qed_hw.c source code [linux/drivers/net/ethernet/qlogic/qed/qed_hw.c]

1	// SPDX-License-Identifier: (GPL-2.0-only OR BSD-3-Clause)
2	/ QLogic qed NIC Driver*
3	* Copyright (c) 2015-2017 QLogic Corporation
4	* Copyright (c) 2019-2020 Marvell International Ltd.
5	*/
6
7	#include <linux/types.h>
8	#include <linux/io.h>
9	#include <linux/delay.h>
10	#include <linux/dma-mapping.h>
11	#include <linux/errno.h>
12	#include <linux/kernel.h>
13	#include <linux/list.h>
14	#include <linux/mutex.h>
15	#include <linux/pci.h>
16	#include <linux/slab.h>
17	#include <linux/spinlock.h>
18	#include <linux/string.h>
19	#include <linux/qed/qed_chain.h>
20	#include "qed.h"
21	#include "qed_hsi.h"
22	#include "qed_hw.h"
23	#include "qed_reg_addr.h"
24	#include "qed_sriov.h"
25
26	#define QED_BAR_ACQUIRE_TIMEOUT_USLEEP_CNT 1000
27	#define QED_BAR_ACQUIRE_TIMEOUT_USLEEP 1000
28	#define QED_BAR_ACQUIRE_TIMEOUT_UDELAY_CNT 100000
29	#define QED_BAR_ACQUIRE_TIMEOUT_UDELAY 10
30
31	/ Invalid values /
32	#define QED_BAR_INVALID_OFFSET (cpu_to_le32(-1))
33
34	struct qed_ptt {
35	struct list_head list_entry;
36	unsigned int idx;
37	struct pxp_ptt_entry pxp;
38	u8 hwfn_id;
39	};
40
41	struct qed_ptt_pool {
42	struct list_head free_list;
43	spinlock_t lock; / ptt synchronized access /
44	struct qed_ptt ptts[PXP_EXTERNAL_BAR_PF_WINDOW_NUM];
45	};
46
47	int qed_ptt_pool_alloc(struct qed_hwfn *p_hwfn)
48	{
49	struct qed_ptt_pool p_pool = kmalloc(size: sizeof(p_pool), GFP_KERNEL);
50	int i;
51
52	if (!p_pool)
53	return -ENOMEM;
54
55	INIT_LIST_HEAD(list: &p_pool->free_list);
56	for (i = `0`; i < PXP_EXTERNAL_BAR_PF_WINDOW_NUM; i++) {
57	p_pool->ptts[i].idx = i;
58	p_pool->ptts[i].pxp.offset = QED_BAR_INVALID_OFFSET;
59	p_pool->ptts[i].pxp.pretend.control = `0`;
60	p_pool->ptts[i].hwfn_id = p_hwfn->my_id;
61	if (i >= RESERVED_PTT_MAX)
62	list_add(new: &p_pool->ptts[i].list_entry,
63	head: &p_pool->free_list);
64	}
65
66	p_hwfn->p_ptt_pool = p_pool;
67	spin_lock_init(&p_pool->lock);
68
69	return `0`;
70	}
71
72	void qed_ptt_invalidate(struct qed_hwfn *p_hwfn)
73	{
74	struct qed_ptt *p_ptt;
75	int i;
76
77	for (i = `0`; i < PXP_EXTERNAL_BAR_PF_WINDOW_NUM; i++) {
78	p_ptt = &p_hwfn->p_ptt_pool->ptts[i];
79	p_ptt->pxp.offset = QED_BAR_INVALID_OFFSET;
80	}
81	}
82
83	void qed_ptt_pool_free(struct qed_hwfn *p_hwfn)
84	{
85	kfree(objp: p_hwfn->p_ptt_pool);
86	p_hwfn->p_ptt_pool = NULL;
87	}
88
89	struct qed_ptt qed_ptt_acquire(struct* qed_hwfn *p_hwfn)
90	{
91	return qed_ptt_acquire_context(p_hwfn, is_atomic: false);
92	}
93
94	struct qed_ptt qed_ptt_acquire_context(struct* qed_hwfn *p_hwfn, bool is_atomic)
95	{
96	struct qed_ptt *p_ptt;
97	unsigned int i, count;
98
99	if (is_atomic)
100	count = QED_BAR_ACQUIRE_TIMEOUT_UDELAY_CNT;
101	else
102	count = QED_BAR_ACQUIRE_TIMEOUT_USLEEP_CNT;
103
104	/ Take the free PTT from the list /
105	for (i = `0`; i < count; i++) {
106	spin_lock_bh(lock: &p_hwfn->p_ptt_pool->lock);
107
108	if (!list_empty(head: &p_hwfn->p_ptt_pool->free_list)) {
109	p_ptt = list_first_entry(&p_hwfn->p_ptt_pool->free_list,
110	struct qed_ptt, list_entry);
111	list_del(entry: &p_ptt->list_entry);
112
113	spin_unlock_bh(lock: &p_hwfn->p_ptt_pool->lock);
114
115	DP_VERBOSE(p_hwfn, NETIF_MSG_HW,
116	"allocated ptt %d\n", p_ptt->idx);
117	return p_ptt;
118	}
119
120	spin_unlock_bh(lock: &p_hwfn->p_ptt_pool->lock);
121
122	if (is_atomic)
123	udelay(QED_BAR_ACQUIRE_TIMEOUT_UDELAY);
124	else
125	usleep_range(QED_BAR_ACQUIRE_TIMEOUT_USLEEP,
126	QED_BAR_ACQUIRE_TIMEOUT_USLEEP * `2`);
127	}
128
129	DP_NOTICE(p_hwfn, "PTT acquire timeout - failed to allocate PTT\n");
130	return NULL;
131	}
132
133	void qed_ptt_release(struct qed_hwfn p_hwfn, struct* qed_ptt *p_ptt)
134	{
135	spin_lock_bh(lock: &p_hwfn->p_ptt_pool->lock);
136	list_add(new: &p_ptt->list_entry, head: &p_hwfn->p_ptt_pool->free_list);
137	spin_unlock_bh(lock: &p_hwfn->p_ptt_pool->lock);
138	}
139
140	u32 qed_ptt_get_hw_addr(struct qed_hwfn p_hwfn, struct* qed_ptt *p_ptt)
141	{
142	/ The HW is using DWORDS and we need to translate it to Bytes /
143	return le32_to_cpu(p_ptt->pxp.offset) << `2`;
144	}
145
146	static u32 qed_ptt_config_addr(struct qed_ptt *p_ptt)
147	{
148	return PXP_PF_WINDOW_ADMIN_PER_PF_START +
149	p_ptt->idx * sizeof(struct pxp_ptt_entry);
150	}
151
152	u32 qed_ptt_get_bar_addr(struct qed_ptt *p_ptt)
153	{
154	return PXP_EXTERNAL_BAR_PF_WINDOW_START +
155	p_ptt->idx * PXP_EXTERNAL_BAR_PF_WINDOW_SINGLE_SIZE;
156	}
157
158	void qed_ptt_set_win(struct qed_hwfn *p_hwfn,
159	struct qed_ptt *p_ptt, u32 new_hw_addr)
160	{
161	u32 prev_hw_addr;
162
163	prev_hw_addr = qed_ptt_get_hw_addr(p_hwfn, p_ptt);
164
165	if (new_hw_addr == prev_hw_addr)
166	return;
167
168	/ Update PTT entery in admin window /
169	DP_VERBOSE(p_hwfn, NETIF_MSG_HW,
170	"Updating PTT entry %d to offset 0x%x\n",
171	p_ptt->idx, new_hw_addr);
172
173	/ The HW is using DWORDS and the address is in Bytes /
174	p_ptt->pxp.offset = cpu_to_le32(new_hw_addr >> `2`);
175
176	REG_WR(p_hwfn,
177	qed_ptt_config_addr(p_ptt) +
178	offsetof(struct pxp_ptt_entry, offset),
179	le32_to_cpu(p_ptt->pxp.offset));
180	}
181
182	static u32 qed_set_ptt(struct qed_hwfn *p_hwfn,
183	struct qed_ptt *p_ptt, u32 hw_addr)
184	{
185	u32 win_hw_addr = qed_ptt_get_hw_addr(p_hwfn, p_ptt);
186	u32 offset;
187
188	offset = hw_addr - win_hw_addr;
189
190	if (p_ptt->hwfn_id != p_hwfn->my_id)
191	DP_NOTICE(p_hwfn,
192	"ptt[%d] of hwfn[%02x] is used by hwfn[%02x]!\n",
193	p_ptt->idx, p_ptt->hwfn_id, p_hwfn->my_id);
194
195	/ Verify the address is within the window /
196	if (hw_addr < win_hw_addr \|\|
197	offset >= PXP_EXTERNAL_BAR_PF_WINDOW_SINGLE_SIZE) {
198	qed_ptt_set_win(p_hwfn, p_ptt, new_hw_addr: hw_addr);
199	offset = `0`;
200	}
201
202	return qed_ptt_get_bar_addr(p_ptt) + offset;
203	}
204
205	struct qed_ptt qed_get_reserved_ptt(struct* qed_hwfn *p_hwfn,
206	enum reserved_ptts ptt_idx)
207	{
208	if (ptt_idx >= RESERVED_PTT_MAX) {
209	DP_NOTICE(p_hwfn,
210	"Requested PTT %d is out of range\n", ptt_idx);
211	return NULL;
212	}
213
214	return &p_hwfn->p_ptt_pool->ptts[ptt_idx];
215	}
216
217	void qed_wr(struct qed_hwfn *p_hwfn,
218	struct qed_ptt *p_ptt,
219	u32 hw_addr, u32 val)
220	{
221	u32 bar_addr = qed_set_ptt(p_hwfn, p_ptt, hw_addr);
222
223	REG_WR(p_hwfn, bar_addr, val);
224	DP_VERBOSE(p_hwfn, NETIF_MSG_HW,
225	"bar_addr 0x%x, hw_addr 0x%x, val 0x%x\n",
226	bar_addr, hw_addr, val);
227	}
228
229	u32 qed_rd(struct qed_hwfn *p_hwfn,
230	struct qed_ptt *p_ptt,
231	u32 hw_addr)
232	{
233	u32 bar_addr = qed_set_ptt(p_hwfn, p_ptt, hw_addr);
234	u32 val = REG_RD(p_hwfn, bar_addr);
235
236	DP_VERBOSE(p_hwfn, NETIF_MSG_HW,
237	"bar_addr 0x%x, hw_addr 0x%x, val 0x%x\n",
238	bar_addr, hw_addr, val);
239
240	return val;
241	}
242
243	static void qed_memcpy_hw(struct qed_hwfn *p_hwfn,
244	struct qed_ptt *p_ptt,
245	void *addr, u32 hw_addr, size_t n, bool to_device)
246	{
247	u32 dw_count, *host_addr, hw_offset;
248	size_t quota, done = `0`;
249	u32 __iomem *reg_addr;
250
251	while (done < n) {
252	quota = min_t(size_t, n - done,
253	PXP_EXTERNAL_BAR_PF_WINDOW_SINGLE_SIZE);
254
255	if (IS_PF(p_hwfn->cdev)) {
256	qed_ptt_set_win(p_hwfn, p_ptt, new_hw_addr: hw_addr + done);
257	hw_offset = qed_ptt_get_bar_addr(p_ptt);
258	} else {
259	hw_offset = hw_addr + done;
260	}
261
262	dw_count = quota / `4`;
263	host_addr = (u32 )((u8 )addr + done);
264	reg_addr = (u32 __iomem *)REG_ADDR(p_hwfn, hw_offset);
265	if (to_device)
266	while (dw_count--)
267	DIRECT_REG_WR(reg_addr++, *host_addr++);
268	else
269	while (dw_count--)
270	*host_addr++ = DIRECT_REG_RD(reg_addr++);
271
272	done += quota;
273	}
274	}
275
276	void qed_memcpy_from(struct qed_hwfn *p_hwfn,
277	struct qed_ptt p_ptt, void* *dest, u32 hw_addr, size_t n)
278	{
279	DP_VERBOSE(p_hwfn, NETIF_MSG_HW,
280	"hw_addr 0x%x, dest %p hw_addr 0x%x, size %lu\n",
281	hw_addr, dest, hw_addr, (unsigned long)n);
282
283	qed_memcpy_hw(p_hwfn, p_ptt, addr: dest, hw_addr, n, to_device: false);
284	}
285
286	void qed_memcpy_to(struct qed_hwfn *p_hwfn,
287	struct qed_ptt p_ptt, u32 hw_addr, void* *src, size_t n)
288	{
289	DP_VERBOSE(p_hwfn, NETIF_MSG_HW,
290	"hw_addr 0x%x, hw_addr 0x%x, src %p size %lu\n",
291	hw_addr, hw_addr, src, (unsigned long)n);
292
293	qed_memcpy_hw(p_hwfn, p_ptt, addr: src, hw_addr, n, to_device: true);
294	}
295
296	void qed_fid_pretend(struct qed_hwfn p_hwfn, struct* qed_ptt *p_ptt, u16 fid)
297	{
298	u16 control = `0`;
299
300	SET_FIELD(control, PXP_PRETEND_CMD_IS_CONCRETE, `1`);
301	SET_FIELD(control, PXP_PRETEND_CMD_PRETEND_FUNCTION, `1`);
302
303	/ Every pretend undos previous pretends, including*
304	* previous port pretend.
305	*/
306	SET_FIELD(control, PXP_PRETEND_CMD_PORT, `0`);
307	SET_FIELD(control, PXP_PRETEND_CMD_USE_PORT, `0`);
308	SET_FIELD(control, PXP_PRETEND_CMD_PRETEND_PORT, `1`);
309
310	if (!GET_FIELD(fid, PXP_CONCRETE_FID_VFVALID))
311	fid = GET_FIELD(fid, PXP_CONCRETE_FID_PFID);
312
313	p_ptt->pxp.pretend.control = cpu_to_le16(control);
314	p_ptt->pxp.pretend.fid.concrete_fid.fid = cpu_to_le16(fid);
315
316	REG_WR(p_hwfn,
317	qed_ptt_config_addr(p_ptt) +
318	offsetof(struct pxp_ptt_entry, pretend),
319	(u32 )&p_ptt->pxp.pretend);
320	}
321
322	void qed_port_pretend(struct qed_hwfn *p_hwfn,
323	struct qed_ptt *p_ptt, u8 port_id)
324	{
325	u16 control = `0`;
326
327	SET_FIELD(control, PXP_PRETEND_CMD_PORT, port_id);
328	SET_FIELD(control, PXP_PRETEND_CMD_USE_PORT, `1`);
329	SET_FIELD(control, PXP_PRETEND_CMD_PRETEND_PORT, `1`);
330
331	p_ptt->pxp.pretend.control = cpu_to_le16(control);
332
333	REG_WR(p_hwfn,
334	qed_ptt_config_addr(p_ptt) +
335	offsetof(struct pxp_ptt_entry, pretend),
336	(u32 )&p_ptt->pxp.pretend);
337	}
338
339	void qed_port_unpretend(struct qed_hwfn p_hwfn, struct* qed_ptt *p_ptt)
340	{
341	u16 control = `0`;
342
343	SET_FIELD(control, PXP_PRETEND_CMD_PORT, `0`);
344	SET_FIELD(control, PXP_PRETEND_CMD_USE_PORT, `0`);
345	SET_FIELD(control, PXP_PRETEND_CMD_PRETEND_PORT, `1`);
346
347	p_ptt->pxp.pretend.control = cpu_to_le16(control);
348
349	REG_WR(p_hwfn,
350	qed_ptt_config_addr(p_ptt) +
351	offsetof(struct pxp_ptt_entry, pretend),
352	(u32 )&p_ptt->pxp.pretend);
353	}
354
355	void qed_port_fid_pretend(struct qed_hwfn *p_hwfn,
356	struct qed_ptt *p_ptt, u8 port_id, u16 fid)
357	{
358	u16 control = `0`;
359
360	SET_FIELD(control, PXP_PRETEND_CMD_PORT, port_id);
361	SET_FIELD(control, PXP_PRETEND_CMD_USE_PORT, `1`);
362	SET_FIELD(control, PXP_PRETEND_CMD_PRETEND_PORT, `1`);
363	SET_FIELD(control, PXP_PRETEND_CMD_IS_CONCRETE, `1`);
364	SET_FIELD(control, PXP_PRETEND_CMD_PRETEND_FUNCTION, `1`);
365	if (!GET_FIELD(fid, PXP_CONCRETE_FID_VFVALID))
366	fid = GET_FIELD(fid, PXP_CONCRETE_FID_PFID);
367	p_ptt->pxp.pretend.control = cpu_to_le16(control);
368	p_ptt->pxp.pretend.fid.concrete_fid.fid = cpu_to_le16(fid);
369	REG_WR(p_hwfn,
370	qed_ptt_config_addr(p_ptt) +
371	offsetof(struct pxp_ptt_entry, pretend),
372	(u32 )&p_ptt->pxp.pretend);
373	}
374
375	u32 qed_vfid_to_concrete(struct qed_hwfn *p_hwfn, u8 vfid)
376	{
377	u32 concrete_fid = `0`;
378
379	SET_FIELD(concrete_fid, PXP_CONCRETE_FID_PFID, p_hwfn->rel_pf_id);
380	SET_FIELD(concrete_fid, PXP_CONCRETE_FID_VFID, vfid);
381	SET_FIELD(concrete_fid, PXP_CONCRETE_FID_VFVALID, `1`);
382
383	return concrete_fid;
384	}
385
386	/ DMAE /
387	#define QED_DMAE_FLAGS_IS_SET(params, flag) \
388	((params) != NULL && GET_FIELD((params)->flags, QED_DMAE_PARAMS_##flag))
389
390	static void qed_dmae_opcode(struct qed_hwfn *p_hwfn,
391	const u8 is_src_type_grc,
392	const u8 is_dst_type_grc,
393	struct qed_dmae_params *p_params)
394	{
395	u8 src_pfid, dst_pfid, port_id;
396	u16 opcode_b = `0`;
397	u32 opcode = `0`;
398
399	/ Whether the source is the PCIe or the GRC.*
400	* 0- The source is the PCIe
401	* 1- The source is the GRC.
402	*/
403	SET_FIELD(opcode, DMAE_CMD_SRC,
404	(is_src_type_grc ? dmae_cmd_src_grc : dmae_cmd_src_pcie));
405	src_pfid = QED_DMAE_FLAGS_IS_SET(p_params, SRC_PF_VALID) ?
406	p_params->src_pfid : p_hwfn->rel_pf_id;
407	SET_FIELD(opcode, DMAE_CMD_SRC_PF_ID, src_pfid);
408
409	/ The destination of the DMA can be: 0-None 1-PCIe 2-GRC 3-None /
410	SET_FIELD(opcode, DMAE_CMD_DST,
411	(is_dst_type_grc ? dmae_cmd_dst_grc : dmae_cmd_dst_pcie));
412	dst_pfid = QED_DMAE_FLAGS_IS_SET(p_params, DST_PF_VALID) ?
413	p_params->dst_pfid : p_hwfn->rel_pf_id;
414	SET_FIELD(opcode, DMAE_CMD_DST_PF_ID, dst_pfid);
415
416
417	/ Whether to write a completion word to the completion destination:*
418	* 0-Do not write a completion word
419	* 1-Write the completion word
420	*/
421	SET_FIELD(opcode, DMAE_CMD_COMP_WORD_EN, `1`);
422	SET_FIELD(opcode, DMAE_CMD_SRC_ADDR_RESET, `1`);
423
424	if (QED_DMAE_FLAGS_IS_SET(p_params, COMPLETION_DST))
425	SET_FIELD(opcode, DMAE_CMD_COMP_FUNC, `1`);
426
427	/ swapping mode 3 - big endian /
428	SET_FIELD(opcode, DMAE_CMD_ENDIANITY_MODE, DMAE_CMD_ENDIANITY);
429
430	port_id = (QED_DMAE_FLAGS_IS_SET(p_params, PORT_VALID)) ?
431	p_params->port_id : p_hwfn->port_id;
432	SET_FIELD(opcode, DMAE_CMD_PORT_ID, port_id);
433
434	/ reset source address in next go /
435	SET_FIELD(opcode, DMAE_CMD_SRC_ADDR_RESET, `1`);
436
437	/ reset dest address in next go /
438	SET_FIELD(opcode, DMAE_CMD_DST_ADDR_RESET, `1`);
439
440	/ SRC/DST VFID: all 1's - pf, otherwise VF id /
441	if (QED_DMAE_FLAGS_IS_SET(p_params, SRC_VF_VALID)) {
442	SET_FIELD(opcode, DMAE_CMD_SRC_VF_ID_VALID, `1`);
443	SET_FIELD(opcode_b, DMAE_CMD_SRC_VF_ID, p_params->src_vfid);
444	} else {
445	SET_FIELD(opcode_b, DMAE_CMD_SRC_VF_ID, `0xFF`);
446	}
447	if (QED_DMAE_FLAGS_IS_SET(p_params, DST_VF_VALID)) {
448	SET_FIELD(opcode, DMAE_CMD_DST_VF_ID_VALID, `1`);
449	SET_FIELD(opcode_b, DMAE_CMD_DST_VF_ID, p_params->dst_vfid);
450	} else {
451	SET_FIELD(opcode_b, DMAE_CMD_DST_VF_ID, `0xFF`);
452	}
453
454	p_hwfn->dmae_info.p_dmae_cmd->opcode = cpu_to_le32(opcode);
455	p_hwfn->dmae_info.p_dmae_cmd->opcode_b = cpu_to_le16(opcode_b);
456	}
457
458	u32 qed_dmae_idx_to_go_cmd(u8 idx)
459	{
460	/ All the DMAE 'go' registers form an array in internal memory /
461	return DMAE_REG_GO_C0 + (idx << `2`);
462	}
463
464	static int qed_dmae_post_command(struct qed_hwfn *p_hwfn,
465	struct qed_ptt *p_ptt)
466	{
467	struct dmae_cmd *p_command = p_hwfn->dmae_info.p_dmae_cmd;
468	u8 idx_cmd = p_hwfn->dmae_info.channel, i;
469	int qed_status = `0`;
470
471	/ verify address is not NULL /
472	if ((((!p_command->dst_addr_lo) && (!p_command->dst_addr_hi)) \|\|
473	((!p_command->src_addr_lo) && (!p_command->src_addr_hi)))) {
474	DP_NOTICE(p_hwfn,
475	"source or destination address 0 idx_cmd=%d\n"
476	"opcode = [0x%08x,0x%04x] len=0x%x src=0x%x:%x dst=0x%x:%x\n",
477	idx_cmd,
478	le32_to_cpu(p_command->opcode),
479	le16_to_cpu(p_command->opcode_b),
480	le16_to_cpu(p_command->length_dw),
481	le32_to_cpu(p_command->src_addr_hi),
482	le32_to_cpu(p_command->src_addr_lo),
483	le32_to_cpu(p_command->dst_addr_hi),
484	le32_to_cpu(p_command->dst_addr_lo));
485
486	return -EINVAL;
487	}
488
489	DP_VERBOSE(p_hwfn,
490	NETIF_MSG_HW,
491	"Posting DMAE command [idx %d]: opcode = [0x%08x,0x%04x] len=0x%x src=0x%x:%x dst=0x%x:%x\n",
492	idx_cmd,
493	le32_to_cpu(p_command->opcode),
494	le16_to_cpu(p_command->opcode_b),
495	le16_to_cpu(p_command->length_dw),
496	le32_to_cpu(p_command->src_addr_hi),
497	le32_to_cpu(p_command->src_addr_lo),
498	le32_to_cpu(p_command->dst_addr_hi),
499	le32_to_cpu(p_command->dst_addr_lo));
500
501	/ Copy the command to DMAE - need to do it before every call*
502	* for source/dest address no reset.
503	* The first 9 DWs are the command registers, the 10 DW is the
504	* GO register, and the rest are result registers
505	* (which are read only by the client).
506	*/
507	for (i = `0`; i < DMAE_CMD_SIZE; i++) {
508	u32 data = (i < DMAE_CMD_SIZE_TO_FILL) ?
509	(((u32 )p_command) + i) : `0`;
510
511	qed_wr(p_hwfn, p_ptt,
512	DMAE_REG_CMD_MEM +
513	(idx_cmd * DMAE_CMD_SIZE * sizeof(u32)) +
514	(i * sizeof(u32)), val: data);
515	}
516
517	qed_wr(p_hwfn, p_ptt, hw_addr: qed_dmae_idx_to_go_cmd(idx: idx_cmd), DMAE_GO_VALUE);
518
519	return qed_status;
520	}
521
522	int qed_dmae_info_alloc(struct qed_hwfn *p_hwfn)
523	{
524	dma_addr_t *p_addr = &p_hwfn->dmae_info.completion_word_phys_addr;
525	struct dmae_cmd **p_cmd = &p_hwfn->dmae_info.p_dmae_cmd;
526	u32 **p_buff = &p_hwfn->dmae_info.p_intermediate_buffer;
527	u32 **p_comp = &p_hwfn->dmae_info.p_completion_word;
528
529	*p_comp = dma_alloc_coherent(dev: &p_hwfn->cdev->pdev->dev,
530	size: sizeof(u32), dma_handle: p_addr, GFP_KERNEL);
531	if (!*p_comp)
532	goto err;
533
534	p_addr = &p_hwfn->dmae_info.dmae_cmd_phys_addr;
535	*p_cmd = dma_alloc_coherent(dev: &p_hwfn->cdev->pdev->dev,
536	size: sizeof(struct dmae_cmd),
537	dma_handle: p_addr, GFP_KERNEL);
538	if (!*p_cmd)
539	goto err;
540
541	p_addr = &p_hwfn->dmae_info.intermediate_buffer_phys_addr;
542	*p_buff = dma_alloc_coherent(dev: &p_hwfn->cdev->pdev->dev,
543	size: sizeof(u32) * DMAE_MAX_RW_SIZE,
544	dma_handle: p_addr, GFP_KERNEL);
545	if (!*p_buff)
546	goto err;
547
548	p_hwfn->dmae_info.channel = p_hwfn->rel_pf_id;
549
550	return `0`;
551	err:
552	qed_dmae_info_free(p_hwfn);
553	return -ENOMEM;
554	}
555
556	void qed_dmae_info_free(struct qed_hwfn *p_hwfn)
557	{
558	dma_addr_t p_phys;
559
560	/ Just make sure no one is in the middle /
561	mutex_lock(&p_hwfn->dmae_info.mutex);
562
563	if (p_hwfn->dmae_info.p_completion_word) {
564	p_phys = p_hwfn->dmae_info.completion_word_phys_addr;
565	dma_free_coherent(dev: &p_hwfn->cdev->pdev->dev,
566	size: sizeof(u32),
567	cpu_addr: p_hwfn->dmae_info.p_completion_word, dma_handle: p_phys);
568	p_hwfn->dmae_info.p_completion_word = NULL;
569	}
570
571	if (p_hwfn->dmae_info.p_dmae_cmd) {
572	p_phys = p_hwfn->dmae_info.dmae_cmd_phys_addr;
573	dma_free_coherent(dev: &p_hwfn->cdev->pdev->dev,
574	size: sizeof(struct dmae_cmd),
575	cpu_addr: p_hwfn->dmae_info.p_dmae_cmd, dma_handle: p_phys);
576	p_hwfn->dmae_info.p_dmae_cmd = NULL;
577	}
578
579	if (p_hwfn->dmae_info.p_intermediate_buffer) {
580	p_phys = p_hwfn->dmae_info.intermediate_buffer_phys_addr;
581	dma_free_coherent(dev: &p_hwfn->cdev->pdev->dev,
582	size: sizeof(u32) * DMAE_MAX_RW_SIZE,
583	cpu_addr: p_hwfn->dmae_info.p_intermediate_buffer,
584	dma_handle: p_phys);
585	p_hwfn->dmae_info.p_intermediate_buffer = NULL;
586	}
587
588	mutex_unlock(lock: &p_hwfn->dmae_info.mutex);
589	}
590
591	static int qed_dmae_operation_wait(struct qed_hwfn *p_hwfn)
592	{
593	u32 wait_cnt_limit = `10000`, wait_cnt = `0`;
594	int qed_status = `0`;
595
596	barrier();
597	while (*p_hwfn->dmae_info.p_completion_word != DMAE_COMPLETION_VAL) {
598	udelay(DMAE_MIN_WAIT_TIME);
599	if (++wait_cnt > wait_cnt_limit) {
600	DP_NOTICE(p_hwfn->cdev,
601	"Timed-out waiting for operation to complete. Completion word is 0x%08x expected 0x%08x.\n",
602	*p_hwfn->dmae_info.p_completion_word,
603	DMAE_COMPLETION_VAL);
604	qed_status = -EBUSY;
605	break;
606	}
607
608	/ to sync the completion_word since we are not*
609	* using the volatile keyword for p_completion_word
610	*/
611	barrier();
612	}
613
614	if (qed_status == `0`)
615	*p_hwfn->dmae_info.p_completion_word = `0`;
616
617	return qed_status;
618	}
619
620	static int qed_dmae_execute_sub_operation(struct qed_hwfn *p_hwfn,
621	struct qed_ptt *p_ptt,
622	u64 src_addr,
623	u64 dst_addr,
624	u8 src_type,
625	u8 dst_type,
626	u32 length_dw)
627	{
628	dma_addr_t phys = p_hwfn->dmae_info.intermediate_buffer_phys_addr;
629	struct dmae_cmd *cmd = p_hwfn->dmae_info.p_dmae_cmd;
630	int qed_status = `0`;
631
632	switch (src_type) {
633	case QED_DMAE_ADDRESS_GRC:
634	case QED_DMAE_ADDRESS_HOST_PHYS:
635	cmd->src_addr_hi = cpu_to_le32(upper_32_bits(src_addr));
636	cmd->src_addr_lo = cpu_to_le32(lower_32_bits(src_addr));
637	break;
638	/ for virtual source addresses we use the intermediate buffer. /
639	case QED_DMAE_ADDRESS_HOST_VIRT:
640	cmd->src_addr_hi = cpu_to_le32(upper_32_bits(phys));
641	cmd->src_addr_lo = cpu_to_le32(lower_32_bits(phys));
642	memcpy(&p_hwfn->dmae_info.p_intermediate_buffer[`0`],
643	(void *)(uintptr_t)src_addr,
644	length_dw * sizeof(u32));
645	break;
646	default:
647	return -EINVAL;
648	}
649
650	switch (dst_type) {
651	case QED_DMAE_ADDRESS_GRC:
652	case QED_DMAE_ADDRESS_HOST_PHYS:
653	cmd->dst_addr_hi = cpu_to_le32(upper_32_bits(dst_addr));
654	cmd->dst_addr_lo = cpu_to_le32(lower_32_bits(dst_addr));
655	break;
656	/ for virtual source addresses we use the intermediate buffer. /
657	case QED_DMAE_ADDRESS_HOST_VIRT:
658	cmd->dst_addr_hi = cpu_to_le32(upper_32_bits(phys));
659	cmd->dst_addr_lo = cpu_to_le32(lower_32_bits(phys));
660	break;
661	default:
662	return -EINVAL;
663	}
664
665	cmd->length_dw = cpu_to_le16((u16)length_dw);
666
667	qed_dmae_post_command(p_hwfn, p_ptt);
668
669	qed_status = qed_dmae_operation_wait(p_hwfn);
670
671	if (qed_status) {
672	DP_NOTICE(p_hwfn,
673	"qed_dmae_host2grc: Wait Failed. source_addr 0x%llx, grc_addr 0x%llx, size_in_dwords 0x%x\n",
674	src_addr, dst_addr, length_dw);
675	return qed_status;
676	}
677
678	if (dst_type == QED_DMAE_ADDRESS_HOST_VIRT)
679	memcpy((void *)(uintptr_t)(dst_addr),
680	&p_hwfn->dmae_info.p_intermediate_buffer[`0`],
681	length_dw * sizeof(u32));
682
683	return `0`;
684	}
685
686	static int qed_dmae_execute_command(struct qed_hwfn *p_hwfn,
687	struct qed_ptt *p_ptt,
688	u64 src_addr, u64 dst_addr,
689	u8 src_type, u8 dst_type,
690	u32 size_in_dwords,
691	struct qed_dmae_params *p_params)
692	{
693	dma_addr_t phys = p_hwfn->dmae_info.completion_word_phys_addr;
694	u16 length_cur = `0`, i = `0`, cnt_split = `0`, length_mod = `0`;
695	struct dmae_cmd *cmd = p_hwfn->dmae_info.p_dmae_cmd;
696	u64 src_addr_split = `0`, dst_addr_split = `0`;
697	u16 length_limit = DMAE_MAX_RW_SIZE;
698	int qed_status = `0`;
699	u32 offset = `0`;
700
701	if (p_hwfn->cdev->recov_in_prog) {
702	DP_VERBOSE(p_hwfn,
703	NETIF_MSG_HW,
704	"Recovery is in progress. Avoid DMAE transaction [{src: addr 0x%llx, type %d}, {dst: addr 0x%llx, type %d}, size %d].\n",
705	src_addr, src_type, dst_addr, dst_type,
706	size_in_dwords);
707
708	/ Let the flow complete w/o any error handling /
709	return `0`;
710	}
711
712	qed_dmae_opcode(p_hwfn,
713	is_src_type_grc: (src_type == QED_DMAE_ADDRESS_GRC),
714	is_dst_type_grc: (dst_type == QED_DMAE_ADDRESS_GRC),
715	p_params);
716
717	cmd->comp_addr_lo = cpu_to_le32(lower_32_bits(phys));
718	cmd->comp_addr_hi = cpu_to_le32(upper_32_bits(phys));
719	cmd->comp_val = cpu_to_le32(DMAE_COMPLETION_VAL);
720
721	/ Check if the grc_addr is valid like < MAX_GRC_OFFSET /
722	cnt_split = size_in_dwords / length_limit;
723	length_mod = size_in_dwords % length_limit;
724
725	src_addr_split = src_addr;
726	dst_addr_split = dst_addr;
727
728	for (i = `0`; i <= cnt_split; i++) {
729	offset = length_limit * i;
730
731	if (!QED_DMAE_FLAGS_IS_SET(p_params, RW_REPL_SRC)) {
732	if (src_type == QED_DMAE_ADDRESS_GRC)
733	src_addr_split = src_addr + offset;
734	else
735	src_addr_split = src_addr + (offset * `4`);
736	}
737
738	if (dst_type == QED_DMAE_ADDRESS_GRC)
739	dst_addr_split = dst_addr + offset;
740	else
741	dst_addr_split = dst_addr + (offset * `4`);
742
743	length_cur = (cnt_split == i) ? length_mod : length_limit;
744
745	/ might be zero on last iteration /
746	if (!length_cur)
747	continue;
748
749	qed_status = qed_dmae_execute_sub_operation(p_hwfn,
750	p_ptt,
751	src_addr: src_addr_split,
752	dst_addr: dst_addr_split,
753	src_type,
754	dst_type,
755	length_dw: length_cur);
756	if (qed_status) {
757	qed_hw_err_notify(p_hwfn, p_ptt, err_type: QED_HW_ERR_DMAE_FAIL,
758	fmt: "qed_dmae_execute_sub_operation Failed with error 0x%x. source_addr 0x%llx, destination addr 0x%llx, size_in_dwords 0x%x\n",
759	qed_status, src_addr,
760	dst_addr, length_cur);
761	break;
762	}
763	}
764
765	return qed_status;
766	}
767
768	int qed_dmae_host2grc(struct qed_hwfn *p_hwfn,
769	struct qed_ptt *p_ptt,
770	u64 source_addr, u32 grc_addr, u32 size_in_dwords,
771	struct qed_dmae_params *p_params)
772	{
773	u32 grc_addr_in_dw = grc_addr / sizeof(u32);
774	int rc;
775
776
777	mutex_lock(&p_hwfn->dmae_info.mutex);
778
779	rc = qed_dmae_execute_command(p_hwfn, p_ptt, src_addr: source_addr,
780	dst_addr: grc_addr_in_dw,
781	src_type: QED_DMAE_ADDRESS_HOST_VIRT,
782	dst_type: QED_DMAE_ADDRESS_GRC,
783	size_in_dwords, p_params);
784
785	mutex_unlock(lock: &p_hwfn->dmae_info.mutex);
786
787	return rc;
788	}
789
790	int qed_dmae_grc2host(struct qed_hwfn *p_hwfn,
791	struct qed_ptt *p_ptt,
792	u32 grc_addr,
793	dma_addr_t dest_addr, u32 size_in_dwords,
794	struct qed_dmae_params *p_params)
795	{
796	u32 grc_addr_in_dw = grc_addr / sizeof(u32);
797	int rc;
798
799
800	mutex_lock(&p_hwfn->dmae_info.mutex);
801
802	rc = qed_dmae_execute_command(p_hwfn, p_ptt, src_addr: grc_addr_in_dw,
803	dst_addr: dest_addr, src_type: QED_DMAE_ADDRESS_GRC,
804	dst_type: QED_DMAE_ADDRESS_HOST_VIRT,
805	size_in_dwords, p_params);
806
807	mutex_unlock(lock: &p_hwfn->dmae_info.mutex);
808
809	return rc;
810	}
811
812	int qed_dmae_host2host(struct qed_hwfn *p_hwfn,
813	struct qed_ptt *p_ptt,
814	dma_addr_t source_addr,
815	dma_addr_t dest_addr,
816	u32 size_in_dwords, struct qed_dmae_params *p_params)
817	{
818	int rc;
819
820	mutex_lock(&(p_hwfn->dmae_info.mutex));
821
822	rc = qed_dmae_execute_command(p_hwfn, p_ptt, src_addr: source_addr,
823	dst_addr: dest_addr,
824	src_type: QED_DMAE_ADDRESS_HOST_PHYS,
825	dst_type: QED_DMAE_ADDRESS_HOST_PHYS,
826	size_in_dwords, p_params);
827
828	mutex_unlock(lock: &(p_hwfn->dmae_info.mutex));
829
830	return rc;
831	}
832
833	void qed_hw_err_notify(struct qed_hwfn p_hwfn, struct* qed_ptt *p_ptt,
834	enum qed_hw_err_type err_type, const char *fmt, ...)
835	{
836	char buf[QED_HW_ERR_MAX_STR_SIZE];
837	va_list vl;
838	int len;
839
840	if (fmt) {
841	va_start(vl, fmt);
842	len = vsnprintf(buf, QED_HW_ERR_MAX_STR_SIZE, fmt, args: vl);
843	va_end(vl);
844
845	if (len > QED_HW_ERR_MAX_STR_SIZE - `1`)
846	len = QED_HW_ERR_MAX_STR_SIZE - `1`;
847
848	DP_NOTICE(p_hwfn, "%s", buf);
849	}
850
851	/ Fan failure cannot be masked by handling of another HW error /
852	if (p_hwfn->cdev->recov_in_prog &&
853	err_type != QED_HW_ERR_FAN_FAIL) {
854	DP_VERBOSE(p_hwfn,
855	NETIF_MSG_DRV,
856	"Recovery is in progress. Avoid notifying about HW error %d.\n",
857	err_type);
858	return;
859	}
860
861	qed_hw_error_occurred(p_hwfn, err_type);
862
863	if (fmt)
864	qed_mcp_send_raw_debug_data(p_hwfn, p_ptt, p_buf: buf, size: len);
865	}
866
867	int qed_dmae_sanity(struct qed_hwfn *p_hwfn,
868	struct qed_ptt p_ptt, const* char *phase)
869	{
870	u32 size = PAGE_SIZE / `2`, val;
871	int rc = `0`;
872	dma_addr_t p_phys;
873	void *p_virt;
874	u32 *p_tmp;
875
876	p_virt = dma_alloc_coherent(dev: &p_hwfn->cdev->pdev->dev,
877	size: `2` * size, dma_handle: &p_phys, GFP_KERNEL);
878	if (!p_virt) {
879	DP_NOTICE(p_hwfn,
880	"DMAE sanity [%s]: failed to allocate memory\n",
881	phase);
882	return -ENOMEM;
883	}
884
885	/ Fill the bottom half of the allocated memory with a known pattern /
886	for (p_tmp = (u32 *)p_virt;
887	p_tmp < (u32 )((u8 )p_virt + size); p_tmp++) {
888	/ Save the address itself as the value /
889	val = (u32)(uintptr_t)p_tmp;
890	*p_tmp = val;
891	}
892
893	/ Zero the top half of the allocated memory /
894	memset((u8 *)p_virt + size, `0`, size);
895
896	DP_VERBOSE(p_hwfn,
897	QED_MSG_SP,
898	"DMAE sanity [%s]: src_addr={phys 0x%llx, virt %p}, dst_addr={phys 0x%llx, virt %p}, size 0x%x\n",
899	phase,
900	(u64)p_phys,
901	p_virt, (u64)(p_phys + size), (u8 *)p_virt + size, size);
902
903	rc = qed_dmae_host2host(p_hwfn, p_ptt, source_addr: p_phys, dest_addr: p_phys + size,
904	size_in_dwords: size / `4`, NULL);
905	if (rc) {
906	DP_NOTICE(p_hwfn,
907	"DMAE sanity [%s]: qed_dmae_host2host() failed. rc = %d.\n",
908	phase, rc);
909	goto out;
910	}
911
912	/ Verify that the top half of the allocated memory has the pattern /
913	for (p_tmp = (u32 )((u8 )p_virt + size);
914	p_tmp < (u32 )((u8 )p_virt + (`2` * size)); p_tmp++) {
915	/ The corresponding address in the bottom half /
916	val = (u32)(uintptr_t)p_tmp - size;
917
918	if (*p_tmp != val) {
919	DP_NOTICE(p_hwfn,
920	"DMAE sanity [%s]: addr={phys 0x%llx, virt %p}, read_val 0x%08x, expected_val 0x%08x\n",
921	phase,
922	(u64)p_phys + ((u8 )p_tmp - (u8 )p_virt),
923	p_tmp, *p_tmp, val);
924	rc = -EINVAL;
925	goto out;
926	}
927	}
928
929	out:
930	dma_free_coherent(dev: &p_hwfn->cdev->pdev->dev, size: `2` * size, cpu_addr: p_virt, dma_handle: p_phys);
931	return rc;
932	}
933

source code of linux/drivers/net/ethernet/qlogic/qed/qed_hw.c