encx24j600-regmap.c source code [linux/drivers/net/ethernet/microchip/encx24j600-regmap.c]

1	// SPDX-License-Identifier: GPL-2.0-only
2	/*
3	* Register map access API - ENCX24J600 support
4	*
5	* Copyright 2015 Gridpoint
6	*
7	* Author: Jon Ringle <jringle@gridpoint.com>
8	*/
9
10	#include <linux/delay.h>
11	#include <linux/errno.h>
12	#include <linux/init.h>
13	#include <linux/module.h>
14	#include <linux/netdevice.h>
15	#include <linux/regmap.h>
16	#include <linux/spi/spi.h>
17
18	#include "encx24j600_hw.h"
19
20	static int encx24j600_switch_bank(struct encx24j600_context *ctx,
21	int bank)
22	{
23	int ret = `0`;
24	int bank_opcode = BANK_SELECT(bank);
25
26	ret = spi_write(spi: ctx->spi, buf: &bank_opcode, len: `1`);
27	if (ret == `0`)
28	ctx->bank = bank;
29
30	return ret;
31	}
32
33	static int encx24j600_cmdn(struct encx24j600_context *ctx, u8 opcode,
34	const void *buf, size_t len)
35	{
36	struct spi_message m;
37	struct spi_transfer t[`2`] = { { .tx_buf = &opcode, .len = `1`, },
38	{ .tx_buf = buf, .len = len }, };
39	spi_message_init(m: &m);
40	spi_message_add_tail(t: &t[`0`], m: &m);
41	spi_message_add_tail(t: &t[`1`], m: &m);
42
43	return spi_sync(spi: ctx->spi, message: &m);
44	}
45
46	static void regmap_lock_mutex(void *context)
47	{
48	struct encx24j600_context *ctx = context;
49
50	mutex_lock(&ctx->mutex);
51	}
52
53	static void regmap_unlock_mutex(void *context)
54	{
55	struct encx24j600_context *ctx = context;
56
57	mutex_unlock(lock: &ctx->mutex);
58	}
59
60	static int regmap_encx24j600_sfr_read(void context, u8 reg, u8 val,
61	size_t len)
62	{
63	struct encx24j600_context *ctx = context;
64	u8 banked_reg = reg & ADDR_MASK;
65	u8 bank = ((reg & BANK_MASK) >> BANK_SHIFT);
66	u8 cmd = RCRU;
67	int ret = `0`;
68	int i = `0`;
69	u8 tx_buf[`2`];
70
71	if (reg < `0x80`) {
72	cmd = RCRCODE \| banked_reg;
73	if ((banked_reg < `0x16`) && (ctx->bank != bank))
74	ret = encx24j600_switch_bank(ctx, bank);
75	if (unlikely(ret))
76	return ret;
77	} else {
78	/ Translate registers that are more effecient using*
79	* 3-byte SPI commands
80	*/
81	switch (reg) {
82	case EGPRDPT:
83	cmd = RGPRDPT; break;
84	case EGPWRPT:
85	cmd = RGPWRPT; break;
86	case ERXRDPT:
87	cmd = RRXRDPT; break;
88	case ERXWRPT:
89	cmd = RRXWRPT; break;
90	case EUDARDPT:
91	cmd = RUDARDPT; break;
92	case EUDAWRPT:
93	cmd = RUDAWRPT; break;
94	case EGPDATA:
95	case ERXDATA:
96	case EUDADATA:
97	default:
98	return -EINVAL;
99	}
100	}
101
102	tx_buf[i++] = cmd;
103	if (cmd == RCRU)
104	tx_buf[i++] = reg;
105
106	ret = spi_write_then_read(spi: ctx->spi, txbuf: tx_buf, n_tx: i, rxbuf: val, n_rx: len);
107
108	return ret;
109	}
110
111	static int regmap_encx24j600_sfr_update(struct encx24j600_context *ctx,
112	u8 reg, u8 *val, size_t len,
113	u8 unbanked_cmd, u8 banked_code)
114	{
115	u8 banked_reg = reg & ADDR_MASK;
116	u8 bank = ((reg & BANK_MASK) >> BANK_SHIFT);
117	u8 cmd = unbanked_cmd;
118	struct spi_message m;
119	struct spi_transfer t[`3`] = { { .tx_buf = &cmd, .len = sizeof(cmd), },
120	{ .tx_buf = &reg, .len = sizeof(reg), },
121	{ .tx_buf = val, .len = len }, };
122
123	if (reg < `0x80`) {
124	int ret = `0`;
125
126	cmd = banked_code \| banked_reg;
127	if ((banked_reg < `0x16`) && (ctx->bank != bank))
128	ret = encx24j600_switch_bank(ctx, bank);
129	if (unlikely(ret))
130	return ret;
131	} else {
132	/ Translate registers that are more effecient using*
133	* 3-byte SPI commands
134	*/
135	switch (reg) {
136	case EGPRDPT:
137	cmd = WGPRDPT; break;
138	case EGPWRPT:
139	cmd = WGPWRPT; break;
140	case ERXRDPT:
141	cmd = WRXRDPT; break;
142	case ERXWRPT:
143	cmd = WRXWRPT; break;
144	case EUDARDPT:
145	cmd = WUDARDPT; break;
146	case EUDAWRPT:
147	cmd = WUDAWRPT; break;
148	case EGPDATA:
149	case ERXDATA:
150	case EUDADATA:
151	default:
152	return -EINVAL;
153	}
154	}
155
156	spi_message_init(m: &m);
157	spi_message_add_tail(t: &t[`0`], m: &m);
158
159	if (cmd == unbanked_cmd) {
160	t[`1`].tx_buf = ®
161	spi_message_add_tail(t: &t[`1`], m: &m);
162	}
163
164	spi_message_add_tail(t: &t[`2`], m: &m);
165	return spi_sync(spi: ctx->spi, message: &m);
166	}
167
168	static int regmap_encx24j600_sfr_write(void context, u8 reg, u8 val,
169	size_t len)
170	{
171	struct encx24j600_context *ctx = context;
172
173	return regmap_encx24j600_sfr_update(ctx, reg, val, len, WCRU, WCRCODE);
174	}
175
176	static int regmap_encx24j600_sfr_set_bits(struct encx24j600_context *ctx,
177	u8 reg, u8 val)
178	{
179	return regmap_encx24j600_sfr_update(ctx, reg, val: &val, len: `1`, BFSU, BFSCODE);
180	}
181
182	static int regmap_encx24j600_sfr_clr_bits(struct encx24j600_context *ctx,
183	u8 reg, u8 val)
184	{
185	return regmap_encx24j600_sfr_update(ctx, reg, val: &val, len: `1`, BFCU, BFCCODE);
186	}
187
188	static int regmap_encx24j600_reg_update_bits(void context, unsigned* int reg,
189	unsigned int mask,
190	unsigned int val)
191	{
192	struct encx24j600_context *ctx = context;
193
194	int ret = `0`;
195	unsigned int set_mask = mask & val;
196	unsigned int clr_mask = mask & ~val;
197
198	if ((reg >= `0x40` && reg < `0x6c`) \|\| reg >= `0x80`)
199	return -EINVAL;
200
201	if (set_mask & `0xff`)
202	ret = regmap_encx24j600_sfr_set_bits(ctx, reg, val: set_mask);
203
204	set_mask = (set_mask & `0xff00`) >> `8`;
205
206	if ((set_mask & `0xff`) && (ret == `0`))
207	ret = regmap_encx24j600_sfr_set_bits(ctx, reg: reg + `1`, val: set_mask);
208
209	if ((clr_mask & `0xff`) && (ret == `0`))
210	ret = regmap_encx24j600_sfr_clr_bits(ctx, reg, val: clr_mask);
211
212	clr_mask = (clr_mask & `0xff00`) >> `8`;
213
214	if ((clr_mask & `0xff`) && (ret == `0`))
215	ret = regmap_encx24j600_sfr_clr_bits(ctx, reg: reg + `1`, val: clr_mask);
216
217	return ret;
218	}
219
220	int regmap_encx24j600_spi_write(void context, u8 reg, const* u8 *data,
221	size_t count)
222	{
223	struct encx24j600_context *ctx = context;
224
225	if (reg < `0xc0`)
226	return encx24j600_cmdn(ctx, opcode: reg, buf: data, len: count);
227
228	/ SPI 1-byte command. Ignore data /
229	return spi_write(spi: ctx->spi, buf: &reg, len: `1`);
230	}
231	EXPORT_SYMBOL_GPL(regmap_encx24j600_spi_write);
232
233	int regmap_encx24j600_spi_read(void context, u8 reg, u8 data, size_t count)
234	{
235	struct encx24j600_context *ctx = context;
236
237	if (reg == RBSEL && count > `1`)
238	count = `1`;
239
240	return spi_write_then_read(spi: ctx->spi, txbuf: &reg, n_tx: sizeof(reg), rxbuf: data, n_rx: count);
241	}
242	EXPORT_SYMBOL_GPL(regmap_encx24j600_spi_read);
243
244	static int regmap_encx24j600_write(void context, const* void *data,
245	size_t len)
246	{
247	u8 dout = (u8 )data;
248	u8 reg = dout[`0`];
249	++dout;
250	--len;
251
252	if (reg > `0xa0`)
253	return regmap_encx24j600_spi_write(context, reg, dout, len);
254
255	if (len > `2`)
256	return -EINVAL;
257
258	return regmap_encx24j600_sfr_write(context, reg, val: dout, len);
259	}
260
261	static int regmap_encx24j600_read(void *context,
262	const void *reg_buf, size_t reg_size,
263	void *val, size_t val_size)
264	{
265	u8 reg = (const* u8 *)reg_buf;
266
267	if (reg_size != `1`) {
268	pr_err("%s: reg=%02x reg_size=%zu\n", __func__, reg, reg_size);
269	return -EINVAL;
270	}
271
272	if (reg > `0xa0`)
273	return regmap_encx24j600_spi_read(context, reg, val, val_size);
274
275	if (val_size > `2`) {
276	pr_err("%s: reg=%02x val_size=%zu\n", __func__, reg, val_size);
277	return -EINVAL;
278	}
279
280	return regmap_encx24j600_sfr_read(context, reg, val, len: val_size);
281	}
282
283	static bool encx24j600_regmap_readable(struct device dev, unsigned* int reg)
284	{
285	if ((reg < `0x36`) \|\|
286	((reg >= `0x40`) && (reg < `0x4c`)) \|\|
287	((reg >= `0x52`) && (reg < `0x56`)) \|\|
288	((reg >= `0x60`) && (reg < `0x66`)) \|\|
289	((reg >= `0x68`) && (reg < `0x80`)) \|\|
290	((reg >= `0x86`) && (reg < `0x92`)) \|\|
291	(reg == `0xc8`))
292	return true;
293	else
294	return false;
295	}
296
297	static bool encx24j600_regmap_writeable(struct device dev, unsigned* int reg)
298	{
299	if ((reg < `0x12`) \|\|
300	((reg >= `0x14`) && (reg < `0x1a`)) \|\|
301	((reg >= `0x1c`) && (reg < `0x36`)) \|\|
302	((reg >= `0x40`) && (reg < `0x4c`)) \|\|
303	((reg >= `0x52`) && (reg < `0x56`)) \|\|
304	((reg >= `0x60`) && (reg < `0x68`)) \|\|
305	((reg >= `0x6c`) && (reg < `0x80`)) \|\|
306	((reg >= `0x86`) && (reg < `0x92`)) \|\|
307	((reg >= `0xc0`) && (reg < `0xc8`)) \|\|
308	((reg >= `0xca`) && (reg < `0xf0`)))
309	return true;
310	else
311	return false;
312	}
313
314	static bool encx24j600_regmap_volatile(struct device dev, unsigned* int reg)
315	{
316	switch (reg) {
317	case ERXHEAD:
318	case EDMACS:
319	case ETXSTAT:
320	case ETXWIRE:
321	case ECON1: / Can be modified via single byte cmds /
322	case ECON2: / Can be modified via single byte cmds /
323	case ESTAT:
324	case EIR: / Can be modified via single byte cmds /
325	case MIRD:
326	case MISTAT:
327	return true;
328	default:
329	break;
330	}
331
332	return false;
333	}
334
335	static bool encx24j600_regmap_precious(struct device dev, unsigned* int reg)
336	{
337	/ single byte cmds are precious /
338	if (((reg >= `0xc0`) && (reg < `0xc8`)) \|\|
339	((reg >= `0xca`) && (reg < `0xf0`)))
340	return true;
341	else
342	return false;
343	}
344
345	static int regmap_encx24j600_phy_reg_read(void context, unsigned* int reg,
346	unsigned int *val)
347	{
348	struct encx24j600_context *ctx = context;
349	int ret;
350	unsigned int mistat;
351
352	reg = MIREGADR_VAL \| (reg & PHREG_MASK);
353	ret = regmap_write(map: ctx->regmap, MIREGADR, val: reg);
354	if (unlikely(ret))
355	goto err_out;
356
357	ret = regmap_write(map: ctx->regmap, MICMD, MIIRD);
358	if (unlikely(ret))
359	goto err_out;
360
361	usleep_range(min: `26`, max: `100`);
362	while (((ret = regmap_read(map: ctx->regmap, MISTAT, val: &mistat)) == `0`) &&
363	(mistat & BUSY))
364	cpu_relax();
365
366	if (unlikely(ret))
367	goto err_out;
368
369	ret = regmap_write(map: ctx->regmap, MICMD, val: `0`);
370	if (unlikely(ret))
371	goto err_out;
372
373	ret = regmap_read(map: ctx->regmap, MIRD, val);
374
375	err_out:
376	if (ret)
377	pr_err("%s: error %d reading reg %02x\n", __func__, ret,
378	reg & PHREG_MASK);
379
380	return ret;
381	}
382
383	static int regmap_encx24j600_phy_reg_write(void context, unsigned* int reg,
384	unsigned int val)
385	{
386	struct encx24j600_context *ctx = context;
387	int ret;
388	unsigned int mistat;
389
390	reg = MIREGADR_VAL \| (reg & PHREG_MASK);
391	ret = regmap_write(map: ctx->regmap, MIREGADR, val: reg);
392	if (unlikely(ret))
393	goto err_out;
394
395	ret = regmap_write(map: ctx->regmap, MIWR, val);
396	if (unlikely(ret))
397	goto err_out;
398
399	usleep_range(min: `26`, max: `100`);
400	while (((ret = regmap_read(map: ctx->regmap, MISTAT, val: &mistat)) == `0`) &&
401	(mistat & BUSY))
402	cpu_relax();
403
404	err_out:
405	if (ret)
406	pr_err("%s: error %d writing reg %02x=%04x\n", __func__, ret,
407	reg & PHREG_MASK, val);
408
409	return ret;
410	}
411
412	static bool encx24j600_phymap_readable(struct device dev, unsigned* int reg)
413	{
414	switch (reg) {
415	case PHCON1:
416	case PHSTAT1:
417	case PHANA:
418	case PHANLPA:
419	case PHANE:
420	case PHCON2:
421	case PHSTAT2:
422	case PHSTAT3:
423	return true;
424	default:
425	return false;
426	}
427	}
428
429	static bool encx24j600_phymap_writeable(struct device dev, unsigned* int reg)
430	{
431	switch (reg) {
432	case PHCON1:
433	case PHCON2:
434	case PHANA:
435	return true;
436	case PHSTAT1:
437	case PHSTAT2:
438	case PHSTAT3:
439	case PHANLPA:
440	case PHANE:
441	default:
442	return false;
443	}
444	}
445
446	static bool encx24j600_phymap_volatile(struct device dev, unsigned* int reg)
447	{
448	switch (reg) {
449	case PHSTAT1:
450	case PHSTAT2:
451	case PHSTAT3:
452	case PHANLPA:
453	case PHANE:
454	case PHCON2:
455	return true;
456	default:
457	return false;
458	}
459	}
460
461	static struct regmap_config regcfg = {
462	.name = "reg",
463	.reg_bits = `8`,
464	.val_bits = `16`,
465	.max_register = `0xee`,
466	.reg_stride = `2`,
467	.cache_type = REGCACHE_RBTREE,
468	.val_format_endian = REGMAP_ENDIAN_LITTLE,
469	.readable_reg = encx24j600_regmap_readable,
470	.writeable_reg = encx24j600_regmap_writeable,
471	.volatile_reg = encx24j600_regmap_volatile,
472	.precious_reg = encx24j600_regmap_precious,
473	.lock = regmap_lock_mutex,
474	.unlock = regmap_unlock_mutex,
475	};
476
477	static struct regmap_bus regmap_encx24j600 = {
478	.write = regmap_encx24j600_write,
479	.read = regmap_encx24j600_read,
480	.reg_update_bits = regmap_encx24j600_reg_update_bits,
481	};
482
483	static struct regmap_config phycfg = {
484	.name = "phy",
485	.reg_bits = `8`,
486	.val_bits = `16`,
487	.max_register = `0x1f`,
488	.cache_type = REGCACHE_RBTREE,
489	.val_format_endian = REGMAP_ENDIAN_LITTLE,
490	.readable_reg = encx24j600_phymap_readable,
491	.writeable_reg = encx24j600_phymap_writeable,
492	.volatile_reg = encx24j600_phymap_volatile,
493	};
494
495	static struct regmap_bus phymap_encx24j600 = {
496	.reg_write = regmap_encx24j600_phy_reg_write,
497	.reg_read = regmap_encx24j600_phy_reg_read,
498	};
499
500	int devm_regmap_init_encx24j600(struct device *dev,
501	struct encx24j600_context *ctx)
502	{
503	mutex_init(&ctx->mutex);
504	regcfg.lock_arg = ctx;
505	ctx->regmap = devm_regmap_init(dev, &regmap_encx24j600, ctx, &regcfg);
506	if (IS_ERR(ptr: ctx->regmap))
507	return PTR_ERR(ptr: ctx->regmap);
508	ctx->phymap = devm_regmap_init(dev, &phymap_encx24j600, ctx, &phycfg);
509	if (IS_ERR(ptr: ctx->phymap))
510	return PTR_ERR(ptr: ctx->phymap);
511
512	return `0`;
513	}
514	EXPORT_SYMBOL_GPL(devm_regmap_init_encx24j600);
515
516	MODULE_LICENSE("GPL");
517

source code of linux/drivers/net/ethernet/microchip/encx24j600-regmap.c