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wdenk3a473b22004-01-03 00:43:19 +00001/*
2 * Copyright - Galileo technology.
3 *
4 * See file CREDITS for list of people who contributed to this
5 * project.
6 *
7 * This program is free software; you can redistribute it and/or
8 * modify it under the terms of the GNU General Public License as
9 * published by the Free Software Foundation; either version 2 of
10 * the License, or (at your option) any later version.
11 *
12 * This program is distributed in the hope that it will be useful,
13 * but WITHOUT ANY WARRANTY; without even the implied warranty of
14 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 * GNU General Public License for more details.
16 *
17 * You should have received a copy of the GNU General Public License
18 * along with this program; if not, write to the Free Software
19 * Foundation, Inc., 59 Temple Place, Suite 330, Boston,
20 * MA 02111-1307 USA
21 */
22
23/*
24 *
25 * written or collected and sometimes rewritten by
26 * Ingo Assmus <ingo.assmus@keymile.com>
27 *
28 */
29
30
31#include <common.h>
32#include "../include/core.h"
33#include "../include/memory.h"
34
35/*******************************************************************************
36* memoryGetBankBaseAddress - Returns the base address of a memory bank.
37* DESCRIPTION:
38* This function returns the base address of one of the SDRAMÂ’s memory
39* banks. There are 4 memory banks and each one represents one DIMM side.
40* INPUT:
41* MEMORY_BANK bank - Selects one of the four banks as defined in Memory.h.
42* OUTPUT:
43* None.
44* RETURN:
45* 32 bit Memory bank base address.
46*******************************************************************************/
47static unsigned long memoryGetBankRegOffset (MEMORY_BANK bank)
48{
49 switch (bank) {
50 case BANK0:
51 return SCS_0_LOW_DECODE_ADDRESS;
52 case BANK1:
53 return SCS_1_LOW_DECODE_ADDRESS;
54 case BANK2:
55 return SCS_2_LOW_DECODE_ADDRESS;
56 case BANK3:
57 return SCS_3_LOW_DECODE_ADDRESS;
58
59 }
60 return SCS_0_LOW_DECODE_ADDRESS; /* default value */
61}
62
63unsigned int memoryGetBankBaseAddress (MEMORY_BANK bank)
64{
65 unsigned int base;
66 unsigned int regOffset = memoryGetBankRegOffset (bank);
67
68 GT_REG_READ (regOffset, &base);
69 base = base << 16; /* MV6436x */
70 return base;
71}
72
73/*******************************************************************************
74* memoryGetDeviceBaseAddress - Returns the base address of a device.
75* DESCRIPTION:
76* This function returns the base address of a device on the system. There
77* are 5 possible devices (0 - 4 and one boot device) as defined in
78* gtMemory.h. Each of the device parameters is maped to one of the CS
79* (Devices chip selects) base address register.
80* INPUT:
81* device - Selects one of the five devices as defined in Memory.h.
82* OUTPUT:
83* None.
84* RETURN:
85* 32 bit Device base address.
86*
87*******************************************************************************/
88static unsigned int memoryGetDeviceRegOffset (DEVICE device)
89{
90 switch (device) {
91 case DEVICE0:
92 return CS_0_LOW_DECODE_ADDRESS;
93 case DEVICE1:
94 return CS_1_LOW_DECODE_ADDRESS;
95 case DEVICE2:
96 return CS_2_LOW_DECODE_ADDRESS;
97 case DEVICE3:
98 return CS_3_LOW_DECODE_ADDRESS;
99 case BOOT_DEVICE:
100 return BOOTCS_LOW_DECODE_ADDRESS;
101 }
102 return CS_0_LOW_DECODE_ADDRESS; /* default value */
103}
104
105unsigned int memoryGetDeviceBaseAddress (DEVICE device)
106{
107 unsigned int regBase;
108 unsigned int regOffset = memoryGetDeviceRegOffset (device);
109
110 GT_REG_READ (regOffset, &regBase);
111
112 regBase = regBase << 16; /* MV6436x */
113 return regBase;
114}
115
116/*******************************************************************************
117* MemoryGetPciBaseAddr - Returns the base address of a PCI window.
118* DESCRIPTION:
119* This function returns the base address of a PCI window. There are 5
120* possible PCI windows (memory 0 - 3 and one for I/O) for each PCI
121* interface as defined in gtMemory.h, used by the CPU's address decoding
122* mechanism.
123* New in MV6436x
124* INPUT:
125* pciWindow - Selects one of the PCI windows as defined in Memory.h.
126* OUTPUT:
127* None.
128* RETURN:
129* 32 bit PCI window base address.
130*******************************************************************************/
131unsigned int MemoryGetPciBaseAddr (PCI_MEM_WINDOW pciWindow)
132{
133 unsigned int baseAddrReg, base;
134
135 switch (pciWindow) {
136 case PCI_0_IO:
137 baseAddrReg = PCI_0I_O_LOW_DECODE_ADDRESS; /*PCI_0_IO_BASE_ADDR; */
138 break;
139 case PCI_0_MEM0:
140 baseAddrReg = PCI_0MEMORY0_LOW_DECODE_ADDRESS; /*PCI_0_MEMORY0_BASE_ADDR; */
141 break;
142 case PCI_0_MEM1:
143 baseAddrReg = PCI_0MEMORY1_LOW_DECODE_ADDRESS; /*PCI_0_MEMORY1_BASE_ADDR; */
144 break;
145 case PCI_0_MEM2:
146 baseAddrReg = PCI_0MEMORY2_LOW_DECODE_ADDRESS; /*PCI_0_MEMORY2_BASE_ADDR; */
147 break;
148 case PCI_0_MEM3:
149 baseAddrReg = PCI_0MEMORY3_LOW_DECODE_ADDRESS; /*PCI_0_MEMORY3_BASE_ADDR; */
150 break;
151#ifdef INCLUDE_PCI_1
152 case PCI_1_IO:
153 baseAddrReg = PCI_1I_O_LOW_DECODE_ADDRESS; /*PCI_1_IO_BASE_ADDR; */
154 break;
155 case PCI_1_MEM0:
156 baseAddrReg = PCI_1MEMORY0_LOW_DECODE_ADDRESS; /*PCI_1_MEMORY0_BASE_ADDR; */
157 break;
158 case PCI_1_MEM1:
159 baseAddrReg = PCI_1MEMORY1_LOW_DECODE_ADDRESS; /*PCI_1_MEMORY1_BASE_ADDR; */
160 break;
161 case PCI_1_MEM2:
162 baseAddrReg = PCI_1MEMORY2_LOW_DECODE_ADDRESS; /*PCI_1_MEMORY2_BASE_ADDR; */
163 break;
164 case PCI_1_MEM3:
165 baseAddrReg = PCI_1MEMORY3_LOW_DECODE_ADDRESS; /*PCI_1_MEMORY3_BASE_ADDR; */
166 break;
167#endif /* INCLUDE_PCI_1 */
168 default:
169 return 0xffffffff;
170 }
171 GT_REG_READ (baseAddrReg, &base);
172 return (base << 16);
173}
174
175/*******************************************************************************
176* memoryGetBankSize - Returns the size of a memory bank.
177* DESCRIPTION:
178* This function returns the size of memory bank as described in
179* 'gtMemoryGetBankBaseAddress' function.
180* INPUT:
181* bank - Selects one of the four banks as defined in Memory.h.
182* OUTPUT:
183* None.
184* RETURN:
185* 32 bit size memory bank size or 0 for a closed or non populated bank.
186*
187*******************************************************************************/
188unsigned int memoryGetBankSize (MEMORY_BANK bank)
189{
190 unsigned int sizeReg, size;
191 MEMORY_WINDOW window;
192
193 switch (bank) {
194 case BANK0:
195 sizeReg = SCS_0_HIGH_DECODE_ADDRESS; /* CS_0_SIZE; */
196 window = CS_0_WINDOW;
197 break;
198 case BANK1:
199 sizeReg = SCS_1_HIGH_DECODE_ADDRESS; /* CS_1_SIZE; */
200 window = CS_1_WINDOW;
201 break;
202 case BANK2:
203 sizeReg = SCS_2_HIGH_DECODE_ADDRESS; /* CS_2_SIZE; */
204 window = CS_2_WINDOW;
205 break;
206 case BANK3:
207 sizeReg = SCS_3_HIGH_DECODE_ADDRESS; /* CS_3_SIZE; */
208 window = CS_3_WINDOW;
209 break;
210 default:
211 return 0;
212 break;
213 }
214 /* If the window is closed, a size of 0 is returned */
215 if (MemoryGetMemWindowStatus (window) != MEM_WINDOW_ENABLED)
216 return 0;
217 GT_REG_READ (sizeReg, &size);
218 size = ((size << 16) | 0xffff) + 1;
219 return size;
220}
221
222/*******************************************************************************
223* memoryGetDeviceSize - Returns the size of a device memory space.
224* DESCRIPTION:
225* This function returns the memory space size of a given device.
226* INPUT:
227* device - Selects one of the five devices as defined in Memory.h.
228* OUTPUT:
229* None.
230* RETURN:
231* 32 bit size of a device memory space.
232*******************************************************************************/
233unsigned int memoryGetDeviceSize (DEVICE device)
234{
235 unsigned int sizeReg, size;
236 MEMORY_WINDOW window;
237
238 switch (device) {
239 case DEVICE0:
240 sizeReg = CS_0_HIGH_DECODE_ADDRESS; /*DEV_CS0_SIZE; */
241 window = DEVCS_0_WINDOW;
242 break;
243 case DEVICE1:
244 sizeReg = CS_1_HIGH_DECODE_ADDRESS; /*DEV_CS1_SIZE; */
245 window = DEVCS_1_WINDOW;
246 break;
247 case DEVICE2:
248 sizeReg = CS_2_HIGH_DECODE_ADDRESS; /*DEV_CS2_SIZE; */
249 window = DEVCS_2_WINDOW;
250 break;
251 case DEVICE3:
252 sizeReg = CS_3_HIGH_DECODE_ADDRESS; /*DEV_CS3_SIZE; */
253 window = DEVCS_3_WINDOW;
254 break;
255 case BOOT_DEVICE:
256 sizeReg = BOOTCS_HIGH_DECODE_ADDRESS; /*BOOTCS_SIZE; */
257 window = BOOT_CS_WINDOW;
258 break;
259 default:
260 return 0;
261 break;
262 }
263 /* If the window is closed, a size of 0 is returned */
264 if (MemoryGetMemWindowStatus (window) != MEM_WINDOW_ENABLED)
265 return 0;
266 GT_REG_READ (sizeReg, &size);
267 size = ((size << 16) | 0xffff) + 1;
268 return size;
269}
270
271/*******************************************************************************
272* MemoryGetPciWindowSize - Returns the size of a PCI memory window.
273* DESCRIPTION:
274* This function returns the size of a PCI window.
275* INPUT:
276* pciWindow - Selects one of the PCI memory windows as defined in
277* Memory.h.
278* OUTPUT:
279* None.
280* RETURN:
281* 32 bit size of a PCI memory window.
282*******************************************************************************/
283unsigned int MemoryGetPciWindowSize (PCI_MEM_WINDOW pciWindow)
284{
285 unsigned int sizeReg, size;
286
287 switch (pciWindow) {
288 case PCI_0_IO:
289 sizeReg = PCI_0I_O_HIGH_DECODE_ADDRESS; /*PCI_0_IO_SIZE; */
290 break;
291 case PCI_0_MEM0:
292 sizeReg = PCI_0MEMORY0_HIGH_DECODE_ADDRESS; /*PCI_0_MEMORY0_SIZE; */
293 break;
294 case PCI_0_MEM1:
295 sizeReg = PCI_0MEMORY1_HIGH_DECODE_ADDRESS; /*PCI_0_MEMORY1_SIZE; */
296 break;
297 case PCI_0_MEM2:
298 sizeReg = PCI_0MEMORY2_HIGH_DECODE_ADDRESS; /*PCI_0_MEMORY2_SIZE; */
299 break;
300 case PCI_0_MEM3:
301 sizeReg = PCI_0MEMORY3_HIGH_DECODE_ADDRESS; /*PCI_0_MEMORY3_SIZE; */
302 break;
303#ifdef INCLUDE_PCI_1
304 case PCI_1_IO:
305 sizeReg = PCI_1I_O_HIGH_DECODE_ADDRESS; /*PCI_1_IO_SIZE; */
306 break;
307 case PCI_1_MEM0:
308 sizeReg = PCI_1MEMORY0_HIGH_DECODE_ADDRESS; /*PCI_1_MEMORY0_SIZE; */
309 break;
310 case PCI_1_MEM1:
311 sizeReg = PCI_1MEMORY1_HIGH_DECODE_ADDRESS; /*PCI_1_MEMORY1_SIZE; */
312 break;
313 case PCI_1_MEM2:
314 sizeReg = PCI_1MEMORY2_HIGH_DECODE_ADDRESS; /*PCI_1_MEMORY2_SIZE; */
315 break;
316 case PCI_1_MEM3:
317 sizeReg = PCI_1MEMORY3_HIGH_DECODE_ADDRESS; /*PCI_1_MEMORY3_SIZE; */
318 break;
319#endif /* INCLUDE_PCI_1 */
320 default:
321 return 0x0;
322 }
323 /* If the memory window is disabled, retrun size = 0 */
324 if (MemoryGetMemWindowStatus (PCI_0_IO_WINDOW << pciWindow)
325 == MEM_WINDOW_DISABLED)
326 return 0;
327 GT_REG_READ (sizeReg, &size);
328 size = ((size << 16) | 0xffff) + 1;
329 return size;
330}
331
332/*******************************************************************************
333* memoryGetDeviceWidth - Returns the width of a given device.
334* DESCRIPTION:
335* The MV's device interface supports up to 32 Bit wide devices. A device
336* can have a 1, 2, 4 or 8 Bytes data width. This function returns the
337* width of a device as defined by the user or the operating system.
338* INPUT:
339* device - Selects one of the five devices as defined in Memory.h.
340* OUTPUT:
341* None.
342* RETURN:
343* Device width in Bytes (1,2,4 or 8), 0 if error had occurred.
344*******************************************************************************/
345unsigned int memoryGetDeviceWidth (DEVICE device)
346{
347 unsigned int width;
348 unsigned int regValue;
349
350 GT_REG_READ (DEVICE_BANK0PARAMETERS + device * 4, &regValue);
351 width = (regValue & (BIT20 | BIT21)) >> 20;
352 return (BIT0 << width);
353}
354
355/*******************************************************************************
356* memoryMapBank - Set new base address and size for one of the memory
357* banks.
358*
359* DESCRIPTION:
360* The CPU interface address decoding map consists of 21 address windows
361* for the different devices (e.g. CS[3:0] ,PCI0 Mem 0/1/2/3...). Each
362* window can have a minimum of 1Mbytes of address space, and up to 4Gbyte
363* space. Each address window is defined by two registers - base and size.
364* The CPU address is compared with the values in the various CPU windows
365* until a match is found and the address is than targeted to that window.
366* This function sets new base and size for one the memory banks
367* (CS0 - CS3). It is the programmer`s responsibility to make sure that
368* there are no conflicts with other memory spaces. When two memory spaces
369* overlap, the MVÂ’s behavior is not defined .If a bank needs to be closed,
370* set the Â’bankLengthÂ’ parameter size to 0x0.
371*
372* INPUT:
373* bank - One of the memory banks (CS0-CS3) as defined in gtMemory.h.
374* bankBase - The memory bank base address.
375* bankLength - The memory bank size. This function will decrement the
376* 'bankLength' parameter by one and then check if the size is
377* valid. A valid size must be programed from LSB to MSB as
378* sequence of ‘1’s followed by sequence of ‘0’s.
379* To close a memory window simply set the size to 0.
380* NOTE!!!
381* The size must be in 64Kbyte granularity.
382* The base address must be aligned to the size.
383* OUTPUT:
384* None.
385* RETURN:
386* False for invalid size, true otherwise.
387*
388* CAUTION: PCI_functions must be implemented later To_do !!!!!!!!!!!!!!!!!
389*
390*******************************************************************************/
391
392bool memoryMapBank (MEMORY_BANK bank, unsigned int bankBase,
393 unsigned int bankLength)
394{
395 unsigned int newBase, newSize, baseReg, sizeReg, temp, rShift;
396
397/* PCI_INTERNAL_BAR pciBAR; */
398
399 switch (bank) {
400 case BANK0:
401 baseReg = SCS_0_LOW_DECODE_ADDRESS; /*CS_0_BASE_ADDR; */
402 sizeReg = SCS_0_HIGH_DECODE_ADDRESS; /*CS_0_SIZE; */
403/* pciBAR = PCI_CS0_BAR; */
404 break;
405 case BANK1:
406 baseReg = SCS_1_LOW_DECODE_ADDRESS; /*CS_1_BASE_ADDR; */
407 sizeReg = SCS_1_HIGH_DECODE_ADDRESS; /*CS_1_SIZE; */
408 /* pciBAR = SCS_0_HIGH_DECODE_ADDRESS; */ /*PCI_CS1_BAR; */
409 break;
410 case BANK2:
411 baseReg = SCS_2_LOW_DECODE_ADDRESS; /*CS_2_BASE_ADDR; */
412 sizeReg = SCS_2_HIGH_DECODE_ADDRESS; /*CS_2_SIZE; */
413/* pciBAR = PCI_CS2_BAR;*/
414 break;
415 case BANK3:
416 baseReg = SCS_3_LOW_DECODE_ADDRESS; /*CS_3_BASE_ADDR; */
417 sizeReg = SCS_3_HIGH_DECODE_ADDRESS; /*CS_3_SIZE; */
418/* pciBAR = PCI_CS3_BAR; */
419 break;
420 default:
421 return false;
422 }
423 /* If the size is 0, the window will be disabled */
424 if (bankLength == 0) {
425 MemoryDisableWindow (CS_0_WINDOW << bank);
426 /* Disable the BAR from the PCI slave side */
427/* gtPci0DisableInternalBAR(pciBAR); */
428/* gtPci1DisableInternalBAR(pciBAR); */
429 return true;
430 }
431 /* The base address must be aligned to the size */
432 if ((bankBase % bankLength) != 0) {
433 return false;
434 }
435 if (bankLength >= MINIMUM_MEM_BANK_SIZE) {
436 newBase = bankBase >> 16;
437 newSize = bankLength >> 16;
438 /* Checking that the size is a sequence of '1' followed by a
439 sequence of '0' starting from LSB to MSB. */
440 temp = newSize - 1;
441 for (rShift = 0; rShift < 16; rShift++) {
442 temp = temp >> rShift;
443 if ((temp & 0x1) == 0) { /* Either we got to the last '1' */
444 /* or the size is not valid */
445 if (temp > 0x0)
446 return false;
447 else
448 break;
449 }
450 }
451#ifdef DEBUG
452 {
453 unsigned int oldBase, oldSize;
454
455 GT_REG_READ (baseReg, &oldBase);
456 GT_REG_READ (sizeReg + 8, &oldSize);
457
458 printf ("b%d Base:%x Size:%x -> Base:%x Size:%x\n",
459 bank, oldBase, oldSize, newBase, newSize);
460 }
461#endif
462 /* writing the new values */
463 GT_REG_WRITE (baseReg, newBase);
464 GT_REG_WRITE (sizeReg, newSize - 1);
465 /* Enable back the window */
466 MemoryEnableWindow (CS_0_WINDOW << bank);
467 /* Enable the BAR from the PCI slave side */
468/* gtPci0EnableInternalBAR(pciBAR); */
469/* gtPci1EnableInternalBAR(pciBAR); */
470 return true;
471 }
472 return false;
473}
474
475
476/*******************************************************************************
477* memoryMapDeviceSpace - Set new base address and size for one of the device
478* windows.
479*
480* DESCRIPTION:
481* The CPU interface address decoding map consists of 21 address windows
482* for the different devices (e.g. CS[3:0] ,PCI0 Mem 0/1/2/3...). Each
483* window can have a minimum of 1Mbytes of address space, and up to 4Gbyte
484* space. Each address window is defined by two registers - base and size.
485* The CPU address is compared with the values in the various CPU windows
486* until a match is found and the address is than targeted to that window.
487* This function sets new base and size for one the device windows
488* (DEV_CS0 - DEV_CS3). It is the programmer`s responsibility to make sure
489* that there are no conflicts with other memory spaces. When two memory
490* spaces overlap, the MVÂ’s behavior is not defined .If a device window
491* needs to be closed, set the 'deviceLength' parameter size to 0x0.
492*
493* INPUT:
494* device - One of the device windows (DEV_CS0-DEV_CS3) as
495* defined in gtMemory.h.
496* deviceBase - The device window base address.
497* deviceLength - The device window size. This function will decrement
498* the 'deviceLength' parameter by one and then
499* check if the size is valid. A valid size must be
500* programed from LSB to MSB as sequence of ‘1’s
501* followed by sequence of ‘0’s.
502* To close a memory window simply set the size to 0.
503*
504* NOTE!!!
505* The size must be in 64Kbyte granularity.
506* The base address must be aligned to the size.
507*
508* OUTPUT:
509* None.
510*
511* RETURN:
512* False for invalid size, true otherwise.
513*
514* CAUTION: PCI_functions must be implemented later To_do !!!!!!!!!!!!!!!!!
515*
516*******************************************************************************/
517
518bool memoryMapDeviceSpace (DEVICE device, unsigned int deviceBase,
519 unsigned int deviceLength)
520{
521 unsigned int newBase, newSize, baseReg, sizeReg, temp, rShift;
522
523/* PCI_INTERNAL_BAR pciBAR;*/
524
525 switch (device) {
526 case DEVICE0:
527 baseReg = CS_0_LOW_DECODE_ADDRESS; /*DEV_CS0_BASE_ADDR; */
528 sizeReg = CS_0_HIGH_DECODE_ADDRESS; /*DEV_CS0_SIZE; */
529/* pciBAR = PCI_DEV_CS0_BAR; */
530 break;
531 case DEVICE1:
532 baseReg = CS_1_LOW_DECODE_ADDRESS; /*DEV_CS1_BASE_ADDR; */
533 sizeReg = CS_1_HIGH_DECODE_ADDRESS; /*DEV_CS1_SIZE; */
534/* pciBAR = PCI_DEV_CS1_BAR; */
535 break;
536 case DEVICE2:
537 baseReg = CS_2_LOW_DECODE_ADDRESS; /*DEV_CS2_BASE_ADDR; */
538 sizeReg = CS_2_HIGH_DECODE_ADDRESS; /*DEV_CS2_SIZE; */
539/* pciBAR = PCI_DEV_CS2_BAR; */
540 break;
541 case DEVICE3:
542 baseReg = CS_3_LOW_DECODE_ADDRESS; /*DEV_CS3_BASE_ADDR; */
543 sizeReg = CS_3_HIGH_DECODE_ADDRESS; /*DEV_CS3_SIZE; */
544/* pciBAR = PCI_DEV_CS3_BAR; */
545 break;
546 case BOOT_DEVICE:
547 baseReg = BOOTCS_LOW_DECODE_ADDRESS; /*BOOTCS_BASE_ADDR; */
548 sizeReg = BOOTCS_HIGH_DECODE_ADDRESS; /*BOOTCS_SIZE; */
549/* pciBAR = PCI_BOOT_CS_BAR; */
550 break;
551 default:
552 return false;
553 }
554 if (deviceLength == 0) {
555 MemoryDisableWindow (DEVCS_0_WINDOW << device);
556 /* Disable the BAR from the PCI slave side */
557/* gtPci0DisableInternalBAR(pciBAR); */
558/* gtPci1DisableInternalBAR(pciBAR); */
559 return true;
560 }
561 /* The base address must be aligned to the size */
562 if ((deviceBase % deviceLength) != 0) {
563 return false;
564 }
565 if (deviceLength >= MINIMUM_DEVICE_WINDOW_SIZE) {
566 newBase = deviceBase >> 16;
567 newSize = deviceLength >> 16;
568 /* Checking that the size is a sequence of '1' followed by a
569 sequence of '0' starting from LSB to MSB. */
570 temp = newSize - 1;
571 for (rShift = 0; rShift < 16; rShift++) {
572 temp = temp >> rShift;
573 if ((temp & 0x1) == 0) { /* Either we got to the last '1' */
574 /* or the size is not valid */
575 if (temp > 0x0)
576 return false;
577 else
578 break;
579 }
580 }
581 /* writing the new values */
582 GT_REG_WRITE (baseReg, newBase);
583 GT_REG_WRITE (sizeReg, newSize - 1);
584 MemoryEnableWindow (DEVCS_0_WINDOW << device);
585 /* Enable the BAR from the PCI slave side */
586/* gtPci0EnableInternalBAR(pciBAR); */
587/* gtPci1EnableInternalBAR(pciBAR); */
588 return true;
589 }
590 return false;
591}
592
593/*******************************************************************************
594* MemorySetPciWindow - Set new base address and size for one of the PCI
595* windows.
596*
597* DESCRIPTION:
598* The CPU interface address decoding map consists of 21 address windows
599* for the different devices (e.g. CS[3:0] ,PCI0 Mem 0/1/2/3...). Each
600* window can have a minimum of 1Mbytes of address space, and up to 4Gbyte
601* space. Each address window is defined by two registers - base and size.
602* The CPU address is compared with the values in the various CPU windows
603* until a match is found and the address is than targeted to that window.
604* This function sets new base and size for one the PCI windows
605* (PCI memory0/1/2..). It is the programmer`s responsibility to make sure
606* that there are no conflicts with other memory spaces. When two memory
607* spaces overlap, the MVÂ’s behavior is not defined .If a PCI window
608* needs to be closed, set the 'pciWindowSize' parameter size to 0x0.
609*
610* INPUT:
611* pciWindow - One of the PCI windows as defined in gtMemory.h.
612* pciWindowBase - The PCI window base address.
613* pciWindowSize - The PCI window size. This function will decrement the
614* 'pciWindowSize' parameter by one and then check if the
615* size is valid. A valid size must be programed from LSB
616* to MSB as sequence of ‘1’s followed by sequence of ‘0’s.
617* To close a memory window simply set the size to 0.
618*
619* NOTE!!!
620* The size must be in 64Kbyte granularity.
621* The base address must be aligned to the size.
622*
623* OUTPUT:
624* None.
625*
626* RETURN:
627* False for invalid size, true otherwise.
628*
629*******************************************************************************/
630bool memorySetPciWindow (PCI_MEM_WINDOW pciWindow, unsigned int pciWindowBase,
631 unsigned int pciWindowSize)
632{
633 unsigned int currentLow, baseAddrReg, sizeReg, temp, rShift;
634
635 switch (pciWindow) {
636 case PCI_0_IO:
637 baseAddrReg = PCI_1I_O_LOW_DECODE_ADDRESS; /*PCI_0_IO_BASE_ADDR; */
638 sizeReg = PCI_0I_O_HIGH_DECODE_ADDRESS; /*PCI_0_IO_SIZE; */
639 break;
640 case PCI_0_MEM0:
641 baseAddrReg = PCI_0MEMORY0_LOW_DECODE_ADDRESS; /*PCI_0_MEMORY0_BASE_ADDR; */
642 sizeReg = PCI_0MEMORY0_HIGH_DECODE_ADDRESS; /*PCI_0_MEMORY0_SIZE; */
643 break;
644 case PCI_0_MEM1:
645 baseAddrReg = PCI_0MEMORY1_LOW_DECODE_ADDRESS; /*PCI_0_MEMORY1_BASE_ADDR; */
646 sizeReg = PCI_0MEMORY1_HIGH_DECODE_ADDRESS; /*PCI_0_MEMORY1_SIZE; */
647 break;
648 case PCI_0_MEM2:
649 baseAddrReg = PCI_0MEMORY2_LOW_DECODE_ADDRESS; /*PCI_0_MEMORY2_BASE_ADDR; */
650 sizeReg = PCI_0MEMORY2_HIGH_DECODE_ADDRESS; /*PCI_0_MEMORY2_SIZE; */
651 break;
652 case PCI_0_MEM3:
653 baseAddrReg = PCI_0MEMORY3_LOW_DECODE_ADDRESS; /*PCI_0_MEMORY3_BASE_ADDR; */
654 sizeReg = PCI_0MEMORY3_HIGH_DECODE_ADDRESS; /*PCI_0_MEMORY3_SIZE; */
655 break;
656#ifdef INCLUDE_PCI_1
657 case PCI_1_IO:
658 baseAddrReg = PCI_1I_O_LOW_DECODE_ADDRESS; /*PCI_1_IO_BASE_ADDR; */
659 sizeReg = PCI_1I_O_HIGH_DECODE_ADDRESS; /*PCI_1_IO_SIZE; */
660 break;
661 case PCI_1_MEM0:
662 baseAddrReg = PCI_1MEMORY0_LOW_DECODE_ADDRESS; /*PCI_1_MEMORY0_BASE_ADDR; */
663 sizeReg = PCI_1MEMORY0_HIGH_DECODE_ADDRESS; /*PCI_1_MEMORY0_SIZE; */
664 break;
665 case PCI_1_MEM1:
666 baseAddrReg = PCI_1MEMORY1_LOW_DECODE_ADDRESS; /*PCI_1_MEMORY1_BASE_ADDR; */
667 sizeReg = PCI_1MEMORY1_HIGH_DECODE_ADDRESS; /*PCI_1_MEMORY1_SIZE; */
668 break;
669 case PCI_1_MEM2:
670 baseAddrReg = PCI_1MEMORY2_LOW_DECODE_ADDRESS; /*PCI_1_MEMORY2_BASE_ADDR; */
671 sizeReg = PCI_1MEMORY2_HIGH_DECODE_ADDRESS; /*PCI_1_MEMORY2_SIZE; */
672 break;
673 case PCI_1_MEM3:
674 baseAddrReg = PCI_1MEMORY3_LOW_DECODE_ADDRESS; /*PCI_1_MEMORY3_BASE_ADDR; */
675 sizeReg = PCI_1MEMORY3_HIGH_DECODE_ADDRESS; /*PCI_1_MEMORY3_SIZE; */
676 break;
677#endif /* INCLUDE_PCI_1 */
678 default:
679 return false;
680 }
681 if (pciWindowSize == 0) {
682 MemoryDisableWindow (PCI_0_IO_WINDOW << pciWindow);
683 return true;
684 }
685 /* The base address must be aligned to the size */
686 if ((pciWindowBase % pciWindowSize) != 0) {
687 return false;
688 }
689 if (pciWindowSize >= MINIMUM_PCI_WINDOW_SIZE) {
690 pciWindowBase >>= 16;
691 pciWindowSize >>= 16;
692 /* Checking that the size is a sequence of '1' followed by a
693 sequence of '0' starting from LSB to MSB. */
694 temp = pciWindowSize - 1;
695 for (rShift = 0; rShift < 16; rShift++) {
696 temp = temp >> rShift;
697 if ((temp & 0x1) == 0) { /* Either we got to the last '1' */
698 /* or the size is not valid */
699 if (temp > 0x0)
700 return false;
701 else
702 break;
703 }
704 }
705 GT_REG_WRITE (sizeReg, pciWindowSize - 1);
706 GT_REG_READ (baseAddrReg, &currentLow);
707 pciWindowBase =
708 (pciWindowBase & 0xfffff) | (currentLow & 0xfff00000);
709 GT_REG_WRITE (baseAddrReg, pciWindowBase);
710 MemoryEnableWindow (PCI_0_IO_WINDOW << pciWindow);
711 return true;
712 }
713 return false;
714}
715
716/*******************************************************************************
717* memoryMapInternalRegistersSpace - Sets new base address for the internal
718* registers memory space.
719*
720* DESCRIPTION:
721* This function set new base address for the internal registerÂ’s memory
722* space (the size is fixed and cannot be modified). The function does not
723* handle overlapping with other memory spaces, it is the programer's
724* responsibility to ensure that overlapping does not occur.
725* When two memory spaces overlap, the MVÂ’s behavior is not defined.
726*
727* INPUT:
728* internalRegBase - new base address for the internal registerÂ’s memory
729* space.
730*
731* OUTPUT:
732* None.
733*
734* RETURN:
735* true on success, false on failure
736*
737*******************************************************************************/
738/********************************************************************
739* memoryMapInternalRegistersSpace - Sets new base address for the internals
740* registers.
741*
742* INPUTS: unsigned int internalRegBase - The new base address.
743* RETURNS: true on success, false on failure
744*********************************************************************/
745bool memoryMapInternalRegistersSpace (unsigned int internalRegBase)
746{
747 unsigned int currentValue;
748 unsigned int internalValue = internalRegBase;
749
750 internalRegBase = (internalRegBase >> 16);
751 GT_REG_READ (INTERNAL_SPACE_DECODE, &currentValue);
752 internalRegBase = (currentValue & 0xff000000) | internalRegBase;
753 GT_REG_WRITE (INTERNAL_SPACE_DECODE, internalRegBase);
754 /* initializing also the global variable 'internalRegBaseAddr' */
755/* gtInternalRegBaseAddr = internalValue; */
756 INTERNAL_REG_BASE_ADDR = internalValue;
757 return true;
758}
759
760/*******************************************************************************
761* memoryGetInternalRegistersSpace - Returns the internal registers Base
762* address.
763*
764* DESCRIPTION:
765* This function returns the base address of the internal registerÂ’s
766* memory space .
767*
768* INPUT:
769* None.
770*
771* OUTPUT:
772* None.
773*
774* RETURN:
775* 32 bit base address of the internal registerÂ’s memory space.
776*
777*******************************************************************************/
778unsigned int memoryGetInternalRegistersSpace (void)
779{
780 unsigned int currentValue = 0;
781
782 GT_REG_READ (INTERNAL_SPACE_DECODE, &currentValue);
783 return ((currentValue & 0x000fffff) << 16);
784}
785
786/*******************************************************************************
787* gtMemoryGetInternalSramBaseAddr - Returns the integrated SRAM base address.
788*
789* DESCRIPTION:
790* The Atlantis incorporate integrated 2Mbit SRAM for general use. This
791* funcnion return the SRAM's base address.
792* INPUT:
793* None.
794* OUTPUT:
795* None.
796* RETURN:
797* 32 bit SRAM's base address.
798*
799*******************************************************************************/
800unsigned int memoryGetInternalSramBaseAddr (void)
801{
802 return ((GTREGREAD (INTEGRATED_SRAM_BASE_ADDR) & 0xfffff) << 16);
803}
804
805/*******************************************************************************
806* gtMemorySetInternalSramBaseAddr - Set the integrated SRAM base address.
807*
808* DESCRIPTION:
809* The Atlantis incorporate integrated 2Mbit SRAM for general use. This
810* function sets a new base address to the SRAM .
811* INPUT:
812* sramBaseAddress - The SRAM's base address.
813* OUTPUT:
814* None.
815* RETURN:
816* None.
817*
818*******************************************************************************/
819void gtMemorySetInternalSramBaseAddr (unsigned int sramBaseAddress)
820{
821 GT_REG_WRITE (INTEGRATED_SRAM_BASE_ADDR, sramBaseAddress >> 16);
822}
823
824/*******************************************************************************
825* memorySetProtectRegion - Set protection mode for one of the 8 regions.
826*
827* DESCRIPTION:
828* The CPU interface supports configurable access protection. This includes
829* up to eight address ranges defined to a different protection type :
830* whether the address range is cacheable or not, whether it is writable or
831* not , and whether it is accessible or not. A Low and High registers
832* define each window while the minimum address range of each window is
833* 1Mbyte. An address driven by the CPU, in addition to the address
834* decoding and remapping process, is compared against the eight Access
835* Protection Low/High registers , if an address matches one of the windows
836* , the MV device checks the transaction type against the protection bits
837* defined in CPU Access Protection register, to determine if the access is
838* allowed. This function set a protection mode to one of the 8 possible
839* regions.
840* NOTE:
841* The CPU address windows are restricted to a size of 2 power n and the
842* start address must be aligned to the window size. For example, if using
843* a 16 MB window, the start address bits [23:0] must be 0.The MV's
844* internal registers space is not protected, even if the access protection
845* windows contain this space.
846*
847* INPUT:
848* region - selects which region to be configured. The values defined in
849* gtMemory.h:
850*
851* - MEM_REGION0
852* - MEM_REGION1
853* - etc.
854*
855* memAccess - Allows or forbids access (read or write ) to the region. The
856* values defined in gtMemory.h:
857*
858* - MEM_ACCESS_ALLOWED
859* - MEM_ACCESS_FORBIDEN
860*
861* memWrite - CPU write protection to the region. The values defined in
862* gtMemory.h:
863*
864* - MEM_WRITE_ALLOWED
865* - MEM_WRITE_FORBIDEN
866*
867* cacheProtection - Defines whether caching the region is allowed or not.
868* The values defined in gtMemory.h:
869*
870* - MEM_CACHE_ALLOWED
871* - MEM_CACHE_FORBIDEN
872*
873* baseAddress - the region's base Address.
874* regionSize - The region's size. This function will decrement the
875* 'regionSize' parameter by one and then check if the size
876* is valid. A valid size must be programed from LSB to MSB
877* as sequence of ‘1’s followed by sequence of ‘0’s.
878* To close a memory window simply set the size to 0.
879*
880* NOTE!!!
881* The size must be in 64Kbyte granularity.
882* The base address must be aligned to the size.
883*
884* OUTPUT:
885* None.
886*
887* RETURN:
888* False for invalid size, true otherwise.
889*
890*******************************************************************************/
891bool memorySetProtectRegion (MEMORY_PROTECT_WINDOW window,
892 MEMORY_ACCESS memAccess,
893 MEMORY_ACCESS_WRITE memWrite,
894 MEMORY_CACHE_PROTECT cacheProtection,
895 unsigned int baseAddress, unsigned int size)
896{
897 unsigned int dataForReg, temp, rShift;
898
899 if (size == 0) {
900 GT_REG_WRITE ((CPU_PROTECT_WINDOW_0_SIZE + 0x10 * window),
901 0x0);
902 return true;
903 }
904 /* The base address must be aligned to the size. */
905 if (baseAddress % size != 0) {
906 return false;
907 }
908 if (size >= MINIMUM_ACCESS_WIN_SIZE) {
909 baseAddress = ((baseAddress >> 16) & 0xfffff);
910 dataForReg = baseAddress | ((memAccess << 20) & BIT20) |
911 ((memWrite << 21) & BIT21) | ((cacheProtection << 22)
912 & BIT22) | BIT31;
913 GT_REG_WRITE (CPU_PROTECT_WINDOW_0_BASE_ADDR + 0x10 * window,
914 dataForReg);
915 size >>= 16;
916 /* Checking that the size is a sequence of '1' followed by a
917 sequence of '0' starting from LSB to MSB. */
918 temp = size - 1;
919 for (rShift = 0; rShift < 16; rShift++) {
920 temp = temp >> rShift;
921 if ((temp & 0x1) == 0) { /* Either we got to the last '1' */
922 /* or the size is not valid */
923 if (temp > 0x0)
924 return false;
925 else
926 break;
927 }
928 }
929 GT_REG_WRITE ((CPU_PROTECT_WINDOW_0_SIZE + 0x10 * window),
930 size - 1);
931 return true;
932 }
933 return false;
934}
935
936/*******************************************************************************
937* gtMemoryDisableProtectRegion - Disable a protected window.
938*
939* DESCRIPTION:
940* This function disable a protected window set by
941* 'gtMemorySetProtectRegion' function.
942*
943* INPUT:
944* window - one of the 4 windows ( defined in gtMemory.h ).
945*
946* OUTPUT:
947* None.
948*
949* RETURN:
950* None.
951*
952*******************************************************************************/
953void memoryDisableProtectRegion (MEMORY_PROTECT_WINDOW window)
954{
955 RESET_REG_BITS (((CPU_PROTECT_WINDOW_0_BASE_ADDR) + (0x10 * window)),
956 BIT31);
957}
958
959/*******************************************************************************
960* memorySetPciRemapValue - Set a remap value to a PCI memory space target.
961*
962* DESCRIPTION:
963* In addition to the address decoding mechanism, the CPU has an address
964* remapping mechanism to be used by every PCI decoding window. Each PCI
965* window can be remaped to a desired address target according to the remap
966* value within the remap register. The address remapping is useful when a
967* CPU address range must be reallocated to a different location on the
968* PCI bus. Also, it enables CPU access to a PCI agent located above the
969* 4Gbyte space. On system boot, each of the PCI memory spaces is maped to
970* a defualt value (see CPU interface section in the MV spec for the
971* default values). The remap mechanism does not always produce the desired
972* address on the PCI bus because of the remap mechanism way of working
973* (to fully understand why, please see the 'Address Remapping' section in
974* the MV's spec). Therefor, this function sets a desired remap value to
975* one of the PCI memory windows and return the effective address that
976* should be used when exiting the PCI memory window. You should ALWAYS use
977* the returned value by this function when remapping a PCI window and
978* exiting it. If for example the base address of PCI0 memory 0 is
979* 0x90000000, the size is 0x03ffffff and the remap value is 0x11000000,
980* the function will return the value of 0x91000000 that MUST
981* be used to exit this memory window in order to achive the deisred
982* remapping.
983*
984* INPUT:
985* memoryWindow - One of the PCI memory windows as defined in Memory.h
986* remapValueLow - The low remap value.
987* remapValueHigh - The high remap value.
988* OUTPUT:
989* None.
990*
991* RETURN:
992* The effective base address to exit the PCI, or 0xffffffff if one of the
993* parameters is erroneous or the effective base address is higher the top
994* decode value.
995*
996*******************************************************************************/
997unsigned int memorySetPciRemapValue (PCI_MEM_WINDOW memoryWindow,
998 unsigned int remapValueHigh,
999 unsigned int remapValueLow)
1000{
1001 unsigned int pciMemWindowBaseAddrReg = 0, baseAddrValue = 0;
1002 unsigned int pciMemWindowSizeReg = 0, windowSizeValue = 0;
1003 unsigned int effectiveBaseAddress, remapRegLow, remapRegHigh;
1004
1005 /* Initializing the base and size variables of the PCI
1006 memory windows */
1007 switch (memoryWindow) {
1008 case PCI_0_IO:
1009 pciMemWindowBaseAddrReg = PCI_0_IO_BASE_ADDR;
1010 pciMemWindowSizeReg = PCI_0_IO_SIZE;
1011 remapRegLow = PCI_0_IO_ADDR_REMAP;
1012 remapRegHigh = PCI_0_IO_ADDR_REMAP;
1013 break;
1014 case PCI_0_MEM0:
1015 pciMemWindowBaseAddrReg = PCI_0_MEMORY0_BASE_ADDR;
1016 pciMemWindowSizeReg = PCI_0_MEMORY0_SIZE;
1017 remapRegLow = PCI_0_MEMORY0_LOW_ADDR_REMAP;
1018 remapRegHigh = PCI_0_MEMORY0_HIGH_ADDR_REMAP;
1019 break;
1020 case PCI_0_MEM1:
1021 pciMemWindowBaseAddrReg = PCI_0_MEMORY1_BASE_ADDR;
1022 pciMemWindowSizeReg = PCI_0_MEMORY1_SIZE;
1023 remapRegLow = PCI_0_MEMORY1_LOW_ADDR_REMAP;
1024 remapRegHigh = PCI_0_MEMORY1_HIGH_ADDR_REMAP;
1025 break;
1026 case PCI_0_MEM2:
1027 pciMemWindowBaseAddrReg = PCI_0_MEMORY2_BASE_ADDR;
1028 pciMemWindowSizeReg = PCI_0_MEMORY2_SIZE;
1029 remapRegLow = PCI_0_MEMORY2_LOW_ADDR_REMAP;
1030 remapRegHigh = PCI_0_MEMORY2_HIGH_ADDR_REMAP;
1031 break;
1032 case PCI_0_MEM3:
1033 pciMemWindowBaseAddrReg = PCI_0_MEMORY3_BASE_ADDR;
1034 pciMemWindowSizeReg = PCI_0_MEMORY3_SIZE;
1035 remapRegLow = PCI_0_MEMORY3_LOW_ADDR_REMAP;
1036 remapRegHigh = PCI_0_MEMORY3_HIGH_ADDR_REMAP;
1037 break;
1038#ifdef INCLUDE_PCI_1
1039 case PCI_1_IO:
1040 pciMemWindowBaseAddrReg = PCI_1_IO_BASE_ADDR;
1041 pciMemWindowSizeReg = PCI_1_IO_SIZE;
1042 remapRegLow = PCI_1_IO_ADDR_REMAP;
1043 remapRegHigh = PCI_1_IO_ADDR_REMAP;
1044 break;
1045 case PCI_1_MEM0:
1046 pciMemWindowBaseAddrReg = PCI_1_MEMORY0_BASE_ADDR;
1047 pciMemWindowSizeReg = PCI_1_MEMORY0_SIZE;
1048 remapRegLow = PCI_1_MEMORY0_LOW_ADDR_REMAP;
1049 remapRegHigh = PCI_1_MEMORY0_HIGH_ADDR_REMAP;
1050 break;
1051 case PCI_1_MEM1:
1052 pciMemWindowBaseAddrReg = PCI_1_MEMORY1_BASE_ADDR;
1053 pciMemWindowSizeReg = PCI_1_MEMORY1_SIZE;
1054 remapRegLow = PCI_1_MEMORY1_LOW_ADDR_REMAP;
1055 remapRegHigh = PCI_1_MEMORY1_HIGH_ADDR_REMAP;
1056 break;
1057 case PCI_1_MEM2:
1058 pciMemWindowBaseAddrReg = PCI_1_MEMORY1_BASE_ADDR;
1059 pciMemWindowSizeReg = PCI_1_MEMORY1_SIZE;
1060 remapRegLow = PCI_1_MEMORY1_LOW_ADDR_REMAP;
1061 remapRegHigh = PCI_1_MEMORY1_HIGH_ADDR_REMAP;
1062 break;
1063 case PCI_1_MEM3:
1064 pciMemWindowBaseAddrReg = PCI_1_MEMORY3_BASE_ADDR;
1065 pciMemWindowSizeReg = PCI_1_MEMORY3_SIZE;
1066 remapRegLow = PCI_1_MEMORY3_LOW_ADDR_REMAP;
1067 remapRegHigh = PCI_1_MEMORY3_HIGH_ADDR_REMAP;
1068 break;
1069#endif /* INCLUDE_PCI_1 */
1070 default:
1071 /* Retrun an invalid effective base address */
1072 return 0xffffffff;
1073 }
1074 /* Writing the remap value to the remap regisers */
1075 GT_REG_WRITE (remapRegHigh, remapValueHigh);
1076 GT_REG_WRITE (remapRegLow, remapValueLow >> 16);
1077 /* Reading the values from the base address and size registers */
1078 baseAddrValue = GTREGREAD (pciMemWindowBaseAddrReg) & 0xfffff;
1079 windowSizeValue = GTREGREAD (pciMemWindowSizeReg) & 0xffff;
1080 /* Start calculating the effective Base Address */
1081 effectiveBaseAddress = baseAddrValue << 16;
1082 /* The effective base address will be combined from the chopped (if any)
1083 remap value (according to the size value and remap mechanism) and the
1084 window's base address */
1085 effectiveBaseAddress |=
1086 (((windowSizeValue << 16) | 0xffff) & remapValueLow);
1087 /* If the effectiveBaseAddress exceed the window boundaries return an
1088 invalid value. */
1089 if (effectiveBaseAddress >
1090 ((baseAddrValue << 16) + ((windowSizeValue << 16) | 0xffff)))
1091 return 0xffffffff;
1092 return effectiveBaseAddress;
1093}
1094
1095/********************************************************************
1096* memorySetRegionSnoopMode - This function modifys one of the 4 regions which
1097* supports Cache Coherency.
1098*
1099*
1100* Inputs: SNOOP_REGION region - One of the four regions.
1101* SNOOP_TYPE snoopType - There is four optional Types:
1102* 1. No Snoop.
1103* 2. Snoop to WT region.
1104* 3. Snoop to WB region.
1105* 4. Snoop & Invalidate to WB region.
1106* unsigned int baseAddress - Base Address of this region.
1107* unsigned int topAddress - Top Address of this region.
1108* Returns: false if one of the parameters is wrong and true else
1109*********************************************************************/
1110/* evb6260 code */
1111#if 0
1112bool memorySetRegionSnoopMode(MEMORY_SNOOP_REGION region,
1113 MEMORY_SNOOP_TYPE snoopType,
1114 unsigned int baseAddress,
1115 unsigned int regionLength)
1116{
1117 unsigned int snoopXbaseAddress;
1118 unsigned int snoopXtopAddress;
1119 unsigned int data;
1120 unsigned int snoopHigh = baseAddress + regionLength;
1121
1122 if( (region > MEM_SNOOP_REGION3) || (snoopType > MEM_SNOOP_WB) )
1123 return false;
1124 snoopXbaseAddress = SNOOP_BASE_ADDRESS_0 + 0x10 * region;
1125 snoopXtopAddress = SNOOP_TOP_ADDRESS_0 + 0x10 * region;
1126 if(regionLength == 0) /* closing the region */
1127 {
1128 GT_REG_WRITE(snoopXbaseAddress,0x0000ffff);
1129 GT_REG_WRITE(snoopXtopAddress,0);
1130 return true;
1131 }
1132 baseAddress = baseAddress & 0xffff0000;
1133 data = (baseAddress >> 16) | snoopType << 16;
1134 GT_REG_WRITE(snoopXbaseAddress,data);
1135 snoopHigh = (snoopHigh & 0xfff00000) >> 20;
1136 GT_REG_WRITE(snoopXtopAddress,snoopHigh - 1);
1137 return true;
1138}
1139#endif
1140
1141/********************************************************************
1142* memoryRemapAddress - This fubction used for address remapping.
1143*
1144*
1145* Inputs: regOffset: remap register
1146* remapValue :
1147* Returns: false if one of the parameters is erroneous,true otherwise.
1148*
1149* Not needed function To_do !!!!
1150*********************************************************************/
1151bool memoryRemapAddress (unsigned int remapReg, unsigned int remapValue)
1152{
1153 unsigned int valueForReg;
1154
1155 valueForReg = (remapValue & 0xfff00000) >> 20;
1156 GT_REG_WRITE (remapReg, valueForReg);
1157 return true;
1158}
1159
1160/*******************************************************************************
1161* memoryGetDeviceParam - Extract the device parameters from the device bank
1162* parameters register.
1163*
1164* DESCRIPTION:
1165* To allow interfacing with very slow devices and fast synchronous SRAMs,
1166* each device can be programed to different timing parameters. Each bank
1167* has its own parameters register. Bank width can be programmed to 8, 16,
1168* or 32-bits. Bank timing parameters can be programmed to support
1169* different device types (e.g. Sync Burst SRAM, Flash , ROM, I/O
1170* Controllers). The MV allows you to set timing parameters and width for
1171* each device through parameters register .
1172* This function extracts the parameters described from the Device Bank
1173* parameters register and fills the given 'deviceParam' (defined in
1174* gtMemory.h) structure with the read data.
1175*
1176* INPUT:
1177* deviceParam - pointer to a structure DEVICE_PARAM (defined in
1178* Memory.h).For details about each structure field please
1179* see the device timing parameter section in the MV
1180* datasheet.
1181* deviceNum - Select on of the five device banks (defined in
1182* Memory.h) :
1183*
1184* - DEVICE0
1185* - DEVICE1
1186* - DEVICE2
1187* - etc.
1188*
1189* OUTPUT:
1190* None.
1191*
1192* RETURN:
1193* false if one of the parameters is erroneous,true otherwise.
1194*
1195*******************************************************************************/
1196/********************************************************************
1197* memoryGetDeviceParam - This function used for getting device parameters from
1198* DEVICE BANK PARAMETERS REGISTER
1199*
1200*
1201* Inputs: - deviceParam: STRUCT with paramiters for DEVICE BANK
1202* PARAMETERS REGISTER
1203* - deviceNum : number of device
1204* Returns: false if one of the parameters is erroneous,true otherwise.
1205*********************************************************************/
1206
1207bool memoryGetDeviceParam (DEVICE_PARAM * deviceParam, DEVICE deviceNum)
1208{
1209 unsigned int valueOfReg;
1210 unsigned int calcData;
1211
1212 if (deviceNum > 4)
1213 return false;
1214 GT_REG_READ (DEVICE_BANK0PARAMETERS + 4 * deviceNum, &valueOfReg);
1215 calcData = (0x7 & valueOfReg) + ((BIT22 & valueOfReg) >> 19);
1216 deviceParam->turnOff = calcData; /* Turn Off */
1217
1218 calcData = ((0x78 & valueOfReg) >> 3) + ((BIT23 & valueOfReg) >> 19);
1219 deviceParam->acc2First = calcData; /* Access To First */
1220
1221 calcData = ((0x780 & valueOfReg) >> 7) + ((BIT24 & valueOfReg) >> 20);
1222 deviceParam->acc2Next = calcData; /* Access To Next */
1223
1224 calcData =
1225 ((0x3800 & valueOfReg) >> 11) + ((BIT25 & valueOfReg) >> 22);
1226 deviceParam->ale2Wr = calcData; /* Ale To Write */
1227
1228 calcData = ((0x1c000 & valueOfReg) >> 14) +
1229 ((BIT26 & valueOfReg) >> 23);
1230 deviceParam->wrLow = calcData; /* Write Active */
1231
1232 calcData = ((0xe0000 & valueOfReg) >> 17) +
1233 ((BIT27 & valueOfReg) >> 24);
1234 deviceParam->wrHigh = calcData; /* Write High */
1235
1236 calcData = ((0x300000 & valueOfReg) >> 20);
1237 deviceParam->deviceWidth = (BIT0 << calcData); /* In bytes */
1238 calcData = ((0x30000000 & valueOfReg) >> 28);
1239 deviceParam->badrSkew = calcData; /* Cycles gap between BAdr
1240 toggle to read data sample. */
1241 calcData = ((0x40000000 & valueOfReg) >> 30);
1242 deviceParam->DPEn = calcData; /* Data Parity enable */
1243 return true;
1244}
1245
1246/*******************************************************************************
1247* memorySetDeviceParam - Set new parameters for a device.
1248*
1249*
1250* DESCRIPTION:
1251* To allow interfacing with very slow devices and fast synchronous SRAMs,
1252* each device can be programed to different timing parameters. Each bank
1253* has its own parameters register. Bank width can be programmed to 8, 16,
1254* or 32-bits. Bank timing parameters can be programmed to support
1255* different device types (e.g. Sync Burst SRAM, Flash , ROM, I/O
1256* Controllers). The MV allows you to set timing parameters and width for
1257* each device through parameters register. This function set new
1258* parameters to a device Bank from the delivered structure 'deviceParam'
1259* (defined in gtMemory.h). The structure must be initialized with data
1260* prior to the use of these function.
1261*
1262* INPUT:
1263* deviceParam - pointer to a structure DEVICE_PARAM (defined in
1264* Memory.h).For details about each structure field please
1265* see the device timing parameter section in the MV
1266* datasheet.
1267* deviceNum - Select on of the five device banks (defined in
1268* Memory.h) :
1269*
1270* - DEVICE0
1271* - DEVICE1
1272* - DEVICE2
1273* - etc.
1274*
1275* OUTPUT:
1276* None.
1277*
1278* RETURN:
1279* false if one of the parameters is erroneous,true otherwise.
1280*
1281*******************************************************************************/
1282/********************************************************************
1283* memorySetDeviceParam - This function used for setting device parameters to
1284* DEVICE BANK PARAMETERS REGISTER
1285*
1286*
1287* Inputs: - deviceParam: STRUCT for store paramiters from DEVICE BANK
1288* PARAMETERS REGISTER
1289* - deviceNum : number of device
1290* Returns: false if one of the parameters is erroneous,true otherwise.
1291*********************************************************************/
1292bool memorySetDeviceParam (DEVICE_PARAM * deviceParam, DEVICE deviceNum)
1293{
1294 unsigned int valueForReg;
1295
1296 if ((deviceParam->turnOff > 0x7) || (deviceParam->acc2First > 0xf) ||
1297 (deviceParam->acc2Next > 0xf) || (deviceParam->ale2Wr > 0x7) ||
1298 (deviceParam->wrLow > 0x7) || (deviceParam->wrHigh > 0x7) ||
1299 (deviceParam->badrSkew > 0x2) || (deviceParam->DPEn > 0x1)) {
1300 return false;
1301 }
1302 valueForReg = (((deviceParam->turnOff) & 0x7) |
1303 (((deviceParam->turnOff) & 0x8) << 19) |
1304 (((deviceParam->acc2First) & 0xf) << 3) |
1305 (((deviceParam->acc2First) & 0x10) << 19) |
1306 (((deviceParam->acc2Next) & 0xf) << 7) |
1307 (((deviceParam->acc2Next) & 0x10) << 20) |
1308 (((deviceParam->ale2Wr) & 0x7) << 11) |
1309 (((deviceParam->ale2Wr) & 0xf) << 22) |
1310 (((deviceParam->wrLow) & 0x7) << 14) |
1311 (((deviceParam->wrLow) & 0xf) << 23) |
1312 (((deviceParam->wrHigh) & 0x7) << 17) |
1313 (((deviceParam->wrHigh) & 0xf) << 24) |
1314 (((deviceParam->badrSkew) & 0x3) << 28) |
1315 (((deviceParam->DPEn) & 0x1) << 30));
1316
1317 /* insert the device width: */
1318 switch (deviceParam->deviceWidth) {
1319 case 1:
1320 valueForReg = valueForReg | _8BIT;
1321 break;
1322 case 2:
1323 valueForReg = valueForReg | _16BIT;
1324 break;
1325 case 4:
1326 valueForReg = valueForReg | _32BIT;
1327 break;
1328 default:
1329 valueForReg = valueForReg | _8BIT;
1330 break;
1331 }
1332 GT_REG_WRITE (DEVICE_BANK0PARAMETERS + 4 * deviceNum, valueForReg);
1333 return true;
1334}
1335
1336/*******************************************************************************
1337* MemoryDisableWindow - Disable a memory space by the disable bit.
1338* DESCRIPTION:
1339* This function disables one of the 21 availiable windows dedicated for
1340* the CPU decoding mechanism. Its possible to combine several windows with
1341* the OR command.
1342* INPUT:
1343* window - One or more of the memory windows (defined in gtMemory.h).
1344* OUTPUT:
1345* None.
1346* RETURN:
1347* None.
1348*******************************************************************************/
1349void MemoryDisableWindow (MEMORY_WINDOW window)
1350{
1351 SET_REG_BITS (BASE_ADDR_ENABLE, window);
1352}
1353
1354/*******************************************************************************
1355* MemoryEnableWindow - Enable a memory space that was disabled by
1356* 'MemoryDisableWindow'.
1357* DESCRIPTION:
1358* This function enables one of the 21 availiable windows dedicated for the
1359* CPU decoding mechanism. Its possible to combine several windows with the
1360* OR command.
1361* INPUT:
1362* window - One or more of the memory windows (defined in gtMemory.h).
1363* OUTPUT:
1364* None.
1365* RETURN:
1366* None.
1367*******************************************************************************/
1368void MemoryEnableWindow (MEMORY_WINDOW window)
1369{
1370 RESET_REG_BITS (BASE_ADDR_ENABLE, window);
1371}
1372
1373/*******************************************************************************
1374* MemoryGetMemWindowStatus - This function check whether the memory window is
1375* disabled or not.
1376* DESCRIPTION:
1377* This function checks if the given memory window is closed .
1378* INPUT:
1379* window - One or more of the memory windows (defined in gtMemory.h).
1380* OUTPUT:
1381* None.
1382* RETURN:
1383* True for a closed window, false otherwise .
1384*******************************************************************************/
1385MEMORY_WINDOW_STATUS MemoryGetMemWindowStatus (MEMORY_WINDOW window)
1386{
1387 if (GTREGREAD (BASE_ADDR_ENABLE) & window)
1388 return MEM_WINDOW_DISABLED;
1389 return MEM_WINDOW_ENABLED;
1390}