mvebu-mbus.c source code [linux/drivers/bus/mvebu-mbus.c]

1	// SPDX-License-Identifier: GPL-2.0-only
2	/*
3	* Address map functions for Marvell EBU SoCs (Kirkwood, Armada
4	* 370/XP, Dove, Orion5x and MV78xx0)
5	*
6	* The Marvell EBU SoCs have a configurable physical address space:
7	* the physical address at which certain devices (PCIe, NOR, NAND,
8	* etc.) sit can be configured. The configuration takes place through
9	* two sets of registers:
10	*
11	* - One to configure the access of the CPU to the devices. Depending
12	* on the families, there are between 8 and 20 configurable windows,
13	* each can be use to create a physical memory window that maps to a
14	* specific device. Devices are identified by a tuple (target,
15	* attribute).
16	*
17	* - One to configure the access to the CPU to the SDRAM. There are
18	* either 2 (for Dove) or 4 (for other families) windows to map the
19	* SDRAM into the physical address space.
20	*
21	* This driver:
22	*
23	* - Reads out the SDRAM address decoding windows at initialization
24	* time, and fills the mvebu_mbus_dram_info structure with these
25	* information. The exported function mv_mbus_dram_info() allow
26	* device drivers to get those information related to the SDRAM
27	* address decoding windows. This is because devices also have their
28	* own windows (configured through registers that are part of each
29	* device register space), and therefore the drivers for Marvell
30	* devices have to configure those device -> SDRAM windows to ensure
31	* that DMA works properly.
32	*
33	* - Provides an API for platform code or device drivers to
34	* dynamically add or remove address decoding windows for the CPU ->
35	* device accesses. This API is mvebu_mbus_add_window_by_id(),
36	* mvebu_mbus_add_window_remap_by_id() and
37	* mvebu_mbus_del_window().
38	*
39	* - Provides a debugfs interface in /sys/kernel/debug/mvebu-mbus/ to
40	* see the list of CPU -> SDRAM windows and their configuration
41	* (file 'sdram') and the list of CPU -> devices windows and their
42	* configuration (file 'devices').
43	*/
44
45	#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt
46
47	#include <linux/kernel.h>
48	#include <linux/module.h>
49	#include <linux/init.h>
50	#include <linux/mbus.h>
51	#include <linux/io.h>
52	#include <linux/ioport.h>
53	#include <linux/of.h>
54	#include <linux/of_address.h>
55	#include <linux/debugfs.h>
56	#include <linux/log2.h>
57	#include <linux/memblock.h>
58	#include <linux/syscore_ops.h>
59
60	/*
61	* DDR target is the same on all platforms.
62	*/
63	#define TARGET_DDR 0
64
65	/*
66	* CPU Address Decode Windows registers
67	*/
68	#define WIN_CTRL_OFF 0x0000
69	#define WIN_CTRL_ENABLE BIT(0)
70	/ Only on HW I/O coherency capable platforms /
71	#define WIN_CTRL_SYNCBARRIER BIT(1)
72	#define WIN_CTRL_TGT_MASK 0xf0
73	#define WIN_CTRL_TGT_SHIFT 4
74	#define WIN_CTRL_ATTR_MASK 0xff00
75	#define WIN_CTRL_ATTR_SHIFT 8
76	#define WIN_CTRL_SIZE_MASK 0xffff0000
77	#define WIN_CTRL_SIZE_SHIFT 16
78	#define WIN_BASE_OFF 0x0004
79	#define WIN_BASE_LOW 0xffff0000
80	#define WIN_BASE_HIGH 0xf
81	#define WIN_REMAP_LO_OFF 0x0008
82	#define WIN_REMAP_LOW 0xffff0000
83	#define WIN_REMAP_HI_OFF 0x000c
84
85	#define UNIT_SYNC_BARRIER_OFF 0x84
86	#define UNIT_SYNC_BARRIER_ALL 0xFFFF
87
88	#define ATTR_HW_COHERENCY (0x1 << 4)
89
90	#define DDR_BASE_CS_OFF(n) (0x0000 + ((n) << 3))
91	#define DDR_BASE_CS_HIGH_MASK 0xf
92	#define DDR_BASE_CS_LOW_MASK 0xff000000
93	#define DDR_SIZE_CS_OFF(n) (0x0004 + ((n) << 3))
94	#define DDR_SIZE_ENABLED BIT(0)
95	#define DDR_SIZE_CS_MASK 0x1c
96	#define DDR_SIZE_CS_SHIFT 2
97	#define DDR_SIZE_MASK 0xff000000
98
99	#define DOVE_DDR_BASE_CS_OFF(n) ((n) << 4)
100
101	/ Relative to mbusbridge_base /
102	#define MBUS_BRIDGE_CTRL_OFF 0x0
103	#define MBUS_BRIDGE_BASE_OFF 0x4
104
105	/ Maximum number of windows, for all known platforms /
106	#define MBUS_WINS_MAX 20
107
108	struct mvebu_mbus_state;
109
110	struct mvebu_mbus_soc_data {
111	unsigned int num_wins;
112	bool has_mbus_bridge;
113	unsigned int (win_cfg_offset)(const* int win);
114	unsigned int (win_remap_offset)(const* int win);
115	void (setup_cpu_target)(struct* mvebu_mbus_state *s);
116	int (save_cpu_target)(struct* mvebu_mbus_state *s,
117	u32 __iomem *store_addr);
118	int (show_cpu_target)(struct* mvebu_mbus_state *s,
119	struct seq_file seq, void* *v);
120	};
121
122	/*
123	* Used to store the state of one MBus window across suspend/resume.
124	*/
125	struct mvebu_mbus_win_data {
126	u32 ctrl;
127	u32 base;
128	u32 remap_lo;
129	u32 remap_hi;
130	};
131
132	struct mvebu_mbus_state {
133	void __iomem *mbuswins_base;
134	void __iomem *sdramwins_base;
135	void __iomem *mbusbridge_base;
136	phys_addr_t sdramwins_phys_base;
137	struct dentry *debugfs_root;
138	struct dentry *debugfs_sdram;
139	struct dentry *debugfs_devs;
140	struct resource pcie_mem_aperture;
141	struct resource pcie_io_aperture;
142	const struct mvebu_mbus_soc_data *soc;
143	int hw_io_coherency;
144
145	/ Used during suspend/resume /
146	u32 mbus_bridge_ctrl;
147	u32 mbus_bridge_base;
148	struct mvebu_mbus_win_data wins[MBUS_WINS_MAX];
149	};
150
151	static struct mvebu_mbus_state mbus_state;
152
153	/*
154	* We provide two variants of the mv_mbus_dram_info() function:
155	*
156	* - The normal one, where the described DRAM ranges may overlap with
157	* the I/O windows, but for which the DRAM ranges are guaranteed to
158	* have a power of two size. Such ranges are suitable for the DMA
159	* masters that only DMA between the RAM and the device, which is
160	* actually all devices except the crypto engines.
161	*
162	* - The 'nooverlap' one, where the described DRAM ranges are
163	* guaranteed to not overlap with the I/O windows, but for which the
164	* DRAM ranges will not have power of two sizes. They will only be
165	* aligned on a 64 KB boundary, and have a size multiple of 64
166	* KB. Such ranges are suitable for the DMA masters that DMA between
167	* the crypto SRAM (which is mapped through an I/O window) and a
168	* device. This is the case for the crypto engines.
169	*/
170
171	static struct mbus_dram_target_info mvebu_mbus_dram_info;
172	static struct mbus_dram_target_info mvebu_mbus_dram_info_nooverlap;
173
174	const struct mbus_dram_target_info mv_mbus_dram_info(void*)
175	{
176	return &mvebu_mbus_dram_info;
177	}
178	EXPORT_SYMBOL_GPL(mv_mbus_dram_info);
179
180	const struct mbus_dram_target_info mv_mbus_dram_info_nooverlap(void*)
181	{
182	return &mvebu_mbus_dram_info_nooverlap;
183	}
184	EXPORT_SYMBOL_GPL(mv_mbus_dram_info_nooverlap);
185
186	/ Checks whether the given window has remap capability /
187	static bool mvebu_mbus_window_is_remappable(struct mvebu_mbus_state *mbus,
188	const int win)
189	{
190	return mbus->soc->win_remap_offset(win) != MVEBU_MBUS_NO_REMAP;
191	}
192
193	/*
194	* Functions to manipulate the address decoding windows
195	*/
196
197	static void mvebu_mbus_read_window(struct mvebu_mbus_state *mbus,
198	int win, int enabled, u64 base,
199	u32 size, u8 target, u8 *attr,
200	u64 *remap)
201	{
202	void __iomem *addr = mbus->mbuswins_base +
203	mbus->soc->win_cfg_offset(win);
204	u32 basereg = readl(addr: addr + WIN_BASE_OFF);
205	u32 ctrlreg = readl(addr: addr + WIN_CTRL_OFF);
206
207	if (!(ctrlreg & WIN_CTRL_ENABLE)) {
208	*enabled = `0`;
209	return;
210	}
211
212	*enabled = `1`;
213	*base = ((u64)basereg & WIN_BASE_HIGH) << `32`;
214	*base \|= (basereg & WIN_BASE_LOW);
215	*size = (ctrlreg \| ~WIN_CTRL_SIZE_MASK) + `1`;
216
217	if (target)
218	*target = (ctrlreg & WIN_CTRL_TGT_MASK) >> WIN_CTRL_TGT_SHIFT;
219
220	if (attr)
221	*attr = (ctrlreg & WIN_CTRL_ATTR_MASK) >> WIN_CTRL_ATTR_SHIFT;
222
223	if (remap) {
224	if (mvebu_mbus_window_is_remappable(mbus, win)) {
225	u32 remap_low, remap_hi;
226	void __iomem *addr_rmp = mbus->mbuswins_base +
227	mbus->soc->win_remap_offset(win);
228	remap_low = readl(addr: addr_rmp + WIN_REMAP_LO_OFF);
229	remap_hi = readl(addr: addr_rmp + WIN_REMAP_HI_OFF);
230	*remap = ((u64)remap_hi << `32`) \| remap_low;
231	} else
232	*remap = `0`;
233	}
234	}
235
236	static void mvebu_mbus_disable_window(struct mvebu_mbus_state *mbus,
237	int win)
238	{
239	void __iomem *addr;
240
241	addr = mbus->mbuswins_base + mbus->soc->win_cfg_offset(win);
242	writel(val: `0`, addr: addr + WIN_BASE_OFF);
243	writel(val: `0`, addr: addr + WIN_CTRL_OFF);
244
245	if (mvebu_mbus_window_is_remappable(mbus, win)) {
246	addr = mbus->mbuswins_base + mbus->soc->win_remap_offset(win);
247	writel(val: `0`, addr: addr + WIN_REMAP_LO_OFF);
248	writel(val: `0`, addr: addr + WIN_REMAP_HI_OFF);
249	}
250	}
251
252	/ Checks whether the given window number is available /
253
254	static int mvebu_mbus_window_is_free(struct mvebu_mbus_state *mbus,
255	const int win)
256	{
257	void __iomem *addr = mbus->mbuswins_base +
258	mbus->soc->win_cfg_offset(win);
259	u32 ctrl = readl(addr: addr + WIN_CTRL_OFF);
260
261	return !(ctrl & WIN_CTRL_ENABLE);
262	}
263
264	/*
265	* Checks whether the given (base, base+size) area doesn't overlap an
266	* existing region
267	*/
268	static int mvebu_mbus_window_conflicts(struct mvebu_mbus_state *mbus,
269	phys_addr_t base, size_t size,
270	u8 target, u8 attr)
271	{
272	u64 end = (u64)base + size;
273	int win;
274
275	for (win = `0`; win < mbus->soc->num_wins; win++) {
276	u64 wbase, wend;
277	u32 wsize;
278	u8 wtarget, wattr;
279	int enabled;
280
281	mvebu_mbus_read_window(mbus, win,
282	enabled: &enabled, base: &wbase, size: &wsize,
283	target: &wtarget, attr: &wattr, NULL);
284
285	if (!enabled)
286	continue;
287
288	wend = wbase + wsize;
289
290	/*
291	* Check if the current window overlaps with the
292	* proposed physical range
293	*/
294	if ((u64)base < wend && end > wbase)
295	return `0`;
296	}
297
298	return `1`;
299	}
300
301	static int mvebu_mbus_find_window(struct mvebu_mbus_state *mbus,
302	phys_addr_t base, size_t size)
303	{
304	int win;
305
306	for (win = `0`; win < mbus->soc->num_wins; win++) {
307	u64 wbase;
308	u32 wsize;
309	int enabled;
310
311	mvebu_mbus_read_window(mbus, win,
312	enabled: &enabled, base: &wbase, size: &wsize,
313	NULL, NULL, NULL);
314
315	if (!enabled)
316	continue;
317
318	if (base == wbase && size == wsize)
319	return win;
320	}
321
322	return -ENODEV;
323	}
324
325	static int mvebu_mbus_setup_window(struct mvebu_mbus_state *mbus,
326	int win, phys_addr_t base, size_t size,
327	phys_addr_t remap, u8 target,
328	u8 attr)
329	{
330	void __iomem *addr = mbus->mbuswins_base +
331	mbus->soc->win_cfg_offset(win);
332	u32 ctrl, remap_addr;
333
334	if (!is_power_of_2(n: size)) {
335	WARN(true, "Invalid MBus window size: 0x%zx\n", size);
336	return -EINVAL;
337	}
338
339	if ((base & (phys_addr_t)(size - `1`)) != `0`) {
340	WARN(true, "Invalid MBus base/size: %pa len 0x%zx\n", &base,
341	size);
342	return -EINVAL;
343	}
344
345	ctrl = ((size - `1`) & WIN_CTRL_SIZE_MASK) \|
346	(attr << WIN_CTRL_ATTR_SHIFT) \|
347	(target << WIN_CTRL_TGT_SHIFT) \|
348	WIN_CTRL_ENABLE;
349	if (mbus->hw_io_coherency)
350	ctrl \|= WIN_CTRL_SYNCBARRIER;
351
352	writel(val: base & WIN_BASE_LOW, addr: addr + WIN_BASE_OFF);
353	writel(val: ctrl, addr: addr + WIN_CTRL_OFF);
354
355	if (mvebu_mbus_window_is_remappable(mbus, win)) {
356	void __iomem *addr_rmp = mbus->mbuswins_base +
357	mbus->soc->win_remap_offset(win);
358
359	if (remap == MVEBU_MBUS_NO_REMAP)
360	remap_addr = base;
361	else
362	remap_addr = remap;
363	writel(val: remap_addr & WIN_REMAP_LOW, addr: addr_rmp + WIN_REMAP_LO_OFF);
364	writel(val: `0`, addr: addr_rmp + WIN_REMAP_HI_OFF);
365	}
366
367	return `0`;
368	}
369
370	static int mvebu_mbus_alloc_window(struct mvebu_mbus_state *mbus,
371	phys_addr_t base, size_t size,
372	phys_addr_t remap, u8 target,
373	u8 attr)
374	{
375	int win;
376
377	if (remap == MVEBU_MBUS_NO_REMAP) {
378	for (win = `0`; win < mbus->soc->num_wins; win++) {
379	if (mvebu_mbus_window_is_remappable(mbus, win))
380	continue;
381
382	if (mvebu_mbus_window_is_free(mbus, win))
383	return mvebu_mbus_setup_window(mbus, win, base,
384	size, remap,
385	target, attr);
386	}
387	}
388
389	for (win = `0`; win < mbus->soc->num_wins; win++) {
390	/ Skip window if need remap but is not supported /
391	if ((remap != MVEBU_MBUS_NO_REMAP) &&
392	!mvebu_mbus_window_is_remappable(mbus, win))
393	continue;
394
395	if (mvebu_mbus_window_is_free(mbus, win))
396	return mvebu_mbus_setup_window(mbus, win, base, size,
397	remap, target, attr);
398	}
399
400	return -ENOMEM;
401	}
402
403	/*
404	* Debugfs debugging
405	*/
406
407	/ Common function used for Dove, Kirkwood, Armada 370/XP and Orion 5x /
408	static int mvebu_sdram_debug_show_orion(struct mvebu_mbus_state *mbus,
409	struct seq_file seq, void* *v)
410	{
411	int i;
412
413	for (i = `0`; i < `4`; i++) {
414	u32 basereg = readl(addr: mbus->sdramwins_base + DDR_BASE_CS_OFF(i));
415	u32 sizereg = readl(addr: mbus->sdramwins_base + DDR_SIZE_CS_OFF(i));
416	u64 base;
417	u32 size;
418
419	if (!(sizereg & DDR_SIZE_ENABLED)) {
420	seq_printf(m: seq, fmt: "[%d] disabled\n", i);
421	continue;
422	}
423
424	base = ((u64)basereg & DDR_BASE_CS_HIGH_MASK) << `32`;
425	base \|= basereg & DDR_BASE_CS_LOW_MASK;
426	size = (sizereg \| ~DDR_SIZE_MASK);
427
428	seq_printf(m: seq, fmt: "[%d] %016llx - %016llx : cs%d\n",
429	i, (unsigned long long)base,
430	(unsigned long long)base + size + `1`,
431	(sizereg & DDR_SIZE_CS_MASK) >> DDR_SIZE_CS_SHIFT);
432	}
433
434	return `0`;
435	}
436
437	/ Special function for Dove /
438	static int mvebu_sdram_debug_show_dove(struct mvebu_mbus_state *mbus,
439	struct seq_file seq, void* *v)
440	{
441	int i;
442
443	for (i = `0`; i < `2`; i++) {
444	u32 map = readl(addr: mbus->sdramwins_base + DOVE_DDR_BASE_CS_OFF(i));
445	u64 base;
446	u32 size;
447
448	if (!(map & `1`)) {
449	seq_printf(m: seq, fmt: "[%d] disabled\n", i);
450	continue;
451	}
452
453	base = map & `0xff800000`;
454	size = `0x100000` << (((map & `0x000f0000`) >> `16`) - `4`);
455
456	seq_printf(m: seq, fmt: "[%d] %016llx - %016llx : cs%d\n",
457	i, (unsigned long long)base,
458	(unsigned long long)base + size, i);
459	}
460
461	return `0`;
462	}
463
464	static int mvebu_sdram_debug_show(struct seq_file seq, void* *v)
465	{
466	struct mvebu_mbus_state *mbus = &mbus_state;
467	return mbus->soc->show_cpu_target(mbus, seq, v);
468	}
469	DEFINE_SHOW_ATTRIBUTE(mvebu_sdram_debug);
470
471	static int mvebu_devs_debug_show(struct seq_file seq, void* *v)
472	{
473	struct mvebu_mbus_state *mbus = &mbus_state;
474	int win;
475
476	for (win = `0`; win < mbus->soc->num_wins; win++) {
477	u64 wbase, wremap;
478	u32 wsize;
479	u8 wtarget, wattr;
480	int enabled;
481
482	mvebu_mbus_read_window(mbus, win,
483	enabled: &enabled, base: &wbase, size: &wsize,
484	target: &wtarget, attr: &wattr, remap: &wremap);
485
486	if (!enabled) {
487	seq_printf(m: seq, fmt: "[%02d] disabled\n", win);
488	continue;
489	}
490
491	seq_printf(m: seq, fmt: "[%02d] %016llx - %016llx : %04x:%04x",
492	win, (unsigned long long)wbase,
493	(unsigned long long)(wbase + wsize), wtarget, wattr);
494
495	if (!is_power_of_2(n: wsize) \|\|
496	((wbase & (u64)(wsize - `1`)) != `0`))
497	seq_puts(m: seq, s: " (Invalid base/size!!)");
498
499	if (mvebu_mbus_window_is_remappable(mbus, win)) {
500	seq_printf(m: seq, fmt: " (remap %016llx)\n",
501	(unsigned long long)wremap);
502	} else
503	seq_printf(m: seq, fmt: "\n");
504	}
505
506	return `0`;
507	}
508	DEFINE_SHOW_ATTRIBUTE(mvebu_devs_debug);
509
510	/*
511	* SoC-specific functions and definitions
512	*/
513
514	static unsigned int generic_mbus_win_cfg_offset(int win)
515	{
516	return win << `4`;
517	}
518
519	static unsigned int armada_370_xp_mbus_win_cfg_offset(int win)
520	{
521	/ The register layout is a bit annoying and the below code*
522	* tries to cope with it.
523	* - At offset 0x0, there are the registers for the first 8
524	* windows, with 4 registers of 32 bits per window (ctrl,
525	* base, remap low, remap high)
526	* - Then at offset 0x80, there is a hole of 0x10 bytes for
527	* the internal registers base address and internal units
528	* sync barrier register.
529	* - Then at offset 0x90, there the registers for 12
530	* windows, with only 2 registers of 32 bits per window
531	* (ctrl, base).
532	*/
533	if (win < `8`)
534	return win << `4`;
535	else
536	return `0x90` + ((win - `8`) << `3`);
537	}
538
539	static unsigned int mv78xx0_mbus_win_cfg_offset(int win)
540	{
541	if (win < `8`)
542	return win << `4`;
543	else
544	return `0x900` + ((win - `8`) << `4`);
545	}
546
547	static unsigned int generic_mbus_win_remap_2_offset(int win)
548	{
549	if (win < `2`)
550	return generic_mbus_win_cfg_offset(win);
551	else
552	return MVEBU_MBUS_NO_REMAP;
553	}
554
555	static unsigned int generic_mbus_win_remap_4_offset(int win)
556	{
557	if (win < `4`)
558	return generic_mbus_win_cfg_offset(win);
559	else
560	return MVEBU_MBUS_NO_REMAP;
561	}
562
563	static unsigned int generic_mbus_win_remap_8_offset(int win)
564	{
565	if (win < `8`)
566	return generic_mbus_win_cfg_offset(win);
567	else
568	return MVEBU_MBUS_NO_REMAP;
569	}
570
571	static unsigned int armada_xp_mbus_win_remap_offset(int win)
572	{
573	if (win < `8`)
574	return generic_mbus_win_cfg_offset(win);
575	else if (win == `13`)
576	return `0xF0` - WIN_REMAP_LO_OFF;
577	else
578	return MVEBU_MBUS_NO_REMAP;
579	}
580
581	/*
582	* Use the memblock information to find the MBus bridge hole in the
583	* physical address space.
584	*/
585	static void __init
586	mvebu_mbus_find_bridge_hole(uint64_t start, uint64_t end)
587	{
588	phys_addr_t reg_start, reg_end;
589	uint64_t i, s = `0`;
590
591	for_each_mem_range(i, &reg_start, &reg_end) {
592	/*
593	* This part of the memory is above 4 GB, so we don't
594	* care for the MBus bridge hole.
595	*/
596	if ((u64)reg_start >= `0x100000000ULL`)
597	continue;
598
599	/*
600	* The MBus bridge hole is at the end of the RAM under
601	* the 4 GB limit.
602	*/
603	if (reg_end > s)
604	s = reg_end;
605	}
606
607	*start = s;
608	*end = `0x100000000ULL`;
609	}
610
611	/*
612	* This function fills in the mvebu_mbus_dram_info_nooverlap data
613	* structure, by looking at the mvebu_mbus_dram_info data, and
614	* removing the parts of it that overlap with I/O windows.
615	*/
616	static void __init
617	mvebu_mbus_setup_cpu_target_nooverlap(struct mvebu_mbus_state *mbus)
618	{
619	uint64_t mbus_bridge_base, mbus_bridge_end;
620	int cs_nooverlap = `0`;
621	int i;
622
623	mvebu_mbus_find_bridge_hole(start: &mbus_bridge_base, end: &mbus_bridge_end);
624
625	for (i = `0`; i < mvebu_mbus_dram_info.num_cs; i++) {
626	struct mbus_dram_window *w;
627	u64 base, size, end;
628
629	w = &mvebu_mbus_dram_info.cs[i];
630	base = w->base;
631	size = w->size;
632	end = base + size;
633
634	/*
635	* The CS is fully enclosed inside the MBus bridge
636	* area, so ignore it.
637	*/
638	if (base >= mbus_bridge_base && end <= mbus_bridge_end)
639	continue;
640
641	/*
642	* Beginning of CS overlaps with end of MBus, raise CS
643	* base address, and shrink its size.
644	*/
645	if (base >= mbus_bridge_base && end > mbus_bridge_end) {
646	size -= mbus_bridge_end - base;
647	base = mbus_bridge_end;
648	}
649
650	/*
651	* End of CS overlaps with beginning of MBus, shrink
652	* CS size.
653	*/
654	if (base < mbus_bridge_base && end > mbus_bridge_base)
655	size -= end - mbus_bridge_base;
656
657	w = &mvebu_mbus_dram_info_nooverlap.cs[cs_nooverlap++];
658	w->cs_index = i;
659	w->mbus_attr = `0xf` & ~(`1` << i);
660	if (mbus->hw_io_coherency)
661	w->mbus_attr \|= ATTR_HW_COHERENCY;
662	w->base = base;
663	w->size = size;
664	}
665
666	mvebu_mbus_dram_info_nooverlap.mbus_dram_target_id = TARGET_DDR;
667	mvebu_mbus_dram_info_nooverlap.num_cs = cs_nooverlap;
668	}
669
670	static void __init
671	mvebu_mbus_default_setup_cpu_target(struct mvebu_mbus_state *mbus)
672	{
673	int i;
674	int cs;
675
676	mvebu_mbus_dram_info.mbus_dram_target_id = TARGET_DDR;
677
678	for (i = `0`, cs = `0`; i < `4`; i++) {
679	u32 base = readl(addr: mbus->sdramwins_base + DDR_BASE_CS_OFF(i));
680	u32 size = readl(addr: mbus->sdramwins_base + DDR_SIZE_CS_OFF(i));
681
682	/*
683	* We only take care of entries for which the chip
684	* select is enabled, and that don't have high base
685	* address bits set (devices can only access the first
686	* 32 bits of the memory).
687	*/
688	if ((size & DDR_SIZE_ENABLED) &&
689	!(base & DDR_BASE_CS_HIGH_MASK)) {
690	struct mbus_dram_window *w;
691
692	w = &mvebu_mbus_dram_info.cs[cs++];
693	w->cs_index = i;
694	w->mbus_attr = `0xf` & ~(`1` << i);
695	if (mbus->hw_io_coherency)
696	w->mbus_attr \|= ATTR_HW_COHERENCY;
697	w->base = base & DDR_BASE_CS_LOW_MASK;
698	w->size = (u64)(size \| ~DDR_SIZE_MASK) + `1`;
699	}
700	}
701	mvebu_mbus_dram_info.num_cs = cs;
702	}
703
704	static int
705	mvebu_mbus_default_save_cpu_target(struct mvebu_mbus_state *mbus,
706	u32 __iomem *store_addr)
707	{
708	int i;
709
710	for (i = `0`; i < `4`; i++) {
711	u32 base = readl(addr: mbus->sdramwins_base + DDR_BASE_CS_OFF(i));
712	u32 size = readl(addr: mbus->sdramwins_base + DDR_SIZE_CS_OFF(i));
713
714	writel(val: mbus->sdramwins_phys_base + DDR_BASE_CS_OFF(i),
715	addr: store_addr++);
716	writel(val: base, addr: store_addr++);
717	writel(val: mbus->sdramwins_phys_base + DDR_SIZE_CS_OFF(i),
718	addr: store_addr++);
719	writel(val: size, addr: store_addr++);
720	}
721
722	/ We've written 16 words to the store address /
723	return `16`;
724	}
725
726	static void __init
727	mvebu_mbus_dove_setup_cpu_target(struct mvebu_mbus_state *mbus)
728	{
729	int i;
730	int cs;
731
732	mvebu_mbus_dram_info.mbus_dram_target_id = TARGET_DDR;
733
734	for (i = `0`, cs = `0`; i < `2`; i++) {
735	u32 map = readl(addr: mbus->sdramwins_base + DOVE_DDR_BASE_CS_OFF(i));
736
737	/*
738	* Chip select enabled?
739	*/
740	if (map & `1`) {
741	struct mbus_dram_window *w;
742
743	w = &mvebu_mbus_dram_info.cs[cs++];
744	w->cs_index = i;
745	w->mbus_attr = `0`; / CS address decoding done inside /
746	/ the DDR controller, no need to /
747	/ provide attributes /
748	w->base = map & `0xff800000`;
749	w->size = `0x100000` << (((map & `0x000f0000`) >> `16`) - `4`);
750	}
751	}
752
753	mvebu_mbus_dram_info.num_cs = cs;
754	}
755
756	static int
757	mvebu_mbus_dove_save_cpu_target(struct mvebu_mbus_state *mbus,
758	u32 __iomem *store_addr)
759	{
760	int i;
761
762	for (i = `0`; i < `2`; i++) {
763	u32 map = readl(addr: mbus->sdramwins_base + DOVE_DDR_BASE_CS_OFF(i));
764
765	writel(val: mbus->sdramwins_phys_base + DOVE_DDR_BASE_CS_OFF(i),
766	addr: store_addr++);
767	writel(val: map, addr: store_addr++);
768	}
769
770	/ We've written 4 words to the store address /
771	return `4`;
772	}
773
774	int mvebu_mbus_save_cpu_target(u32 __iomem *store_addr)
775	{
776	return mbus_state.soc->save_cpu_target(&mbus_state, store_addr);
777	}
778
779	static const struct mvebu_mbus_soc_data armada_370_mbus_data = {
780	.num_wins = `20`,
781	.has_mbus_bridge = true,
782	.win_cfg_offset = armada_370_xp_mbus_win_cfg_offset,
783	.win_remap_offset = generic_mbus_win_remap_8_offset,
784	.setup_cpu_target = mvebu_mbus_default_setup_cpu_target,
785	.show_cpu_target = mvebu_sdram_debug_show_orion,
786	.save_cpu_target = mvebu_mbus_default_save_cpu_target,
787	};
788
789	static const struct mvebu_mbus_soc_data armada_xp_mbus_data = {
790	.num_wins = `20`,
791	.has_mbus_bridge = true,
792	.win_cfg_offset = armada_370_xp_mbus_win_cfg_offset,
793	.win_remap_offset = armada_xp_mbus_win_remap_offset,
794	.setup_cpu_target = mvebu_mbus_default_setup_cpu_target,
795	.show_cpu_target = mvebu_sdram_debug_show_orion,
796	.save_cpu_target = mvebu_mbus_default_save_cpu_target,
797	};
798
799	static const struct mvebu_mbus_soc_data kirkwood_mbus_data = {
800	.num_wins = `8`,
801	.win_cfg_offset = generic_mbus_win_cfg_offset,
802	.save_cpu_target = mvebu_mbus_default_save_cpu_target,
803	.win_remap_offset = generic_mbus_win_remap_4_offset,
804	.setup_cpu_target = mvebu_mbus_default_setup_cpu_target,
805	.show_cpu_target = mvebu_sdram_debug_show_orion,
806	};
807
808	static const struct mvebu_mbus_soc_data dove_mbus_data = {
809	.num_wins = `8`,
810	.win_cfg_offset = generic_mbus_win_cfg_offset,
811	.save_cpu_target = mvebu_mbus_dove_save_cpu_target,
812	.win_remap_offset = generic_mbus_win_remap_4_offset,
813	.setup_cpu_target = mvebu_mbus_dove_setup_cpu_target,
814	.show_cpu_target = mvebu_sdram_debug_show_dove,
815	};
816
817	/*
818	* Some variants of Orion5x have 4 remappable windows, some other have
819	* only two of them.
820	*/
821	static const struct mvebu_mbus_soc_data orion5x_4win_mbus_data = {
822	.num_wins = `8`,
823	.win_cfg_offset = generic_mbus_win_cfg_offset,
824	.save_cpu_target = mvebu_mbus_default_save_cpu_target,
825	.win_remap_offset = generic_mbus_win_remap_4_offset,
826	.setup_cpu_target = mvebu_mbus_default_setup_cpu_target,
827	.show_cpu_target = mvebu_sdram_debug_show_orion,
828	};
829
830	static const struct mvebu_mbus_soc_data orion5x_2win_mbus_data = {
831	.num_wins = `8`,
832	.win_cfg_offset = generic_mbus_win_cfg_offset,
833	.save_cpu_target = mvebu_mbus_default_save_cpu_target,
834	.win_remap_offset = generic_mbus_win_remap_2_offset,
835	.setup_cpu_target = mvebu_mbus_default_setup_cpu_target,
836	.show_cpu_target = mvebu_sdram_debug_show_orion,
837	};
838
839	static const struct mvebu_mbus_soc_data mv78xx0_mbus_data = {
840	.num_wins = `14`,
841	.win_cfg_offset = mv78xx0_mbus_win_cfg_offset,
842	.save_cpu_target = mvebu_mbus_default_save_cpu_target,
843	.win_remap_offset = generic_mbus_win_remap_8_offset,
844	.setup_cpu_target = mvebu_mbus_default_setup_cpu_target,
845	.show_cpu_target = mvebu_sdram_debug_show_orion,
846	};
847
848	static const struct of_device_id of_mvebu_mbus_ids[] = {
849	{ .compatible = "marvell,armada370-mbus",
850	.data = &armada_370_mbus_data, },
851	{ .compatible = "marvell,armada375-mbus",
852	.data = &armada_xp_mbus_data, },
853	{ .compatible = "marvell,armada380-mbus",
854	.data = &armada_xp_mbus_data, },
855	{ .compatible = "marvell,armadaxp-mbus",
856	.data = &armada_xp_mbus_data, },
857	{ .compatible = "marvell,kirkwood-mbus",
858	.data = &kirkwood_mbus_data, },
859	{ .compatible = "marvell,dove-mbus",
860	.data = &dove_mbus_data, },
861	{ .compatible = "marvell,orion5x-88f5281-mbus",
862	.data = &orion5x_4win_mbus_data, },
863	{ .compatible = "marvell,orion5x-88f5182-mbus",
864	.data = &orion5x_2win_mbus_data, },
865	{ .compatible = "marvell,orion5x-88f5181-mbus",
866	.data = &orion5x_2win_mbus_data, },
867	{ .compatible = "marvell,orion5x-88f6183-mbus",
868	.data = &orion5x_4win_mbus_data, },
869	{ .compatible = "marvell,mv78xx0-mbus",
870	.data = &mv78xx0_mbus_data, },
871	{ },
872	};
873
874	/*
875	* Public API of the driver
876	*/
877	int mvebu_mbus_add_window_remap_by_id(unsigned int target,
878	unsigned int attribute,
879	phys_addr_t base, size_t size,
880	phys_addr_t remap)
881	{
882	struct mvebu_mbus_state *s = &mbus_state;
883
884	if (!mvebu_mbus_window_conflicts(mbus: s, base, size, target, attr: attribute)) {
885	pr_err("cannot add window '%x:%x', conflicts with another window\n",
886	target, attribute);
887	return -EINVAL;
888	}
889
890	return mvebu_mbus_alloc_window(mbus: s, base, size, remap, target, attr: attribute);
891	}
892	EXPORT_SYMBOL_GPL(mvebu_mbus_add_window_remap_by_id);
893
894	int mvebu_mbus_add_window_by_id(unsigned int target, unsigned int attribute,
895	phys_addr_t base, size_t size)
896	{
897	return mvebu_mbus_add_window_remap_by_id(target, attribute, base,
898	size, MVEBU_MBUS_NO_REMAP);
899	}
900	EXPORT_SYMBOL_GPL(mvebu_mbus_add_window_by_id);
901
902	int mvebu_mbus_del_window(phys_addr_t base, size_t size)
903	{
904	int win;
905
906	win = mvebu_mbus_find_window(mbus: &mbus_state, base, size);
907	if (win < `0`)
908	return win;
909
910	mvebu_mbus_disable_window(mbus: &mbus_state, win);
911	return `0`;
912	}
913	EXPORT_SYMBOL_GPL(mvebu_mbus_del_window);
914
915	void mvebu_mbus_get_pcie_mem_aperture(struct resource *res)
916	{
917	if (!res)
918	return;
919	*res = mbus_state.pcie_mem_aperture;
920	}
921	EXPORT_SYMBOL_GPL(mvebu_mbus_get_pcie_mem_aperture);
922
923	void mvebu_mbus_get_pcie_io_aperture(struct resource *res)
924	{
925	if (!res)
926	return;
927	*res = mbus_state.pcie_io_aperture;
928	}
929	EXPORT_SYMBOL_GPL(mvebu_mbus_get_pcie_io_aperture);
930
931	int mvebu_mbus_get_dram_win_info(phys_addr_t phyaddr, u8 target, u8 attr)
932	{
933	const struct mbus_dram_target_info *dram;
934	int i;
935
936	/ Get dram info /
937	dram = mv_mbus_dram_info();
938	if (!dram) {
939	pr_err("missing DRAM information\n");
940	return -ENODEV;
941	}
942
943	/ Try to find matching DRAM window for phyaddr /
944	for (i = `0`; i < dram->num_cs; i++) {
945	const struct mbus_dram_window *cs = dram->cs + i;
946
947	if (cs->base <= phyaddr &&
948	phyaddr <= (cs->base + cs->size - `1`)) {
949	*target = dram->mbus_dram_target_id;
950	*attr = cs->mbus_attr;
951	return `0`;
952	}
953	}
954
955	pr_err("invalid dram address %pa\n", &phyaddr);
956	return -EINVAL;
957	}
958	EXPORT_SYMBOL_GPL(mvebu_mbus_get_dram_win_info);
959
960	int mvebu_mbus_get_io_win_info(phys_addr_t phyaddr, u32 size, u8 target,
961	u8 *attr)
962	{
963	int win;
964
965	for (win = `0`; win < mbus_state.soc->num_wins; win++) {
966	u64 wbase;
967	int enabled;
968
969	mvebu_mbus_read_window(mbus: &mbus_state, win, enabled: &enabled, base: &wbase,
970	size, target, attr, NULL);
971
972	if (!enabled)
973	continue;
974
975	if (wbase <= phyaddr && phyaddr <= wbase + *size)
976	return win;
977	}
978
979	return -EINVAL;
980	}
981	EXPORT_SYMBOL_GPL(mvebu_mbus_get_io_win_info);
982
983	static __init int mvebu_mbus_debugfs_init(void)
984	{
985	struct mvebu_mbus_state *s = &mbus_state;
986
987	/*
988	* If no base has been initialized, doesn't make sense to
989	* register the debugfs entries. We may be on a multiplatform
990	* kernel that isn't running a Marvell EBU SoC.
991	*/
992	if (!s->mbuswins_base)
993	return `0`;
994
995	s->debugfs_root = debugfs_create_dir(name: "mvebu-mbus", NULL);
996	if (s->debugfs_root) {
997	s->debugfs_sdram = debugfs_create_file(name: "sdram", S_IRUGO,
998	parent: s->debugfs_root, NULL,
999	fops: &mvebu_sdram_debug_fops);
1000	s->debugfs_devs = debugfs_create_file(name: "devices", S_IRUGO,
1001	parent: s->debugfs_root, NULL,
1002	fops: &mvebu_devs_debug_fops);
1003	}
1004
1005	return `0`;
1006	}
1007	fs_initcall(mvebu_mbus_debugfs_init);
1008
1009	static int mvebu_mbus_suspend(void)
1010	{
1011	struct mvebu_mbus_state *s = &mbus_state;
1012	int win;
1013
1014	if (!s->mbusbridge_base)
1015	return -ENODEV;
1016
1017	for (win = `0`; win < s->soc->num_wins; win++) {
1018	void __iomem *addr = s->mbuswins_base +
1019	s->soc->win_cfg_offset(win);
1020	void __iomem *addr_rmp;
1021
1022	s->wins[win].base = readl(addr: addr + WIN_BASE_OFF);
1023	s->wins[win].ctrl = readl(addr: addr + WIN_CTRL_OFF);
1024
1025	if (!mvebu_mbus_window_is_remappable(mbus: s, win))
1026	continue;
1027
1028	addr_rmp = s->mbuswins_base +
1029	s->soc->win_remap_offset(win);
1030
1031	s->wins[win].remap_lo = readl(addr: addr_rmp + WIN_REMAP_LO_OFF);
1032	s->wins[win].remap_hi = readl(addr: addr_rmp + WIN_REMAP_HI_OFF);
1033	}
1034
1035	s->mbus_bridge_ctrl = readl(addr: s->mbusbridge_base +
1036	MBUS_BRIDGE_CTRL_OFF);
1037	s->mbus_bridge_base = readl(addr: s->mbusbridge_base +
1038	MBUS_BRIDGE_BASE_OFF);
1039
1040	return `0`;
1041	}
1042
1043	static void mvebu_mbus_resume(void)
1044	{
1045	struct mvebu_mbus_state *s = &mbus_state;
1046	int win;
1047
1048	writel(val: s->mbus_bridge_ctrl,
1049	addr: s->mbusbridge_base + MBUS_BRIDGE_CTRL_OFF);
1050	writel(val: s->mbus_bridge_base,
1051	addr: s->mbusbridge_base + MBUS_BRIDGE_BASE_OFF);
1052
1053	for (win = `0`; win < s->soc->num_wins; win++) {
1054	void __iomem *addr = s->mbuswins_base +
1055	s->soc->win_cfg_offset(win);
1056	void __iomem *addr_rmp;
1057
1058	writel(val: s->wins[win].base, addr: addr + WIN_BASE_OFF);
1059	writel(val: s->wins[win].ctrl, addr: addr + WIN_CTRL_OFF);
1060
1061	if (!mvebu_mbus_window_is_remappable(mbus: s, win))
1062	continue;
1063
1064	addr_rmp = s->mbuswins_base +
1065	s->soc->win_remap_offset(win);
1066
1067	writel(val: s->wins[win].remap_lo, addr: addr_rmp + WIN_REMAP_LO_OFF);
1068	writel(val: s->wins[win].remap_hi, addr: addr_rmp + WIN_REMAP_HI_OFF);
1069	}
1070	}
1071
1072	static struct syscore_ops mvebu_mbus_syscore_ops = {
1073	.suspend = mvebu_mbus_suspend,
1074	.resume = mvebu_mbus_resume,
1075	};
1076
1077	static int __init mvebu_mbus_common_init(struct mvebu_mbus_state *mbus,
1078	phys_addr_t mbuswins_phys_base,
1079	size_t mbuswins_size,
1080	phys_addr_t sdramwins_phys_base,
1081	size_t sdramwins_size,
1082	phys_addr_t mbusbridge_phys_base,
1083	size_t mbusbridge_size,
1084	bool is_coherent)
1085	{
1086	int win;
1087
1088	mbus->mbuswins_base = ioremap(offset: mbuswins_phys_base, size: mbuswins_size);
1089	if (!mbus->mbuswins_base)
1090	return -ENOMEM;
1091
1092	mbus->sdramwins_base = ioremap(offset: sdramwins_phys_base, size: sdramwins_size);
1093	if (!mbus->sdramwins_base) {
1094	iounmap(addr: mbus->mbuswins_base);
1095	return -ENOMEM;
1096	}
1097
1098	mbus->sdramwins_phys_base = sdramwins_phys_base;
1099
1100	if (mbusbridge_phys_base) {
1101	mbus->mbusbridge_base = ioremap(offset: mbusbridge_phys_base,
1102	size: mbusbridge_size);
1103	if (!mbus->mbusbridge_base) {
1104	iounmap(addr: mbus->sdramwins_base);
1105	iounmap(addr: mbus->mbuswins_base);
1106	return -ENOMEM;
1107	}
1108	} else
1109	mbus->mbusbridge_base = NULL;
1110
1111	for (win = `0`; win < mbus->soc->num_wins; win++)
1112	mvebu_mbus_disable_window(mbus, win);
1113
1114	mbus->soc->setup_cpu_target(mbus);
1115	mvebu_mbus_setup_cpu_target_nooverlap(mbus);
1116
1117	if (is_coherent)
1118	writel(UNIT_SYNC_BARRIER_ALL,
1119	addr: mbus->mbuswins_base + UNIT_SYNC_BARRIER_OFF);
1120
1121	register_syscore_ops(ops: &mvebu_mbus_syscore_ops);
1122
1123	return `0`;
1124	}
1125
1126	int __init mvebu_mbus_init(const char *soc, phys_addr_t mbuswins_phys_base,
1127	size_t mbuswins_size,
1128	phys_addr_t sdramwins_phys_base,
1129	size_t sdramwins_size)
1130	{
1131	const struct of_device_id *of_id;
1132
1133	for (of_id = of_mvebu_mbus_ids; of_id->compatible[`0`]; of_id++)
1134	if (!strcmp(of_id->compatible, soc))
1135	break;
1136
1137	if (!of_id->compatible[`0`]) {
1138	pr_err("could not find a matching SoC family\n");
1139	return -ENODEV;
1140	}
1141
1142	mbus_state.soc = of_id->data;
1143
1144	return mvebu_mbus_common_init(mbus: &mbus_state,
1145	mbuswins_phys_base,
1146	mbuswins_size,
1147	sdramwins_phys_base,
1148	sdramwins_size, mbusbridge_phys_base: `0`, mbusbridge_size: `0`, is_coherent: false);
1149	}
1150
1151	#ifdef CONFIG_OF
1152	/*
1153	* The window IDs in the ranges DT property have the following format:
1154	* - bits 28 to 31: MBus custom field
1155	* - bits 24 to 27: window target ID
1156	* - bits 16 to 23: window attribute ID
1157	* - bits 0 to 15: unused
1158	*/
1159	#define CUSTOM(id) (((id) & 0xF0000000) >> 24)
1160	#define TARGET(id) (((id) & 0x0F000000) >> 24)
1161	#define ATTR(id) (((id) & 0x00FF0000) >> 16)
1162
1163	static int __init mbus_dt_setup_win(struct mvebu_mbus_state *mbus,
1164	u32 base, u32 size,
1165	u8 target, u8 attr)
1166	{
1167	if (!mvebu_mbus_window_conflicts(mbus, base, size, target, attr)) {
1168	pr_err("cannot add window '%04x:%04x', conflicts with another window\n",
1169	target, attr);
1170	return -EBUSY;
1171	}
1172
1173	if (mvebu_mbus_alloc_window(mbus, base, size, MVEBU_MBUS_NO_REMAP,
1174	target, attr)) {
1175	pr_err("cannot add window '%04x:%04x', too many windows\n",
1176	target, attr);
1177	return -ENOMEM;
1178	}
1179	return `0`;
1180	}
1181
1182	static int __init mbus_dt_setup(struct mvebu_mbus_state *mbus,
1183	struct device_node *np)
1184	{
1185	int ret;
1186	struct of_range_parser parser;
1187	struct of_range range;
1188
1189	ret = of_range_parser_init(parser: &parser, node: np);
1190	if (ret < `0`)
1191	return `0`;
1192
1193	for_each_of_range(&parser, &range) {
1194	u32 windowid = upper_32_bits(range.bus_addr);
1195	u8 target, attr;
1196
1197	/*
1198	* An entry with a non-zero custom field do not
1199	* correspond to a static window, so skip it.
1200	*/
1201	if (CUSTOM(windowid))
1202	continue;
1203
1204	target = TARGET(windowid);
1205	attr = ATTR(windowid);
1206
1207	ret = mbus_dt_setup_win(mbus, base: range.cpu_addr, size: range.size, target, attr);
1208	if (ret < `0`)
1209	return ret;
1210	}
1211	return `0`;
1212	}
1213
1214	static void __init mvebu_mbus_get_pcie_resources(struct device_node *np,
1215	struct resource *mem,
1216	struct resource *io)
1217	{
1218	u32 reg[`2`];
1219	int ret;
1220
1221	/*
1222	* These are optional, so we make sure that resource_size(x) will
1223	* return 0.
1224	*/
1225	memset(mem, `0`, sizeof(struct resource));
1226	mem->end = -`1`;
1227	memset(io, `0`, sizeof(struct resource));
1228	io->end = -`1`;
1229
1230	ret = of_property_read_u32_array(np, propname: "pcie-mem-aperture", out_values: reg, ARRAY_SIZE(reg));
1231	if (!ret) {
1232	mem->start = reg[`0`];
1233	mem->end = mem->start + reg[`1`] - `1`;
1234	mem->flags = IORESOURCE_MEM;
1235	}
1236
1237	ret = of_property_read_u32_array(np, propname: "pcie-io-aperture", out_values: reg, ARRAY_SIZE(reg));
1238	if (!ret) {
1239	io->start = reg[`0`];
1240	io->end = io->start + reg[`1`] - `1`;
1241	io->flags = IORESOURCE_IO;
1242	}
1243	}
1244
1245	int __init mvebu_mbus_dt_init(bool is_coherent)
1246	{
1247	struct resource mbuswins_res, sdramwins_res, mbusbridge_res;
1248	struct device_node np, controller;
1249	const struct of_device_id *of_id;
1250	const __be32 *prop;
1251	int ret;
1252
1253	np = of_find_matching_node_and_match(NULL, matches: of_mvebu_mbus_ids, match: &of_id);
1254	if (!np) {
1255	pr_err("could not find a matching SoC family\n");
1256	return -ENODEV;
1257	}
1258
1259	mbus_state.soc = of_id->data;
1260
1261	prop = of_get_property(node: np, name: "controller", NULL);
1262	if (!prop) {
1263	pr_err("required 'controller' property missing\n");
1264	return -EINVAL;
1265	}
1266
1267	controller = of_find_node_by_phandle(be32_to_cpup(p: prop));
1268	if (!controller) {
1269	pr_err("could not find an 'mbus-controller' node\n");
1270	return -ENODEV;
1271	}
1272
1273	if (of_address_to_resource(dev: controller, index: `0`, r: &mbuswins_res)) {
1274	pr_err("cannot get MBUS register address\n");
1275	return -EINVAL;
1276	}
1277
1278	if (of_address_to_resource(dev: controller, index: `1`, r: &sdramwins_res)) {
1279	pr_err("cannot get SDRAM register address\n");
1280	return -EINVAL;
1281	}
1282
1283	/*
1284	* Set the resource to 0 so that it can be left unmapped by
1285	* mvebu_mbus_common_init() if the DT doesn't carry the
1286	* necessary information. This is needed to preserve backward
1287	* compatibility.
1288	*/
1289	memset(&mbusbridge_res, `0`, sizeof(mbusbridge_res));
1290
1291	if (mbus_state.soc->has_mbus_bridge) {
1292	if (of_address_to_resource(dev: controller, index: `2`, r: &mbusbridge_res))
1293	pr_warn(FW_WARN "deprecated mbus-mvebu Device Tree, suspend/resume will not work\n");
1294	}
1295
1296	mbus_state.hw_io_coherency = is_coherent;
1297
1298	/ Get optional pcie-{mem,io}-aperture properties /
1299	mvebu_mbus_get_pcie_resources(np, mem: &mbus_state.pcie_mem_aperture,
1300	io: &mbus_state.pcie_io_aperture);
1301
1302	ret = mvebu_mbus_common_init(mbus: &mbus_state,
1303	mbuswins_phys_base: mbuswins_res.start,
1304	mbuswins_size: resource_size(res: &mbuswins_res),
1305	sdramwins_phys_base: sdramwins_res.start,
1306	sdramwins_size: resource_size(res: &sdramwins_res),
1307	mbusbridge_phys_base: mbusbridge_res.start,
1308	mbusbridge_size: resource_size(res: &mbusbridge_res),
1309	is_coherent);
1310	if (ret)
1311	return ret;
1312
1313	/ Setup statically declared windows in the DT /
1314	return mbus_dt_setup(mbus: &mbus_state, np);
1315	}
1316	#endif
1317

source code of linux/drivers/bus/mvebu-mbus.c