ecard.c source code [linux/arch/arm/mach-rpc/ecard.c]

1	// SPDX-License-Identifier: GPL-2.0-only
2	/*
3	* linux/arch/arm/kernel/ecard.c
4	*
5	* Copyright 1995-2001 Russell King
6	*
7	* Find all installed expansion cards, and handle interrupts from them.
8	*
9	* Created from information from Acorns RiscOS3 PRMs
10	*
11	* 08-Dec-1996 RMK Added code for the 9'th expansion card - the ether
12	* podule slot.
13	* 06-May-1997 RMK Added blacklist for cards whose loader doesn't work.
14	* 12-Sep-1997 RMK Created new handling of interrupt enables/disables
15	* - cards can now register their own routine to control
16	* interrupts (recommended).
17	* 29-Sep-1997 RMK Expansion card interrupt hardware not being re-enabled
18	* on reset from Linux. (Caused cards not to respond
19	* under RiscOS without hard reset).
20	* 15-Feb-1998 RMK Added DMA support
21	* 12-Sep-1998 RMK Added EASI support
22	* 10-Jan-1999 RMK Run loaders in a simulated RISC OS environment.
23	* 17-Apr-1999 RMK Support for EASI Type C cycles.
24	*/
25	#define ECARD_C
26
27	#include <linux/module.h>
28	#include <linux/kernel.h>
29	#include <linux/types.h>
30	#include <linux/sched.h>
31	#include <linux/sched/mm.h>
32	#include <linux/interrupt.h>
33	#include <linux/completion.h>
34	#include <linux/reboot.h>
35	#include <linux/mm.h>
36	#include <linux/slab.h>
37	#include <linux/proc_fs.h>
38	#include <linux/seq_file.h>
39	#include <linux/device.h>
40	#include <linux/init.h>
41	#include <linux/mutex.h>
42	#include <linux/kthread.h>
43	#include <linux/irq.h>
44	#include <linux/io.h>
45
46	#include <asm/dma.h>
47	#include <asm/ecard.h>
48	#include <mach/hardware.h>
49	#include <asm/irq.h>
50	#include <asm/mmu_context.h>
51	#include <asm/mach/irq.h>
52	#include <asm/tlbflush.h>
53
54	#include "ecard.h"
55
56	struct ecard_request {
57	void (fn)(struct* ecard_request *);
58	ecard_t *ec;
59	unsigned int address;
60	unsigned int length;
61	unsigned int use_loader;
62	void *buffer;
63	struct completion *complete;
64	};
65
66	struct expcard_quirklist {
67	unsigned short manufacturer;
68	unsigned short product;
69	const char *type;
70	void (init)(ecard_t ec);
71	};
72
73	static ecard_t *cards;
74	static ecard_t *slot_to_expcard[MAX_ECARDS];
75	static unsigned int ectcr;
76
77	static void atomwide_3p_quirk(ecard_t *ec);
78
79	/ List of descriptions of cards which don't have an extended*
80	* identification, or chunk directories containing a description.
81	*/
82	static struct expcard_quirklist quirklist[] __initdata = {
83	{ MANU_ACORN, PROD_ACORN_ETHER1, "Acorn Ether1" },
84	{ MANU_ATOMWIDE, PROD_ATOMWIDE_3PSERIAL, NULL, atomwide_3p_quirk },
85	};
86
87	asmlinkage extern int
88	ecard_loader_reset(unsigned long base, loader_t loader);
89	asmlinkage extern int
90	ecard_loader_read(int off, unsigned long base, loader_t loader);
91
92	static inline unsigned short ecard_getu16(unsigned char *v)
93	{
94	return v[`0`] \| v[`1`] << `8`;
95	}
96
97	static inline signed long ecard_gets24(unsigned char *v)
98	{
99	return v[`0`] \| v[`1`] << `8` \| v[`2`] << `16` \| ((v[`2`] & `0x80`) ? `0xff000000` : `0`);
100	}
101
102	static inline ecard_t slot_to_ecard(unsigned* int slot)
103	{
104	return slot < MAX_ECARDS ? slot_to_expcard[slot] : NULL;
105	}
106
107	/ ===================== Expansion card daemon ======================== /
108	/*
109	* Since the loader programs on the expansion cards need to be run
110	* in a specific environment, create a separate task with this
111	* environment up, and pass requests to this task as and when we
112	* need to.
113	*
114	* This should allow 99% of loaders to be called from Linux.
115	*
116	* From a security standpoint, we trust the card vendors. This
117	* may be a misplaced trust.
118	*/
119	static void ecard_task_reset(struct ecard_request *req)
120	{
121	struct expansion_card *ec = req->ec;
122	struct resource *res;
123
124	res = ec->slot_no == `8`
125	? &ec->resource[ECARD_RES_MEMC]
126	: ec->easi
127	? &ec->resource[ECARD_RES_EASI]
128	: &ec->resource[ECARD_RES_IOCSYNC];
129
130	ecard_loader_reset(res->start, ec->loader);
131	}
132
133	static void ecard_task_readbytes(struct ecard_request *req)
134	{
135	struct expansion_card *ec = req->ec;
136	unsigned char *buf = req->buffer;
137	unsigned int len = req->length;
138	unsigned int off = req->address;
139
140	if (ec->slot_no == `8`) {
141	void __iomem base = (void* __iomem *)
142	ec->resource[ECARD_RES_MEMC].start;
143
144	/*
145	* The card maintains an index which increments the address
146	* into a 4096-byte page on each access. We need to keep
147	* track of the counter.
148	*/
149	static unsigned int index;
150	unsigned int page;
151
152	page = (off >> `12`) * `4`;
153	if (page > `256` * `4`)
154	return;
155
156	off &= `4095`;
157
158	/*
159	* If we are reading offset 0, or our current index is
160	* greater than the offset, reset the hardware index counter.
161	*/
162	if (off == `0` \|\| index > off) {
163	writeb(val: `0`, addr: base);
164	index = `0`;
165	}
166
167	/*
168	* Increment the hardware index counter until we get to the
169	* required offset. The read bytes are discarded.
170	*/
171	while (index < off) {
172	readb(addr: base + page);
173	index += `1`;
174	}
175
176	while (len--) {
177	*buf++ = readb(addr: base + page);
178	index += `1`;
179	}
180	} else {
181	unsigned long base = (ec->easi
182	? &ec->resource[ECARD_RES_EASI]
183	: &ec->resource[ECARD_RES_IOCSYNC])->start;
184	void __iomem pbase = (void* __iomem *)base;
185
186	if (!req->use_loader \|\| !ec->loader) {
187	off *= `4`;
188	while (len--) {
189	*buf++ = readb(addr: pbase + off);
190	off += `4`;
191	}
192	} else {
193	while(len--) {
194	/*
195	* The following is required by some
196	* expansion card loader programs.
197	*/
198	(unsigned* long *)`0x108` = `0`;
199	*buf++ = ecard_loader_read(off++, base,
200	ec->loader);
201	}
202	}
203	}
204
205	}
206
207	static DECLARE_WAIT_QUEUE_HEAD(ecard_wait);
208	static struct ecard_request *ecard_req;
209	static DEFINE_MUTEX(ecard_mutex);
210
211	/*
212	* Set up the expansion card daemon's page tables.
213	*/
214	static void ecard_init_pgtables(struct mm_struct *mm)
215	{
216	struct vm_area_struct vma = TLB_FLUSH_VMA(mm, VM_EXEC);
217
218	/ We want to set up the page tables for the following mapping:*
219	* Virtual Physical
220	* 0x03000000 0x03000000
221	* 0x03010000 unmapped
222	* 0x03210000 0x03210000
223	* 0x03400000 unmapped
224	* 0x08000000 0x08000000
225	* 0x10000000 unmapped
226	*
227	* FIXME: we don't follow this 100% yet.
228	*/
229	pgd_t src_pgd, dst_pgd;
230
231	src_pgd = pgd_offset(mm, (unsigned long)IO_BASE);
232	dst_pgd = pgd_offset(mm, IO_START);
233
234	memcpy(dst_pgd, src_pgd, sizeof(pgd_t) * (IO_SIZE / PGDIR_SIZE));
235
236	src_pgd = pgd_offset(mm, (unsigned long)EASI_BASE);
237	dst_pgd = pgd_offset(mm, EASI_START);
238
239	memcpy(dst_pgd, src_pgd, sizeof(pgd_t) * (EASI_SIZE / PGDIR_SIZE));
240
241	flush_tlb_range(&vma, IO_START, IO_START + IO_SIZE);
242	flush_tlb_range(&vma, EASI_START, EASI_START + EASI_SIZE);
243	}
244
245	static int ecard_init_mm(void)
246	{
247	struct mm_struct * mm = mm_alloc();
248	struct mm_struct *active_mm = current->active_mm;
249
250	if (!mm)
251	return -ENOMEM;
252
253	current->mm = mm;
254	current->active_mm = mm;
255	activate_mm(active_mm, mm);
256	mmdrop_lazy_tlb(mm: active_mm);
257	ecard_init_pgtables(mm);
258	return `0`;
259	}
260
261	static int
262	ecard_task(void * unused)
263	{
264	/*
265	* Allocate a mm. We're not a lazy-TLB kernel task since we need
266	* to set page table entries where the user space would be. Note
267	* that this also creates the page tables. Failure is not an
268	* option here.
269	*/
270	if (ecard_init_mm())
271	panic(fmt: "kecardd: unable to alloc mm\n");
272
273	while (`1`) {
274	struct ecard_request *req;
275
276	wait_event_interruptible(ecard_wait, ecard_req != NULL);
277
278	req = xchg(&ecard_req, NULL);
279	if (req != NULL) {
280	req->fn(req);
281	complete(req->complete);
282	}
283	}
284	}
285
286	/*
287	* Wake the expansion card daemon to action our request.
288	*
289	* FIXME: The test here is not sufficient to detect if the
290	* kcardd is running.
291	*/
292	static void ecard_call(struct ecard_request *req)
293	{
294	DECLARE_COMPLETION_ONSTACK(completion);
295
296	req->complete = &completion;
297
298	mutex_lock(&ecard_mutex);
299	ecard_req = req;
300	wake_up(&ecard_wait);
301
302	/*
303	* Now wait for kecardd to run.
304	*/
305	wait_for_completion(&completion);
306	mutex_unlock(lock: &ecard_mutex);
307	}
308
309	/ ======================= Mid-level card control ===================== /
310
311	static void
312	ecard_readbytes(void addr, ecard_t ec, int off, int len, int useld)
313	{
314	struct ecard_request req;
315
316	req.fn = ecard_task_readbytes;
317	req.ec = ec;
318	req.address = off;
319	req.length = len;
320	req.use_loader = useld;
321	req.buffer = addr;
322
323	ecard_call(req: &req);
324	}
325
326	int ecard_readchunk(struct in_chunk_dir cd, ecard_t ec, int id, int num)
327	{
328	struct ex_chunk_dir excd;
329	int index = `16`;
330	int useld = `0`;
331
332	if (!ec->cid.cd)
333	return `0`;
334
335	while(`1`) {
336	ecard_readbytes(&excd, ec, index, `8`, useld);
337	index += `8`;
338	if (c_id(&excd) == `0`) {
339	if (!useld && ec->loader) {
340	useld = `1`;
341	index = `0`;
342	continue;
343	}
344	return `0`;
345	}
346	if (c_id(&excd) == `0xf0`) { / link /
347	index = c_start(&excd);
348	continue;
349	}
350	if (c_id(&excd) == `0x80`) { / loader /
351	if (!ec->loader) {
352	ec->loader = kmalloc(c_len(&excd),
353	GFP_KERNEL);
354	if (ec->loader)
355	ecard_readbytes(ec->loader, ec,
356	(int)c_start(&excd),
357	c_len(&excd), useld);
358	else
359	return `0`;
360	}
361	continue;
362	}
363	if (c_id(&excd) == id && num-- == `0`)
364	break;
365	}
366
367	if (c_id(&excd) & `0x80`) {
368	switch (c_id(&excd) & `0x70`) {
369	case `0x70`:
370	ecard_readbytes((unsigned char *)excd.d.string, ec,
371	(int)c_start(&excd), c_len(&excd),
372	useld);
373	break;
374	case `0x00`:
375	break;
376	}
377	}
378	cd->start_offset = c_start(&excd);
379	memcpy(cd->d.string, excd.d.string, `256`);
380	return `1`;
381	}
382
383	/ ======================= Interrupt control ============================ /
384
385	static void ecard_def_irq_enable(ecard_t ec, int* irqnr)
386	{
387	}
388
389	static void ecard_def_irq_disable(ecard_t ec, int* irqnr)
390	{
391	}
392
393	static int ecard_def_irq_pending(ecard_t *ec)
394	{
395	return !ec->irqmask \|\| readb(addr: ec->irqaddr) & ec->irqmask;
396	}
397
398	static void ecard_def_fiq_enable(ecard_t ec, int* fiqnr)
399	{
400	panic(fmt: "ecard_def_fiq_enable called - impossible");
401	}
402
403	static void ecard_def_fiq_disable(ecard_t ec, int* fiqnr)
404	{
405	panic(fmt: "ecard_def_fiq_disable called - impossible");
406	}
407
408	static int ecard_def_fiq_pending(ecard_t *ec)
409	{
410	return !ec->fiqmask \|\| readb(addr: ec->fiqaddr) & ec->fiqmask;
411	}
412
413	static expansioncard_ops_t ecard_default_ops = {
414	ecard_def_irq_enable,
415	ecard_def_irq_disable,
416	ecard_def_irq_pending,
417	ecard_def_fiq_enable,
418	ecard_def_fiq_disable,
419	ecard_def_fiq_pending
420	};
421
422	/*
423	* Enable and disable interrupts from expansion cards.
424	* (interrupts are disabled for these functions).
425	*
426	* They are not meant to be called directly, but via enable/disable_irq.
427	*/
428	static void ecard_irq_unmask(struct irq_data *d)
429	{
430	ecard_t *ec = irq_data_get_irq_chip_data(d);
431
432	if (ec) {
433	if (!ec->ops)
434	ec->ops = &ecard_default_ops;
435
436	if (ec->claimed && ec->ops->irqenable)
437	ec->ops->irqenable(ec, d->irq);
438	else
439	printk(KERN_ERR "ecard: rejecting request to "
440	"enable IRQs for %d\n", d->irq);
441	}
442	}
443
444	static void ecard_irq_mask(struct irq_data *d)
445	{
446	ecard_t *ec = irq_data_get_irq_chip_data(d);
447
448	if (ec) {
449	if (!ec->ops)
450	ec->ops = &ecard_default_ops;
451
452	if (ec->ops && ec->ops->irqdisable)
453	ec->ops->irqdisable(ec, d->irq);
454	}
455	}
456
457	static struct irq_chip ecard_chip = {
458	.name = "ECARD",
459	.irq_ack = ecard_irq_mask,
460	.irq_mask = ecard_irq_mask,
461	.irq_unmask = ecard_irq_unmask,
462	};
463
464	void ecard_enablefiq(unsigned int fiqnr)
465	{
466	ecard_t *ec = slot_to_ecard(fiqnr);
467
468	if (ec) {
469	if (!ec->ops)
470	ec->ops = &ecard_default_ops;
471
472	if (ec->claimed && ec->ops->fiqenable)
473	ec->ops->fiqenable(ec, fiqnr);
474	else
475	printk(KERN_ERR "ecard: rejecting request to "
476	"enable FIQs for %d\n", fiqnr);
477	}
478	}
479
480	void ecard_disablefiq(unsigned int fiqnr)
481	{
482	ecard_t *ec = slot_to_ecard(fiqnr);
483
484	if (ec) {
485	if (!ec->ops)
486	ec->ops = &ecard_default_ops;
487
488	if (ec->ops->fiqdisable)
489	ec->ops->fiqdisable(ec, fiqnr);
490	}
491	}
492
493	static void ecard_dump_irq_state(void)
494	{
495	ecard_t *ec;
496
497	printk("Expansion card IRQ state:\n");
498
499	for (ec = cards; ec; ec = ec->next) {
500	const char *claimed;
501
502	if (ec->slot_no == `8`)
503	continue;
504
505	claimed = ec->claimed ? "" : "not ";
506
507	if (ec->ops && ec->ops->irqpending &&
508	ec->ops != &ecard_default_ops)
509	printk(" %d: %sclaimed irq %spending\n",
510	ec->slot_no, claimed,
511	ec->ops->irqpending(ec) ? "" : "not ");
512	else
513	printk(" %d: %sclaimed irqaddr %p, mask = %02X, status = %02X\n",
514	ec->slot_no, claimed,
515	ec->irqaddr, ec->irqmask, readb(ec->irqaddr));
516	}
517	}
518
519	static void ecard_check_lockup(struct irq_desc *desc)
520	{
521	static unsigned long last;
522	static int lockup;
523
524	/*
525	* If the timer interrupt has not run since the last million
526	* unrecognised expansion card interrupts, then there is
527	* something seriously wrong. Disable the expansion card
528	* interrupts so at least we can continue.
529	*
530	* Maybe we ought to start a timer to re-enable them some time
531	* later?
532	*/
533	if (last == jiffies) {
534	lockup += `1`;
535	if (lockup > `1000000`) {
536	printk(KERN_ERR "\nInterrupt lockup detected - "
537	"disabling all expansion card interrupts\n");
538
539	desc->irq_data.chip->irq_mask(&desc->irq_data);
540	ecard_dump_irq_state();
541	}
542	} else
543	lockup = `0`;
544
545	/*
546	* If we did not recognise the source of this interrupt,
547	* warn the user, but don't flood the user with these messages.
548	*/
549	if (!last \|\| time_after(jiffies, last + `5`*HZ)) {
550	last = jiffies;
551	printk(KERN_WARNING "Unrecognised interrupt from backplane\n");
552	ecard_dump_irq_state();
553	}
554	}
555
556	static void ecard_irq_handler(struct irq_desc *desc)
557	{
558	ecard_t *ec;
559	int called = `0`;
560
561	desc->irq_data.chip->irq_mask(&desc->irq_data);
562	for (ec = cards; ec; ec = ec->next) {
563	int pending;
564
565	if (!ec->claimed \|\| !ec->irq \|\| ec->slot_no == `8`)
566	continue;
567
568	if (ec->ops && ec->ops->irqpending)
569	pending = ec->ops->irqpending(ec);
570	else
571	pending = ecard_default_ops.irqpending(ec);
572
573	if (pending) {
574	generic_handle_irq(ec->irq);
575	called ++;
576	}
577	}
578	desc->irq_data.chip->irq_unmask(&desc->irq_data);
579
580	if (called == `0`)
581	ecard_check_lockup(desc);
582	}
583
584	static void __iomem __ecard_address(ecard_t ec, card_type_t type, card_speed_t speed)
585	{
586	void __iomem *address = NULL;
587	int slot = ec->slot_no;
588
589	if (ec->slot_no == `8`)
590	return ECARD_MEMC8_BASE;
591
592	ectcr &= ~(`1` << slot);
593
594	switch (type) {
595	case ECARD_MEMC:
596	if (slot < `4`)
597	address = ECARD_MEMC_BASE + (slot << `14`);
598	break;
599
600	case ECARD_IOC:
601	if (slot < `4`)
602	address = ECARD_IOC_BASE + (slot << `14`);
603	else
604	address = ECARD_IOC4_BASE + ((slot - `4`) << `14`);
605	if (address)
606	address += speed << `19`;
607	break;
608
609	case ECARD_EASI:
610	address = ECARD_EASI_BASE + (slot << `24`);
611	if (speed == ECARD_FAST)
612	ectcr \|= `1` << slot;
613	break;
614
615	default:
616	break;
617	}
618
619	#ifdef IOMD_ECTCR
620	iomd_writeb(ectcr, IOMD_ECTCR);
621	#endif
622	return address;
623	}
624
625	static int ecard_prints(struct seq_file m, ecard_t ec)
626	{
627	seq_printf(m, fmt: " %d: %s ", ec->slot_no, ec->easi ? "EASI" : " ");
628
629	if (ec->cid.id == `0`) {
630	struct in_chunk_dir incd;
631
632	seq_printf(m, fmt: "[%04X:%04X] ",
633	ec->cid.manufacturer, ec->cid.product);
634
635	if (!ec->card_desc && ec->cid.cd &&
636	ecard_readchunk(&incd, ec, `0xf5`, `0`)) {
637	ec->card_desc = kmalloc(strlen(incd.d.string)+`1`, GFP_KERNEL);
638
639	if (ec->card_desc)
640	strcpy((char *)ec->card_desc, incd.d.string);
641	}
642
643	seq_printf(m, fmt: "%s\n", ec->card_desc ? ec->card_desc : "unknown");
644	} else
645	seq_printf(m, fmt: "Simple card %d\n", ec->cid.id);
646
647	return `0`;
648	}
649
650	static int ecard_devices_proc_show(struct seq_file m, void* *v)
651	{
652	ecard_t *ec = cards;
653
654	while (ec) {
655	ecard_prints(m, ec);
656	ec = ec->next;
657	}
658	return `0`;
659	}
660
661	static struct proc_dir_entry *proc_bus_ecard_dir = NULL;
662
663	static void ecard_proc_init(void)
664	{
665	proc_bus_ecard_dir = proc_mkdir("bus/ecard", NULL);
666	proc_create_single("devices", `0`, proc_bus_ecard_dir,
667	ecard_devices_proc_show);
668	}
669
670	#define ec_set_resource(ec,nr,st,sz) \
671	do { \
672	(ec)->resource[nr].name = dev_name(&ec->dev); \
673	(ec)->resource[nr].start = st; \
674	(ec)->resource[nr].end = (st) + (sz) - 1; \
675	(ec)->resource[nr].flags = IORESOURCE_MEM; \
676	} while (0)
677
678	static void __init ecard_free_card(struct expansion_card *ec)
679	{
680	int i;
681
682	for (i = `0`; i < ECARD_NUM_RESOURCES; i++)
683	if (ec->resource[i].flags)
684	release_resource(&ec->resource[i]);
685
686	kfree(objp: ec);
687	}
688
689	static struct expansion_card __init ecard_alloc_card(int* type, int slot)
690	{
691	struct expansion_card *ec;
692	unsigned long base;
693	int i;
694
695	ec = kzalloc(sizeof(ecard_t), GFP_KERNEL);
696	if (!ec) {
697	ec = ERR_PTR(error: -ENOMEM);
698	goto nomem;
699	}
700
701	ec->slot_no = slot;
702	ec->easi = type == ECARD_EASI;
703	ec->irq = `0`;
704	ec->fiq = `0`;
705	ec->dma = NO_DMA;
706	ec->ops = &ecard_default_ops;
707
708	dev_set_name(dev: &ec->dev, name: "ecard%d", slot);
709	ec->dev.parent = NULL;
710	ec->dev.bus = &ecard_bus_type;
711	ec->dev.dma_mask = &ec->dma_mask;
712	ec->dma_mask = (u64)`0xffffffff`;
713	ec->dev.coherent_dma_mask = ec->dma_mask;
714
715	if (slot < `4`) {
716	ec_set_resource(ec, ECARD_RES_MEMC,
717	PODSLOT_MEMC_BASE + (slot << `14`),
718	PODSLOT_MEMC_SIZE);
719	base = PODSLOT_IOC0_BASE + (slot << `14`);
720	} else
721	base = PODSLOT_IOC4_BASE + ((slot - `4`) << `14`);
722
723	#ifdef CONFIG_ARCH_RPC
724	if (slot < `8`) {
725	ec_set_resource(ec, ECARD_RES_EASI,
726	PODSLOT_EASI_BASE + (slot << `24`),
727	PODSLOT_EASI_SIZE);
728	}
729
730	if (slot == `8`) {
731	ec_set_resource(ec, ECARD_RES_MEMC, NETSLOT_BASE, NETSLOT_SIZE);
732	} else
733	#endif
734
735	for (i = `0`; i <= ECARD_RES_IOCSYNC - ECARD_RES_IOCSLOW; i++)
736	ec_set_resource(ec, i + ECARD_RES_IOCSLOW,
737	base + (i << `19`), PODSLOT_IOC_SIZE);
738
739	for (i = `0`; i < ECARD_NUM_RESOURCES; i++) {
740	if (ec->resource[i].flags &&
741	request_resource(&iomem_resource, &ec->resource[i])) {
742	dev_err(&ec->dev, "resource(s) not available\n");
743	ec->resource[i].end -= ec->resource[i].start;
744	ec->resource[i].start = `0`;
745	ec->resource[i].flags = `0`;
746	}
747	}
748
749	nomem:
750	return ec;
751	}
752
753	static ssize_t irq_show(struct device dev, struct* device_attribute attr, char* *buf)
754	{
755	struct expansion_card *ec = ECARD_DEV(dev);
756	return sprintf(buf, fmt: "%u\n", ec->irq);
757	}
758	static DEVICE_ATTR_RO(irq);
759
760	static ssize_t dma_show(struct device dev, struct* device_attribute attr, char* *buf)
761	{
762	struct expansion_card *ec = ECARD_DEV(dev);
763	return sprintf(buf, fmt: "%u\n", ec->dma);
764	}
765	static DEVICE_ATTR_RO(dma);
766
767	static ssize_t resource_show(struct device dev, struct* device_attribute attr, char* *buf)
768	{
769	struct expansion_card *ec = ECARD_DEV(dev);
770	char *str = buf;
771	int i;
772
773	for (i = `0`; i < ECARD_NUM_RESOURCES; i++)
774	str += sprintf(str, "%08x %08x %08lx\n",
775	ec->resource[i].start,
776	ec->resource[i].end,
777	ec->resource[i].flags);
778
779	return str - buf;
780	}
781	static DEVICE_ATTR_RO(resource);
782
783	static ssize_t vendor_show(struct device dev, struct* device_attribute attr, char* *buf)
784	{
785	struct expansion_card *ec = ECARD_DEV(dev);
786	return sprintf(buf, fmt: "%u\n", ec->cid.manufacturer);
787	}
788	static DEVICE_ATTR_RO(vendor);
789
790	static ssize_t device_show(struct device dev, struct* device_attribute attr, char* *buf)
791	{
792	struct expansion_card *ec = ECARD_DEV(dev);
793	return sprintf(buf, fmt: "%u\n", ec->cid.product);
794	}
795	static DEVICE_ATTR_RO(device);
796
797	static ssize_t type_show(struct device dev, struct* device_attribute attr, char* *buf)
798	{
799	struct expansion_card *ec = ECARD_DEV(dev);
800	return sprintf(buf, fmt: "%s\n", ec->easi ? "EASI" : "IOC");
801	}
802	static DEVICE_ATTR_RO(type);
803
804	static struct attribute *ecard_dev_attrs[] = {
805	&dev_attr_device.attr,
806	&dev_attr_dma.attr,
807	&dev_attr_irq.attr,
808	&dev_attr_resource.attr,
809	&dev_attr_type.attr,
810	&dev_attr_vendor.attr,
811	NULL,
812	};
813	ATTRIBUTE_GROUPS(ecard_dev);
814
815	int ecard_request_resources(struct expansion_card *ec)
816	{
817	int i, err = `0`;
818
819	for (i = `0`; i < ECARD_NUM_RESOURCES; i++) {
820	if (ecard_resource_end(ec, i) &&
821	!request_mem_region(ecard_resource_start(ec, i),
822	ecard_resource_len(ec, i),
823	ec->dev.driver->name)) {
824	err = -EBUSY;
825	break;
826	}
827	}
828
829	if (err) {
830	while (i--)
831	if (ecard_resource_end(ec, i))
832	release_mem_region(ecard_resource_start(ec, i),
833	ecard_resource_len(ec, i));
834	}
835	return err;
836	}
837	EXPORT_SYMBOL(ecard_request_resources);
838
839	void ecard_release_resources(struct expansion_card *ec)
840	{
841	int i;
842
843	for (i = `0`; i < ECARD_NUM_RESOURCES; i++)
844	if (ecard_resource_end(ec, i))
845	release_mem_region(ecard_resource_start(ec, i),
846	ecard_resource_len(ec, i));
847	}
848	EXPORT_SYMBOL(ecard_release_resources);
849
850	void ecard_setirq(struct expansion_card ec, const* struct expansion_card_ops ops, void* *irq_data)
851	{
852	ec->irq_data = irq_data;
853	barrier();
854	ec->ops = ops;
855	}
856	EXPORT_SYMBOL(ecard_setirq);
857
858	void __iomem ecardm_iomap(struct* expansion_card ec, unsigned* int res,
859	unsigned long offset, unsigned long maxsize)
860	{
861	unsigned long start = ecard_resource_start(ec, res);
862	unsigned long end = ecard_resource_end(ec, res);
863
864	if (offset > (end - start))
865	return NULL;
866
867	start += offset;
868	if (maxsize && end - start > maxsize)
869	end = start + maxsize;
870
871	return devm_ioremap(dev: &ec->dev, offset: start, size: end - start);
872	}
873	EXPORT_SYMBOL(ecardm_iomap);
874
875	static void atomwide_3p_quirk(ecard_t *ec)
876	{
877	void __iomem *addr = __ecard_address(ec, ECARD_IOC, ECARD_SYNC);
878	unsigned int i;
879
880	/ Disable interrupts on each port /
881	for (i = `0x2000`; i <= `0x2800`; i += `0x0400`)
882	writeb(val: `0`, addr: addr + i + `4`);
883	}
884
885	/*
886	* Probe for an expansion card.
887	*
888	* If bit 1 of the first byte of the card is set, then the
889	* card does not exist.
890	*/
891	static int __init ecard_probe(int slot, unsigned irq, card_type_t type)
892	{
893	ecard_t **ecp;
894	ecard_t *ec;
895	struct ex_ecid cid;
896	void __iomem *addr;
897	int i, rc;
898
899	ec = ecard_alloc_card(type, slot);
900	if (IS_ERR(ec)) {
901	rc = PTR_ERR(ec);
902	goto nomem;
903	}
904
905	rc = -ENODEV;
906	if ((addr = __ecard_address(ec, type, ECARD_SYNC)) == NULL)
907	goto nodev;
908
909	cid.r_zero = `1`;
910	ecard_readbytes(&cid, ec, `0`, `16`, `0`);
911	if (cid.r_zero)
912	goto nodev;
913
914	ec->cid.id = cid.r_id;
915	ec->cid.cd = cid.r_cd;
916	ec->cid.is = cid.r_is;
917	ec->cid.w = cid.r_w;
918	ec->cid.manufacturer = ecard_getu16(cid.r_manu);
919	ec->cid.product = ecard_getu16(cid.r_prod);
920	ec->cid.country = cid.r_country;
921	ec->cid.irqmask = cid.r_irqmask;
922	ec->cid.irqoff = ecard_gets24(cid.r_irqoff);
923	ec->cid.fiqmask = cid.r_fiqmask;
924	ec->cid.fiqoff = ecard_gets24(cid.r_fiqoff);
925	ec->fiqaddr =
926	ec->irqaddr = addr;
927
928	if (ec->cid.is) {
929	ec->irqmask = ec->cid.irqmask;
930	ec->irqaddr += ec->cid.irqoff;
931	ec->fiqmask = ec->cid.fiqmask;
932	ec->fiqaddr += ec->cid.fiqoff;
933	} else {
934	ec->irqmask = `1`;
935	ec->fiqmask = `4`;
936	}
937
938	for (i = `0`; i < ARRAY_SIZE(quirklist); i++)
939	if (quirklist[i].manufacturer == ec->cid.manufacturer &&
940	quirklist[i].product == ec->cid.product) {
941	if (quirklist[i].type)
942	ec->card_desc = quirklist[i].type;
943	if (quirklist[i].init)
944	quirklist[i].init(ec);
945	break;
946	}
947
948	ec->irq = irq;
949
950	/*
951	* hook the interrupt handlers
952	*/
953	if (slot < `8`) {
954	irq_set_chip_and_handler(ec->irq, &ecard_chip,
955	handle_level_irq);
956	irq_set_chip_data(ec->irq, ec);
957	irq_clear_status_flags(ec->irq, IRQ_NOREQUEST);
958	}
959
960	#ifdef CONFIG_ARCH_RPC
961	/ On RiscPC, only first two slots have DMA capability /
962	if (slot < `2`)
963	ec->dma = `2` + slot;
964	#endif
965
966	for (ecp = &cards; ecp; ecp = &(ecp)->next);
967
968	*ecp = ec;
969	slot_to_expcard[slot] = ec;
970
971	rc = device_register(&ec->dev);
972	if (rc)
973	goto nodev;
974
975	return `0`;
976
977	nodev:
978	ecard_free_card(ec);
979	nomem:
980	return rc;
981	}
982
983	/*
984	* Initialise the expansion card system.
985	* Locate all hardware - interrupt management and
986	* actual cards.
987	*/
988	static int __init ecard_init(void)
989	{
990	struct task_struct *task;
991	int slot, irqbase;
992
993	irqbase = irq_alloc_descs(-`1`, `0`, `8`, -`1`);
994	if (irqbase < `0`)
995	return irqbase;
996
997	task = kthread_run(ecard_task, NULL, "kecardd");
998	if (IS_ERR(ptr: task)) {
999	printk(KERN_ERR "Ecard: unable to create kernel thread: %ld\n",
1000	PTR_ERR(task));
1001	irq_free_descs(irq: irqbase, cnt: `8`);
1002	return PTR_ERR(ptr: task);
1003	}
1004
1005	printk("Probing expansion cards\n");
1006
1007	for (slot = `0`; slot < `8`; slot ++) {
1008	if (ecard_probe(slot, irq: irqbase + slot, type: ECARD_EASI) == -ENODEV)
1009	ecard_probe(slot, irq: irqbase + slot, type: ECARD_IOC);
1010	}
1011
1012	ecard_probe(slot: `8`, irq: `11`, type: ECARD_IOC);
1013
1014	irq_set_chained_handler(IRQ_EXPANSIONCARD, ecard_irq_handler);
1015
1016	ecard_proc_init();
1017
1018	return `0`;
1019	}
1020
1021	subsys_initcall(ecard_init);
1022
1023	/*
1024	* ECARD "bus"
1025	*/
1026	static const struct ecard_id *
1027	ecard_match_device(const struct ecard_id ids, struct* expansion_card *ec)
1028	{
1029	int i;
1030
1031	for (i = `0`; ids[i].manufacturer != `65535`; i++)
1032	if (ec->cid.manufacturer == ids[i].manufacturer &&
1033	ec->cid.product == ids[i].product)
1034	return ids + i;
1035
1036	return NULL;
1037	}
1038
1039	static int ecard_drv_probe(struct device *dev)
1040	{
1041	struct expansion_card *ec = ECARD_DEV(dev);
1042	struct ecard_driver *drv = ECARD_DRV(dev->driver);
1043	const struct ecard_id *id;
1044	int ret;
1045
1046	id = ecard_match_device(ids: drv->id_table, ec);
1047
1048	ec->claimed = `1`;
1049	ret = drv->probe(ec, id);
1050	if (ret)
1051	ec->claimed = `0`;
1052	return ret;
1053	}
1054
1055	static void ecard_drv_remove(struct device *dev)
1056	{
1057	struct expansion_card *ec = ECARD_DEV(dev);
1058	struct ecard_driver *drv = ECARD_DRV(dev->driver);
1059
1060	drv->remove(ec);
1061	ec->claimed = `0`;
1062
1063	/*
1064	* Restore the default operations. We ensure that the
1065	* ops are set before we change the data.
1066	*/
1067	ec->ops = &ecard_default_ops;
1068	barrier();
1069	ec->irq_data = NULL;
1070	}
1071
1072	/*
1073	* Before rebooting, we must make sure that the expansion card is in a
1074	* sensible state, so it can be re-detected. This means that the first
1075	* page of the ROM must be visible. We call the expansion cards reset
1076	* handler, if any.
1077	*/
1078	static void ecard_drv_shutdown(struct device *dev)
1079	{
1080	struct expansion_card *ec = ECARD_DEV(dev);
1081	struct ecard_driver *drv = ECARD_DRV(dev->driver);
1082	struct ecard_request req;
1083
1084	if (dev->driver) {
1085	if (drv->shutdown)
1086	drv->shutdown(ec);
1087	ec->claimed = `0`;
1088	}
1089
1090	/*
1091	* If this card has a loader, call the reset handler.
1092	*/
1093	if (ec->loader) {
1094	req.fn = ecard_task_reset;
1095	req.ec = ec;
1096	ecard_call(req: &req);
1097	}
1098	}
1099
1100	int ecard_register_driver(struct ecard_driver *drv)
1101	{
1102	drv->drv.bus = &ecard_bus_type;
1103
1104	return driver_register(drv: &drv->drv);
1105	}
1106
1107	void ecard_remove_driver(struct ecard_driver *drv)
1108	{
1109	driver_unregister(drv: &drv->drv);
1110	}
1111
1112	static int ecard_match(struct device _dev, struct* device_driver *_drv)
1113	{
1114	struct expansion_card *ec = ECARD_DEV(_dev);
1115	struct ecard_driver *drv = ECARD_DRV(_drv);
1116	int ret;
1117
1118	if (drv->id_table) {
1119	ret = ecard_match_device(ids: drv->id_table, ec) != NULL;
1120	} else {
1121	ret = ec->cid.id == drv->id;
1122	}
1123
1124	return ret;
1125	}
1126
1127	struct bus_type ecard_bus_type = {
1128	.name = "ecard",
1129	.dev_groups = ecard_dev_groups,
1130	.match = ecard_match,
1131	.probe = ecard_drv_probe,
1132	.remove = ecard_drv_remove,
1133	.shutdown = ecard_drv_shutdown,
1134	};
1135
1136	static int ecard_bus_init(void)
1137	{
1138	return bus_register(bus: &ecard_bus_type);
1139	}
1140
1141	postcore_initcall(ecard_bus_init);
1142
1143	EXPORT_SYMBOL(ecard_readchunk);
1144	EXPORT_SYMBOL(ecard_register_driver);
1145	EXPORT_SYMBOL(ecard_remove_driver);
1146	EXPORT_SYMBOL(ecard_bus_type);
1147

source code of linux/arch/arm/mach-rpc/ecard.c