fsl_pamu.c source code [linux/drivers/iommu/fsl_pamu.c]

1	// SPDX-License-Identifier: GPL-2.0-only
2	/*
3	*
4	* Copyright (C) 2013 Freescale Semiconductor, Inc.
5	*/
6
7	#define pr_fmt(fmt) "fsl-pamu: %s: " fmt, __func__
8
9	#include "fsl_pamu.h"
10
11	#include <linux/fsl/guts.h>
12	#include <linux/interrupt.h>
13	#include <linux/genalloc.h>
14	#include <linux/of_address.h>
15	#include <linux/of_irq.h>
16	#include <linux/platform_device.h>
17
18	#include <asm/mpc85xx.h>
19
20	/ define indexes for each operation mapping scenario /
21	#define OMI_QMAN 0x00
22	#define OMI_FMAN 0x01
23	#define OMI_QMAN_PRIV 0x02
24	#define OMI_CAAM 0x03
25
26	#define make64(high, low) (((u64)(high) << 32) \| (low))
27
28	struct pamu_isr_data {
29	void __iomem pamu_reg_base; /* Base address of PAMU regs /
30	unsigned int count; / The number of PAMUs /
31	};
32
33	static struct paace *ppaact;
34	static struct paace *spaact;
35
36	static bool probed; / Has PAMU been probed? /
37
38	/*
39	* Table for matching compatible strings, for device tree
40	* guts node, for QorIQ SOCs.
41	* "fsl,qoriq-device-config-2.0" corresponds to T4 & B4
42	* SOCs. For the older SOCs "fsl,qoriq-device-config-1.0"
43	* string would be used.
44	*/
45	static const struct of_device_id guts_device_ids[] = {
46	{ .compatible = "fsl,qoriq-device-config-1.0", },
47	{ .compatible = "fsl,qoriq-device-config-2.0", },
48	{}
49	};
50
51	/*
52	* Table for matching compatible strings, for device tree
53	* L3 cache controller node.
54	* "fsl,t4240-l3-cache-controller" corresponds to T4,
55	* "fsl,b4860-l3-cache-controller" corresponds to B4 &
56	* "fsl,p4080-l3-cache-controller" corresponds to other,
57	* SOCs.
58	*/
59	static const struct of_device_id l3_device_ids[] = {
60	{ .compatible = "fsl,t4240-l3-cache-controller", },
61	{ .compatible = "fsl,b4860-l3-cache-controller", },
62	{ .compatible = "fsl,p4080-l3-cache-controller", },
63	{}
64	};
65
66	/ maximum subwindows permitted per liodn /
67	static u32 max_subwindow_count;
68
69	/**
70	* pamu_get_ppaace() - Return the primary PACCE
71	* @liodn: liodn PAACT index for desired PAACE
72	*
73	* Returns the ppace pointer upon success else return
74	* null.
75	*/
76	static struct paace pamu_get_ppaace(int* liodn)
77	{
78	if (!ppaact \|\| liodn >= PAACE_NUMBER_ENTRIES) {
79	pr_debug("PPAACT doesn't exist\n");
80	return NULL;
81	}
82
83	return &ppaact[liodn];
84	}
85
86	/**
87	* pamu_enable_liodn() - Set valid bit of PACCE
88	* @liodn: liodn PAACT index for desired PAACE
89	*
90	* Returns 0 upon success else error code < 0 returned
91	*/
92	int pamu_enable_liodn(int liodn)
93	{
94	struct paace *ppaace;
95
96	ppaace = pamu_get_ppaace(liodn);
97	if (!ppaace) {
98	pr_debug("Invalid primary paace entry\n");
99	return -ENOENT;
100	}
101
102	if (!get_bf(ppaace->addr_bitfields, PPAACE_AF_WSE)) {
103	pr_debug("liodn %d not configured\n", liodn);
104	return -EINVAL;
105	}
106
107	/ Ensure that all other stores to the ppaace complete first /
108	mb();
109
110	set_bf(ppaace->addr_bitfields, PAACE_AF_V, PAACE_V_VALID);
111	mb();
112
113	return `0`;
114	}
115
116	/**
117	* pamu_disable_liodn() - Clears valid bit of PACCE
118	* @liodn: liodn PAACT index for desired PAACE
119	*
120	* Returns 0 upon success else error code < 0 returned
121	*/
122	int pamu_disable_liodn(int liodn)
123	{
124	struct paace *ppaace;
125
126	ppaace = pamu_get_ppaace(liodn);
127	if (!ppaace) {
128	pr_debug("Invalid primary paace entry\n");
129	return -ENOENT;
130	}
131
132	set_bf(ppaace->addr_bitfields, PAACE_AF_V, PAACE_V_INVALID);
133	mb();
134
135	return `0`;
136	}
137
138	/ Derive the window size encoding for a particular PAACE entry /
139	static unsigned int map_addrspace_size_to_wse(phys_addr_t addrspace_size)
140	{
141	/ Bug if not a power of 2 /
142	BUG_ON(addrspace_size & (addrspace_size - `1`));
143
144	/ window size is 2^(WSE+1) bytes /
145	return fls64(x: addrspace_size) - `2`;
146	}
147
148	/*
149	* Set the PAACE type as primary and set the coherency required domain
150	* attribute
151	*/
152	static void pamu_init_ppaace(struct paace *ppaace)
153	{
154	set_bf(ppaace->addr_bitfields, PAACE_AF_PT, PAACE_PT_PRIMARY);
155
156	set_bf(ppaace->domain_attr.to_host.coherency_required, PAACE_DA_HOST_CR,
157	PAACE_M_COHERENCE_REQ);
158	}
159
160	/*
161	* Function used for updating stash destination for the coressponding
162	* LIODN.
163	*/
164	int pamu_update_paace_stash(int liodn, u32 value)
165	{
166	struct paace *paace;
167
168	paace = pamu_get_ppaace(liodn);
169	if (!paace) {
170	pr_debug("Invalid liodn entry\n");
171	return -ENOENT;
172	}
173	set_bf(paace->impl_attr, PAACE_IA_CID, value);
174
175	mb();
176
177	return `0`;
178	}
179
180	/**
181	* pamu_config_ppaace() - Sets up PPAACE entry for specified liodn
182	*
183	* @liodn: Logical IO device number
184	* @omi: Operation mapping index -- if ~omi == 0 then omi not defined
185	* @stashid: cache stash id for associated cpu -- if ~stashid == 0 then
186	* stashid not defined
187	* @prot: window permissions
188	*
189	* Returns 0 upon success else error code < 0 returned
190	*/
191	int pamu_config_ppaace(int liodn, u32 omi, u32 stashid, int prot)
192	{
193	struct paace *ppaace;
194
195	ppaace = pamu_get_ppaace(liodn);
196	if (!ppaace)
197	return -ENOENT;
198
199	/ window size is 2^(WSE+1) bytes /
200	set_bf(ppaace->addr_bitfields, PPAACE_AF_WSE,
201	map_addrspace_size_to_wse(`1ULL` << `36`));
202
203	pamu_init_ppaace(ppaace);
204
205	ppaace->wbah = `0`;
206	set_bf(ppaace->addr_bitfields, PPAACE_AF_WBAL, `0`);
207
208	/ set up operation mapping if it's configured /
209	if (omi < OME_NUMBER_ENTRIES) {
210	set_bf(ppaace->impl_attr, PAACE_IA_OTM, PAACE_OTM_INDEXED);
211	ppaace->op_encode.index_ot.omi = omi;
212	} else if (~omi != `0`) {
213	pr_debug("bad operation mapping index: %d\n", omi);
214	return -ENODEV;
215	}
216
217	/ configure stash id /
218	if (~stashid != `0`)
219	set_bf(ppaace->impl_attr, PAACE_IA_CID, stashid);
220
221	set_bf(ppaace->impl_attr, PAACE_IA_ATM, PAACE_ATM_WINDOW_XLATE);
222	ppaace->twbah = `0`;
223	set_bf(ppaace->win_bitfields, PAACE_WIN_TWBAL, `0`);
224	set_bf(ppaace->addr_bitfields, PAACE_AF_AP, prot);
225	set_bf(ppaace->impl_attr, PAACE_IA_WCE, `0`);
226	set_bf(ppaace->addr_bitfields, PPAACE_AF_MW, `0`);
227	mb();
228
229	return `0`;
230	}
231
232	/**
233	* get_ome_index() - Returns the index in the operation mapping table
234	* for device.
235	* @omi_index: pointer for storing the index value
236	* @dev: target device
237	*
238	*/
239	void get_ome_index(u32 omi_index, struct* device *dev)
240	{
241	if (of_device_is_compatible(device: dev->of_node, "fsl,qman-portal"))
242	*omi_index = OMI_QMAN;
243	if (of_device_is_compatible(device: dev->of_node, "fsl,qman"))
244	*omi_index = OMI_QMAN_PRIV;
245	}
246
247	/**
248	* get_stash_id - Returns stash destination id corresponding to a
249	* cache type and vcpu.
250	* @stash_dest_hint: L1, L2 or L3
251	* @vcpu: vpcu target for a particular cache type.
252	*
253	* Returs stash on success or ~(u32)0 on failure.
254	*
255	*/
256	u32 get_stash_id(u32 stash_dest_hint, u32 vcpu)
257	{
258	const u32 *prop;
259	struct device_node *node;
260	u32 cache_level;
261	int len, found = `0`;
262	int i;
263
264	/ Fastpath, exit early if L3/CPC cache is target for stashing /
265	if (stash_dest_hint == PAMU_ATTR_CACHE_L3) {
266	node = of_find_matching_node(NULL, matches: l3_device_ids);
267	if (node) {
268	prop = of_get_property(node, name: "cache-stash-id", NULL);
269	if (!prop) {
270	pr_debug("missing cache-stash-id at %pOF\n",
271	node);
272	of_node_put(node);
273	return ~(u32)`0`;
274	}
275	of_node_put(node);
276	return be32_to_cpup(p: prop);
277	}
278	return ~(u32)`0`;
279	}
280
281	for_each_of_cpu_node(node) {
282	prop = of_get_property(node, name: "reg", lenp: &len);
283	for (i = `0`; i < len / sizeof(u32); i++) {
284	if (be32_to_cpup(p: &prop[i]) == vcpu) {
285	found = `1`;
286	goto found_cpu_node;
287	}
288	}
289	}
290	found_cpu_node:
291
292	/ find the hwnode that represents the cache /
293	for (cache_level = PAMU_ATTR_CACHE_L1; (cache_level < PAMU_ATTR_CACHE_L3) && found; cache_level++) {
294	if (stash_dest_hint == cache_level) {
295	prop = of_get_property(node, "cache-stash-id", NULL);
296	if (!prop) {
297	pr_debug("missing cache-stash-id at %pOF\n",
298	node);
299	of_node_put(node);
300	return ~(u32)`0`;
301	}
302	of_node_put(node);
303	return be32_to_cpup(prop);
304	}
305
306	prop = of_get_property(node, "next-level-cache", NULL);
307	if (!prop) {
308	pr_debug("can't find next-level-cache at %pOF\n", node);
309	of_node_put(node);
310	return ~(u32)`0`; / can't traverse any further /
311	}
312	of_node_put(node);
313
314	/ advance to next node in cache hierarchy /
315	node = of_find_node_by_phandle(*prop);
316	if (!node) {
317	pr_debug("Invalid node for cache hierarchy\n");
318	return ~(u32)`0`;
319	}
320	}
321
322	pr_debug("stash dest not found for %d on vcpu %d\n",
323	stash_dest_hint, vcpu);
324	return ~(u32)`0`;
325	}
326
327	/ Identify if the PAACT table entry belongs to QMAN, BMAN or QMAN Portal /
328	#define QMAN_PAACE 1
329	#define QMAN_PORTAL_PAACE 2
330	#define BMAN_PAACE 3
331
332	/*
333	* Setup operation mapping and stash destinations for QMAN and QMAN portal.
334	* Memory accesses to QMAN and BMAN private memory need not be coherent, so
335	* clear the PAACE entry coherency attribute for them.
336	*/
337	static void setup_qbman_paace(struct paace ppaace, int* paace_type)
338	{
339	switch (paace_type) {
340	case QMAN_PAACE:
341	set_bf(ppaace->impl_attr, PAACE_IA_OTM, PAACE_OTM_INDEXED);
342	ppaace->op_encode.index_ot.omi = OMI_QMAN_PRIV;
343	/ setup QMAN Private data stashing for the L3 cache /
344	set_bf(ppaace->impl_attr, PAACE_IA_CID, get_stash_id(PAMU_ATTR_CACHE_L3, `0`));
345	set_bf(ppaace->domain_attr.to_host.coherency_required, PAACE_DA_HOST_CR,
346	`0`);
347	break;
348	case QMAN_PORTAL_PAACE:
349	set_bf(ppaace->impl_attr, PAACE_IA_OTM, PAACE_OTM_INDEXED);
350	ppaace->op_encode.index_ot.omi = OMI_QMAN;
351	/ Set DQRR and Frame stashing for the L3 cache /
352	set_bf(ppaace->impl_attr, PAACE_IA_CID, get_stash_id(PAMU_ATTR_CACHE_L3, `0`));
353	break;
354	case BMAN_PAACE:
355	set_bf(ppaace->domain_attr.to_host.coherency_required, PAACE_DA_HOST_CR,
356	`0`);
357	break;
358	}
359	}
360
361	/*
362	* Setup the operation mapping table for various devices. This is a static
363	* table where each table index corresponds to a particular device. PAMU uses
364	* this table to translate device transaction to appropriate corenet
365	* transaction.
366	*/
367	static void setup_omt(struct ome *omt)
368	{
369	struct ome *ome;
370
371	/ Configure OMI_QMAN /
372	ome = &omt[OMI_QMAN];
373
374	ome->moe[IOE_READ_IDX] = EOE_VALID \| EOE_READ;
375	ome->moe[IOE_EREAD0_IDX] = EOE_VALID \| EOE_RSA;
376	ome->moe[IOE_WRITE_IDX] = EOE_VALID \| EOE_WRITE;
377	ome->moe[IOE_EWRITE0_IDX] = EOE_VALID \| EOE_WWSAO;
378
379	ome->moe[IOE_DIRECT0_IDX] = EOE_VALID \| EOE_LDEC;
380	ome->moe[IOE_DIRECT1_IDX] = EOE_VALID \| EOE_LDECPE;
381
382	/ Configure OMI_FMAN /
383	ome = &omt[OMI_FMAN];
384	ome->moe[IOE_READ_IDX] = EOE_VALID \| EOE_READI;
385	ome->moe[IOE_WRITE_IDX] = EOE_VALID \| EOE_WRITE;
386
387	/ Configure OMI_QMAN private /
388	ome = &omt[OMI_QMAN_PRIV];
389	ome->moe[IOE_READ_IDX] = EOE_VALID \| EOE_READ;
390	ome->moe[IOE_WRITE_IDX] = EOE_VALID \| EOE_WRITE;
391	ome->moe[IOE_EREAD0_IDX] = EOE_VALID \| EOE_RSA;
392	ome->moe[IOE_EWRITE0_IDX] = EOE_VALID \| EOE_WWSA;
393
394	/ Configure OMI_CAAM /
395	ome = &omt[OMI_CAAM];
396	ome->moe[IOE_READ_IDX] = EOE_VALID \| EOE_READI;
397	ome->moe[IOE_WRITE_IDX] = EOE_VALID \| EOE_WRITE;
398	}
399
400	/*
401	* Get the maximum number of PAACT table entries
402	* and subwindows supported by PAMU
403	*/
404	static void get_pamu_cap_values(unsigned long pamu_reg_base)
405	{
406	u32 pc_val;
407
408	pc_val = in_be32((u32 *)(pamu_reg_base + PAMU_PC3));
409	/ Maximum number of subwindows per liodn /
410	max_subwindow_count = `1` << (`1` + PAMU_PC3_MWCE(pc_val));
411	}
412
413	/ Setup PAMU registers pointing to PAACT, SPAACT and OMT /
414	static int setup_one_pamu(unsigned long pamu_reg_base, unsigned long pamu_reg_size,
415	phys_addr_t ppaact_phys, phys_addr_t spaact_phys,
416	phys_addr_t omt_phys)
417	{
418	u32 *pc;
419	struct pamu_mmap_regs *pamu_regs;
420
421	pc = (u32 *) (pamu_reg_base + PAMU_PC);
422	pamu_regs = (struct pamu_mmap_regs *)
423	(pamu_reg_base + PAMU_MMAP_REGS_BASE);
424
425	/ set up pointers to corenet control blocks /
426
427	out_be32(&pamu_regs->ppbah, upper_32_bits(ppaact_phys));
428	out_be32(&pamu_regs->ppbal, lower_32_bits(ppaact_phys));
429	ppaact_phys = ppaact_phys + PAACT_SIZE;
430	out_be32(&pamu_regs->pplah, upper_32_bits(ppaact_phys));
431	out_be32(&pamu_regs->pplal, lower_32_bits(ppaact_phys));
432
433	out_be32(&pamu_regs->spbah, upper_32_bits(spaact_phys));
434	out_be32(&pamu_regs->spbal, lower_32_bits(spaact_phys));
435	spaact_phys = spaact_phys + SPAACT_SIZE;
436	out_be32(&pamu_regs->splah, upper_32_bits(spaact_phys));
437	out_be32(&pamu_regs->splal, lower_32_bits(spaact_phys));
438
439	out_be32(&pamu_regs->obah, upper_32_bits(omt_phys));
440	out_be32(&pamu_regs->obal, lower_32_bits(omt_phys));
441	omt_phys = omt_phys + OMT_SIZE;
442	out_be32(&pamu_regs->olah, upper_32_bits(omt_phys));
443	out_be32(&pamu_regs->olal, lower_32_bits(omt_phys));
444
445	/*
446	* set PAMU enable bit,
447	* allow ppaact & omt to be cached
448	* & enable PAMU access violation interrupts.
449	*/
450
451	out_be32((u32 *)(pamu_reg_base + PAMU_PICS),
452	PAMU_ACCESS_VIOLATION_ENABLE);
453	out_be32(pc, PAMU_PC_PE \| PAMU_PC_OCE \| PAMU_PC_SPCC \| PAMU_PC_PPCC);
454	return `0`;
455	}
456
457	/ Enable all device LIODNS /
458	static void setup_liodns(void)
459	{
460	int i, len;
461	struct paace *ppaace;
462	struct device_node *node = NULL;
463	const u32 *prop;
464
465	for_each_node_with_property(node, "fsl,liodn") {
466	prop = of_get_property(node, name: "fsl,liodn", lenp: &len);
467	for (i = `0`; i < len / sizeof(u32); i++) {
468	int liodn;
469
470	liodn = be32_to_cpup(p: &prop[i]);
471	if (liodn >= PAACE_NUMBER_ENTRIES) {
472	pr_debug("Invalid LIODN value %d\n", liodn);
473	continue;
474	}
475	ppaace = pamu_get_ppaace(liodn);
476	pamu_init_ppaace(ppaace);
477	/ window size is 2^(WSE+1) bytes /
478	set_bf(ppaace->addr_bitfields, PPAACE_AF_WSE, `35`);
479	ppaace->wbah = `0`;
480	set_bf(ppaace->addr_bitfields, PPAACE_AF_WBAL, `0`);
481	set_bf(ppaace->impl_attr, PAACE_IA_ATM,
482	PAACE_ATM_NO_XLATE);
483	set_bf(ppaace->addr_bitfields, PAACE_AF_AP,
484	PAACE_AP_PERMS_ALL);
485	if (of_device_is_compatible(device: node, "fsl,qman-portal"))
486	setup_qbman_paace(ppaace, QMAN_PORTAL_PAACE);
487	if (of_device_is_compatible(device: node, "fsl,qman"))
488	setup_qbman_paace(ppaace, QMAN_PAACE);
489	if (of_device_is_compatible(device: node, "fsl,bman"))
490	setup_qbman_paace(ppaace, BMAN_PAACE);
491	mb();
492	pamu_enable_liodn(liodn);
493	}
494	}
495	}
496
497	static irqreturn_t pamu_av_isr(int irq, void *arg)
498	{
499	struct pamu_isr_data *data = arg;
500	phys_addr_t phys;
501	unsigned int i, j, ret;
502
503	pr_emerg("access violation interrupt\n");
504
505	for (i = `0`; i < data->count; i++) {
506	void __iomem p = data->pamu_reg_base + i PAMU_OFFSET;
507	u32 pics = in_be32(p + PAMU_PICS);
508
509	if (pics & PAMU_ACCESS_VIOLATION_STAT) {
510	u32 avs1 = in_be32(p + PAMU_AVS1);
511	struct paace *paace;
512
513	pr_emerg("POES1=%08x\n", in_be32(p + PAMU_POES1));
514	pr_emerg("POES2=%08x\n", in_be32(p + PAMU_POES2));
515	pr_emerg("AVS1=%08x\n", avs1);
516	pr_emerg("AVS2=%08x\n", in_be32(p + PAMU_AVS2));
517	pr_emerg("AVA=%016llx\n",
518	make64(in_be32(p + PAMU_AVAH),
519	in_be32(p + PAMU_AVAL)));
520	pr_emerg("UDAD=%08x\n", in_be32(p + PAMU_UDAD));
521	pr_emerg("POEA=%016llx\n",
522	make64(in_be32(p + PAMU_POEAH),
523	in_be32(p + PAMU_POEAL)));
524
525	phys = make64(in_be32(p + PAMU_POEAH),
526	in_be32(p + PAMU_POEAL));
527
528	/ Assume that POEA points to a PAACE /
529	if (phys) {
530	u32 *paace = phys_to_virt(address: phys);
531
532	/ Only the first four words are relevant /
533	for (j = `0`; j < `4`; j++)
534	pr_emerg("PAACE[%u]=%08x\n",
535	j, in_be32(paace + j));
536	}
537
538	/ clear access violation condition /
539	out_be32(p + PAMU_AVS1, avs1 & PAMU_AV_MASK);
540	paace = pamu_get_ppaace(liodn: avs1 >> PAMU_AVS1_LIODN_SHIFT);
541	BUG_ON(!paace);
542	/ check if we got a violation for a disabled LIODN /
543	if (!get_bf(paace->addr_bitfields, PAACE_AF_V)) {
544	/*
545	* As per hardware erratum A-003638, access
546	* violation can be reported for a disabled
547	* LIODN. If we hit that condition, disable
548	* access violation reporting.
549	*/
550	pics &= ~PAMU_ACCESS_VIOLATION_ENABLE;
551	} else {
552	/ Disable the LIODN /
553	ret = pamu_disable_liodn(liodn: avs1 >> PAMU_AVS1_LIODN_SHIFT);
554	BUG_ON(ret);
555	pr_emerg("Disabling liodn %x\n",
556	avs1 >> PAMU_AVS1_LIODN_SHIFT);
557	}
558	out_be32((p + PAMU_PICS), pics);
559	}
560	}
561
562	return IRQ_HANDLED;
563	}
564
565	#define LAWAR_EN 0x80000000
566	#define LAWAR_TARGET_MASK 0x0FF00000
567	#define LAWAR_TARGET_SHIFT 20
568	#define LAWAR_SIZE_MASK 0x0000003F
569	#define LAWAR_CSDID_MASK 0x000FF000
570	#define LAWAR_CSDID_SHIFT 12
571
572	#define LAW_SIZE_4K 0xb
573
574	struct ccsr_law {
575	u32 lawbarh; / LAWn base address high /
576	u32 lawbarl; / LAWn base address low /
577	u32 lawar; / LAWn attributes /
578	u32 reserved;
579	};
580
581	/*
582	* Create a coherence subdomain for a given memory block.
583	*/
584	static int create_csd(phys_addr_t phys, size_t size, u32 csd_port_id)
585	{
586	struct device_node *np;
587	const __be32 *iprop;
588	void __iomem lac = NULL; /* Local Access Control registers /
589	struct ccsr_law __iomem *law;
590	void __iomem *ccm = NULL;
591	u32 __iomem *csdids;
592	unsigned int i, num_laws, num_csds;
593	u32 law_target = `0`;
594	u32 csd_id = `0`;
595	int ret = `0`;
596
597	np = of_find_compatible_node(NULL, NULL, compat: "fsl,corenet-law");
598	if (!np)
599	return -ENODEV;
600
601	iprop = of_get_property(node: np, name: "fsl,num-laws", NULL);
602	if (!iprop) {
603	ret = -ENODEV;
604	goto error;
605	}
606
607	num_laws = be32_to_cpup(p: iprop);
608	if (!num_laws) {
609	ret = -ENODEV;
610	goto error;
611	}
612
613	lac = of_iomap(node: np, index: `0`);
614	if (!lac) {
615	ret = -ENODEV;
616	goto error;
617	}
618
619	/ LAW registers are at offset 0xC00 /
620	law = lac + `0xC00`;
621
622	of_node_put(node: np);
623
624	np = of_find_compatible_node(NULL, NULL, compat: "fsl,corenet-cf");
625	if (!np) {
626	ret = -ENODEV;
627	goto error;
628	}
629
630	iprop = of_get_property(node: np, name: "fsl,ccf-num-csdids", NULL);
631	if (!iprop) {
632	ret = -ENODEV;
633	goto error;
634	}
635
636	num_csds = be32_to_cpup(p: iprop);
637	if (!num_csds) {
638	ret = -ENODEV;
639	goto error;
640	}
641
642	ccm = of_iomap(node: np, index: `0`);
643	if (!ccm) {
644	ret = -ENOMEM;
645	goto error;
646	}
647
648	/ The undocumented CSDID registers are at offset 0x600 /
649	csdids = ccm + `0x600`;
650
651	of_node_put(node: np);
652	np = NULL;
653
654	/ Find an unused coherence subdomain ID /
655	for (csd_id = `0`; csd_id < num_csds; csd_id++) {
656	if (!csdids[csd_id])
657	break;
658	}
659
660	/ Store the Port ID in the (undocumented) proper CIDMRxx register /
661	csdids[csd_id] = csd_port_id;
662
663	/ Find the DDR LAW that maps to our buffer. /
664	for (i = `0`; i < num_laws; i++) {
665	if (law[i].lawar & LAWAR_EN) {
666	phys_addr_t law_start, law_end;
667
668	law_start = make64(law[i].lawbarh, law[i].lawbarl);
669	law_end = law_start +
670	(`2ULL` << (law[i].lawar & LAWAR_SIZE_MASK));
671
672	if (law_start <= phys && phys < law_end) {
673	law_target = law[i].lawar & LAWAR_TARGET_MASK;
674	break;
675	}
676	}
677	}
678
679	if (i == `0` \|\| i == num_laws) {
680	/ This should never happen /
681	ret = -ENOENT;
682	goto error;
683	}
684
685	/ Find a free LAW entry /
686	while (law[--i].lawar & LAWAR_EN) {
687	if (i == `0`) {
688	/ No higher priority LAW slots available /
689	ret = -ENOENT;
690	goto error;
691	}
692	}
693
694	law[i].lawbarh = upper_32_bits(phys);
695	law[i].lawbarl = lower_32_bits(phys);
696	wmb();
697	law[i].lawar = LAWAR_EN \| law_target \| (csd_id << LAWAR_CSDID_SHIFT) \|
698	(LAW_SIZE_4K + get_order(size));
699	wmb();
700
701	error:
702	if (ccm)
703	iounmap(addr: ccm);
704
705	if (lac)
706	iounmap(addr: lac);
707
708	if (np)
709	of_node_put(node: np);
710
711	return ret;
712	}
713
714	/*
715	* Table of SVRs and the corresponding PORT_ID values. Port ID corresponds to a
716	* bit map of snoopers for a given range of memory mapped by a LAW.
717	*
718	* All future CoreNet-enabled SOCs will have this erratum(A-004510) fixed, so this
719	* table should never need to be updated. SVRs are guaranteed to be unique, so
720	* there is no worry that a future SOC will inadvertently have one of these
721	* values.
722	*/
723	static const struct {
724	u32 svr;
725	u32 port_id;
726	} port_id_map[] = {
727	{(SVR_P2040 << `8`) \| `0x10`, `0xFF000000`}, / P2040 1.0 /
728	{(SVR_P2040 << `8`) \| `0x11`, `0xFF000000`}, / P2040 1.1 /
729	{(SVR_P2041 << `8`) \| `0x10`, `0xFF000000`}, / P2041 1.0 /
730	{(SVR_P2041 << `8`) \| `0x11`, `0xFF000000`}, / P2041 1.1 /
731	{(SVR_P3041 << `8`) \| `0x10`, `0xFF000000`}, / P3041 1.0 /
732	{(SVR_P3041 << `8`) \| `0x11`, `0xFF000000`}, / P3041 1.1 /
733	{(SVR_P4040 << `8`) \| `0x20`, `0xFFF80000`}, / P4040 2.0 /
734	{(SVR_P4080 << `8`) \| `0x20`, `0xFFF80000`}, / P4080 2.0 /
735	{(SVR_P5010 << `8`) \| `0x10`, `0xFC000000`}, / P5010 1.0 /
736	{(SVR_P5010 << `8`) \| `0x20`, `0xFC000000`}, / P5010 2.0 /
737	{(SVR_P5020 << `8`) \| `0x10`, `0xFC000000`}, / P5020 1.0 /
738	{(SVR_P5021 << `8`) \| `0x10`, `0xFF800000`}, / P5021 1.0 /
739	{(SVR_P5040 << `8`) \| `0x10`, `0xFF800000`}, / P5040 1.0 /
740	};
741
742	#define SVR_SECURITY 0x80000 /* The Security (E) bit */
743
744	static int fsl_pamu_probe(struct platform_device *pdev)
745	{
746	struct device *dev = &pdev->dev;
747	void __iomem *pamu_regs = NULL;
748	struct ccsr_guts __iomem *guts_regs = NULL;
749	u32 pamubypenr, pamu_counter;
750	unsigned long pamu_reg_off;
751	unsigned long pamu_reg_base;
752	struct pamu_isr_data *data = NULL;
753	struct device_node *guts_node;
754	u64 size;
755	struct page *p;
756	int ret = `0`;
757	int irq;
758	phys_addr_t ppaact_phys;
759	phys_addr_t spaact_phys;
760	struct ome *omt;
761	phys_addr_t omt_phys;
762	size_t mem_size = `0`;
763	unsigned int order = `0`;
764	u32 csd_port_id = `0`;
765	unsigned i;
766	/*
767	* enumerate all PAMUs and allocate and setup PAMU tables
768	* for each of them,
769	* NOTE : All PAMUs share the same LIODN tables.
770	*/
771
772	if (WARN_ON(probed))
773	return -EBUSY;
774
775	pamu_regs = of_iomap(node: dev->of_node, index: `0`);
776	if (!pamu_regs) {
777	dev_err(dev, "ioremap of PAMU node failed\n");
778	return -ENOMEM;
779	}
780	of_get_address(dev: dev->of_node, index: `0`, size: &size, NULL);
781
782	irq = irq_of_parse_and_map(node: dev->of_node, index: `0`);
783	if (!irq) {
784	dev_warn(dev, "no interrupts listed in PAMU node\n");
785	goto error;
786	}
787
788	data = kzalloc(size: sizeof(*data), GFP_KERNEL);
789	if (!data) {
790	ret = -ENOMEM;
791	goto error;
792	}
793	data->pamu_reg_base = pamu_regs;
794	data->count = size / PAMU_OFFSET;
795
796	/ The ISR needs access to the regs, so we won't iounmap them /
797	ret = request_irq(irq, handler: pamu_av_isr, flags: `0`, name: "pamu", dev: data);
798	if (ret < `0`) {
799	dev_err(dev, "error %i installing ISR for irq %i\n", ret, irq);
800	goto error;
801	}
802
803	guts_node = of_find_matching_node(NULL, matches: guts_device_ids);
804	if (!guts_node) {
805	dev_err(dev, "could not find GUTS node %pOF\n", dev->of_node);
806	ret = -ENODEV;
807	goto error;
808	}
809
810	guts_regs = of_iomap(node: guts_node, index: `0`);
811	of_node_put(node: guts_node);
812	if (!guts_regs) {
813	dev_err(dev, "ioremap of GUTS node failed\n");
814	ret = -ENODEV;
815	goto error;
816	}
817
818	/ read in the PAMU capability registers /
819	get_pamu_cap_values(pamu_reg_base: (unsigned long)pamu_regs);
820	/*
821	* To simplify the allocation of a coherency domain, we allocate the
822	* PAACT and the OMT in the same memory buffer. Unfortunately, this
823	* wastes more memory compared to allocating the buffers separately.
824	*/
825	/ Determine how much memory we need /
826	mem_size = (PAGE_SIZE << get_order(PAACT_SIZE)) +
827	(PAGE_SIZE << get_order(SPAACT_SIZE)) +
828	(PAGE_SIZE << get_order(OMT_SIZE));
829	order = get_order(size: mem_size);
830
831	p = alloc_pages(GFP_KERNEL \| __GFP_ZERO, order);
832	if (!p) {
833	dev_err(dev, "unable to allocate PAACT/SPAACT/OMT block\n");
834	ret = -ENOMEM;
835	goto error;
836	}
837
838	ppaact = page_address(p);
839	ppaact_phys = page_to_phys(p);
840
841	/ Make sure the memory is naturally aligned /
842	if (ppaact_phys & ((PAGE_SIZE << order) - `1`)) {
843	dev_err(dev, "PAACT/OMT block is unaligned\n");
844	ret = -ENOMEM;
845	goto error;
846	}
847
848	spaact = (void *)ppaact + (PAGE_SIZE << get_order(PAACT_SIZE));
849	omt = (void *)spaact + (PAGE_SIZE << get_order(SPAACT_SIZE));
850
851	dev_dbg(dev, "ppaact virt=%p phys=%pa\n", ppaact, &ppaact_phys);
852
853	/ Check to see if we need to implement the work-around on this SOC /
854
855	/ Determine the Port ID for our coherence subdomain /
856	for (i = `0`; i < ARRAY_SIZE(port_id_map); i++) {
857	if (port_id_map[i].svr == (mfspr(SPRN_SVR) & ~SVR_SECURITY)) {
858	csd_port_id = port_id_map[i].port_id;
859	dev_dbg(dev, "found matching SVR %08x\n",
860	port_id_map[i].svr);
861	break;
862	}
863	}
864
865	if (csd_port_id) {
866	dev_dbg(dev, "creating coherency subdomain at address %pa, size %zu, port id 0x%08x",
867	&ppaact_phys, mem_size, csd_port_id);
868
869	ret = create_csd(phys: ppaact_phys, size: mem_size, csd_port_id);
870	if (ret) {
871	dev_err(dev, "could not create coherence subdomain\n");
872	goto error;
873	}
874	}
875
876	spaact_phys = virt_to_phys(address: spaact);
877	omt_phys = virt_to_phys(address: omt);
878
879	pamubypenr = in_be32(&guts_regs->pamubypenr);
880
881	for (pamu_reg_off = `0`, pamu_counter = `0x80000000`; pamu_reg_off < size;
882	pamu_reg_off += PAMU_OFFSET, pamu_counter >>= `1`) {
883
884	pamu_reg_base = (unsigned long)pamu_regs + pamu_reg_off;
885	setup_one_pamu(pamu_reg_base, pamu_reg_size: pamu_reg_off, ppaact_phys,
886	spaact_phys, omt_phys);
887	/ Disable PAMU bypass for this PAMU /
888	pamubypenr &= ~pamu_counter;
889	}
890
891	setup_omt(omt);
892
893	/ Enable all relevant PAMU(s) /
894	out_be32(&guts_regs->pamubypenr, pamubypenr);
895
896	iounmap(addr: guts_regs);
897
898	/ Enable DMA for the LIODNs in the device tree /
899
900	setup_liodns();
901
902	probed = true;
903
904	return `0`;
905
906	error:
907	if (irq)
908	free_irq(irq, data);
909
910	kfree_sensitive(objp: data);
911
912	if (pamu_regs)
913	iounmap(addr: pamu_regs);
914
915	if (guts_regs)
916	iounmap(addr: guts_regs);
917
918	if (ppaact)
919	free_pages(addr: (unsigned long)ppaact, order);
920
921	ppaact = NULL;
922
923	return ret;
924	}
925
926	static struct platform_driver fsl_of_pamu_driver = {
927	.driver = {
928	.name = "fsl-of-pamu",
929	},
930	.probe = fsl_pamu_probe,
931	};
932
933	static __init int fsl_pamu_init(void)
934	{
935	struct platform_device *pdev = NULL;
936	struct device_node *np;
937	int ret;
938
939	/*
940	* The normal OF process calls the probe function at some
941	* indeterminate later time, after most drivers have loaded. This is
942	* too late for us, because PAMU clients (like the Qman driver)
943	* depend on PAMU being initialized early.
944	*
945	* So instead, we "manually" call our probe function by creating the
946	* platform devices ourselves.
947	*/
948
949	/*
950	* We assume that there is only one PAMU node in the device tree. A
951	* single PAMU node represents all of the PAMU devices in the SOC
952	* already. Everything else already makes that assumption, and the
953	* binding for the PAMU nodes doesn't allow for any parent-child
954	* relationships anyway. In other words, support for more than one
955	* PAMU node would require significant changes to a lot of code.
956	*/
957
958	np = of_find_compatible_node(NULL, NULL, compat: "fsl,pamu");
959	if (!np) {
960	pr_err("could not find a PAMU node\n");
961	return -ENODEV;
962	}
963
964	ret = platform_driver_register(&fsl_of_pamu_driver);
965	if (ret) {
966	pr_err("could not register driver (err=%i)\n", ret);
967	goto error_driver_register;
968	}
969
970	pdev = platform_device_alloc(name: "fsl-of-pamu", id: `0`);
971	if (!pdev) {
972	pr_err("could not allocate device %pOF\n", np);
973	ret = -ENOMEM;
974	goto error_device_alloc;
975	}
976	pdev->dev.of_node = of_node_get(node: np);
977
978	ret = pamu_domain_init();
979	if (ret)
980	goto error_device_add;
981
982	ret = platform_device_add(pdev);
983	if (ret) {
984	pr_err("could not add device %pOF (err=%i)\n", np, ret);
985	goto error_device_add;
986	}
987
988	return `0`;
989
990	error_device_add:
991	of_node_put(node: pdev->dev.of_node);
992	pdev->dev.of_node = NULL;
993
994	platform_device_put(pdev);
995
996	error_device_alloc:
997	platform_driver_unregister(&fsl_of_pamu_driver);
998
999	error_driver_register:
1000	of_node_put(node: np);
1001
1002	return ret;
1003	}
1004	arch_initcall(fsl_pamu_init);
1005

source code of linux/drivers/iommu/fsl_pamu.c