Blackfin Serial Driver: macro away the IER differences between processors
[linux/fpc-iii.git] / drivers / pci / hotplug / cpqphp_nvram.c
blobcb174888002ba537ee2884a46fcac24513f1b1fe
1 /*
2 * Compaq Hot Plug Controller Driver
4 * Copyright (C) 1995,2001 Compaq Computer Corporation
5 * Copyright (C) 2001 Greg Kroah-Hartman (greg@kroah.com)
6 * Copyright (C) 2001 IBM Corp.
8 * All rights reserved.
10 * This program is free software; you can redistribute it and/or modify
11 * it under the terms of the GNU General Public License as published by
12 * the Free Software Foundation; either version 2 of the License, or (at
13 * your option) any later version.
15 * This program is distributed in the hope that it will be useful, but
16 * WITHOUT ANY WARRANTY; without even the implied warranty of
17 * MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, GOOD TITLE or
18 * NON INFRINGEMENT. See the GNU General Public License for more
19 * details.
21 * You should have received a copy of the GNU General Public License
22 * along with this program; if not, write to the Free Software
23 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
25 * Send feedback to <greg@kroah.com>
29 #include <linux/module.h>
30 #include <linux/kernel.h>
31 #include <linux/types.h>
32 #include <linux/proc_fs.h>
33 #include <linux/slab.h>
34 #include <linux/workqueue.h>
35 #include <linux/pci.h>
36 #include <linux/pci_hotplug.h>
37 #include <linux/init.h>
38 #include <asm/uaccess.h>
39 #include "cpqphp.h"
40 #include "cpqphp_nvram.h"
43 #define ROM_INT15_PHY_ADDR 0x0FF859
44 #define READ_EV 0xD8A4
45 #define WRITE_EV 0xD8A5
47 struct register_foo {
48 union {
49 unsigned long lword; /* eax */
50 unsigned short word; /* ax */
52 struct {
53 unsigned char low; /* al */
54 unsigned char high; /* ah */
55 } byte;
56 } data;
58 unsigned char opcode; /* see below */
59 unsigned long length; /* if the reg. is a pointer, how much data */
60 } __attribute__ ((packed));
62 struct all_reg {
63 struct register_foo eax_reg;
64 struct register_foo ebx_reg;
65 struct register_foo ecx_reg;
66 struct register_foo edx_reg;
67 struct register_foo edi_reg;
68 struct register_foo esi_reg;
69 struct register_foo eflags_reg;
70 } __attribute__ ((packed));
73 struct ev_hrt_header {
74 u8 Version;
75 u8 num_of_ctrl;
76 u8 next;
79 struct ev_hrt_ctrl {
80 u8 bus;
81 u8 device;
82 u8 function;
83 u8 mem_avail;
84 u8 p_mem_avail;
85 u8 io_avail;
86 u8 bus_avail;
87 u8 next;
91 static u8 evbuffer_init;
92 static u8 evbuffer_length;
93 static u8 evbuffer[1024];
95 static void __iomem *compaq_int15_entry_point;
97 static spinlock_t int15_lock; /* lock for ordering int15_bios_call() */
100 /* This is a series of function that deals with
101 setting & getting the hotplug resource table in some environment variable.
105 * We really shouldn't be doing this unless there is a _very_ good reason to!!!
106 * greg k-h
110 static u32 add_byte( u32 **p_buffer, u8 value, u32 *used, u32 *avail)
112 u8 **tByte;
114 if ((*used + 1) > *avail)
115 return(1);
117 *((u8*)*p_buffer) = value;
118 tByte = (u8**)p_buffer;
119 (*tByte)++;
120 *used+=1;
121 return(0);
125 static u32 add_dword( u32 **p_buffer, u32 value, u32 *used, u32 *avail)
127 if ((*used + 4) > *avail)
128 return(1);
130 **p_buffer = value;
131 (*p_buffer)++;
132 *used+=4;
133 return(0);
138 * check_for_compaq_ROM
140 * this routine verifies that the ROM OEM string is 'COMPAQ'
142 * returns 0 for non-Compaq ROM, 1 for Compaq ROM
144 static int check_for_compaq_ROM (void __iomem *rom_start)
146 u8 temp1, temp2, temp3, temp4, temp5, temp6;
147 int result = 0;
149 temp1 = readb(rom_start + 0xffea + 0);
150 temp2 = readb(rom_start + 0xffea + 1);
151 temp3 = readb(rom_start + 0xffea + 2);
152 temp4 = readb(rom_start + 0xffea + 3);
153 temp5 = readb(rom_start + 0xffea + 4);
154 temp6 = readb(rom_start + 0xffea + 5);
155 if ((temp1 == 'C') &&
156 (temp2 == 'O') &&
157 (temp3 == 'M') &&
158 (temp4 == 'P') &&
159 (temp5 == 'A') &&
160 (temp6 == 'Q')) {
161 result = 1;
163 dbg ("%s - returned %d\n", __func__, result);
164 return result;
168 static u32 access_EV (u16 operation, u8 *ev_name, u8 *buffer, u32 *buf_size)
170 unsigned long flags;
171 int op = operation;
172 int ret_val;
174 if (!compaq_int15_entry_point)
175 return -ENODEV;
177 spin_lock_irqsave(&int15_lock, flags);
178 __asm__ (
179 "xorl %%ebx,%%ebx\n" \
180 "xorl %%edx,%%edx\n" \
181 "pushf\n" \
182 "push %%cs\n" \
183 "cli\n" \
184 "call *%6\n"
185 : "=c" (*buf_size), "=a" (ret_val)
186 : "a" (op), "c" (*buf_size), "S" (ev_name),
187 "D" (buffer), "m" (compaq_int15_entry_point)
188 : "%ebx", "%edx");
189 spin_unlock_irqrestore(&int15_lock, flags);
191 return((ret_val & 0xFF00) >> 8);
196 * load_HRT
198 * Read the hot plug Resource Table from NVRAM
200 static int load_HRT (void __iomem *rom_start)
202 u32 available;
203 u32 temp_dword;
204 u8 temp_byte = 0xFF;
205 u32 rc;
207 if (!check_for_compaq_ROM(rom_start)) {
208 return -ENODEV;
211 available = 1024;
213 // Now load the EV
214 temp_dword = available;
216 rc = access_EV(READ_EV, "CQTHPS", evbuffer, &temp_dword);
218 evbuffer_length = temp_dword;
220 // We're maintaining the resource lists so write FF to invalidate old info
221 temp_dword = 1;
223 rc = access_EV(WRITE_EV, "CQTHPS", &temp_byte, &temp_dword);
225 return rc;
230 * store_HRT
232 * Save the hot plug Resource Table in NVRAM
234 static u32 store_HRT (void __iomem *rom_start)
236 u32 *buffer;
237 u32 *pFill;
238 u32 usedbytes;
239 u32 available;
240 u32 temp_dword;
241 u32 rc;
242 u8 loop;
243 u8 numCtrl = 0;
244 struct controller *ctrl;
245 struct pci_resource *resNode;
246 struct ev_hrt_header *p_EV_header;
247 struct ev_hrt_ctrl *p_ev_ctrl;
249 available = 1024;
251 if (!check_for_compaq_ROM(rom_start)) {
252 return(1);
255 buffer = (u32*) evbuffer;
257 if (!buffer)
258 return(1);
260 pFill = buffer;
261 usedbytes = 0;
263 p_EV_header = (struct ev_hrt_header *) pFill;
265 ctrl = cpqhp_ctrl_list;
267 // The revision of this structure
268 rc = add_byte( &pFill, 1 + ctrl->push_flag, &usedbytes, &available);
269 if (rc)
270 return(rc);
272 // The number of controllers
273 rc = add_byte( &pFill, 1, &usedbytes, &available);
274 if (rc)
275 return(rc);
277 while (ctrl) {
278 p_ev_ctrl = (struct ev_hrt_ctrl *) pFill;
280 numCtrl++;
282 // The bus number
283 rc = add_byte( &pFill, ctrl->bus, &usedbytes, &available);
284 if (rc)
285 return(rc);
287 // The device Number
288 rc = add_byte( &pFill, PCI_SLOT(ctrl->pci_dev->devfn), &usedbytes, &available);
289 if (rc)
290 return(rc);
292 // The function Number
293 rc = add_byte( &pFill, PCI_FUNC(ctrl->pci_dev->devfn), &usedbytes, &available);
294 if (rc)
295 return(rc);
297 // Skip the number of available entries
298 rc = add_dword( &pFill, 0, &usedbytes, &available);
299 if (rc)
300 return(rc);
302 // Figure out memory Available
304 resNode = ctrl->mem_head;
306 loop = 0;
308 while (resNode) {
309 loop ++;
311 // base
312 rc = add_dword( &pFill, resNode->base, &usedbytes, &available);
313 if (rc)
314 return(rc);
316 // length
317 rc = add_dword( &pFill, resNode->length, &usedbytes, &available);
318 if (rc)
319 return(rc);
321 resNode = resNode->next;
324 // Fill in the number of entries
325 p_ev_ctrl->mem_avail = loop;
327 // Figure out prefetchable memory Available
329 resNode = ctrl->p_mem_head;
331 loop = 0;
333 while (resNode) {
334 loop ++;
336 // base
337 rc = add_dword( &pFill, resNode->base, &usedbytes, &available);
338 if (rc)
339 return(rc);
341 // length
342 rc = add_dword( &pFill, resNode->length, &usedbytes, &available);
343 if (rc)
344 return(rc);
346 resNode = resNode->next;
349 // Fill in the number of entries
350 p_ev_ctrl->p_mem_avail = loop;
352 // Figure out IO Available
354 resNode = ctrl->io_head;
356 loop = 0;
358 while (resNode) {
359 loop ++;
361 // base
362 rc = add_dword( &pFill, resNode->base, &usedbytes, &available);
363 if (rc)
364 return(rc);
366 // length
367 rc = add_dword( &pFill, resNode->length, &usedbytes, &available);
368 if (rc)
369 return(rc);
371 resNode = resNode->next;
374 // Fill in the number of entries
375 p_ev_ctrl->io_avail = loop;
377 // Figure out bus Available
379 resNode = ctrl->bus_head;
381 loop = 0;
383 while (resNode) {
384 loop ++;
386 // base
387 rc = add_dword( &pFill, resNode->base, &usedbytes, &available);
388 if (rc)
389 return(rc);
391 // length
392 rc = add_dword( &pFill, resNode->length, &usedbytes, &available);
393 if (rc)
394 return(rc);
396 resNode = resNode->next;
399 // Fill in the number of entries
400 p_ev_ctrl->bus_avail = loop;
402 ctrl = ctrl->next;
405 p_EV_header->num_of_ctrl = numCtrl;
407 // Now store the EV
409 temp_dword = usedbytes;
411 rc = access_EV(WRITE_EV, "CQTHPS", (u8*) buffer, &temp_dword);
413 dbg("usedbytes = 0x%x, length = 0x%x\n", usedbytes, temp_dword);
415 evbuffer_length = temp_dword;
417 if (rc) {
418 err(msg_unable_to_save);
419 return(1);
422 return(0);
426 void compaq_nvram_init (void __iomem *rom_start)
428 if (rom_start) {
429 compaq_int15_entry_point = (rom_start + ROM_INT15_PHY_ADDR - ROM_PHY_ADDR);
431 dbg("int15 entry = %p\n", compaq_int15_entry_point);
433 /* initialize our int15 lock */
434 spin_lock_init(&int15_lock);
438 int compaq_nvram_load (void __iomem *rom_start, struct controller *ctrl)
440 u8 bus, device, function;
441 u8 nummem, numpmem, numio, numbus;
442 u32 rc;
443 u8 *p_byte;
444 struct pci_resource *mem_node;
445 struct pci_resource *p_mem_node;
446 struct pci_resource *io_node;
447 struct pci_resource *bus_node;
448 struct ev_hrt_ctrl *p_ev_ctrl;
449 struct ev_hrt_header *p_EV_header;
451 if (!evbuffer_init) {
452 // Read the resource list information in from NVRAM
453 if (load_HRT(rom_start))
454 memset (evbuffer, 0, 1024);
456 evbuffer_init = 1;
459 // If we saved information in NVRAM, use it now
460 p_EV_header = (struct ev_hrt_header *) evbuffer;
462 // The following code is for systems where version 1.0 of this
463 // driver has been loaded, but doesn't support the hardware.
464 // In that case, the driver would incorrectly store something
465 // in NVRAM.
466 if ((p_EV_header->Version == 2) ||
467 ((p_EV_header->Version == 1) && !ctrl->push_flag)) {
468 p_byte = &(p_EV_header->next);
470 p_ev_ctrl = (struct ev_hrt_ctrl *) &(p_EV_header->next);
472 p_byte += 3;
474 if (p_byte > ((u8*)p_EV_header + evbuffer_length))
475 return 2;
477 bus = p_ev_ctrl->bus;
478 device = p_ev_ctrl->device;
479 function = p_ev_ctrl->function;
481 while ((bus != ctrl->bus) ||
482 (device != PCI_SLOT(ctrl->pci_dev->devfn)) ||
483 (function != PCI_FUNC(ctrl->pci_dev->devfn))) {
484 nummem = p_ev_ctrl->mem_avail;
485 numpmem = p_ev_ctrl->p_mem_avail;
486 numio = p_ev_ctrl->io_avail;
487 numbus = p_ev_ctrl->bus_avail;
489 p_byte += 4;
491 if (p_byte > ((u8*)p_EV_header + evbuffer_length))
492 return 2;
494 // Skip forward to the next entry
495 p_byte += (nummem + numpmem + numio + numbus) * 8;
497 if (p_byte > ((u8*)p_EV_header + evbuffer_length))
498 return 2;
500 p_ev_ctrl = (struct ev_hrt_ctrl *) p_byte;
502 p_byte += 3;
504 if (p_byte > ((u8*)p_EV_header + evbuffer_length))
505 return 2;
507 bus = p_ev_ctrl->bus;
508 device = p_ev_ctrl->device;
509 function = p_ev_ctrl->function;
512 nummem = p_ev_ctrl->mem_avail;
513 numpmem = p_ev_ctrl->p_mem_avail;
514 numio = p_ev_ctrl->io_avail;
515 numbus = p_ev_ctrl->bus_avail;
517 p_byte += 4;
519 if (p_byte > ((u8*)p_EV_header + evbuffer_length))
520 return 2;
522 while (nummem--) {
523 mem_node = kmalloc(sizeof(struct pci_resource), GFP_KERNEL);
525 if (!mem_node)
526 break;
528 mem_node->base = *(u32*)p_byte;
529 dbg("mem base = %8.8x\n",mem_node->base);
530 p_byte += 4;
532 if (p_byte > ((u8*)p_EV_header + evbuffer_length)) {
533 kfree(mem_node);
534 return 2;
537 mem_node->length = *(u32*)p_byte;
538 dbg("mem length = %8.8x\n",mem_node->length);
539 p_byte += 4;
541 if (p_byte > ((u8*)p_EV_header + evbuffer_length)) {
542 kfree(mem_node);
543 return 2;
546 mem_node->next = ctrl->mem_head;
547 ctrl->mem_head = mem_node;
550 while (numpmem--) {
551 p_mem_node = kmalloc(sizeof(struct pci_resource), GFP_KERNEL);
553 if (!p_mem_node)
554 break;
556 p_mem_node->base = *(u32*)p_byte;
557 dbg("pre-mem base = %8.8x\n",p_mem_node->base);
558 p_byte += 4;
560 if (p_byte > ((u8*)p_EV_header + evbuffer_length)) {
561 kfree(p_mem_node);
562 return 2;
565 p_mem_node->length = *(u32*)p_byte;
566 dbg("pre-mem length = %8.8x\n",p_mem_node->length);
567 p_byte += 4;
569 if (p_byte > ((u8*)p_EV_header + evbuffer_length)) {
570 kfree(p_mem_node);
571 return 2;
574 p_mem_node->next = ctrl->p_mem_head;
575 ctrl->p_mem_head = p_mem_node;
578 while (numio--) {
579 io_node = kmalloc(sizeof(struct pci_resource), GFP_KERNEL);
581 if (!io_node)
582 break;
584 io_node->base = *(u32*)p_byte;
585 dbg("io base = %8.8x\n",io_node->base);
586 p_byte += 4;
588 if (p_byte > ((u8*)p_EV_header + evbuffer_length)) {
589 kfree(io_node);
590 return 2;
593 io_node->length = *(u32*)p_byte;
594 dbg("io length = %8.8x\n",io_node->length);
595 p_byte += 4;
597 if (p_byte > ((u8*)p_EV_header + evbuffer_length)) {
598 kfree(io_node);
599 return 2;
602 io_node->next = ctrl->io_head;
603 ctrl->io_head = io_node;
606 while (numbus--) {
607 bus_node = kmalloc(sizeof(struct pci_resource), GFP_KERNEL);
609 if (!bus_node)
610 break;
612 bus_node->base = *(u32*)p_byte;
613 p_byte += 4;
615 if (p_byte > ((u8*)p_EV_header + evbuffer_length)) {
616 kfree(bus_node);
617 return 2;
620 bus_node->length = *(u32*)p_byte;
621 p_byte += 4;
623 if (p_byte > ((u8*)p_EV_header + evbuffer_length)) {
624 kfree(bus_node);
625 return 2;
628 bus_node->next = ctrl->bus_head;
629 ctrl->bus_head = bus_node;
632 // If all of the following fail, we don't have any resources for
633 // hot plug add
634 rc = 1;
635 rc &= cpqhp_resource_sort_and_combine(&(ctrl->mem_head));
636 rc &= cpqhp_resource_sort_and_combine(&(ctrl->p_mem_head));
637 rc &= cpqhp_resource_sort_and_combine(&(ctrl->io_head));
638 rc &= cpqhp_resource_sort_and_combine(&(ctrl->bus_head));
640 if (rc)
641 return(rc);
642 } else {
643 if ((evbuffer[0] != 0) && (!ctrl->push_flag))
644 return 1;
647 return 0;
651 int compaq_nvram_store (void __iomem *rom_start)
653 int rc = 1;
655 if (rom_start == NULL)
656 return -ENODEV;
658 if (evbuffer_init) {
659 rc = store_HRT(rom_start);
660 if (rc) {
661 err(msg_unable_to_save);
664 return rc;