i = 0; i < FEC_MAX_PORTS; i++) {
5212 + dev = alloc_etherdev(sizeof(struct fec_priv));
5213 + if (!dev)
5214 + return -ENOMEM;
5215 + err = fec_enet_init(dev);
5216 + if (err) {
5217 + free_netdev(dev);
5218 + continue;
5219 + }
5220 + if (register_netdev(dev) != 0) {
5221 + free_netdev(dev);
5222 + return -EIO;
5223 + }
5224 +
5225 + printk(KERN_INFO "%s: ethernet %s\n",
5226 + dev->name, print_mac(mac, dev->dev_addr));
5227 + }
5228 + return 0;
5229 +}
5230 +
5231 +/*
5232 + * Stop a device
5233 + */
5234 +void fec_stop(struct net_device *dev)
5235 +{
5236 + struct fec_priv *fp = netdev_priv(dev);
5237 +
5238 + dma_remove_initiator(fp->fecpriv_initiator_tx);
5239 + dma_remove_initiator(fp->fecpriv_initiator_rx);
5240 +
5241 + if (dev->irq)
5242 + free_irq(dev->irq, dev);
5243 +}
5244 +
5245 +/************************************************************************
5246 +* NAME: fec_open
5247 +*
5248 +* DESCRIPTION: This function performs the initialization of
5249 +* of FEC and corresponding KS8721 transiver
5250 +*
5251 +* RETURNS: If no error occurs, this function returns zero.
5252 +*************************************************************************/
5253 +
5254 +int fec_open(struct net_device *dev)
5255 +{
5256 + struct fec_priv *fp = netdev_priv(dev);
5257 + unsigned long base_addr = (unsigned long) dev->base_addr;
5258 + int fduplex;
5259 + int i;
5260 + int channel;
5261 + int error_code = -EBUSY;
5262 +
5263 +printk(KERN_INFO "FECOPEN: index=%d\n", fp->index);
5264 +
5265 + //Receive the DMA channels
5266 + channel = dma_set_channel_fec(fp->fecpriv_rx_requestor);
5267 +
5268 + if (channel == -1)
5269 + {
5270 + printk("Dma channel cannot be reserved\n");
5271 + goto ERRORS;
5272 + }
5273 +
5274 + fp->fecpriv_fec_rx_channel = channel;
5275 +
5276 + dma_connect(channel, (int) fp->fecpriv_interrupt_fec_rx_handler);
5277 +
5278 + channel = dma_set_channel_fec(fp->fecpriv_tx_requestor);
5279 +
5280 + if (channel == -1)
5281 + {
5282 + printk("Dma channel cannot be reserved\n");
5283 + goto ERRORS;
5284 + }
5285 +printk(KERN_INFO "FECOPEN2\n");
5286 +
5287 + fp->fecpriv_fec_tx_channel = channel;
5288 +
5289 + dma_connect(channel, (int) fp->fecpriv_interrupt_fec_tx_handler);
5290 +
5291 + // init tasklet for controller reinitialization
5292 + tasklet_init(&fp->fecpriv_tasklet_reinit, fec_interrupt_fec_reinit, (unsigned long) dev);
5293 +printk(KERN_INFO "FECOPEN3\n");
5294 +
5295 + // Reset FIFOs
5296 + FEC_FECFRST(base_addr) |= FEC_SW_RST | FEC_RST_CTL;
5297 + FEC_FECFRST(base_addr) &= ~FEC_SW_RST;
5298 +
5299 + // Reset and disable FEC
5300 + FEC_ECR(base_addr) = FEC_ECR_RESET;
5301 +
5302 + // Wait
5303 + udelay(10);
5304 +
5305 + // Clear all events
5306 + FEC_EIR(base_addr) = FEC_EIR_CLEAR;
5307 +
5308 + // Reset FIFO status
5309 + FEC_FECTFSR(base_addr) = FEC_FECTFSR_MSK;
5310 + FEC_FECRFSR(base_addr) = FEC_FECRFSR_MSK;
5311 +
5312 +#if 0
5313 +/* JKM -- move into HW init */
5314 + // Copy the default address to the device structure
5315 + memcpy(dev->dev_addr, fp->fecpriv_mac_addr, ETH_ALEN);
5316 +#endif
5317 +
5318 + // Set the default address
5319 + FEC_PALR(base_addr) = (fp->fecpriv_mac_addr[0] << 24) | (fp->fecpriv_mac_addr[1] << 16) | (fp->fecpriv_mac_addr[2] << 8) | fp->fecpriv_mac_addr[3];
5320 + FEC_PAUR(base_addr) = (fp->fecpriv_mac_addr[4] << 24) | (fp->fecpriv_mac_addr[5] << 16) | 0x8808;
5321 +
5322 + // Reset the group address descriptor
5323 + FEC_GALR(base_addr) = 0x00000000;
5324 + FEC_GAUR(base_addr) = 0x00000000;
5325 +
5326 + // Reset the individual address descriptor
5327 + FEC_IALR(base_addr) = 0x00000000;
5328 + FEC_IAUR(base_addr) = 0x00000000;
5329 +
5330 + // Set the receive control register
5331 + FEC_RCR(base_addr) = FEC_RCR_MAX_FRM_SIZE | FEC_RCR_MII;
5332 +
5333 + // Set the receive FIFO control register
5334 +// FEC_FECRFCR(base_addr) = FEC_FECRFCR_FRM | FEC_FECRFCR_GR | FEC_FECRFCR_MSK;
5335 + FEC_FECRFCR(base_addr) = FEC_FECRFCR_FRM | FEC_FECRFCR_GR
5336 + | (FEC_FECRFCR_MSK // disable all but ...
5337 + & ~FEC_FECRFCR_FAE // enable frame accept error
5338 + & ~FEC_FECRFCR_RXW // enable receive wait condition
5339 +// & ~FEC_FECRFCR_UF // enable FIFO underflow
5340 + );
5341 +
5342 + //Set the receive FIFO alarm register
5343 + FEC_FECRFAR(base_addr) = FEC_FECRFAR_ALARM;
5344 +
5345 + // Set the transmit FIFO control register
5346 +// FEC_FECTFCR(base_addr) = FEC_FECTFCR_FRM | FEC_FECTFCR_GR | FEC_FECTFCR_MSK;
5347 + FEC_FECTFCR(base_addr) = FEC_FECTFCR_FRM | FEC_FECTFCR_GR
5348 + | (FEC_FECTFCR_MSK // disable all but ...
5349 + & ~FEC_FECTFCR_FAE // enable frame accept error
5350 +// & ~FEC_FECTFCR_TXW // enable transmit wait condition
5351 +// & ~FEC_FECTFCR_UF // enable FIFO underflow
5352 + & ~FEC_FECTFCR_OF); // enable FIFO overflow
5353 +
5354 + //Set the transmit FIFO alarm register
5355 + FEC_FECTFAR(base_addr) = FEC_FECTFAR_ALARM;
5356 +
5357 + // Set the Tx FIFO watermark
5358 + FEC_FECTFWR(base_addr) = FEC_FECTFWR_XWMRK;
5359 +
5360 + // Enable the transmitter to append the CRC
5361 + FEC_CTCWR(base_addr) = FEC_CTCWR_TFCW_CRC;
5362 +
5363 + // Enable the ethernet interrupts
5364 +// FEC_EIMR(base_addr) = FEC_EIMR_MASK;
5365 + FEC_EIMR(base_addr) = FEC_EIMR_DISABLE
5366 + | FEC_EIR_LC
5367 + | FEC_EIR_RL
5368 + | FEC_EIR_HBERR
5369 + | FEC_EIR_XFUN
5370 + | FEC_EIR_XFERR
5371 + | FEC_EIR_RFERR
5372 + ;
5373 +printk(KERN_INFO "FECOPEN4\n");
5374 +
5375 +#ifdef CONFIG_FEC_548x_AUTO_NEGOTIATION
5376 + if ((error_code = init_transceiver(base_addr, &fduplex)) != 0)
5377 + {
5378 + printk("Initialization of the transceiver is failed\n");
5379 + goto ERRORS;
5380 + }
5381 +#else
5382 + fduplex = 1;
5383 +#endif
5384 +printk(KERN_INFO "FECOPEN5\n");
5385 +
5386 + if (fduplex)
5387 + // Enable the full duplex mode
5388 + FEC_TCR(base_addr) = FEC_TCR_FDEN | FEC_TCR_HBC;
5389 + else
5390 + // Disable reception of frames while transmitting
5391 + FEC_RCR(base_addr) |= FEC_RCR_DRT;
5392 +
5393 + // Enable MIB
5394 + FEC_MIBC(base_addr) = FEC_MIBC_ENABLE;
5395 +
5396 + // Enable FEC
5397 + FEC_ECR(base_addr) |= FEC_ECR_ETHEREN;
5398 +
5399 + // Initialize transmission descriptors and start DMA for the transmission
5400 + for (i = 0; i < FEC_TX_BUF_NUMBER; i++)
5401 + fp->fecpriv_txdesc[i].statCtrl = MCD_FEC_INTERRUPT;
5402 +printk(KERN_INFO "FECOPEN6\n");
5403 +
5404 + fp->fecpriv_txdesc[i - 1].statCtrl |= MCD_FEC_WRAP;
5405 +
5406 + fp->fecpriv_current_tx = fp->fecpriv_next_tx = 0;
5407 +
5408 + MCD_startDma(fp->fecpriv_fec_tx_channel, (char *) fp->fecpriv_txdesc, 0,
5409 + (unsigned char *) &(FEC_FECTFDR(base_addr)), 0,
5410 + FEC_MAX_FRM_SIZE, 0, fp->fecpriv_initiator_tx,
5411 + FEC_TX_DMA_PRI, MCD_FECTX_DMA | MCD_INTERRUPT,
5412 + MCD_NO_CSUM | MCD_NO_BYTE_SWAP);
5413 +
5414 + // Initialize reception descriptors and start DMA for the reception
5415 + for (i = 0; i < FEC_RX_BUF_NUMBER; i++)
5416 + {
5417 + fp->askb_rx[i] = alloc_skb(FEC_MAXBUF_SIZE + 16, GFP_DMA);
5418 + if (!fp->askb_rx[i])
5419 + {
5420 + fp->fecpriv_rxdesc[i].dataPointer = 0;
5421 + fp->fecpriv_rxdesc[i].statCtrl = 0;
5422 + fp->fecpriv_rxdesc[i].length = 0;
5423 + }
5424 + else
5425 + {
5426 + skb_reserve(fp->askb_rx[i], 16);
5427 + fp->askb_rx[i]->dev = dev;
5428 + fp->fecpriv_rxdesc[i].dataPointer = (unsigned int) virt_to_phys(fp->askb_rx[i]->tail);
5429 + fp->fecpriv_rxdesc[i].statCtrl = MCD_FEC_BUF_READY | MCD_FEC_INTERRUPT;
5430 + fp->fecpriv_rxdesc[i].length = FEC_MAXBUF_SIZE;
5431 + }
5432 + }
5433 +printk(KERN_INFO "FECOPEN7\n");
5434 +
5435 + fp->fecpriv_rxdesc[i - 1].statCtrl |= MCD_FEC_WRAP;
5436 + fp->fecpriv_current_rx = 0;
5437 +
5438 + // flush entire data cache before restarting the DMA
5439 +#if 0
5440 +/* JKM -- currently running with cache turned off */
5441 + DcacheFlushInvalidate();
5442 +#endif
5443 +
5444 + MCD_startDma(fp->fecpriv_fec_rx_channel, (char *) fp->fecpriv_rxdesc, 0,
5445 + (unsigned char *) &(FEC_FECRFDR(base_addr)), 0,
5446 + FEC_MAX_FRM_SIZE, 0, fp->fecpriv_initiator_rx,
5447 + FEC_RX_DMA_PRI, MCD_FECRX_DMA | MCD_INTERRUPT,
5448 + MCD_NO_CSUM | MCD_NO_BYTE_SWAP);
5449 +
5450 + netif_start_queue(dev);
5451 +
5452 +// MOD_INC_USE_COUNT;
5453 +printk(KERN_INFO "FECOPEN: finished\n");
5454 +
5455 + return 0;
5456 +
5457 +ERRORS:
5458 +
5459 + // Remove the channels and return with the error code
5460 + if (fp->fecpriv_fec_rx_channel != -1)
5461 + {
5462 + dma_disconnect(fp->fecpriv_fec_rx_channel);
5463 + dma_remove_channel_by_number(fp->fecpriv_fec_rx_channel);
5464 + fp->fecpriv_fec_rx_channel = -1;
5465 + }
5466 +
5467 + if (fp->fecpriv_fec_tx_channel != -1)
5468 + {
5469 + dma_disconnect(fp->fecpriv_fec_tx_channel);
5470 + dma_remove_channel_by_number(fp->fecpriv_fec_tx_channel);
5471 + fp->fecpriv_fec_tx_channel = -1;
5472 + }
5473 +
5474 + return error_code;
5475 +
5476 +}
5477 +
5478 +/************************************************************************
5479 +* NAME: fec_close
5480 +*
5481 +* DESCRIPTION: This function performs the graceful stop of the
5482 +* transmission and disables FEC
5483 +*
5484 +* RETURNS: This function always returns zero.
5485 +*************************************************************************/
5486 +int fec_close(struct net_device *dev)
5487 +{
5488 + //Receive the pointer to the private structure
5489 + struct fec_priv *fp = netdev_priv(dev);
5490 +
5491 + // Receive the base address
5492 + unsigned long base_addr = (unsigned long) dev->base_addr;
5493 +
5494 + unsigned long time;
5495 +
5496 + int i;
5497 +
5498 + netif_stop_queue(dev);
5499 +
5500 + // Perform the graceful stop
5501 + FEC_TCR(base_addr) |= FEC_TCR_GTS;
5502 +
5503 + time = jiffies;
5504 +
5505 + // Wait for the graceful stop
5506 + while (!(FEC_EIR(base_addr) & FEC_EIR_GRA) && jiffies - time < FEC_GR_TIMEOUT * HZ)
5507 + schedule();
5508 +
5509 + // Disable FEC
5510 + FEC_ECR(base_addr) = FEC_ECR_DISABLE;
5511 +
5512 + // Reset the DMA channels
5513 + spin_lock_irq(&fp->fecpriv_lock);
5514 + MCD_killDma(fp->fecpriv_fec_tx_channel);
5515 + spin_unlock_irq(&fp->fecpriv_lock);
5516 + dma_remove_channel_by_number(fp->fecpriv_fec_tx_channel);
5517 + dma_disconnect(fp->fecpriv_fec_tx_channel);
5518 + fp->fecpriv_fec_tx_channel = -1;
5519 +
5520 + for (i = 0; i < FEC_TX_BUF_NUMBER; i++)
5521 + if (fp->fecpriv_txbuf[i])
5522 + {
5523 + kfree(fp->fecpriv_txbuf[i]);
5524 + fp->fecpriv_txbuf[i] = NULL;
5525 + }
5526 +
5527 + spin_lock_irq(&fp->fecpriv_lock);
5528 + MCD_killDma(fp->fecpriv_fec_rx_channel);
5529 + spin_unlock_irq(&fp->fecpriv_lock);
5530 +
5531 + dma_remove_channel_by_number(fp->fecpriv_fec_rx_channel);
5532 + dma_disconnect(fp->fecpriv_fec_rx_channel);
5533 + fp->fecpriv_fec_rx_channel = -1;
5534 +
5535 + for (i = 0; i < FEC_RX_BUF_NUMBER; i++)
5536 + {
5537 + if (fp->askb_rx[i])
5538 + {
5539 + kfree_skb(fp->askb_rx[i]);
5540 + fp->askb_rx[i] = NULL;
5541 + }
5542 + }
5543 +// MOD_DEC_USE_COUNT;
5544 +
5545 + return 0;
5546 +}
5547 +
5548 +/************************************************************************
5549 +* +NAME: fec_get_stat
5550 +*
5551 +* RETURNS: This function returns the statistical information.
5552 +*************************************************************************/
5553 +struct net_device_stats * fec_get_stat(struct net_device *dev)
5554 +{
5555 +
5556 + //Receive the pointer to the private structure
5557 + struct fec_priv *fp = netdev_priv(dev);
5558 +
5559 + // Receive the base address
5560 + unsigned long base_addr = dev->base_addr;
5561 +
5562 + // Receive the statistical information
5563 + fp->fecpriv_stat.rx_packets = FECSTAT_RMON_R_PACKETS(base_addr);
5564 + fp->fecpriv_stat.tx_packets = FECSTAT_RMON_T_PACKETS(base_addr);
5565 + fp->fecpriv_stat.rx_bytes = FECSTAT_RMON_R_OCTETS(base_addr);
5566 + fp->fecpriv_stat.tx_bytes = FECSTAT_RMON_T_OCTETS(base_addr);
5567 +
5568 + fp->fecpriv_stat.multicast = FECSTAT_RMON_R_MC_PKT(base_addr);
5569 + fp->fecpriv_stat.collisions = FECSTAT_RMON_T_COL(base_addr);
5570 +
5571 + fp->fecpriv_stat.rx_length_errors = FECSTAT_RMON_R_UNDERSIZE(base_addr) + FECSTAT_RMON_R_OVERSIZE(base_addr) + FECSTAT_RMON_R_FRAG(base_addr) + FECSTAT_RMON_R_JAB(base_addr);
5572 + fp->fecpriv_stat.rx_crc_errors = FECSTAT_IEEE_R_CRC(base_addr);
5573 + fp->fecpriv_stat.rx_frame_errors = FECSTAT_IEEE_R_ALIGN(base_addr);
5574 + fp->fecpriv_stat.rx_over_errors = FECSTAT_IEEE_R_MACERR(base_addr);
5575 +
5576 + fp->fecpriv_stat.tx_carrier_errors = FECSTAT_IEEE_T_CSERR(base_addr);
5577 + fp->fecpriv_stat.tx_fifo_errors = FECSTAT_IEEE_T_MACERR(base_addr);
5578 + fp->fecpriv_stat.tx_window_errors = FECSTAT_IEEE_T_LCOL(base_addr);
5579 +
5580 + // I hope that one frame doesn't have more than one error
5581 + fp->fecpriv_stat.rx_errors = fp->fecpriv_stat.rx_length_errors + fp->fecpriv_stat.rx_crc_errors + fp->fecpriv_stat.rx_frame_errors + fp->fecpriv_stat.rx_over_errors + fp->fecpriv_stat.rx_dropped;
5582 + fp->fecpriv_stat.tx_errors = fp->fecpriv_stat.tx_carrier_errors + fp->fecpriv_stat.tx_fifo_errors + fp->fecpriv_stat.tx_window_errors + fp->fecpriv_stat.tx_aborted_errors + fp->fecpriv_stat.tx_heartbeat_errors + fp->fecpriv_stat.tx_dropped;
5583 +
5584 + return &fp->fecpriv_stat;
5585 +}
5586 +
5587 +/************************************************************************
5588 +* NAME: fec_set_multicast_list
5589 +*
5590 +* DESCRIPTION: This function sets the frame filtering parameters
5591 +*************************************************************************/
5592 +void fec_set_multicast_list(struct net_device *dev)
5593 +{
5594 + // Pointer to the address list
5595 + struct dev_mc_list *dmi;
5596 +
5597 + unsigned int crc, data;
5598 + int i, j, k;
5599 +
5600 + // Receive the base address
5601 + unsigned long base_addr = (unsigned long) dev->base_addr;
5602 +
5603 + if (dev->flags & IFF_PROMISC || dev->flags & IFF_ALLMULTI)
5604 + {
5605 + // Allow all incoming frames
5606 + FEC_GALR(base_addr) = 0xFFFFFFFF;
5607 + FEC_GAUR(base_addr) = 0xFFFFFFFF;
5608 + return;
5609 + }
5610 + // Reset the group address register
5611 + FEC_GALR(base_addr) = 0x00000000;
5612 + FEC_GAUR(base_addr) = 0x00000000;
5613 +
5614 + // Process all addresses
5615 + for (i = 0, dmi = dev->mc_list; i < dev->mc_count; i++, dmi = dmi->next)
5616 + {
5617 + // Processing must be only for the group addresses
5618 + if (!(dmi->dmi_addr[0] & 1))
5619 + continue;
5620 +
5621 + // Calculate crc value for the current address
5622 + crc = 0xFFFFFFFF;
5623 + for (j = 0; j < dmi->dmi_addrlen; j++)
5624 + {
5625 +
5626 + for (k = 0, data = dmi->dmi_addr[j]; k < 8; k++, data >>= 1)
5627 + {
5628 + if ((crc ^ data) & 1)
5629 + crc = (crc >> 1) ^ FEC_CRCPOL;
5630 + else
5631 + crc >>= 1;
5632 +
5633 + }
5634 +
5635 + }
5636 +
5637 + // Add this value
5638 + crc >>= 26;
5639 + crc &= 0x3F;
5640 + if (crc > 31)
5641 + FEC_GAUR(base_addr) |= 0x1 << (crc - 32);
5642 + else
5643 + FEC_GALR(base_addr) |= 0x1 << crc;
5644 +
5645 + }
5646 +
5647 +}
5648 +
5649 +/************************************************************************
5650 +* NAME: fec_set_mac_address
5651 +*
5652 +* DESCRIPTION: This function sets the MAC address
5653 +*************************************************************************/
5654 +int fec_set_mac_address(struct net_device *dev, void *p)
5655 +{
5656 + //Receive the pointer to the private structure
5657 + struct fec_priv *fp = netdev_priv(dev);
5658 +
5659 + // Receive the base address
5660 + unsigned long base_addr = (unsigned long) dev->base_addr;
5661 +
5662 + struct sockaddr *addr = p;
5663 +
5664 + if (netif_running(dev))
5665 + return -EBUSY;
5666 +
5667 + // Copy a new address to the device structure
5668 + memcpy(dev->dev_addr, addr->sa_data, dev->addr_len);
5669 +
5670 + // Copy a new address to the private structure
5671 + memcpy(fp->fecpriv_mac_addr, addr->sa_data, 6);
5672 +
5673 + // Set the address to the registers
5674 + FEC_PALR(base_addr) = (fp->fecpriv_mac_addr[0] << 24) | (fp->fecpriv_mac_addr[1] << 16) | (fp->fecpriv_mac_addr[2] << 8) | fp->fecpriv_mac_addr[3];
5675 + FEC_PAUR(base_addr) = (fp->fecpriv_mac_addr[4] << 24) | (fp->fecpriv_mac_addr[5] << 16) | 0x8808;
5676 +
5677 + return 0;
5678 +}
5679 +
5680 +/************************************************************************
5681 +* NAME: fec_tx
5682 +*
5683 +* DESCRIPTION: This function starts transmission of the frame using DMA
5684 +*
5685 +* RETURNS: This function always returns zero.
5686 +*************************************************************************/
5687 +int fec_tx(struct sk_buff *skb, struct net_device *dev)
5688 +{
5689 +
5690 + //Receive the pointer to the private structure
5691 + struct fec_priv *fp = netdev_priv(dev);
5692 +
5693 + void *data, *data_aligned;
5694 + int offset;
5695 +
5696 +printk(KERN_INFO "fec_tx\n");
5697 + data = kmalloc(skb->len + 15, GFP_DMA | GFP_ATOMIC);
5698 +
5699 + if (!data)
5700 + {
5701 + fp->fecpriv_stat.tx_dropped++;
5702 + dev_kfree_skb(skb);
5703 + return 0;
5704 + }
5705 +
5706 + offset = (((unsigned long)virt_to_phys(data) + 15) & 0xFFFFFFF0) - (unsigned long)virt_to_phys(data);
5707 + data_aligned = (void*)((unsigned long)data + offset);
5708 + memcpy(data_aligned, skb->data, skb->len);
5709 +
5710 + // flush data cache before initializing the descriptor and starting DMA
5711 +#if 0
5712 +/* JKM -- currently running with cache turned off */
5713 + DcacheFlushInvalidateCacheBlock((void*)virt_to_phys(data_aligned), skb->len);
5714 +#endif
5715 +
5716 + spin_lock_irq(&fp->fecpriv_lock);
5717 +
5718 + // Initialize the descriptor
5719 + fp->fecpriv_txbuf[fp->fecpriv_next_tx] = data;
5720 + fp->fecpriv_txdesc[fp->fecpriv_next_tx].dataPointer = (unsigned int) virt_to_phys(data_aligned);
5721 + fp->fecpriv_txdesc[fp->fecpriv_next_tx].length = skb->len;
5722 + fp->fecpriv_txdesc[fp->fecpriv_next_tx].statCtrl |= (MCD_FEC_END_FRAME | MCD_FEC_BUF_READY);
5723 + fp->fecpriv_next_tx = (fp->fecpriv_next_tx + 1) & FEC_TX_INDEX_MASK;
5724 +
5725 + if (fp->fecpriv_txbuf[fp->fecpriv_current_tx] && fp->fecpriv_current_tx == fp->fecpriv_next_tx)
5726 + netif_stop_queue(dev);
5727 +
5728 + spin_unlock_irq(&fp->fecpriv_lock);
5729 +
5730 + // Tell the DMA to continue the transmission
5731 + MCD_continDma(fp->fecpriv_fec_tx_channel);
5732 +
5733 + dev_kfree_skb(skb);
5734 +
5735 + dev->trans_start = jiffies;
5736 +
5737 + return 0;
5738 +}
5739 +
5740 +/************************************************************************
5741 +* NAME: fec_tx_timeout
5742 +*
5743 +* DESCRIPTION: If the interrupt processing of received frames was lost
5744 +* and DMA stopped the reception, this function clears
5745 +* the transmission descriptors and starts DMA
5746 +*
5747 +*************************************************************************/
5748 +void fec_tx_timeout(struct net_device *dev)
5749 +{
5750 + int i;
5751 + struct fec_priv *fp = netdev_priv(dev);
5752 + unsigned long base_addr = (unsigned long) dev->base_addr;
5753 +
5754 +printk(KERN_INFO "fec_tx_timeout\n");
5755 + spin_lock_irq(&fp->fecpriv_lock);
5756 + MCD_killDma(fp->fecpriv_fec_tx_channel);
5757 + for (i = 0; i < FEC_TX_BUF_NUMBER; i++)
5758 + {
5759 + if (fp->fecpriv_txbuf[i])
5760 + {
5761 +
5762 + kfree(fp->fecpriv_txbuf[i]);
5763 + fp->fecpriv_txbuf[i] = NULL;
5764 +
5765 + }
5766 + fp->fecpriv_txdesc[i].statCtrl = MCD_FEC_INTERRUPT;
5767 + }
5768 + fp->fecpriv_txdesc[i - 1].statCtrl |= MCD_FEC_WRAP;
5769 +
5770 + fp->fecpriv_current_tx = fp->fecpriv_next_tx = 0;
5771 +
5772 + // Reset FIFOs
5773 + FEC_FECFRST(base_addr) |= FEC_SW_RST;
5774 + FEC_FECFRST(base_addr) &= ~FEC_SW_RST;
5775 +
5776 + // Reset and disable FEC
5777 +// FEC_ECR(base_addr) = FEC_ECR_RESET;
5778 +
5779 + // Enable FEC
5780 + FEC_ECR(base_addr) |= FEC_ECR_ETHEREN;
5781 +
5782 + MCD_startDma(fp->fecpriv_fec_tx_channel, (char *) fp->fecpriv_txdesc, 0,
5783 + (unsigned char *) &(FEC_FECTFDR(base_addr)), 0,
5784 + FEC_MAX_FRM_SIZE, 0, fp->fecpriv_initiator_tx,
5785 + FEC_TX_DMA_PRI, MCD_FECTX_DMA | MCD_INTERRUPT,
5786 + MCD_NO_CSUM | MCD_NO_BYTE_SWAP);
5787 +
5788 + spin_unlock_irq(&fp->fecpriv_lock);
5789 +
5790 + netif_wake_queue(dev);
5791 +
5792 +}
5793 +
5794 +/************************************************************************
5795 +* NAME: fec_read_mii
5796 +*
5797 +* DESCRIPTION: This function reads the value from the MII register
5798 +*
5799 +* RETURNS: If no error occurs, this function returns zero.
5800 +*************************************************************************/
5801 +int fec_read_mii(unsigned int base_addr, unsigned int pa, unsigned int ra, unsigned int *data)
5802 +{
5803 + unsigned long time;
5804 +
5805 + // Clear the MII interrupt bit
5806 + FEC_EIR(base_addr) = FEC_EIR_MII;
5807 +
5808 + // Write to the MII management frame register
5809 + FEC_MMFR(base_addr) = FEC_MMFR_READ | (pa << 23) | (ra << 18);
5810 +
5811 + time = jiffies;
5812 +
5813 + // Wait for the reading
5814 + while (!(FEC_EIR(base_addr) & FEC_EIR_MII))
5815 + {
5816 + if (jiffies - time > FEC_MII_TIMEOUT * HZ)
5817 + return -ETIME;
5818 + schedule();
5819 + }
5820 +
5821 + // Clear the MII interrupt bit
5822 + FEC_EIR(base_addr) = FEC_EIR_MII;
5823 +
5824 + *data = FEC_MMFR(base_addr) & 0x0000FFFF;
5825 +
5826 + return 0;
5827 +}
5828 +
5829 +/************************************************************************
5830 +* NAME: fec_write_mii
5831 +*
5832 +* DESCRIPTION: This function writes the value to the MII register
5833 +*
5834 +* RETURNS: If no error occurs, this function returns zero.
5835 +*************************************************************************/
5836 +int fec_write_mii(unsigned int base_addr, unsigned int pa, unsigned int ra, unsigned int data)
5837 +{
5838 + unsigned long time;
5839 +
5840 + // Clear the MII interrupt bit
5841 + FEC_EIR(base_addr) = FEC_EIR_MII;
5842 +
5843 + // Write to the MII management frame register
5844 + FEC_MMFR(base_addr) = FEC_MMFR_WRITE | (pa << 23) | (ra << 18) | data;
5845 +
5846 + time = jiffies;
5847 +
5848 + // Wait for the writing
5849 +
5850 + while (!(FEC_EIR(base_addr) & FEC_EIR_MII))
5851 + {
5852 + if (jiffies - time > FEC_MII_TIMEOUT * HZ)
5853 + return -ETIME;
5854 +
5855 + schedule();
5856 + }
5857 +
5858 + // Clear the MII interrupt bit
5859 + FEC_EIR(base_addr) = FEC_EIR_MII;
5860 +
5861 + return 0;
5862 +}
5863 +
5864 +/************************************************************************
5865 +* NAME: fec_interrupt_tx_handler
5866 +*
5867 +* DESCRIPTION: This function is called when the data
5868 +* transmission from the buffer to the FEC is completed.
5869 +*
5870 +*************************************************************************/
5871 +void fec_interrupt_fec_tx_handler(struct net_device *dev)
5872 +{
5873 + struct fec_priv *fp = netdev_priv(dev);
5874 +
5875 +printk(KERN_INFO "fectxint\n");
5876 + //Release the socket buffer
5877 + if(fp->fecpriv_txbuf[fp->fecpriv_current_tx])
5878 + {
5879 + kfree(fp->fecpriv_txbuf[fp->fecpriv_current_tx]);
5880 + fp->fecpriv_txbuf[fp->fecpriv_current_tx] = NULL;
5881 + }
5882 + fp->fecpriv_current_tx = (fp->fecpriv_current_tx + 1) & FEC_TX_INDEX_MASK;
5883 +
5884 + if (MCD_dmaStatus(fp->fecpriv_fec_tx_channel) == MCD_DONE)
5885 + for (; fp->fecpriv_current_tx != fp->fecpriv_next_tx; fp->fecpriv_current_tx = (fp->fecpriv_current_tx + 1) & FEC_TX_INDEX_MASK)
5886 + {
5887 + if(fp->fecpriv_txbuf[fp->fecpriv_current_tx])
5888 + {
5889 + kfree(fp->fecpriv_txbuf[fp->fecpriv_current_tx]);
5890 + fp->fecpriv_txbuf[fp->fecpriv_current_tx] = NULL;
5891 + }
5892 + }
5893 +
5894 + if (netif_queue_stopped(dev))
5895 + netif_wake_queue(dev);
5896 +
5897 +}
5898 +
5899 +/************************************************************************
5900 +* NAME: fec_interrupt_rx_handler
5901 +*
5902 +* DESCRIPTION: This function is called when the data
5903 +* reception from the FEC to the reception buffer is completed.
5904 +*
5905 +*************************************************************************/
5906 +void fec_interrupt_fec_rx_handler(struct net_device *dev)
5907 +{
5908 + struct fec_priv *fp = netdev_priv(dev);
5909 + struct sk_buff *skb;
5910 +
5911 +printk(KERN_INFO "fecrxint\n");
5912 + fp->fecpriv_rxflag = 1;
5913 +/*
5914 + // Some buffers can be missed
5915 + if(!(fp->fecpriv_rxdesc[fp->fecpriv_current_rx].statCtrl & MCD_FEC_END_FRAME))
5916 + {
5917 + // Find a valid index
5918 + for(i = 0; i < FEC_RX_BUF_NUMBER && !(fp->fecpriv_rxdesc[fp->fecpriv_current_rx].statCtrl & MCD_FEC_END_FRAME); i++, fp->fecpriv_current_rx = (fp->fecpriv_current_rx + 1) & FEC_RX_INDEX_MASK);
5919 +
5920 + if(i == FEC_RX_BUF_NUMBER)
5921 + {
5922 + // There are no data to process
5923 + // Tell the DMA to continue the reception
5924 + MCD_continDma(fp->fecpriv_fec_rx_channel);
5925 +
5926 + fp->fecpriv_rxflag = 0;
5927 +
5928 + return;
5929 + }
5930 + }
5931 +*/
5932 + for (; fp->fecpriv_rxdesc[fp->fecpriv_current_rx].statCtrl & MCD_FEC_END_FRAME; fp->fecpriv_current_rx = (fp->fecpriv_current_rx + 1) & FEC_RX_INDEX_MASK)
5933 + {
5934 + if( (fp->fecpriv_rxdesc[fp->fecpriv_current_rx].length <= FEC_MAXBUF_SIZE) &&
5935 + (fp->fecpriv_rxdesc[fp->fecpriv_current_rx].length > 4)) // --tym--
5936 + {
5937 + skb = fp->askb_rx[fp->fecpriv_current_rx];
5938 + if (!skb)
5939 + {
5940 + fp->fecpriv_stat.rx_dropped++;
5941 + }
5942 + else
5943 + {
5944 + // flush data cache before initializing the descriptor and starting DMA
5945 +// DcacheFlushInvalidateCacheBlock((void*)virt_to_phys(fp->askb_rx[fp->fecpriv_current_rx]->tail), fp->askb_rx[fp->fecpriv_current_rx]->len);
5946 +
5947 + skb_put(skb, fp->fecpriv_rxdesc[fp->fecpriv_current_rx].length - 4);
5948 +// skb->dev = dev;
5949 + skb->protocol = eth_type_trans(skb, dev);
5950 + netif_rx(skb);
5951 + }
5952 + fp->fecpriv_rxdesc[fp->fecpriv_current_rx].statCtrl &= ~MCD_FEC_END_FRAME;
5953 + // allocate new skbuff
5954 + fp->askb_rx[fp->fecpriv_current_rx] = alloc_skb(FEC_MAXBUF_SIZE + 16, /*GFP_ATOMIC |*/ GFP_DMA);
5955 + if (!fp->askb_rx[fp->fecpriv_current_rx])
5956 + {
5957 + fp->fecpriv_rxdesc[fp->fecpriv_current_rx].dataPointer = 0;
5958 + fp->fecpriv_rxdesc[fp->fecpriv_current_rx].length = 0;
5959 + fp->fecpriv_stat.rx_dropped++;
5960 + }
5961 + else
5962 + {
5963 + skb_reserve(fp->askb_rx[fp->fecpriv_current_rx], 16);
5964 + fp->askb_rx[fp->fecpriv_current_rx]->dev = dev;
5965 +
5966 + // flush data cache before initializing the descriptor and starting DMA
5967 +#if 0
5968 +/* JKM -- currently running with cache turned off */
5969 + DcacheFlushInvalidateCacheBlock((void*)virt_to_phys(fp->askb_rx[fp->fecpriv_current_rx]->tail), FEC_MAXBUF_SIZE);
5970 +#endif
5971 +
5972 + fp->fecpriv_rxdesc[fp->fecpriv_current_rx].dataPointer = (unsigned int) virt_to_phys(fp->askb_rx[fp->fecpriv_current_rx]->tail);
5973 + fp->fecpriv_rxdesc[fp->fecpriv_current_rx].length = FEC_MAXBUF_SIZE;
5974 + fp->fecpriv_rxdesc[fp->fecpriv_current_rx].statCtrl |= MCD_FEC_BUF_READY;
5975 +
5976 + // flush data cache before initializing the descriptor and starting DMA
5977 +// DcacheFlushInvalidateCacheBlock((void*)virt_to_phys(fp->askb_rx[fp->fecpriv_current_rx]->tail), FEC_MAXBUF_SIZE);
5978 + }
5979 + }
5980 +
5981 + }
5982 +
5983 + // Tell the DMA to continue the reception
5984 + MCD_continDma(fp->fecpriv_fec_rx_channel);
5985 +
5986 + fp->fecpriv_rxflag = 0;
5987 +
5988 +}
5989 +
5990 +/************************************************************************
5991 +* NAME: fec_interrupt_handler
5992 +*
5993 +* DESCRIPTION: This function is called when some special errors occur
5994 +*
5995 +*************************************************************************/
5996 +irqreturn_t fec_interrupt_handler(int irq, void *dev_id)
5997 +{
5998 +
5999 + struct net_device *dev = (struct net_device *)dev_id;
6000 + struct fec_priv *fp = netdev_priv(dev);
6001 + unsigned long base_addr = (unsigned long) dev->base_addr;
6002 + unsigned long events;
6003 +
6004 +printk(KERN_INFO "fecerrint\n");
6005 + // Read and clear the events
6006 + events = FEC_EIR(base_addr) & FEC_EIMR(base_addr);
6007 +
6008 + if (events & FEC_EIR_HBERR)
6009 + {
6010 + fp->fecpriv_stat.tx_heartbeat_errors++;
6011 + FEC_EIR(base_addr) = FEC_EIR_HBERR;
6012 + }
6013 +
6014 + // receive/transmit FIFO error
6015 + if (((events & FEC_EIR_RFERR) != 0) || ((events & FEC_EIR_XFERR) != 0))
6016 + {
6017 + // kill DMA receive channel
6018 + MCD_killDma (fp->fecpriv_fec_rx_channel);
6019 + // kill running transmission by DMA
6020 + MCD_killDma (fp->fecpriv_fec_tx_channel);
6021 +
6022 + // Reset FIFOs
6023 + FEC_FECFRST(base_addr) |= FEC_SW_RST;
6024 + FEC_FECFRST(base_addr) &= ~FEC_SW_RST;
6025 +
6026 + // reset receive FIFO status register
6027 + FEC_FECRFSR(base_addr) = FEC_FECRFSR_FAE
6028 + | FEC_FECRFSR_RXW
6029 + | FEC_FECRFSR_UF;
6030 +
6031 + // reset transmit FIFO status register
6032 + FEC_FECTFSR(base_addr) = FEC_FECTFSR_FAE
6033 + | FEC_FECTFSR_TXW
6034 + | FEC_FECTFSR_UF
6035 + | FEC_FECTFSR_OF;
6036 +
6037 + // reset RFERR and XFERR event
6038 + FEC_EIR(base_addr) = FEC_EIR_RFERR | FEC_EIR_XFERR;
6039 +
6040 + // stop queue
6041 + netif_stop_queue(dev);
6042 +
6043 + // execute reinitialization as tasklet
6044 + tasklet_schedule(&fp->fecpriv_tasklet_reinit);
6045 +
6046 + fp->fecpriv_stat.rx_dropped++;
6047 +
6048 + }
6049 +
6050 + // transmit FIFO underrun
6051 + if ((events & FEC_EIR_XFUN) != 0)
6052 + {
6053 + // reset XFUN event
6054 + FEC_EIR(base_addr) = FEC_EIR_XFUN;
6055 + fp->fecpriv_stat.tx_aborted_errors++;
6056 + }
6057 +
6058 + // late collision
6059 + if ((events & FEC_EIR_LC) != 0)
6060 + {
6061 + // reset LC event
6062 + FEC_EIR(base_addr) = FEC_EIR_LC;
6063 + fp->fecpriv_stat.tx_aborted_errors++;
6064 + }
6065 +
6066 + // collision retry limit
6067 + if ((events & FEC_EIR_RL) != 0)
6068 + {
6069 + // reset RL event
6070 + FEC_EIR(base_addr) = FEC_EIR_RL;
6071 + fp->fecpriv_stat.tx_aborted_errors++;
6072 + }
6073 +
6074 + return 0;
6075 +}
6076 +
6077 +/************************************************************************
6078 +* NAME: fec_interrupt_reinit
6079 +*
6080 +* DESCRIPTION: This function is called from interrupt handler
6081 +* when controller must be reinitialized.
6082 +*
6083 +*************************************************************************/
6084 +void fec_interrupt_fec_reinit(unsigned long data)
6085 +{
6086 + int i;
6087 + struct net_device *dev = (struct net_device*)data;
6088 + struct fec_priv *fp = netdev_priv(dev);
6089 + unsigned long base_addr = (unsigned long) dev->base_addr;
6090 +
6091 +printk(KERN_INFO "fecreinit\n");
6092 + // Initialize reception descriptors and start DMA for the reception
6093 + for (i = 0; i < FEC_RX_BUF_NUMBER; i++)
6094 + {
6095 + if (!fp->askb_rx[i])
6096 + {
6097 + fp->askb_rx[i] = alloc_skb(FEC_MAXBUF_SIZE + 16, GFP_ATOMIC | GFP_DMA);
6098 + if (!fp->askb_rx[i])
6099 + {
6100 + fp->fecpriv_rxdesc[i].dataPointer = 0;
6101 + fp->fecpriv_rxdesc[i].statCtrl = 0;
6102 + fp->fecpriv_rxdesc[i].length = 0;
6103 + continue;
6104 + }
6105 + fp->askb_rx[i]->dev = dev;
6106 + skb_reserve(fp->askb_rx[i], 16);
6107 + }
6108 + fp->fecpriv_rxdesc[i].dataPointer = (unsigned int) virt_to_phys(fp->askb_rx[i]->tail);
6109 + fp->fecpriv_rxdesc[i].statCtrl = MCD_FEC_BUF_READY | MCD_FEC_INTERRUPT;
6110 + fp->fecpriv_rxdesc[i].length = FEC_MAXBUF_SIZE;
6111 + }
6112 +
6113 + fp->fecpriv_rxdesc[i - 1].statCtrl |= MCD_FEC_WRAP;
6114 + fp->fecpriv_current_rx = 0;
6115 +
6116 + // restart frame transmission
6117 + for (i = 0; i < FEC_TX_BUF_NUMBER; i++)
6118 + {
6119 + if (fp->fecpriv_txbuf[i])
6120 + {
6121 +
6122 + kfree(fp->fecpriv_txbuf[i]);
6123 + fp->fecpriv_txbuf[i] = NULL;
6124 + fp->fecpriv_stat.tx_dropped++;
6125 + }
6126 + fp->fecpriv_txdesc[i].statCtrl = MCD_FEC_INTERRUPT;
6127 + }
6128 + fp->fecpriv_txdesc[i - 1].statCtrl |= MCD_FEC_WRAP;
6129 + fp->fecpriv_current_tx = fp->fecpriv_next_tx = 0;
6130 +
6131 + // flush entire data cache before restarting the DMA
6132 +#if 0
6133 +/* JKM -- currently running with cache turned off */
6134 + DcacheFlushInvalidate();
6135 +#endif
6136 +
6137 + // restart DMA from beginning
6138 + MCD_startDma(fp->fecpriv_fec_rx_channel,
6139 + (char *) fp->fecpriv_rxdesc, 0,
6140 + (unsigned char *) &(FEC_FECRFDR(base_addr)), 0,
6141 + FEC_MAX_FRM_SIZE, 0, fp->fecpriv_initiator_rx,
6142 + FEC_RX_DMA_PRI, MCD_FECRX_DMA | MCD_INTERRUPT,
6143 + MCD_NO_CSUM | MCD_NO_BYTE_SWAP);
6144 +
6145 + MCD_startDma(fp->fecpriv_fec_tx_channel, (char *) fp->fecpriv_txdesc, 0,
6146 + (unsigned char *) &(FEC_FECTFDR(base_addr)), 0,
6147 + FEC_MAX_FRM_SIZE, 0, fp->fecpriv_initiator_tx,
6148 + FEC_TX_DMA_PRI, MCD_FECTX_DMA | MCD_INTERRUPT,
6149 + MCD_NO_CSUM | MCD_NO_BYTE_SWAP);
6150 +
6151 + // Enable FEC
6152 + FEC_ECR(base_addr) |= FEC_ECR_ETHEREN;
6153 +
6154 + netif_wake_queue(dev);
6155 +
6156 +}
6157 +
6158 +/************************************************************************
6159 +* NAME: fec_interrupt_tx_handler_fec0
6160 +*
6161 +* DESCRIPTION: This is the DMA interrupt handler using for FEC0
6162 +* transmission.
6163 +*
6164 +*************************************************************************/
6165 +void fec_interrupt_fec_tx_handler_fec0(void)
6166 +{
6167 + fec_interrupt_fec_tx_handler(fec_dev[0]);
6168 +}
6169 +
6170 +#ifdef FEC_2
6171 +/************************************************************************
6172 +* NAME: fec_interrupt_tx_handler_fec1
6173 +*
6174 +* DESCRIPTION: This is the DMA interrupt handler using for the FEC1
6175 +* transmission.
6176 +*
6177 +*************************************************************************/
6178 +void fec_interrupt_fec_tx_handler_fec1(void)
6179 +{
6180 + fec_interrupt_fec_tx_handler(fec_dev[1]);
6181 +}
6182 +#endif
6183 +
6184 +/************************************************************************
6185 +* NAME: fec_interrupt_rx_handler_fec0
6186 +*
6187 +* DESCRIPTION: This is the DMA interrupt handler using for the FEC0
6188 +* reception.
6189 +*
6190 +*************************************************************************/
6191 +void fec_interrupt_fec_rx_handler_fec0(void)
6192 +{
6193 + fec_interrupt_fec_rx_handler(fec_dev[0]);
6194 +}
6195 +
6196 +#ifdef FEC_2
6197 +/************************************************************************
6198 +* NAME: fec_interrupt_rx_handler_fec1
6199 +*
6200 +* DESCRIPTION: This is the DMA interrupt handler using for the FEC1
6201 +* reception.
6202 +*
6203 +*************************************************************************/
6204 +void fec_interrupt_fec_rx_handler_fec1(void)
6205 +{
6206 + fec_interrupt_fec_rx_handler(fec_dev[1]);
6207 +}
6208 +
6209 +#endif
6210 +#ifndef MODULE
6211 +
6212 +/************************************************************************
6213 +* NAME: fec_mac_setup0
6214 +*
6215 +* DESCRIPTION: This function sets the MAC address of FEC0 from command line
6216 +*
6217 +*************************************************************************/
6218 +int __init fec_mac_setup0(char *s)
6219 +{
6220 + if(!s || !*s)
6221 + return 1;
6222 +
6223 + if(fec_str_to_mac(s, fec_mac_addr_fec0))
6224 + printk("The MAC address of FEC0 cannot be set from command line");
6225 + return 1;
6226 +
6227 +}
6228 +
6229 +#ifdef FEC_2
6230 +
6231 +/************************************************************************
6232 +* NAME: fec_mac_setup1
6233 +*
6234 +* DESCRIPTION: This function sets the MAC address of FEC1 from command line
6235 +*
6236 +*************************************************************************/
6237 +int __init fec_mac_setup1(char *s)
6238 +{
6239 + if(!s || !*s)
6240 + return 1;
6241 +
6242 +
6243 + if(fec_str_to_mac(s, fec_mac_addr_fec1))
6244 + printk("The MAC address of FEC1 cannot be set from command line");
6245 + return 1;
6246 +
6247 +}
6248 +#endif
6249 +
6250 +/************************************************************************
6251 +* NAME: fec_str_to_mac
6252 +*
6253 +* DESCRIPTION: This function interprets the character string into MAC addr
6254 +*
6255 +*************************************************************************/
6256 +int fec_str_to_mac( char *str_mac, unsigned char* addr)
6257 +{
6258 + unsigned long val;
6259 + char c;
6260 + unsigned long octet[6], *octetptr = octet;
6261 + int i;
6262 +again:
6263 +
6264 + val = 0;
6265 + while ((c = *str_mac) != '\0')
6266 + {
6267 + if ((c>='0')&&(c<='9'))
6268 + {
6269 + val = (val * 16) + (c - '0');
6270 + str_mac++;
6271 + continue;
6272 + }
6273 + else
6274 + if (((c>='a')&&(c<='f'))||((c>='A')&&(c<='F')))
6275 + {
6276 + val = (val << 4) + (c + 10 - (((c>='a')&&(c<='f')) ? 'a' : 'A'));
6277 + str_mac++;
6278 + continue;
6279 + }
6280 + break;
6281 + }
6282 + if (*str_mac == ':')
6283 + {
6284 + *octetptr++ = val, str_mac++;
6285 + if (octetptr >= octet + 6)
6286 + return 1;
6287 + goto again;
6288 + }
6289 +
6290 + //Check for trailing characters.
6291 + if (*str_mac && !(*str_mac==' '))
6292 + return 1;
6293 + *octetptr++ = val;
6294 +
6295 + if ((octetptr - octet)==6)
6296 + {
6297 + for(i=0;i<=6;i++)
6298 + addr[i]=octet[i];
6299 + }
6300 + else
6301 + return 1;
6302 +
6303 + return 0;
6304 +
6305 +}
6306 +#endif
6307 --- /dev/null
6308 +++ b/drivers/net/fec/fec.h
6309 @@ -0,0 +1,162 @@
6310 +
6311 +#define FEC_BASE_ADDR_FEC0 ((unsigned int)MCF_MBAR + 0x9000)
6312 +#define FEC_BASE_ADDR_FEC1 ((unsigned int)MCF_MBAR + 0x9800)
6313 +
6314 +//#define FEC_INTC_IMRH_INT_MASK38 (0x00000040)
6315 +//#define FEC_INTC_IMRH_INT_MASK39 (0x00000080)
6316 +//#define FEC_INTC_ICR_FEC0 (0x30)
6317 +//#define FEC_INTC_ICR_FEC1 (0x31)
6318 +#define FEC_FECI2CIRQ (0xFFC0)
6319 +#define FEC_GPIO_PAR_FECI2CIRQ *(volatile unsigned short*)((unsigned int)MCF_MBAR + 0xA44)
6320 +//#define FEC_INTC_ICRn(x) (*(volatile unsigned char *)(void*)((unsigned int) MCF_MBAR + 0x000740+((x)*0x001)))
6321 +//#define FEC_INTC_IMRH *(volatile unsigned int*)((unsigned int)MCF_MBAR + 0x000708)
6322 +
6323 +#define FEC_ECR_DISABLE (0x00000000)
6324 +
6325 +#define FEC_ECR(x) *(volatile unsigned int *)(x + 0x024)
6326 +#define FEC_EIR(x) *(volatile unsigned int*)(x + 0x004)
6327 +#define FEC_PALR(x) *(volatile unsigned int*)(x + 0x0E4)
6328 +#define FEC_PAUR(x) *(volatile unsigned int*)(x + 0x0E8)
6329 +#define FEC_IALR(x) *(volatile unsigned int*)(x + 0x11C)
6330 +#define FEC_IAUR(x) *(volatile unsigned int*)(x + 0x118)
6331 +#define FEC_GALR(x) *(volatile unsigned int*)(x + 0x124)
6332 +#define FEC_GAUR(x) *(volatile unsigned int*)(x + 0x120)
6333 +#define FEC_RCR(x) *(volatile unsigned int*)(x + 0x084)
6334 +#define FEC_FECRFCR(x) *(volatile unsigned int*)(x + 0x18C)
6335 +#define FEC_FECRFAR(x) *(volatile unsigned int*)(x + 0x198)
6336 +#define FEC_FECTFCR(x) *(volatile unsigned int*)(x + 0x1AC)
6337 +#define FEC_FECTFAR(x) *(volatile unsigned int*)(x + 0x1B8)
6338 +#define FEC_FECTFWR(x) *(volatile unsigned int*)(x + 0x144)
6339 +#define FEC_CTCWR(x) *(volatile unsigned int*)(x + 0x1C8)
6340 +#define FEC_EIMR(x) *(volatile unsigned int*)(x + 0x008)
6341 +#define FEC_TCR(x) *(volatile unsigned int*)(x + 0x0C4)
6342 +#define FEC_MIBC(x) *(volatile unsigned int*)(x + 0x064)
6343 +#define FEC_MSCR(x) *(volatile unsigned int*)(x + 0x044)
6344 +#define FEC_FECTFDR(x) *(volatile unsigned int*)(x + 0x1A4)
6345 +#define FEC_FECRFDR(x) *(volatile unsigned int*)(x + 0x184)
6346 +#define FEC_FECTFSR(x) *(volatile unsigned int*)(x + 0x1A8)
6347 +#define FEC_FECRFSR(x) *(volatile unsigned int*)(x + 0x188)
6348 +#define FECSTAT_RMON_R_PACKETS(x) *(volatile unsigned int*)(x + 0x284)
6349 +#define FECSTAT_RMON_T_PACKETS(x) *(volatile unsigned int*)(x + 0x204)
6350 +#define FECSTAT_RMON_R_OCTETS(x) *(volatile unsigned int*)(x + 0x2C4)
6351 +#define FECSTAT_RMON_T_OCTETS(x) *(volatile unsigned int*)(x + 0x244)
6352 +#define FECSTAT_RMON_R_UNDERSIZE(x) *(volatile unsigned int*)(x + 0x294)
6353 +#define FECSTAT_RMON_R_OVERSIZE(x) *(volatile unsigned int*)(x + 0x298)
6354 +#define FECSTAT_RMON_R_FRAG(x) *(volatile unsigned int*)(x + 0x29C)
6355 +#define FECSTAT_RMON_R_JAB(x) *(volatile unsigned int*)(x + 0x2A0)
6356 +#define FECSTAT_RMON_R_MC_PKT(x) *(volatile unsigned int*)(x + 0x28C)
6357 +#define FECSTAT_RMON_T_COL(x) *(volatile unsigned int*)(x + 0x224)
6358 +#define FECSTAT_IEEE_R_ALIGN(x) *(volatile unsigned int*)(x + 0x2D4)
6359 +#define FECSTAT_IEEE_R_CRC(x) *(volatile unsigned int*)(x + 0x2D0)
6360 +#define FECSTAT_IEEE_R_MACERR(x) *(volatile unsigned int*)(x + 0x2D8)
6361 +#define FECSTAT_IEEE_T_CSERR(x) *(volatile unsigned int*)(x + 0x268)
6362 +#define FECSTAT_IEEE_T_MACERR(x) *(volatile unsigned int*)(x + 0x264)
6363 +#define FECSTAT_IEEE_T_LCOL(x) *(volatile unsigned int*)(x + 0x25C)
6364 +#define FECSTAT_IEEE_R_OCTETS_OK(x) *(volatile unsigned int*)(x + 0x2E0)
6365 +#define FECSTAT_IEEE_T_OCTETS_OK(x) *(volatile unsigned int*)(x + 0x274)
6366 +#define FECSTAT_IEEE_R_DROP(x) *(volatile unsigned int*)(x + 0x2C8)
6367 +#define FECSTAT_IEEE_T_DROP(x) *(volatile unsigned int*)(x + 0x248)
6368 +#define FECSTAT_IEEE_R_FRAME_OK(x) *(volatile unsigned int*)(x + 0x2CC)
6369 +#define FECSTAT_IEEE_T_FRAME_OK(x) *(volatile unsigned int*)(x + 0x24C)
6370 +#define FEC_MMFR(x) *(volatile unsigned int*)(x + 0x040)
6371 +#define FEC_FECFRST(x) *(volatile unsigned int*)(x + 0x1C4)
6372 +
6373 +#define FEC_MAX_FRM_SIZE (1518)
6374 +#define FEC_MAXBUF_SIZE (1520)
6375 +
6376 +// Register values
6377 +#define FEC_ECR_RESET (0x00000001)
6378 +#define FEC_EIR_CLEAR (0xFFFFFFFF)
6379 +#define FEC_EIR_RL (0x00100000)
6380 +#define FEC_EIR_HBERR (0x80000000)
6381 +#define FEC_EIR_BABR (0x40000000) // babbling receive error
6382 +#define FEC_EIR_BABT (0x20000000) // babbling transmit error
6383 +#define FEC_EIR_TXF (0x08000000) // transmit frame interrupt
6384 +#define FEC_EIR_MII (0x00800000) // MII interrupt
6385 +#define FEC_EIR_LC (0x00200000) // late collision
6386 +#define FEC_EIR_XFUN (0x00080000) // transmit FIFO underrun
6387 +#define FEC_EIR_XFERR (0x00040000) // transmit FIFO error
6388 +#define FEC_EIR_RFERR (0x00020000) // receive FIFO error
6389 +#define FEC_RCR_MAX_FRM_SIZE (FEC_MAX_FRM_SIZE << 16)
6390 +#define FEC_RCR_MII (0x00000004)
6391 +#define FEC_FECRFCR_FAE (0x00400000) // frame accept error
6392 +#define FEC_FECRFCR_RXW (0x00200000) // receive wait condition
6393 +#define FEC_FECRFCR_UF (0x00100000) // receive FIFO underflow
6394 +#define FEC_FECRFCR_FRM (0x08000000)
6395 +#define FEC_FECRFCR_GR (0x7 << 24)
6396 +
6397 +#define FEC_EIMR_DISABLE (0x00000000)
6398 +
6399 +#define FEC_FECRFAR_ALARM (0x300)
6400 +#define FEC_FECTFCR_FRM (0x08000000)
6401 +#define FEC_FECTFCR_GR (0x7 << 24)
6402 +#define FEC_FECTFCR_FAE (0x00400000) // frame accept error
6403 +#define FEC_FECTFCR_TXW (0x00040000) // transmit wait condition
6404 +#define FEC_FECTFCR_UF (0x00100000) // transmit FIFO underflow
6405 +#define FEC_FECTFCR_OF (0x00080000) // transmit FIFO overflow
6406 +
6407 +#define FEC_FECTFAR_ALARM (0x100)
6408 +#define FEC_FECTFWR_XWMRK (0x00000000)
6409 +
6410 +#define FEC_FECTFSR_MSK (0xC0B00000)
6411 +#define FEC_FECTFSR_TXW (0x40000000) // transmit wait condition
6412 +#define FEC_FECTFSR_FAE (0x00800000) // frame accept error
6413 +#define FEC_FECTFSR_UF (0x00200000) // transmit FIFO underflow
6414 +#define FEC_FECTFSR_OF (0x00100000) // transmit FIFO overflow
6415 +
6416 +#define FEC_FECRFSR_MSK (0x80F00000)
6417 +#define FEC_FECRFSR_FAE (0x00800000) // frame accept error
6418 +#define FEC_FECRFSR_RXW (0x00400000) // receive wait condition
6419 +#define FEC_FECRFSR_UF (0x00200000) // receive FIFO underflow
6420 +
6421 +#define FEC_CTCWR_TFCW_CRC (0x03000000)
6422 +#define FEC_TCR_FDEN (0x00000004)
6423 +#define FEC_TCR_HBC (0x00000002)
6424 +#define FEC_RCR_DRT (0x00000002)
6425 +#define FEC_EIMR_MASK (FEC_EIR_RL | FEC_EIR_HBERR)
6426 +#define FEC_ECR_ETHEREN (0x00000002)
6427 +#define FEC_FECTFCR_MSK (0x00FC0000)
6428 +#define FEC_FECRFCR_MSK (0x00F80000)
6429 +#define FEC_EIR_GRA (0x10000000)
6430 +#define FEC_TCR_GTS (0x00000001)
6431 +#define FEC_MIBC_ENABLE (0x00000000)
6432 +#define FEC_MIB_LEN (228)
6433 +#define FEC_PHY_ADDR (0x01)
6434 +
6435 +#define FEC_RX_DMA_PRI (6)
6436 +#define FEC_TX_DMA_PRI (6)
6437 +
6438 +#define FEC_TX_BUF_NUMBER (8)
6439 +#define FEC_RX_BUF_NUMBER (64)
6440 +
6441 +#define FEC_TX_INDEX_MASK (0x7)
6442 +#define FEC_RX_INDEX_MASK (0x3f)
6443 +
6444 +#define FEC_RX_DESC_FEC0 SYS_SRAM_FEC_START
6445 +#define FEC_TX_DESC_FEC0 FEC_RX_DESC_FEC0 + FEC_RX_BUF_NUMBER * sizeof(MCD_bufDescFec)
6446 +
6447 +#define FEC_RX_DESC_FEC1 SYS_SRAM_FEC_START + SYS_SRAM_FEC_SIZE/2
6448 +#define FEC_TX_DESC_FEC1 FEC_RX_DESC_FEC1 + FEC_RX_BUF_NUMBER * sizeof(MCD_bufDescFec)
6449 +
6450 +#define FEC_EIR_MII (0x00800000)
6451 +#define FEC_MMFR_READ (0x60020000)
6452 +#define FEC_MMFR_WRITE (0x50020000)
6453 +
6454 +#define FEC_FLAGS_RX (0x00000001)
6455 +
6456 +#define FEC_CRCPOL (0xEDB88320)
6457 +
6458 +#define FEC_MII_TIMEOUT (2)
6459 +#define FEC_GR_TIMEOUT (1)
6460 +#define FEC_TX_TIMEOUT (1)
6461 +#define FEC_RX_TIMEOUT (1)
6462 +
6463 +#define FEC_SW_RST 0x2000000
6464 +#define FEC_RST_CTL 0x1000000
6465 +
6466 +int fec_read_mii(unsigned int base_addr, unsigned int pa, unsigned int ra,
6467 + unsigned int *data);
6468 +int fec_write_mii(unsigned int base_addr, unsigned int pa, unsigned int ra,
6469 + unsigned int data);
6470 +
6471 +#define init_transceiver ks8721_init_transceiver
6472 --- /dev/null
6473 +++ b/drivers/net/fec/ks8721.c
6474 @@ -0,0 +1,125 @@
6475 +#include <linux/module.h>
6476 +#include <linux/kernel.h>
6477 +#include <linux/string.h>
6478 +#include <linux/ptrace.h>
6479 +#include <linux/errno.h>
6480 +#include <linux/ioport.h>
6481 +#include <linux/slab.h>
6482 +#include <linux/interrupt.h>
6483 +#include <linux/pci.h>
6484 +#include <linux/init.h>
6485 +#include <linux/delay.h>
6486 +#include <linux/netdevice.h>
6487 +#include <linux/etherdevice.h>
6488 +#include <linux/skbuff.h>
6489 +#include <linux/spinlock.h>
6490 +#include <linux/workqueue.h>
6491 +#include <linux/bitops.h>
6492 +
6493 +#if 0
6494 +#include <linux/config.h>
6495 +#include <linux/sched.h>
6496 +#include <linux/errno.h>
6497 +#include <asm/coldfire.h>
6498 +#endif
6499 +#include <asm/coldfire.h>
6500 +#include <asm/mcfsim.h>
6501 +
6502 +#include "fec.h"
6503 +#include "ks8721.h"
6504 +
6505 +#ifdef CONFIG_FEC_548x_AUTO_NEGOTIATION
6506 +#define KS8721_AUTO_NEGOTIATION_ENABLE
6507 +#endif
6508 +
6509 +/************************************************************************
6510 +* +NAME: ks8721_init_transceiver
6511 +*
6512 +* DESCRIPTION: This function initializes the transceiver
6513 +*
6514 +* RETURNS: If no error occurs, this function returns zero.
6515 +* Otherwise, it returns 1
6516 +*************************************************************************/
6517 +
6518 +int ks8721_init_transceiver(unsigned long base_addr, int *fduplex)
6519 +{
6520 +
6521 + int data;
6522 + unsigned long time;
6523 + int flag = 1;
6524 +
6525 + int result;
6526 +
6527 + // Set the frequency of MII
6528 + FEC_MSCR(base_addr) = FEC_MII_SPEED;
6529 +
6530 + // Reset
6531 + if ((result = fec_write_mii(base_addr, FEC_PHY_ADDR, KS8721_CTRL, KS8721_CTRL_RESET)))
6532 + return result;
6533 +
6534 + // Read back
6535 + if ((result = fec_read_mii(base_addr, FEC_PHY_ADDR, KS8721_CTRL, &data)) != 0)
6536 + return result;
6537 +
6538 + // If reset bit is set, return
6539 + if (data & KS8721_CTRL_RESET)
6540 + return -ETIME;
6541 +
6542 +#ifdef KS8721_AUTO_NEGOTIATION_ENABLE
6543 +
6544 + // Disable the auto-negotiation
6545 + if ((result = fec_write_mii(base_addr, FEC_PHY_ADDR, KS8721_CTRL, 0)) != 0)
6546 + return result;
6547 +
6548 + // Set the auto-negotiation advertisement register
6549 + if ((result = fec_write_mii(base_addr, FEC_PHY_ADDR, KS8721_ANADV, KS8721_ANADV_ADV_ALL)) != 0)
6550 + return result;
6551 +
6552 + // Enable the auto-negotiation
6553 + if ((result = fec_write_mii(base_addr, FEC_PHY_ADDR, KS8721_CTRL, KS8721_CTRL_AN_ENABLE)) != 0)
6554 + return result;
6555 +
6556 + // Read PHY status register
6557 + if ((result = fec_read_mii(base_addr, FEC_PHY_ADDR, KS8721_STAT, &data)) != 0)
6558 + return result;
6559 + // Set the current time
6560 + time = jiffies;
6561 +
6562 + // Wait for the auto-negotiation completion
6563 + while (!(data & KS8721_STAT_ANCOMPLETE))
6564 + {
6565 +
6566 + if (jiffies - time > KS8721_TIMEOUT * HZ)
6567 + {
6568 + flag = 0;
6569 + break;
6570 + }
6571 +
6572 + schedule();
6573 +
6574 + // Read PHY status register
6575 + if ((result = fec_read_mii(base_addr, FEC_PHY_ADDR, KS8721_STAT, &data)) != 0)
6576 + return result;
6577 + }
6578 +
6579 + if (flag)
6580 + {
6581 + // Set the duplex flag
6582 + if (data & KS8721_STAT_FDUPLEX)
6583 + *fduplex = 1;
6584 + else
6585 + *fduplex = 0;
6586 +
6587 + return 0;
6588 + }
6589 +
6590 +#endif
6591 +
6592 + // Set the default mode (Full duplex, 100 Mbps)
6593 + if ((result = fec_write_mii(base_addr, FEC_PHY_ADDR, KS8721_CTRL, KS8721_CTRL_DEFAULT_MODE)) != 0)
6594 + return result;
6595 + *fduplex = KS8721_CTRL_DEFAULT_MODE & 0x100;
6596 +
6597 + return 0;
6598 +
6599 +}
6600 --- /dev/null
6601 +++ b/drivers/net/fec/ks8721.h
6602 @@ -0,0 +1,21 @@
6603 +
6604 +#define FEC_MII_SPEED (((unsigned int)(MCF_BUSCLK / 5000000)) << 1)
6605 +
6606 +// Numbers of the transceiver registers
6607 +#define KS8721_CTRL 0x00
6608 +#define KS8721_ANADV 0x04
6609 +#define KS8721_STAT 0x01
6610 +
6611 +// Register values
6612 +#define KS8721_CTRL_RESET 0x8000
6613 +#define KS8721_ANADV_ADV_ALL 0x01E1
6614 +#define KS8721_CTRL_AN_ENABLE 0x1280
6615 +#define KS8721_CTRL_DEFAULT_MODE 0x2100
6616 +#define KS8721_STAT_ANCOMPLETE 0x0020
6617 +#define KS8721_STAT_LINK 0x0004
6618 +#define KS8721_STAT_FDUPLEX 0x5000
6619 +
6620 +// Timeout for the auto-negotiation mode
6621 +#define KS8721_TIMEOUT 5
6622 +
6623 +int ks8721_init_transceiver(unsigned long base_addr, int *fduplex);
6624 --- /dev/null
6625 +++ b/include/asm-m68k/MCD_dma.h
6626 @@ -0,0 +1,408 @@
6627 +/*********************************************************************
6628 + *
6629 + * Copyright (C) 2004 Motorola, Inc.
6630 + * MOTOROLA, INC. All Rights Reserved.
6631 + * You are hereby granted a copyright license to use
6632 + * the SOFTWARE so long as this entire notice is
6633 + * retained without alteration in any modified and/or redistributed
6634 + * versions, and that such modified versions are clearly identified
6635 + * as such. No licenses are granted by implication, estoppel or
6636 + * otherwise under any patents or trademarks of Motorola, Inc. This
6637 + * software is provided on an "AS IS" basis and without warranty.
6638 + *
6639 + * To the maximum extent permitted by applicable law, MOTOROLA
6640 + * DISCLAIMS ALL WARRANTIES WHETHER EXPRESS OR IMPLIED, INCLUDING
6641 + * IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR
6642 + * PURPOSE AND ANY WARRANTY AGAINST INFRINGEMENT WITH REGARD TO THE
6643 + * SOFTWARE (INCLUDING ANY MODIFIED VERSIONS THEREOF) AND ANY
6644 + * ACCOMPANYING WRITTEN MATERIALS.
6645 + *
6646 + * To the maximum extent permitted by applicable law, IN NO EVENT
6647 + * SHALL MOTOROLA BE LIABLE FOR ANY DAMAGES WHATSOEVER (INCLUDING
6648 + * WITHOUT LIMITATION, DAMAGES FOR LOSS OF BUSINESS PROFITS, BUSINESS
6649 + * INTERRUPTION, LOSS OF BUSINESS INFORMATION, OR OTHER PECUNIARY
6650 + * LOSS) ARISING OF THE USE OR INABILITY TO USE THE SOFTWARE.
6651 + *
6652 + * Motorola assumes no responsibility for the maintenance and support
6653 + * of this software
6654 + ********************************************************************/
6655 +
6656 +/*
6657 + * File: MCD_dma.h
6658 + * Purpose: Main header file for multi-channel DMA API.
6659 + *
6660 + * Notes:
6661 + *
6662 + * Modifications:
6663 + */
6664 +#ifndef _MCD_API_H
6665 +#define _MCD_API_H
6666 +
6667 +#include <asm/types.h>
6668 +
6669 +/*
6670 + * Turn Execution Unit tasks ON (#define) or OFF (#undef)
6671 + */
6672 +#undef MCD_INCLUDE_EU
6673 +
6674 +/*
6675 + * Number of DMA channels
6676 + */
6677 +#define NCHANNELS 16
6678 +
6679 +/*
6680 + * Total number of variants
6681 + */
6682 +#ifdef MCD_INCLUDE_EU
6683 +#define NUMOFVARIANTS 6
6684 +#else
6685 +#define NUMOFVARIANTS 4
6686 +#endif
6687 +
6688 +/*
6689 + * Define sizes of the various tables
6690 + */
6691 +#define TASK_TABLE_SIZE (NCHANNELS*32)
6692 +#define VAR_TAB_SIZE (128)
6693 +#define CONTEXT_SAVE_SIZE (128)
6694 +#define FUNCDESC_TAB_SIZE (256)
6695 +
6696 +#ifdef MCD_INCLUDE_EU
6697 +#define FUNCDESC_TAB_NUM 16
6698 +#else
6699 +#define FUNCDESC_TAB_NUM 1
6700 +#endif
6701 +
6702 +
6703 +#ifndef DEFINESONLY
6704 +
6705 +/*
6706 + * Portability typedefs
6707 + */
6708 + /*
6709 +#ifndef s32
6710 +typedef int s32;
6711 +#endif
6712 +#ifndef u32
6713 +typedef unsigned int u32;
6714 +#endif
6715 +#ifndef s16
6716 +typedef short s16;
6717 +#endif
6718 +#ifndef u16
6719 +typedef unsigned short u16;
6720 +#endif
6721 +#ifndef s8
6722 +typedef char s8;
6723 +#endif
6724 +#ifndef u8
6725 +typedef unsigned char u8;
6726 +#endif
6727 +*/
6728 +/*
6729 + * These structures represent the internal registers of the
6730 + * multi-channel DMA
6731 + */
6732 +struct dmaRegs_s {
6733 + u32 taskbar; /* task table base address register */
6734 + u32 currPtr;
6735 + u32 endPtr;
6736 + u32 varTablePtr;
6737 + u16 dma_rsvd0;
6738 + u16 ptdControl; /* ptd control */
6739 + u32 intPending; /* interrupt pending register */
6740 + u32 intMask; /* interrupt mask register */
6741 + u16 taskControl[16]; /* task control registers */
6742 + u8 priority[32]; /* priority registers */
6743 + u32 initiatorMux; /* initiator mux control */
6744 + u32 taskSize0; /* task size control register 0. */
6745 + u32 taskSize1; /* task size control register 1. */
6746 + u32 dma_rsvd1; /* reserved */
6747 + u32 dma_rsvd2; /* reserved */
6748 + u32 debugComp1; /* debug comparator 1 */
6749 + u32 debugComp2; /* debug comparator 2 */
6750 + u32 debugControl; /* debug control */
6751 + u32 debugStatus; /* debug status */
6752 + u32 ptdDebug; /* priority task decode debug */
6753 + u32 dma_rsvd3[31]; /* reserved */
6754 +};
6755 +typedef volatile struct dmaRegs_s dmaRegs;
6756 +
6757 +#endif
6758 +
6759 +/*
6760 + * PTD contrl reg bits
6761 + */
6762 +#define PTD_CTL_TSK_PRI 0x8000
6763 +#define PTD_CTL_COMM_PREFETCH 0x0001
6764 +
6765 +/*
6766 + * Task Control reg bits and field masks
6767 + */
6768 +#define TASK_CTL_EN 0x8000
6769 +#define TASK_CTL_VALID 0x4000
6770 +#define TASK_CTL_ALWAYS 0x2000
6771 +#define TASK_CTL_INIT_MASK 0x1f00
6772 +#define TASK_CTL_ASTRT 0x0080
6773 +#define TASK_CTL_HIPRITSKEN 0x0040
6774 +#define TASK_CTL_HLDINITNUM 0x0020
6775 +#define TASK_CTL_ASTSKNUM_MASK 0x000f
6776 +
6777 +/*
6778 + * Priority reg bits and field masks
6779 + */
6780 +#define PRIORITY_HLD 0x80
6781 +#define PRIORITY_PRI_MASK 0x07
6782 +
6783 +/*
6784 + * Debug Control reg bits and field masks
6785 + */
6786 +#define DBG_CTL_BLOCK_TASKS_MASK 0xffff0000
6787 +#define DBG_CTL_AUTO_ARM 0x00008000
6788 +#define DBG_CTL_BREAK 0x00004000
6789 +#define DBG_CTL_COMP1_TYP_MASK 0x00003800
6790 +#define DBG_CTL_COMP2_TYP_MASK 0x00000070
6791 +#define DBG_CTL_EXT_BREAK 0x00000004
6792 +#define DBG_CTL_INT_BREAK 0x00000002
6793 +
6794 +/*
6795 + * PTD Debug reg selector addresses
6796 + * This reg must be written with a value to show the contents of
6797 + * one of the desired internal register.
6798 + */
6799 +#define PTD_DBG_REQ 0x00 /* shows the state of 31 initiators */
6800 +#define PTD_DBG_TSK_VLD_INIT 0x01 /* shows which 16 tasks are valid and
6801 + have initiators asserted */
6802 +
6803 +
6804 +/*
6805 + * General return values
6806 + */
6807 +#define MCD_OK 0
6808 +#define MCD_ERROR -1
6809 +#define MCD_TABLE_UNALIGNED -2
6810 +#define MCD_CHANNEL_INVALID -3
6811 +
6812 +/*
6813 + * MCD_initDma input flags
6814 + */
6815 +#define MCD_RELOC_TASKS 0x00000001
6816 +#define MCD_NO_RELOC_TASKS 0x00000000
6817 +#define MCD_COMM_PREFETCH_EN 0x00000002 /* Commbus Prefetching - MCF547x/548x ONLY */
6818 +
6819 +/*
6820 + * MCD_dmaStatus Status Values for each channel
6821 + */
6822 +#define MCD_NO_DMA 1 /* No DMA has been requested since reset */
6823 +#define MCD_IDLE 2 /* DMA active, but the initiator is currently inactive */
6824 +#define MCD_RUNNING 3 /* DMA active, and the initiator is currently active */
6825 +#define MCD_PAUSED 4 /* DMA active but it is currently paused */
6826 +#define MCD_HALTED 5 /* the most recent DMA has been killed with MCD_killTask() */
6827 +#define MCD_DONE 6 /* the most recent DMA has completed. */
6828 +
6829 +
6830 +/*
6831 + * MCD_startDma parameter defines
6832 + */
6833 +
6834 +/*
6835 + * Constants for the funcDesc parameter
6836 + */
6837 +/* Byte swapping: */
6838 +#define MCD_NO_BYTE_SWAP 0x00045670 /* to disable byte swapping. */
6839 +#define MCD_BYTE_REVERSE 0x00076540 /* to reverse the bytes of each u32 of the DMAed data. */
6840 +#define MCD_U16_REVERSE 0x00067450 /* to reverse the 16-bit halves of
6841 + each 32-bit data value being DMAed.*/
6842 +#define MCD_U16_BYTE_REVERSE 0x00054760 /* to reverse the byte halves of each
6843 + 16-bit half of each 32-bit data value DMAed */
6844 +#define MCD_NO_BIT_REV 0x00000000 /* do not reverse the bits of each byte DMAed. */
6845 +#define MCD_BIT_REV 0x00088880 /* reverse the bits of each byte DMAed */
6846 +/* CRCing: */
6847 +#define MCD_CRC16 0xc0100000 /* to perform CRC-16 on DMAed data. */
6848 +#define MCD_CRCCCITT 0xc0200000 /* to perform CRC-CCITT on DMAed data. */
6849 +#define MCD_CRC32 0xc0300000 /* to perform CRC-32 on DMAed data. */
6850 +#define MCD_CSUMINET 0xc0400000 /* to perform internet checksums on DMAed data.*/
6851 +#define MCD_NO_CSUM 0xa0000000 /* to perform no checksumming. */
6852 +
6853 +#define MCD_FUNC_NOEU1 (MCD_NO_BYTE_SWAP | MCD_NO_BIT_REV | MCD_NO_CSUM)
6854 +#define MCD_FUNC_NOEU2 (MCD_NO_BYTE_SWAP | MCD_NO_CSUM)
6855 +
6856 +/*
6857 + * Constants for the flags parameter
6858 + */
6859 +#define MCD_TT_FLAGS_RL 0x00000001 /* Read line */
6860 +#define MCD_TT_FLAGS_CW 0x00000002 /* Combine Writes */
6861 +#define MCD_TT_FLAGS_SP 0x00000004 /* Speculative prefetch(XLB) MCF547x/548x ONLY */
6862 +#define MCD_TT_FLAGS_MASK 0x000000ff
6863 +#define MCD_TT_FLAGS_DEF (MCD_TT_FLAGS_RL | MCD_TT_FLAGS_CW)
6864 +
6865 +#define MCD_SINGLE_DMA 0x00000100 /* Unchained DMA */
6866 +#define MCD_CHAIN_DMA /* TBD */
6867 +#define MCD_EU_DMA /* TBD */
6868 +#define MCD_FECTX_DMA 0x00001000 /* FEC TX ring DMA */
6869 +#define MCD_FECRX_DMA 0x00002000 /* FEC RX ring DMA */
6870 +
6871 +
6872 +/* these flags are valid for MCD_startDma and the chained buffer descriptors */
6873 +#define MCD_BUF_READY 0x80000000 /* indicates that this buffer is now under the DMA's control */
6874 +#define MCD_WRAP 0x20000000 /* to tell the FEC Dmas to wrap to the first BD */
6875 +#define MCD_INTERRUPT 0x10000000 /* to generate an interrupt after completion of the DMA. */
6876 +#define MCD_END_FRAME 0x08000000 /* tell the DMA to end the frame when transferring
6877 + last byte of data in buffer */
6878 +#define MCD_CRC_RESTART 0x40000000 /* to empty out the accumulated checksum
6879 + prior to performing the DMA. */
6880 +
6881 +/* Defines for the FEC buffer descriptor control/status word*/
6882 +#define MCD_FEC_BUF_READY 0x8000
6883 +#define MCD_FEC_WRAP 0x2000
6884 +#define MCD_FEC_INTERRUPT 0x1000
6885 +#define MCD_FEC_END_FRAME 0x0800
6886 +
6887 +
6888 +/*
6889 + * Defines for general intuitiveness
6890 + */
6891 +
6892 +#define MCD_TRUE 1
6893 +#define MCD_FALSE 0
6894 +
6895 +/*
6896 + * Three different cases for destination and source.
6897 + */
6898 +#define MINUS1 -1
6899 +#define ZERO 0
6900 +#define PLUS1 1
6901 +
6902 +#ifndef DEFINESONLY
6903 +
6904 +/* Task Table Entry struct*/
6905 +typedef struct {
6906 + u32 TDTstart; /* task descriptor table start */
6907 + u32 TDTend; /* task descriptor table end */
6908 + u32 varTab; /* variable table start */
6909 + u32 FDTandFlags; /* function descriptor table start and flags */
6910 + volatile u32 descAddrAndStatus;
6911 + volatile u32 modifiedVarTab;
6912 + u32 contextSaveSpace; /* context save space start */
6913 + u32 literalBases;
6914 +} TaskTableEntry;
6915 +
6916 +
6917 +/* Chained buffer descriptor */
6918 +typedef volatile struct MCD_bufDesc_struct MCD_bufDesc;
6919 +struct MCD_bufDesc_struct {
6920 + u32 flags; /* flags describing the DMA */
6921 + u32 csumResult; /* checksum from checksumming performed since last checksum reset */
6922 + s8 *srcAddr; /* the address to move data from */
6923 + s8 *destAddr; /* the address to move data to */
6924 + s8 *lastDestAddr; /* the last address written to */
6925 + u32 dmaSize; /* the number of bytes to transfer independent of the transfer size */
6926 + MCD_bufDesc *next; /* next buffer descriptor in chain */
6927 + u32 info; /* private information about this descriptor; DMA does not affect it */
6928 +};
6929 +
6930 +/* Progress Query struct */
6931 +typedef volatile struct MCD_XferProg_struct {
6932 + s8 *lastSrcAddr; /* the most-recent or last, post-increment source address */
6933 + s8 *lastDestAddr; /* the most-recent or last, post-increment destination address */
6934 + u32 dmaSize; /* the amount of data transferred for the current buffer */
6935 + MCD_bufDesc *currBufDesc;/* pointer to the current buffer descriptor being DMAed */
6936 +} MCD_XferProg;
6937 +
6938 +
6939 +/* FEC buffer descriptor */
6940 +typedef volatile struct MCD_bufDescFec_struct {
6941 + u16 statCtrl;
6942 + u16 length;
6943 + u32 dataPointer;
6944 +} MCD_bufDescFec;
6945 +
6946 +
6947 +/*************************************************************************/
6948 +/*
6949 + * API function Prototypes - see MCD_dmaApi.c for further notes
6950 + */
6951 +
6952 +/*
6953 + * MCD_startDma starts a particular kind of DMA .
6954 + */
6955 +int MCD_startDma (
6956 + int channel, /* the channel on which to run the DMA */
6957 + s8 *srcAddr, /* the address to move data from, or buffer-descriptor address */
6958 + s16 srcIncr, /* the amount to increment the source address per transfer */
6959 + s8 *destAddr, /* the address to move data to */
6960 + s16 destIncr, /* the amount to increment the destination address per transfer */
6961 + u32 dmaSize, /* the number of bytes to transfer independent of the transfer size */
6962 + u32 xferSize, /* the number bytes in of each data movement (1, 2, or 4) */
6963 + u32 initiator, /* what device initiates the DMA */
6964 + int priority, /* priority of the DMA */
6965 + u32 flags, /* flags describing the DMA */
6966 + u32 funcDesc /* a description of byte swapping, bit swapping, and CRC actions */
6967 +);
6968 +
6969 +/*
6970 + * MCD_initDma() initializes the DMA API by setting up a pointer to the DMA
6971 + * registers, relocating and creating the appropriate task structures, and
6972 + * setting up some global settings
6973 + */
6974 +int MCD_initDma (dmaRegs *sDmaBarAddr, void *taskTableDest, u32 flags);
6975 +
6976 +/*
6977 + * MCD_dmaStatus() returns the status of the DMA on the requested channel.
6978 + */
6979 +int MCD_dmaStatus (int channel);
6980 +
6981 +/*
6982 + * MCD_XferProgrQuery() returns progress of DMA on requested channel
6983 + */
6984 +int MCD_XferProgrQuery (int channel, MCD_XferProg *progRep);
6985 +
6986 +/*
6987 + * MCD_killDma() halts the DMA on the requested channel, without any
6988 + * intention of resuming the DMA.
6989 + */
6990 +int MCD_killDma (int channel);
6991 +
6992 +/*
6993 + * MCD_continDma() continues a DMA which as stopped due to encountering an
6994 + * unready buffer descriptor.
6995 + */
6996 +int MCD_continDma (int channel);
6997 +
6998 +/*
6999 + * MCD_pauseDma() pauses the DMA on the given channel ( if any DMA is
7000 + * running on that channel).
7001 + */
7002 +int MCD_pauseDma (int channel);
7003 +
7004 +/*
7005 + * MCD_resumeDma() resumes the DMA on a given channel (if any DMA is
7006 + * running on that channel).
7007 + */
7008 +int MCD_resumeDma (int channel);
7009 +
7010 +/*
7011 + * MCD_csumQuery provides the checksum/CRC after performing a non-chained DMA
7012 + */
7013 +int MCD_csumQuery (int channel, u32 *csum);
7014 +
7015 +/*
7016 + * MCD_getCodeSize provides the packed size required by the microcoded task
7017 + * and structures.
7018 + */
7019 +int MCD_getCodeSize(void);
7020 +
7021 +/*
7022 + * MCD_getVersion provides a pointer to a version string and returns a
7023 + * version number.
7024 + */
7025 +int MCD_getVersion(char **longVersion);
7026 +
7027 +/* macro for setting a location in the variable table */
7028 +#define MCD_SET_VAR(taskTab,idx,value) ((u32 *)(taskTab)->varTab)[idx] = value
7029 + /* Note that MCD_SET_VAR() is invoked many times in firing up a DMA function,
7030 + so I'm avoiding surrounding it with "do {} while(0)" */
7031 +
7032 +#endif /* DEFINESONLY */
7033 +
7034 +#endif /* _MCD_API_H */
7035 --- a/include/asm-m68k/coldfire.h
7036 +++ b/include/asm-m68k/coldfire.h
7037 @@ -7,6 +7,7 @@
7038 #define MCF_SRAM 0x80000000
7039 #elif defined(CONFIG_M547X_8X)
7040 #define MCF_MBAR 0xE0000000
7041 +#define MCF_MMUBAR 0xE1000000
7042 #define MCF_RAMBAR0 0xE3000000
7043 #define MCF_RAMBAR1 0xE3001000
7044 #endif
7045 --- a/include/asm-m68k/dma.h
7046 +++ b/include/asm-m68k/dma.h
7047 @@ -1,16 +1,120 @@
7048 #ifndef _M68K_DMA_H
7049 #define _M68K_DMA_H 1
7050
7051 -
7052 /* it's useless on the m68k, but unfortunately needed by the new
7053 bootmem allocator (but this should do it for this) */
7054 #define MAX_DMA_ADDRESS PAGE_OFFSET
7055
7056 +#ifndef CONFIG_COLDFIRE
7057 #define MAX_DMA_CHANNELS 8
7058
7059 extern int request_dma(unsigned int dmanr, const char * device_id); /* reserve a DMA channel */
7060 extern void free_dma(unsigned int dmanr); /* release it again */
7061
7062 +#else /* not (defined(CONFIG_MCF5474) || defined(CONFIG_MCF5484) || defined(CONFIG_MCF5475) || defined(CONFIG_MCF5485)) */
7063 +
7064 +/************************************************
7065 + * Multichannel DMA definitions *
7066 + ************************************************/
7067 +#ifdef CONFIG_MCD_DMA
7068 +#include <asm/MCD_dma.h>
7069 +#include <asm/m5485dma.h>
7070 +
7071 +struct scatterlist;
7072 +
7073 +#define MAX_DMA_CHANNELS NCHANNELS
7074 +/*
7075 + * identifiers for each initiator/requestor
7076 + */
7077 +#define DMA_ALWAYS (0)
7078 +#define DMA_DSPI_RX (1)
7079 +#define DMA_DSPI_TX (2)
7080 +#define DMA_DREQ0 (3)
7081 +#define DMA_PSC0_RX (4)
7082 +#define DMA_PSC0_TX (5)
7083 +#define DMA_USBEP0 (6)
7084 +#define DMA_USBEP1 (7)
7085 +#define DMA_USBEP2 (8)
7086 +#define DMA_USBEP3 (9)
7087 +#define DMA_PCI_TX (10)
7088 +#define DMA_PCI_RX (11)
7089 +#define DMA_PSC1_RX (12)
7090 +#define DMA_PSC1_TX (13)
7091 +#define DMA_I2C_RX (14)
7092 +#define DMA_I2C_TX (15)
7093 +#define DMA_FEC0_RX (16)
7094 +#define DMA_FEC0_TX (17)
7095 +#define DMA_FEC1_RX (18)
7096 +#define DMA_FEC1_TX (19)
7097 +#define DMA_DREQ1 (20)
7098 +#define DMA_CTM0 (21)
7099 +#define DMA_CTM1 (22)
7100 +#define DMA_CTM2 (23)
7101 +#define DMA_CTM3 (24)
7102 +#define DMA_CTM4 (25)
7103 +#define DMA_CTM5 (26)
7104 +#define DMA_CTM6 (27)
7105 +#define DMA_CTM7 (28)
7106 +#define DMA_USBEP4 (29)
7107 +#define DMA_USBEP5 (30)
7108 +#define DMA_USBEP6 (31)
7109 +#define DMA_PSC2_RX (32)
7110 +#define DMA_PSC2_TX (33)
7111 +#define DMA_PSC3_RX (34)
7112 +#define DMA_PSC3_TX (35)
7113 +#define DMA_FEC_RX(x) ((x == 0) ? DMA_FEC0_RX : DMA_FEC1_RX)
7114 +#define DMA_FEC_TX(x) ((x == 0) ? DMA_FEC0_TX : DMA_FEC1_TX)
7115 +
7116 +int dma_set_initiator(int);
7117 +unsigned int dma_get_initiator(int);
7118 +void dma_remove_initiator(int);
7119 +int dma_set_channel(int);
7120 +int dma_get_channel(int);
7121 +void dma_remove_channel(int);
7122 +int dma_set_channel_fec(int requestor);
7123 +int dma_connect(int channel, int address);
7124 +int dma_disconnect(int channel);
7125 +void dma_remove_channel_by_number(int channel);
7126 +int dma_init(void);
7127 +
7128 +#endif /* CONFIG_MCD_DMA */
7129 +
7130 +extern spinlock_t dma_spin_lock;
7131 +
7132 +static __inline__ unsigned long claim_dma_lock(void)
7133 +{
7134 + unsigned long flags;
7135 + spin_lock_irqsave(&dma_spin_lock, flags);
7136 + return flags;
7137 +}
7138 +
7139 +static __inline__ void release_dma_lock(unsigned long flags)
7140 +{
7141 + spin_unlock_irqrestore(&dma_spin_lock, flags);
7142 +}
7143 +
7144 +
7145 +/*
7146 + * Linux standard DMA stuff
7147 + */
7148 +#if 0
7149 +int request_dma(unsigned int channel, const char * device_id);
7150 +void free_dma(unsigned int channel);
7151 +void enable_dma(unsigned int channel);
7152 +void disable_dma(unsigned int channel);
7153 +int dma_channel_active(unsigned int channel);
7154 +void set_dma_sg(unsigned int channel, struct scatterlist *sg, int nr_sg);
7155 +void set_dma_page(unsigned int channel, char pagenr);
7156 +void set_dma_addr(unsigned int channel, unsigned long physaddr);
7157 +void set_dma_count(unsigned int channel, unsigned long count);
7158 +void set_dma_mode(unsigned int channel, unsigned int mode);
7159 +void set_dma_speed(unsigned int channel, int cycle_ns);
7160 +int get_dma_residue(unsigned int channel);
7161 +#endif
7162 +#define clear_dma_ff(channel)
7163 +
7164 +#endif /* not (defined(CONFIG_MCF5474) || defined(CONFIG_MCF5484) || defined(CONFIG_MCF5475) || defined(CONFIG_MCF5485)) */
7165 +
7166 #ifdef CONFIG_PCI
7167 extern int isa_dma_bridge_buggy;
7168 #else
7169 --- /dev/null
7170 +++ b/include/asm-m68k/m5485dma.h
7171 @@ -0,0 +1,97 @@
7172 +/*
7173 + * m5485dma.h -- ColdFire 547x/548x DMA controller support.
7174 + */
7175 +#ifndef __MCF548X_DMA_H__
7176 +#define __MCF548X_DMA_H__
7177 +
7178 +
7179 +/* Register read/write macros */
7180 +#define MCF_DMA_DIPR (*(volatile u32*)(void*)(MCF_MBAR+0x008014))
7181 +#define MCF_DMA_DIMR (*(volatile u32*)(void*)(MCF_MBAR+0x008018))
7182 +#define MCF_DMA_IMCR (*(volatile u32*)(void*)(MCF_MBAR+0x00805C))
7183 +
7184 +/* Bit definitions and macros for MCF_DMA_DIPR */
7185 +#define MCF_DMA_DIPR_TASK0 (0x00000001)
7186 +#define MCF_DMA_DIPR_TASK1 (0x00000002)
7187 +#define MCF_DMA_DIPR_TASK2 (0x00000004)
7188 +#define MCF_DMA_DIPR_TASK3 (0x00000008)
7189 +#define MCF_DMA_DIPR_TASK4 (0x00000010)
7190 +#define MCF_DMA_DIPR_TASK5 (0x00000020)
7191 +#define MCF_DMA_DIPR_TASK6 (0x00000040)
7192 +#define MCF_DMA_DIPR_TASK7 (0x00000080)
7193 +#define MCF_DMA_DIPR_TASK8 (0x00000100)
7194 +#define MCF_DMA_DIPR_TASK9 (0x00000200)
7195 +#define MCF_DMA_DIPR_TASK10 (0x00000400)
7196 +#define MCF_DMA_DIPR_TASK11 (0x00000800)
7197 +#define MCF_DMA_DIPR_TASK12 (0x00001000)
7198 +#define MCF_DMA_DIPR_TASK13 (0x00002000)
7199 +#define MCF_DMA_DIPR_TASK14 (0x00004000)
7200 +#define MCF_DMA_DIPR_TASK15 (0x00008000)
7201 +
7202 +/* Bit definitions and macros for MCF_DMA_DIMR */
7203 +#define MCF_DMA_DIMR_TASK0 (0x00000001)
7204 +#define MCF_DMA_DIMR_TASK1 (0x00000002)
7205 +#define MCF_DMA_DIMR_TASK2 (0x00000004)
7206 +#define MCF_DMA_DIMR_TASK3 (0x00000008)
7207 +#define MCF_DMA_DIMR_TASK4 (0x00000010)
7208 +#define MCF_DMA_DIMR_TASK5 (0x00000020)
7209 +#define MCF_DMA_DIMR_TASK6 (0x00000040)
7210 +#define MCF_DMA_DIMR_TASK7 (0x00000080)
7211 +#define MCF_DMA_DIMR_TASK8 (0x00000100)
7212 +#define MCF_DMA_DIMR_TASK9 (0x00000200)
7213 +#define MCF_DMA_DIMR_TASK10 (0x00000400)
7214 +#define MCF_DMA_DIMR_TASK11 (0x00000800)
7215 +#define MCF_DMA_DIMR_TASK12 (0x00001000)
7216 +#define MCF_DMA_DIMR_TASK13 (0x00002000)
7217 +#define MCF_DMA_DIMR_TASK14 (0x00004000)
7218 +#define MCF_DMA_DIMR_TASK15 (0x00008000)
7219 +
7220 +/* Bit definitions and macros for MCF_DMA_IMCR */
7221 +#define MCF_DMA_IMCR_SRC16(x) (((x)&0x00000003)<<0)
7222 +#define MCF_DMA_IMCR_SRC17(x) (((x)&0x00000003)<<2)
7223 +#define MCF_DMA_IMCR_SRC18(x) (((x)&0x00000003)<<4)
7224 +#define MCF_DMA_IMCR_SRC19(x) (((x)&0x00000003)<<6)
7225 +#define MCF_DMA_IMCR_SRC20(x) (((x)&0x00000003)<<8)
7226 +#define MCF_DMA_IMCR_SRC21(x) (((x)&0x00000003)<<10)
7227 +#define MCF_DMA_IMCR_SRC22(x) (((x)&0x00000003)<<12)
7228 +#define MCF_DMA_IMCR_SRC23(x) (((x)&0x00000003)<<14)
7229 +#define MCF_DMA_IMCR_SRC24(x) (((x)&0x00000003)<<16)
7230 +#define MCF_DMA_IMCR_SRC25(x) (((x)&0x00000003)<<18)
7231 +#define MCF_DMA_IMCR_SRC26(x) (((x)&0x00000003)<<20)
7232 +#define MCF_DMA_IMCR_SRC27(x) (((x)&0x00000003)<<22)
7233 +#define MCF_DMA_IMCR_SRC28(x) (((x)&0x00000003)<<24)
7234 +#define MCF_DMA_IMCR_SRC29(x) (((x)&0x00000003)<<26)
7235 +#define MCF_DMA_IMCR_SRC30(x) (((x)&0x00000003)<<28)
7236 +#define MCF_DMA_IMCR_SRC31(x) (((x)&0x00000003)<<30)
7237 +#define MCF_DMA_IMCR_SRC16_FEC0RX (0x00000000)
7238 +#define MCF_DMA_IMCR_SRC17_FEC0TX (0x00000000)
7239 +#define MCF_DMA_IMCR_SRC18_FEC0RX (0x00000020)
7240 +#define MCF_DMA_IMCR_SRC19_FEC0TX (0x00000080)
7241 +#define MCF_DMA_IMCR_SRC20_FEC1RX (0x00000100)
7242 +#define MCF_DMA_IMCR_SRC21_DREQ1 (0x00000000)
7243 +#define MCF_DMA_IMCR_SRC21_FEC1TX (0x00000400)
7244 +#define MCF_DMA_IMCR_SRC22_FEC0RX (0x00001000)
7245 +#define MCF_DMA_IMCR_SRC23_FEC0TX (0x00004000)
7246 +#define MCF_DMA_IMCR_SRC24_CTM0 (0x00010000)
7247 +#define MCF_DMA_IMCR_SRC24_FEC1RX (0x00020000)
7248 +#define MCF_DMA_IMCR_SRC25_CTM1 (0x00040000)
7249 +#define MCF_DMA_IMCR_SRC25_FEC1TX (0x00080000)
7250 +#define MCF_DMA_IMCR_SRC26_USBEP4 (0x00000000)
7251 +#define MCF_DMA_IMCR_SRC26_CTM2 (0x00200000)
7252 +#define MCF_DMA_IMCR_SRC27_USBEP5 (0x00000000)
7253 +#define MCF_DMA_IMCR_SRC27_CTM3 (0x00800000)
7254 +#define MCF_DMA_IMCR_SRC28_USBEP6 (0x00000000)
7255 +#define MCF_DMA_IMCR_SRC28_CTM4 (0x01000000)
7256 +#define MCF_DMA_IMCR_SRC28_DREQ1 (0x02000000)
7257 +#define MCF_DMA_IMCR_SRC28_PSC2RX (0x03000000)
7258 +#define MCF_DMA_IMCR_SRC29_DREQ1 (0x04000000)
7259 +#define MCF_DMA_IMCR_SRC29_CTM5 (0x08000000)
7260 +#define MCF_DMA_IMCR_SRC29_PSC2TX (0x0C000000)
7261 +#define MCF_DMA_IMCR_SRC30_FEC1RX (0x00000000)
7262 +#define MCF_DMA_IMCR_SRC30_CTM6 (0x10000000)
7263 +#define MCF_DMA_IMCR_SRC30_PSC3RX (0x30000000)
7264 +#define MCF_DMA_IMCR_SRC31_FEC1TX (0x00000000)
7265 +#define MCF_DMA_IMCR_SRC31_CTM7 (0x80000000)
7266 +#define MCF_DMA_IMCR_SRC31_PSC3TX (0xC0000000)
7267 +
7268 +#endif /* __MCF548X_DMA_H__ */
7269 --- /dev/null
7270 +++ b/include/asm-m68k/m5485sram.h
7271 @@ -0,0 +1,12 @@
7272 +#ifndef SYS_SRAM_H
7273 +#define SYS_SRAM_H
7274 +
7275 +
7276 +#define SYS_SRAM_DMA_START MCF_MBAR + 0x10000
7277 +#define SYS_SRAM_DMA_SIZE 8192
7278 +#define SYS_SRAM_FEC_START SYS_SRAM_DMA_START + SYS_SRAM_DMA_SIZE
7279 +#define SYS_SRAM_FEC_SIZE 2048
7280 +#define SYS_SRAM_SEC_START SYS_SRAM_FEC_START + SYS_SRAM_FEC_SIZE
7281 +#define SYS_SRAM_SEC_SIZE 1280
7282 +
7283 +#endif /* SYS_SRAM_H */
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